Franklin, WI 53132 - caleffi.com · Franklin, WI 53132 T: 414.421.1000 F: 414.421.2878 Dear...
Transcript of Franklin, WI 53132 - caleffi.com · Franklin, WI 53132 T: 414.421.1000 F: 414.421.2878 Dear...
Caleffi North America, Inc. 9850 South 54th Street Franklin, WI 53132 T: 414.421.1000 F: 414.421.2878
Dear Hydronic Professional,
Welcome to the 2nd edition of idronics – Caleffi’s semi-annual design journal for hydronic professionals.
The 1st edition of idronics was released in January 2007 and distributed to over 80,000 people in North America. It focused on the topic hydraulic separation. From the feedback received, it’s evident we attained our goal of explaining the benefits and proper application of this modern design technique for hydronic systems.
If you haven’t yet received a copy of idronics #1, you can do so by sending in the attached reader response card, or by registering online at www.caleffi.us. The publication will be mailed to you free of charge. You can also download the complete journal as a PDF file from our Web site.
This second edition addresses air and dirt in hydronic systems. Though not a new topic to our industry, the use of modern high-efficiency equipment demands a thorough understanding of the harmful effects of air and dirt, as well as knowledge on how to eliminate them. Doing so helps ensure the systems you design will operate at peak efficiency and provide long trouble-free service.
We trust you will find this issue of idronics a useful educational tool and a handy reference for your future hydronic system designs. We also encourage you to send us feedback on this issue of idronics using the attached reader response card or by e-mailing us at [email protected].
Sincerely,
Mark Olson General Manager,Caleffi North America, Inc.
A Technical Journalfrom
Caleffi Hydronic Solutions
CALEFFI NORTH AMERICA, INC3883 W. Milwaukee Rd
Milwaukee, Wisconsin 53208 USA
Tel: 414-238-2360FAX: 414-238-2366
E-mail: idronics@caleffi .comWebsite: www.caleffi .us
To receive future idronics issues FREE, register online www.caleffi .us
Dear Hydronic and Plumbing Professional,
Twelve years after Caleffi North America was established, air issues, dirt issues and hydraulic separation issues continue to be frequent topics in the technical support calls we receive. Some of these calls are from contractors trying to correct problems in existing systems. Others are from designers looking for the best way to apply our products in a new system. Some callers simply ask: “Can you explain how this device works?”
These calls confirm that an understanding of air & dirt separation, as well as hydraulic separation, is critically important to those who design, install or maintain hydronic systems. Those who comprehend these topics well are more capable of creating and maintaining the modern, energy-efficient systems today’s marketplace demands.
This 15th edition of idronics combines the topics discussed in our 1st and 2nd issues from 2007, and updates those topics to reflect several new products now available from Caleffi. Some of these new products combine the functions previously performed by single components. Others expand the range of application from residential jobs through large commercial systems that provide heating and cooling.
From time to time, we receive photos showing installations of Caleffi products. We sincerely appreciate these submittals. They help us show and explain the best way to apply and install specific products. This issue includes several such photos. We sincerely thank all those who have sent us these photos and encourage you to continue sharing them with us.
We hope you enjoy this issue and encourage you to send us any feedback about idronics by e-mailing us at [email protected].
For prior issues, please visit us at www.caleffi.us and click on the icon. There you can download the PDF files. You can also register to receive hard copies of future issues.
© Copyright 2014
Caleffi North America, Inc.
Printed: Milwaukee, Wisconsin USA
INDEX
Disclaimer: Caleffi makes no warranty that the information presented in idronics meets the mechanical, electrical or other code requirements applicable within a given jurisdiction. The diagrams presented in idronics are conceptual, and do not represent complete schematics for any specifi c installation. Local codes may require differences in design, or safety devices relative to those shown in idronics. It is the responsibility of those adapting any information presented in idronics to verify that such adaptations meet or exceed local code requirements.
Mark Olson
General Manager & CEO
Mixed SourcesProducts from well-managedforests, controlled sources andrecycled wood or fiber.
3
To “separate” means to disconnect or segregate. The word separate has several meanings in the context of hydronic heating or cooling systems. This issue of idronics examines three distinctly different forms of separation within such systems. They are:
1. Air separation2. Dirt separation3. Hydraulic separation
All of these are desirable characteristics that exist in well-planned hydronic systems.
The ideal fluid in a hydronic heating or cooling system is water without any impurities, air bubbles or dissolved gases such as oxygen and nitrogen. However, every hydronic system starts out with air in all of its components. A well-planned system will quickly enable this air to be gathered and removed from the system. It will also reduce the dissolved air gases in the water to levels where they are of no concern. The system should then maintain the water at a very low level of dissolved air content over its entire life. Any small amounts of air that may enter the system during component maintenance should be quickly captured and ejected.
A newly assembled hydronic system usually contains dirt or remnants of oils used during manufacturing, transportation or installation. It may also contain pieces of joint sealing tape, rubber particles or ferrous metal particles. The latter is common when cast iron or steel components such as circulators, panel radiators or cast iron sectional boilers are used in the system.
Dirt or metal particles are undesirable in hydronic systems. Fine particles of dirt can interfere with the operation of moving parts within valves or circulators. They can also coat the internal surfaces of both heat sources and heat emitters, decreasing rates of heat transfer. Metal particles such as iron oxides can collect in circulators due to the magnetic fields they create. All well-planned and properly commissioned hydronic systems should contain very
little dirt. What dirt the system does contain should be captured and removed. The state-of-the-art dirt separators discussed in this issue of idronics can remove particles as small as 5 microns in diameter.
Many hydronic systems contain multiple circulators, some of which need to operate at the same time. Ideally, the operation of any one of these circulators will not create any change in the flow or head produced by any other circulator in the system that also happens to be operating. When this is achieved, the circulators are said to be hydraulically separated from each other.
There are several methods by which hydraulic separation can be achieved. This issue of idronics discusses each of them, along with their strengths and limitations.
For many applications, it makes sense to combine the three fundamental forms of separation into a single device. In other applications, or for retrofit situations, this may not be possible or practical.
A thorough understanding of the principles involved in each type of separation equips designers to select the best products and installation locations for the system at hand. This issue of idronics was written to provide this understanding.
Air control within hydronic systems has always presented challenges. It began with the earliest hydronic systems that did not have circulators. Water flow was created by the buoyancy difference between hot water in the boiler and cooler water returning from the heat emitters. These systems used large-diameter piping and operated at very low flow velocities. Air removal was mostly a matter of waiting for air pockets to form and then releasing this air through manually operated valves located at high points in the system where the air accumulated.
Most of these early systems were “open-loop” rather than closed-loop systems. An expansion tank vented to the atmosphere was located at the high point of the
Separation in Hydronic Systems
4
system—usually in the attic or upper floor, as seen in Figure 2-1, which appeared in a heating design manual published in 1906.
Although air could leave this tank as the water in the system was heated and expanded, it could also reenter the tank as the water cooled. This allowed a constant presence of dissolved oxygen molecules within the water, which often sustained oxygen-based corrosion within these systems constructed of iron and steel piping.
Occupants in buildings got used to “bleeding” the air from the system when its presence caused a drop in heat output or an annoying noises in the system.
During the 1940s, engineers began designing closed-loop hydronic systems. They created devices to help capture air and separate it from the circulating water. A system of this vintage typically used a standard expansion tank that was supported above the boiler, as shown in Figure 2-2.
"open" expansion tank at top of system
To!expansion!
tank
dip
tube
from!boiler
boiler!Þtting
air bubbles
water!to!
system
wat
er to
sys
tem
Courtesy of Bell & Gossett
Figure 2-1
Figure 2-2
5
Air bubbles rising from the boiler were captured by a special “boiler fitting,” and directed through a pipe to the expansion tank. Another special “tank fitting” was used to minimize the absorption of air within the expansion tank into the system water. The overall process is best described as air control rather than air elimination. Although some of these systems are still in operation, they do not represent modern technology. Very few systems are now installed using this approach.
Even when closed-loop hydronic systems became standard, industry veterans can attest that air elimination, especially during system commissioning, often remained a challenge. Significant time went into ridding systems of air, especially in large, complex piping systems. Keeping the air out of those systems also required frequent attention.
This is partially because closed-loop hydronic systems are not 100% sealed against air entry. Although such systems appear to hold pressure reasonably well for months, and seldom have visible water leaks, they are not perfectly sealed. Small amounts of the gases that make up air can enter closed-loop hydronic systems in a variety of ways, especially if those systems are poorly designed. Examples include air weepage at valve packings and circulator flange gaskets, as well as molecular oxygen diffusion directly through the walls of non-barrier PEX or other types of polymer tubing. Air can even be sucked into hydronic circuits through devices intended to expel it. This occurs when improper design, improper component placement or maintenance allow the pressure in the piping where the devices are located to drop below atmospheric pressure.
Problems due to air in hydronic systems can be frustrating to occupants as well as heating professionals. If these problems are not fully understood, the attempted solution often produces only temporary correction. Eventually, those trying to remedy the situation may give up, thinking that the system is incapable of operating air-free. This is unfortunate and unnecessary, because every properly designed modern hydronic system can quickly rid itself of air and maintain itself essentially air-free for years.
The following problems can arise due to air in hydronic systems:
occupants
circulators
transfer surfaces are not wetted
ferrous metals
in flow
air pockets
One benefit provided by a properly designed and installed hydronic system is the near-silent conveyance of heat. Building occupants should not hear water as it travels through tubing and heat emitters. Properly deaerated water traveling through piping at velocities of 4 feet per second or less produces sound levels that are virtually undetectable by human ears. However, a mixture of water and air is much more acoustically active.
Figure 2-3
Figure 2-4
6
Entrapped air sounds often become noticeable as flow begins to disturb stationary air pockets. Air-filled cavities within piping and radiators act as acoustic amplifying chambers, especially if water enters a component which has trapped a large pocket of air. Noise is also generated when dissolved gases within water are released due to a sudden drop in pressure. This is called gaseous cavitation, and it often occurs at the orifice of valves or the inlet of circulators.
Circulator impellers are designed to transfer mechanical energy called “head” to incompressible liquids. A mixture of water and air is not an incompressible liquid. Although most circulators can maintain flow when the liquid passing through contains some entrained air, mechanical energy transfer is not as efficient as when the liquid is fully deaerated. This decreases circulator efficiency and reduces the rate of heat conveyance by the system. Noise is also present as a mixture of liquid and air bubbles pass through a circulator.
Air has much lower heat transfer properties than water. A given volume of water can absorb almost 3500 times more heat than the same volume of air. When air displaces water away from heat transfer surfaces within heat sources or heat emitters, the rate of heat transfer can be significantly reduced. “Cool spots” on radiators usually indicate entrapped air, as shown in Figure 2-5.
Air is about 23% oxygen, and oxygen in contact with ferrous metals such as steel and cast iron causes corrosion. Many improperly deaerated
hydronic systems that experience chronic air problems are constantly allowing air to enter the system. This resupplies oxygen that furthers the corrosion reaction. Poorly deaerated hydronic systems can fail prematurely due to such corrosion. Corrosion of internal surfaces can lead to leakage in thin steel components such as panel radiators or expansion tank shells. Corrosion on other surfaces can eventually break off as ferrous oxide particles that can be carried throughout the system and possibly become trapped in components such as circulators or heat exchangers.
The following chemical reactions can occur in hydronic systems containing ferrous (iron-containing) components.
The compound Fe3O4 is called magnetite and appears as a dark gray sludge within the system. Magnetite is also attracted to magnetic fields created by circulators, especially those containing powerful permanent magnets. Circulator manufacturers have developed improved methods of forestalling magnetite or other ferrous metal particles from reaching the rotating inner parts of their circulators, but the potential for some magnetite entry into such parts still exists.
If oxygen continues to be present in the system, magnetite will be converted to hematite (Fe2O3), which can cause pitting corrosion throughout the system.
O2 + Fe+ 2H2O Fe(OH )2 + H2OXYGEN IRON IONS WATER
FERROUSHYDROXIDE HYDROGEN
3Fe(OH )2 Fe3O4 + H2 + H2OFERROUS
HYDROXIDE MAGNETITE HYDROGEN WATER
FeFF 3O4MAGNETITE
FFFFFFFFFFFFFFFFFFF OOOOOOOOOOOOOOOOOOOFFFFFFFFFFFFFFFFFFFF OOOOOOOOOOOOOOOOOOOFFFFFFFFFFFFFFFFFFeeFeFeeFeFeeeeee OOOOOOOOOOOOOOOOOOOFFFFFFFFFFFFFFFFFFeeFeFeeFeFeeeeee OOOOOOOOOOOOOOOOOOOFFFFFFFFFFFFFFFFFFeeFeFFeeFeFee3eeee333333OOOOOOOOOOOOOOOO44OO44O44444FFFFFFFFFFFFFFFeeeeFeFe3eeee333333OOOOOOOOOOOOO44OO44O444443333333 44444444433333 44444444MMMAAMMAAM GGAAGGA NNENNNN TTEETTE TTTTITT EETTEETMAMMAAM GAAGGA NNNNN TEETTE TTTITT ETTEET
Figure 2-5
Figure 2-6
7
Figure 2-7 shows a pipe and circulator with accumulated iron oxide sludge. Consider the effect such accumulation would have on flow rate.
Modern wet-rotor circulators have ceramic bushings that depend on system water for lubrication. Due to its lower density, air tends to accumulate near the pump shaft and these bushings. The presence of air bubbles or air pockets can displace lubricating water and hence create premature bushing failure. The likely result is replacement of the entire circulator.
Circulators installed in vertical piping with upward flow and having spring-loaded check valves near their discharge are especially susceptible to large pockets
Courtesy of Tony Hillard
Courtesy of Heatboy
spring-loadedinternal check
valve trapsrising air in volute
dissolved gases released from solutioncreate gaseous cavitation within circulator
Figure 2-7a
Figure 2-7b
Figure 2-8
Figure 2-9
8
of air. If a sufficient volume of air enters the volute and displaces water in the impeller, the circulator may be unable to clear itself and will quickly be running without lubrication. Failure is almost certain.
Gaseous cavitation occurs within circulators when the pressure at the eye of the impeller drops below the saturation pressure of gases such as oxygen or nitrogen in solution with the water. The dissolved gas molecules instantly form bubbles that interfere with circulator performance, as depicted in Figure 2-9.
Sediments formed by oxidation within the system can be deposited on the impeller and volute of circulators, lowering their performance or causing total blockage (see Figure 2-6).
Hydronic balancing valves are precision devices designed to perform within tight specifications when conveying liquids. The presence of air in the water changes the pressure drop versus flow rate characteristics of the valves, allowing flow rates to drift away from desired settings. This in turn can lead to improper heat delivery in various portions of the system. Highly throttled balancing valves can also experience gaseous cavitation when water with a high dissolved air content passes through them. Such cavitation can lead to annoying noises, especially in valves located within or near occupied spaces.
If a stationary air pocket is large enough, and the piping system is tall enough, the system’s circulator cannot generate sufficient lift to force water over the top of the system. Under such circumstances, there will be complete loss of flow in the circuit. Even if the circulator can establish some flow over the top of the system, that flow may not be sufficient to entrain air and help dislodge the air pocket.
Air exists in three distinct forms within hydronic systems:
Every hydronic system is completely filled with air at the start of its commissioning. As water enters the lower portions of the system, air rises upward. However, some components or improper piping configurations may not allow all the air initially contained in the system to rise to the top where an air venting device may be present. This results in trapped air pockets. These pockets
can form at the top of heat emitters, boiler sections, unvented tanks, inverted diaphragm-type expansion tanks or heat exchangers. Air pockets can also form in horizontal piping that eventually turns downward or piping that is routed above obstacles in its path, as shown in Figure 2-10.
As water enters the system, these locations can trap air, especially if water approaches them from both directions. Slow water movement during the filling process also enhances air pocket formation.
Stationary air pockets can also reform when air bubbles merge and migrate toward high points. This is especially likely in components with low flow velocities, where slow-moving fluid is unable to push or drag the air along with it. Examples of such components include large heat emitters, large diameter piping and storage tanks.
A moving fluid may be able to carry air bubbles along with the flow (e.g., entrain them). This is desirable from the standpoint of moving air bubbles from remote parts of the system back to a central air-separating device, where they can be captured and expelled. However, if the fluid’s flow velocity through the air-separating device is too high, the entrained air cannot be efficiently separated and could end up passing through the separator many times.
The ability of a fluid to entrain air can be judged by its ability to move bubbles vertically downward, against their natural tendency to rise. If the fluid moves downward faster than a bubble can rise, it will pull the bubble along. A minimum flow velocity of 2 feet per second is needed to entrain air bubbles within downward-flowing pipes.
air pocketFigure 2-10
9
Air can also exist in hydronic systems as microbubbles. Individually, most microbubbles are too small to be seen by the human eye. However, dense collections of microbubbles can make otherwise clear water appear cloudy. A common place to see temporary clouds of microbubbles is in a drinking glass just filled with water from a faucet having an aerator device. Figure 2-11 shows a visually enhanced microscopic view of microbubbles.
In hydronic systems, microbubbles form when water with dissolved gases such as oxygen and nitrogen is heated in a boiler or other heat source. In chilled-water cooling systems, it is possible for microbubbles to form within terminal units as the water absorbs heat under low water pressure conditions. They can also form when water passes through a component that creates a sudden and significant pressure drop, such as a valve that is almost closed.
Microbubbles have extremely low rise velocities and are easily entrained by moving fluids. This characteristic makes them more difficult to capture compared to larger bubbles. Some hydronic systems, especially older systems, have air-separating devices that do not provide sufficiently low flow velocities or suitable internal detailing to allow efficient microbubble separation. While larger bubbles are more easily captured due to their greater rise velocities, microbubbles are often swept through older style air-separating devices without being captured. The result can be a system that takes days, or sometimes weeks, to reduce its air content to acceptable levels.
Molecules of the gases that make up air (nitrogen, oxygen, carbon dioxide and some other compounds) can exist “in solution” with water molecules. Since molecules are too small to be seen, water that appears perfectly clear and free of bubbles can still contain a significant amount of dissolved gases that ultimately need to be removed from the system.
The amount of dissolved gases that water can hold depends on the water’s temperature and pressure. At higher temperatures, the ability of water to contain dissolved gases decreases, and vice versa. As the pressure of the water increases, so does its ability to hold dissolved gases in solution.
The contours in Figure 2-12 show the maximum amount of dissolved air gases contained in water over a range of temperatures and pressures (expressed as a percentage of total volume). For example, at 15 psi gauge pressure and a temperature of 65ºF, up to 3.6% of the molecules in a container of water can be dissolved gases (oxygen, nitrogen and other trace gases). However, if the water’s temperature is raised to 170ºF while maintaining the same pressure, its ability to hold dissolved gas is reduced to 1.8% of its volume, half the previous level. Such a change in temperature would be typical of cold water heated within a boiler and illustrates the “degassing” effect of increased temperature.
Source: www.urmc.rochester.edu
Max
am
ount
in g
allo
ns o
f dis
solv
ed a
ir pe
r 100
gal
lons
of w
ater
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
0 psi
15 psi
30 psi 45 psi 60 psi 75 psi 90 psi 105 psi
Gauge pressure
Water temperature ( )
32 65 100 135 170 205 240 275 310 345
Figure 2-11
Figure 2-12
10
As the pressure of the water is lowered, so is its ability to hold dissolved gases in solution. Figure 2-12 shows that reducing the pressure of 170ºF water from 15 to 0 psi gauge pressure reduces the amount of dissolved gas it can contain from 1.8% to about 0.6% of its volume. This explains why air bubbles are more likely to form in the upper portions of a multi-story hydronic system. Lower static pressure in the upper portions of the building makes it easier for dissolved air to come out of solution. Higher static pressure near the bottom of the system tends to keep gases in solution.
Temperature also affects the solubility of dissolved gases in water. Figure 2-13 shows a simple piping system with representative temperatures and gauge pressures at four locations.
The graph to the right of the piping schematic shows the combination of temperature and gauge pressures at these four locations. Notice that point A is the lowest of the four points, and thus represents the lowest solubility of air in water of the four locations. The lower the solubility, the more likely microbubbles are present; thus point A is the preferred location for the Caleffi Discal air separator.
Water can repeatedly absorb and release gases as its temperature and/or pressure changes. This can affect hydronic systems in several ways—some good and some not so good.
For example, the ability of water to absorb air as it cools helps reduce the volume of stationary pockets in areas of the system where flow is slow. This absorbed air can be carried back to a high-efficiency separating device where it is then captured and ejected from the system. The ability of water to absorb air can also cause an undesirable condition called “water logging” in older style expansion tanks without diaphragms or bladders.
It’s always desirable to minimize the dissolved air content of the system’s water. This is accomplished by establishing conditions that encourage dissolved gases to come out of solution (e.g., high temperatures and low pressures), and placing an effective air separating device at a location where such conditions occur.
Most air removal devices used in hydronic systems can be classified as either:
1. High-point vents 2. Central air separators
High-point vents release air from one or more high points in the system where it tends to accumulate. Typical locations for high-point vents are the top of each heat emitter, the top of distribution risers, the top of tanks or hydraulic separators, or wherever piping turns downward following an upward or horizontal run. Figure 2-14 shows some examples.
Max
am
ount
in g
allo
ns o
f dis
solv
ed a
ir pe
r 100
gal
lons
of w
ater
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
0 psi
15 psi
30 psi 45 psi 60 psi 75 psi 90 psi 105 psi
Gauge pressure
Water temperature ( )
32 65 100 135 170 205 240 275 310 345
low head loss boiler
170ºF
20 psi
169.9ºF32 psi
18 psi
143ºF
19.8 psi
135ºF
Discal airseparator
ON
A
B C
DVENT
NOTE: pressures shown onpiping are gauge pressures
A
BC
D
location of lowest air solubility in water
Figure 2-13
11
A central air separator is used to remove entrained air from a flowing fluid, as well as to maintain the system at the lowest possible air content.
The simplest type of high-point venting device is a manual air vent. These components are essentially small valves that thread into 1/8-inch or 1/4-inch FPT tappings, and are operated with a screwdriver or square head key. When opened, air moves through the valve seat and exits through a small side opening.
Manual air vents are commonly installed at the top of each heat emitter. An example of a manual air vent installed at the top of a panel radiator is shown in Figure 2-15. Such vents are opened to release air that rises to the high point as fluid enters lower in the system. When the fluid level reaches the manual air vent, a small stream of water will flow out the side of the vent. A small piece of flexible tubing can be used to guide this stream into a can or pail. It’s important to capture this water and not allow it to stain carpets or otherwise damage surrounding materials. When a steady stream of water has been flowing from the vent for several seconds, it should be closed. After air has been removed from the system, be sure to check that the system has adequate static water pressure.
Manual air vents can also be mounted on a special fitting called a baseboard tee, an example of which is shown in Figure 2-16a. These
TRV
TRV
buffer tank
hydraulicseparator
air vent
manifoldstation
pip
ing
riser
s
solar
colle
ctor a
rray
manual air vent
manual air vent
manualair vent
air vent air vent
air vent
air vent
Figure 2-14
Figure 2-15a
Figure 2-15b
12
fittings resemble a 90º elbow, but with an extra port having either 1/8” or 1/4” FPT threads. They are typically installed at high points where piping changes from vertical to horizontal. Their name comes from a common application in which they are mounted on the outlet of a fin-tube element within a baseboard convector, as seen in Figure 2-16b.
HyGROSCOpIC AIR veNTS:Another type of small high-point venting device is called a hygroscopic air vent. An example of such a device is shown in Figure 2-17a. Figure 2-17b shows this device installed at the top of a cast iron radiator.
Hygroscopic air vents contain a special cellulose fiber disc that, when dry, allows air to pass through it and exit the vent. When moisture reaches the disc, it expands very quickly to stop further flow from the device. The location and thickness of the fiber disc is illustrated in Figure 2-18.
Hygroscopic air vents can be used in either automatic or manual mode. When the knob is opened one turn from its fully closed position, as shown in Figure 2-19a, it operates the same as a manual air vent. Any pressurized air at the base of the vent exits through a small hole at the side of the vent’s brass body.
When the knob is fully closed, an internal O-ring seals off the side port. However, if air is present at the vent, the fiber discs will dry and allow air to pass through them. This air is discharged under the vent’s knob, as shown in Figure 2-19b. Once the air has been vented and water reaches the fiber discs, they swell very quickly to seal off any further discharge.
Minerals or sediment in the system water can interfere with the operation of the internal hygroscopic disc. It is generally recommended that these discs be replaced every three years. Caleffi hygroscopic air vents contain an internal spring-loaded check valve that closes whenever the upper portion of the vent body is removed, such as when changing the fiber discs. This is illustrated in Figure 2-19c.
Although hygroscopic air vents are automatic, they can be manually opened and are therefore not recommended in locations where tampering is possible. A float-type air vent is a preferred choice in such locations.
air vent
baseboard tee
Þnned-tube baseboard element
ßow
internal disc
(DRY)
internal disc
(WET)
hygroscopic!air vent
Figure 2-16a Figure 2-16b
Figure 2-17a Figure 2-17b
Figure 2-18
13
A float-type air vent provides fully automatic air release and instantaneous response to the presence of water. An example of such a device is shown in Figure 2-20.
It contains an air chamber, a float assembly and an air valve. As air accumulates within the chamber, the float descends. A linkage attached to the float eventually opens the valve mechanism at the top of the unit. As air is released, water flows into the chamber and lifts the float to close the valve. Some Caleffi float-type vents are equipped with hygroscopic caps that seal the vent from water leakage, and thus provide secondary leak protection if the vent’s internal valve mechanism does not operate properly.
Most float-type air vents are equipped with a cap that protects the valve mechanism from debris. It’s important
that this cap is loosened when the vent is put into operation. If the cap is fully closed, the vent cannot operate. Caleffi vents can be equipped with Caleffi-specific “anti-siphon” caps that prevent airflow into the vent if the pressure at the vent location drops below atmospheric pressure.
Float-type air vents are available in different sizes and shapes. Compact designs allow mounting within the enclosures of heat emitters, such as fin-tube convectors or fan-coils. Larger “high-capacity” vents are available for use at the top of central air separators, storage tanks, or other locations where high-volume air venting is needed.
It’s important to remember that some float-type air vents can also allow air to enter the system if the system pressure at their installed location drops below atmospheric pressure. This can happen as a result of improper placement of the expansion tank relative to the circulator. It can also be caused by low static pressure in the system. Caleffi anti-siphon vent caps are designed to prevent this intake of air.
It’s good practice to design and commission all closed-loop hydronic systems so there is at least 5 psi of positive static pressure at the top of the system. This ensures that float-type vents will always be able to expel any air that accumulates.
It’s also important to verify that the pressure rating of float-type air vents is suitable for the conditions and locations where they will be located in the system. Hydronic systems that have piping installed over several building stories can generate high static pressure in the lower portions of the system, where such vents may be located at the top of tanks, heat exchangers, hydraulic separators, boilers or other devices.
cap, (sealed when closed)
spring-loaded stemvalve seat & O-ring
linkageair
water
inlet
air outlet ports
Figure 2-19a Figure 2-19b
Figure 2-20a Figure 2-20b
Figure 2-19c
14
The ability to maintain very low air levels within a closed-loop hydronic system is vital to quiet, efficient and reliable operation. The key component in providing this function is a central air separator. Such devices can be categorized as either air purgers or microbubble air separators.
Figure 2-21a shows an example of a cast iron air purger. These relatively simple devices encourage well-formed air bubbles to rise into a collection chamber and then pass out through a float-type air vent at the top of that chamber. They rely heavily on the buoyancy of well-formed bubbles as the means of separation. To achieve proper operation, the velocity of the flow stream entering the separator must be kept below 4 feet per second. Lower velocities increase
the air removal efficiency of these devices, albeit at the cost of larger and more expensive hardware. Air purgers are not designed to capture microbubbles, and as such, cannot lower the dissolved air content of the system as well as separators specifically designed for this purpose. A cutaway illustration of a typical air purger is shown in Figure 2-21b.
Due to their small size and low buoyancy, microbubbles are more difficult to capture relative to well-formed bubbles or large air pockets. Doing so requires surfaces upon which microbubbles can cling and eventually merge into larger bubbles. This process is called coalescence and is critically important to attaining and maintaining minimum air levels in hydronic systems.
capair discharge valve
Figure 2-21a Figure 2-21b
Figure 2-22a Figure 2-22b
15
As microbubbles coalesce together, they form larger bubbles. Eventually, the bubbles attain a volume large enough that buoyancy forces overcome the adhesion forces holding them to the coalescing surface. The bubbles then rise along the coalescing surfaces to a chamber above the main flow stream where they can be collected and expelled through a float-type air vent. The concept of coalescence inside such a separator is illustrated in Figure 2-22b.
The surface on which microbubbles coalesce is called the “coalescing media.” Some microbubble air separators use metal meshes for this media, while others use special polymers. In either case, the coalescing media must provide high surface contact area, enhancement of vertical bubble movement and a relatively low pressure drop.
Central air separators work best when located where the solubility of dissolved gases within the system water is lowest. In heating systems, they should be mounted near the outlet of the heat source (see Figure 2-23). In cooling systems, they should be mounted on the inlet side of the chiller (e.g., where water temperatures are warmer).
In some situations, it is convenient to use a central air separator that can mount in a
vertical pipe. Figure 2-24 shows an example of such an application. Notice how the air separator placement allows flow through it during space-heating as well as domestic water-heating operating modes. The greater the number of times system water passes through the heat source and central air separator, the better the latter device can “scrub” dissolved gases from the water and expel them.
The ability of a microbubble air separator to lower the water’s dissolved gas content allows that water to absorb air back into solution as it cools. A common example of this is water cooling within piping and heat emitters during an off-cycle. Think of this cooling water as a “sponge” that soaks up molecules of air gases with which it comes in contact. Since these molecules are pulled into and held in solution under these conditions, they will eventually be carried back to the heat source when flow resumes. Upon heating, they will be released from solution as microbubbles and captured by the microbubble air separator. This process is ongoing and can eventually bring the dissolved air content of the water to approximately 0.4% of system volume. In this state, the water can provide efficient and virtually silent conveyance of heat, and its very low oxygen content discourages corrosion.
VENT
microbubbleair separator(vertical)
VENT
microbubbleair separator(horizontal)
chiller
microbubbleair separator(vertical mount)
DHW
circ
ulat
or
heat
ing
circ
ulat
or
Indirect domesticwater heater
to / from space heating
system
boiler
VENT
Figure 2-23
Figure 2-24
16
There are some situations in which it is not desirable to eject air from a closed-loop hydronic system. Instead, the air in the system needs to be maintained in part of the system.
A closed-loop solar thermal system using drainback freeze protection is one such situation. Consider the closed-loop, drainback protection solar combisystem shown in Figure 2-25.
For drainback freeze protection to work, there must be air in the collectors and any exposed piping whenever the collector circulator is off. Total air elimination, as previously discussed, would defeat the purpose of drainback freeze protection. However, the air in the collectors and upper portion of the storage tank should not be allowed to find its way into the distribution system where it could potentially cause problems such as noise, poor circulator performance or trapped air pockets. Thus, the air in the system must be “managed.”
Air management maintains the internal air volume in its proper location within the system. In the system shown in Figure 2-25, any air that is captured by the microbubble air separator is returned to the air-filled portion of the system rather than being ejected from the system. This allows the pressurized closed-loop system to maintain its initial pressurization, since air is not being expelled from it. Likewise, when the collector circulator turns off, air from the top of the tank moves back through the air return tube, and then up into the collector array. At the same time, water within the collector array and exposed piping flows back down to the tank. No air is ejected from the system.
Notice that there is no automatic makeup water assembly on this system. Such an assembly, if present, would eventually allow the system to fill with water should there be an air leak at any point.
Also note that there is no expansion tank in this system. The captive air volume at the top of the storage tank, if properly sized, provides the volume needed to accommodate the expansion volume of the system’s water and serve as the drainback space.
ThermoCon tank
sig
htgl
ass
air space
air pressure adjust
Starmax V collectors
microbubble air separator
auxiliary boiler
air return tube
to / fromdistribution
Figure 2-25
17
There are many ways dirt can enter a hydronic system. Perhaps the most common is through repeated handling of piping and system components from manufacturing through transportation and installation. Piping and components stored on-site can accumulate wind-blown dust or even larger dirt particles if dragged over the ground or dirty floor surfaces. Insects can nest in piping stored in warehouses or on jobsites.
Sediment can also be present in hydronic systems, especially older systems containing steel or iron piping and cast iron radiators. This is especially true for systems that originally operated with steam and are being converted to hot water circulation.
Even new cast iron boilers or radiators can contain residue associated with their manufacturing. Metal chips from reaming copper or iron piping often lodge inside pipes during installation. Access solder often forms small pellets inside piping. Welding slag grains are also common in systems using steel pipe.
The ideal hydronic heating or cooling system would be dirt-free. The presence of dirt can have serious consequences, including:
impeller and bushing surfaces. Figures 3-1 and 3-2 show two examples of circulators with clogged impellers caused by debris and iron oxides within hydronic systems.
sources, such as the cast iron boiler section seen in Figure 3-3. Fouling due to dirt accumulation is especially problematic in boilers or other heat sources with compact heat exchangers.
Fouling due to dirt accumulation can also drastically affect the thermal and hydraulic performance of heat exchangers. Figure 3-4 shows an example of a heavily fouled plate from a plate & frame heat exchanger.
Photo courtesy of Ken Shockley
Figure 3-1
Figure 3-2
Figure 3-3
Figure 3-4
18
Similar fouling can occur with chillers and heat exchangers in chilled-water cooling systems.
Dirt in the flow stream can also exasperate internal erosion of copper tubing, as shown in Figure 3-5. The higher the flow velocity, the more aggressive the erosion.
Dirt in systems, especially very fine particles, can eventually collect on transparent surfaces such as those used in sightglasses, rotameter flow meters or flow meters built into manifold stations. This can make it difficult or impossible to read the flow level in the sightglass or the flow rate through the meter. Figures 3-6 and 3-7 show two examples.
With sufficient accumulation, dirt buildup can cause the moveable parts in the flow meter to jam, rendering the meter useless.
Dirt can also cause erosion and/or clogging of relief valves, balancing valves, check valves, venting valves and thermostatic radiator valves, as depicted in Figures 3-8 and 3-9.
Courtesy of Illinois State Water Survey
Figure 3-5
Figure 3-6
Figure 3-7
Figure 3-8
Figure 3-9
19
DIRT SepARATION meTHODS:There are three common methods for capturing and expelling dirt from hydronic systems:
1. Use of chemical “flocculants” to wash the inside of the system.2. Use of basket strainers.3. Use of low-velocity-zone particle separators.
Chemical flocculants act as detergents within piping systems. They provide the chemical reactions necessary to dislodge certain types of accumulated sediments and assist in bonding fine particles together so that they can be entrained in a flowing stream. A typical system cleaning procedure involves adding the flocculants to the system, then operating it at elevated temperatures for several hours so that accumulated sediment or corrosion residuals can be dislodged and carried along by the flow. The system is then drained and flushed with clean water to expel as much of the sediment as possible. This procedure can be done when the system is first commissioned or as a remedial measure for systems in which sediment or corrosion scale has decreased performance. Some flocculants also coat the inside of piping and components with a residual film to protect against corrosion.
Basket strainers, also known as Y-strainers, entrap dirt within a “basket” made of stainless steel or brass mesh. The cross section of a typical Y-strainer is shown in Figure 3-10.
Y-strainers work similarly to the strainer inside the neck of a funnel. All system flow passes through the strainer and particles larger than the mesh size of the basket are trapped. Particles smaller than the mesh size may pass through the basket, as shown in Figure 3-11.
As debris collects inside the strainer’s basket, it impedes flow. This results in increased pressure drop and hence higher head loss. If the strainer basket is not properly maintained, such head loss can be excessive. Figure 3-12 shows an example of a heavily loaded basket from a Y-strainer.
Flow reductions due to dirt accumulation in Y-strainers will reduce heat conveyance by the system. When restricted strainers are present near the inlet of circulators, they can induce vapor cavitation due to significant pressure drop. This can severely damage a circulator if not corrected.
Experimental testing of Y-strainers in which 70% of the free area of the basket screen is covered with debris have shown a pressure drop 450% higher than the same Y-strainer with a clean basket screen. Figure 3-13 compares the pressure
Figure 3-10
Figure 3-11
Figure 3-12
20
drop of two 1” pipe size Y-strainers: one with a clean basket, and the other with the basket 70% plugged with debris.
In most systems, the pressure drop across a basket strainer is monitored to determine when cleaning is necessary. A pressure drop of 5% or more of the differential pressure across the circulator is a reasonable indication that the strainer should be cleaned. Ball valves are installed to isolate the strainer so its basket can be removed without significant fluid loss, as shown in Figure 3-14. Flow through the system must be stopped during this cleaning procedure.
Low-velocity-zone dirt separators allow gravity and deflection to separate dirt particles from the flow stream. The velocity of the flow stream entering such a separator
is reduced, often by a factor of 9 or more. The reduced velocity makes it difficult for the flow stream to continue entraining the dirt particles. A specially designed media within the low-velocity-zone dirt separator further impedes dirt entrainment. The dirt particles drop out of the active flow region of the separator and collect in the bowl at the bottom of the separator. When a valve at the bottom of this bowl is opened, the accumulated dirt is “blown down” (e.g., expelled) to a hose or bucket. An example of a Caleffi Dirtcal low-velocity-zone dirt separator is shown in Figure 3-15.
A low-velocity-zone dirt separator has much lower head loss and pressure drop compared to the same size Y-strainer with a clean screen. Figure 3-16 compares the pressure drop of a 1” pipe size Caleffi Dirtcal separator to that of a 1” pipe size Y-strainer with a clean basket, as well
0
1
2
3
4
5
6
0 2 4 6 8 10 12 14 16
pres
sure
dro
p (p
si)
1" Y-strainer (70% plugged)
1" Y-strainer (clean basket)
basket strainer
P across strainer ismonitored to determine
when cleaning is necessary
ball valves isolate strainer during cleaning
0
1
2
3
4
5
6
0 2 4 6 8 10 12 14 16
pres
sure
dro
p (p
si)
1" Y-strainer (70% plugged)
1" Y-strainer (clean basket)
1" Dirtcal
Figure 3-13
Figure 3-14
Figure 3-15
Figure 3-16
21
as the same Y-strainer with a basket that is 70% plugged.
Lower head loss and pressure drop reduces the circulator power required for a given flow rate. This reduces long-term system operating cost.
Because sediment accumulates below the flow stream, low-velocity-zone dirt separators can operate for relatively long periods between blowdowns. Furthermore, flow through the system does not need to stop during the blowdown procedure.
As with air separation, flow velocity through a low-velocity-zone dirt separator affects performance. The maximum flow velocity through such a device is 4 feet per second.
No dirt separator or Y-strainer can capture 100% of the dirt in a flow stream during a single pass through the device. This is especially true of very small particles, such as iron oxide, which are easily entrained with flow. The smaller the particles, the greater the number of cycles required to remove them. Figure 3-17 shows the results of a particle separation test performed on a Caleffi low-velocity-zone dirt separator. Results reflect particle size, flow velocity and the number of passes (e.g., number of times the entire system volume has passed through the separator).
Testing has shown that Caleffi low-velocity-zone separators can remove nearly 100% of small sand particles in sizes greater than 100 micrometers (approximately 0.004 inches) when operating with flow rates up to 4 feet per second. Eventually these separators can remove particles as small as 5 micrometers (approximately 0.0002 inch). This dimension is less than 1/10th the diameter of a human hair, and much smaller than the particle size that can be captured by a typical Y-strainer.
Many hydronic systems contain cast iron or steel components. The presence of these ferrous metals creates the opportunity for iron oxides to form. The greater the presence of oxygen, and the more conductive the water, the faster these oxides form. It follows that
iron oxides are a common type of debris that could be present in many hydronic systems.
Iron oxide particles are attracted to magnetic fields. The most common location of such fields within hydronic systems is near a circulator’s motor. Manufacturers of wet-rotor circulators have continually improved the ability of their circulators to isolate such particles from the fluid-filled space between the rotor and stator poles. Still, circulators installed in systems with high iron oxide content are more likely to experience eventual accumulation of these particles within the rotor can. In severe cases, this accumulation can jam the rotor within the
1000
Efficiency50 passages ( 2 f/s)
502010
40
20
0
60
80
100
Efficiency (%)Efficiency50 passages ( 4 f/s)
Mic
ropa
rticl
e si
ze(μ
m)
0 5 16 35 63 105
150
250
210
500
DIRTCALWORKING ZONE
CARTRIDGE FILTERS
SPECIAL STRAINERS
Y-STRAINERS
Separated quantityInitial quantity
.100%( )
Figure 3-17
Figure 3-18
22
rotor can, preventing the circulator from operating.
The high-efficiency wet-rotor circulators that are increasingly used in hydronic systems contain very strong rare earth magnets within their rotors, as demonstrated in Figure 3-18. They may also use closer spacing between the rotor can and rotor to improve magnetic coupling between the rotor and stator, which improves motor efficiency.
Evidence suggests that the long-term wire-to-
water efficiency of these circulators can decrease by 20% or more due to accumulation of iron-based particles within the circulator, as seen in Figure 3-19. Although the circulator may still operate, it does so at reduced flow and head relative to when first installed. In other cases, the circulator can be completely stalled by the accumulation of such particles.
One way to help ensure that high-efficiency circulators maintain good performance is to trap iron oxide particles, as well as other debris, before they can accumulate within the circulator. This is possible using magnetically enhanced, low-velocity-zone dirt separators.
The ability of a low-velocity-zone dirt separator to capture iron oxide particles is enhanced by installing
powerful rare-earth magnets on or within the separator. Iron oxide particles are attracted to these magnets, improving the capture efficiency of the separator. When the magnetic portion of the separator is removed, the iron oxide particles along with other debris can be flushed out from the lower bowl of the separator.
Figures 3-20 and 3-21 show external and internal views of a Caleffi DirtMag magnetic dirt separator. Notice the black collar near the bottom of the separator’s bowl. This collar contains powerful rare earth magnets that attract ferrous metal particles and hold them against the side of the brass body, which is nonmagnetic.
The permanent magnets used in this collar maintain their full strength over time, allowing the separator to constantly attract and capture ferrous particles as they form in the system.
Figures 3-22 and 3-23 shows another variation on a magnetic dirt separator. In this case, the separator’s body is made of engineered polymer. The body connects to a rotatable brass base fixture that allows the body to remain vertical regardless of the orientation of the pipe to which it is attached. This separator also contains a media that helps separate dirt from the flow stream. The magnetic collar can be seen at the lower end of the body.
Figure 3-24 shows a DirtMag separator being drained. Notice that the magnetic collar has been removed during the drainage process. This allows the captured ferrous metal particles to drop into the lower bowl and be flushed out with other debris.
Figure 3-25 shows how a magnet attracts iron containing dirt particles that have been captured in the effluent flushed from the DirtMag separator.
Figure 3-19
Figure 3-20 Figure 3-21
Figure 3-22 Figure 3-23
23
plACemeNT Of DIRT SepARATORS:Because most dirt particles have a density greater than water, they tend to migrate toward the lower portions of the system. Thus, it makes sense to separate and capture them in this area. It also makes sense to continually route system flow through a dirt separator to increase the number of passes the system volume makes through the device in a given amount of time.
Dirt separators are commonly placed on the inlet side of boilers, heat exchangers and other heat sources,
as shown in Figure 3-26. This is especially important in systems using boilers or other heat sources with compact heat exchangers. It’s also very important in systems where a new boiler is installed in a system containing older piping and/or cast iron radiators, as shown in Figure 3-27.
The dirt separator is placed on the return side of the distribution system to capture particles that might otherwise flow through the new boiler. A magnetic dirt separator is especially appropriate for such systems given the higher potential of iron oxide particles in the flow stream.
VENT
distribution
piping
systemdirt
separator
magnetic!dirt!
separator
air!separator
old cast iron!radiator system
system!circulator
purge!valve
Figure 3-24
Figure 3-25
Figure 3-26
Figure 3-27
24
Notice that purging valves have been located just upstream of the dirt separator. This allows some of the dirt in the system to be flushed out during initial filling and purging. This, in turn, decreases the amount of dirt the separator will eventually have to capture.
When possible, it’s also desirable to place the dirt separator upstream of circulators. This helps extract dirt before flow passes through the circulator. When doing so, allow at least 12 pipe diameters of straight pipe between the outlet of the air separator and inlet of the circulator.
Some systems use multiple circulators to push flow from different circuits into the boiler. In this case, the compromise is to place the dirt separator upstream of the boiler, as shown in Figure 3-28.
In systems with a main mixing valve, it’s best to place dirt separators in the return line from the distribution system ahead of the valve. This increases flow through the separator and better protects the mixing valve from dirt.
With all installations, be sure to plan sufficient space to connect a drain hose or place a bucket under the dirt separator to capture the expelled fluid and dirt.
Low-velocity-zone dirt separators are also well-suited to protect the small fluid passageways within plate-type heat exchangers from dirt accumulation. Separators should be installed near the inlets of both the primary and secondary sides of the heat exchanger, as shown in Figure 3-29.
heating
DHW
boiler
DirtMag dirtseparator
Discal airseparator
DHW
heating
brazed -plateheat
exchanger
dirtseparator
dirtseparator
Figure 3-28
Figure 3-29
25
Some designers prefer to combine the function of air separation and dirt separation into a single device. This approach saves space, especially in tight mechanical rooms. It also reduces cost relative to installing two individual separators.
Combined air & dirt separators use the same principles of microbubble air separation in the upper portion of the separator body, combined with low-velocity-zone dirt separation in the lower portion of the separator body. They have a float-type
automatic air vent at the top of the body and a drainage valve at the bottom, as seen in Figure 4-1.
Caleffi also offers combined air & dirt separators with magnetically enhanced separation of ferrous particles. A cross section of one such separator is shown in Figure 4-2.
VENT
combined air & dirt separator
ThermoCon buffer tank
temperaturesensor
variable-speedpressure-regulated
circulator
chilled-waterair handlers
balancingvalves
chiller
air ventCombined air & dirt separator
air vent
Figure 4-1 Figure 4-2 Figure 4-3
Figure 4-4
26
The preferred placement of a combination air & dirt separator depends on the application and system piping. In heating systems, preference should be given to air separation. The preferred placement of the combined air & dirt separator is near the outlet of the heat source, as shown in Figure 4-3. This creates conditions favorable to air separation (e.g., higher fluid temperature and lower pressure).
In cooling systems, the preferred placement of the air & dirt separator is near the return to the chiller plant, as shown in Figure 4-4. Water at this location has a slightly higher temperature compared to water leaving the chiller. This improves the conditions under which microbubbles can form. It also places the dirt separating function on the inlet to the chiller plant, which reduces the potential of dirt accumulation within the chiller.
The ability of an air separator, dirt separator or a combined air & dirt separator to remove the undesired materials from a stream of water depends on the flow velocity of that stream. Slower flow velocities improve separation efficiency. For optimum performance, the pipe size for any of these separators should limit flow velocity to 4 feet per second. Higher flow velocities of up to 10 feet per second are possible but will decrease the efficiency of air and dirt separation. Separation will still occur, but over a longer time. Figure 4-5 lists the nominal pipe size of separators along with the flow rates corresponding to flow velocities of 4 feet per second and 10 feet per second.
10 ft/sec
4 ft/sec GPM
GPM 19.0 22.1 25.0 88.8 150 227 355 616 904 1570 2450 3530
8.0 9.3 10.0 37.3 63 95 149 259 380 625 980 1410
3/4" 1" 1.25" 2" 2.5" 3" 4" 5" 6" 8" 10" 12"
BRASS STEEL
size
88.8 150 227 355 616 904 1570 2450 3530
37.3 63 95 149 259 380 625 980 1410
2" 2.5" 3" 4" 5" 6" 8" 10" 12"
STEEL
Figure 4-5
27
Many hydronic systems contain multiple independently controlled circulators. These circulators can vary widely in their flow and head characteristics. Some may operate at fixed speeds, while others will operate at variable speeds.
When two or more circulators operate simultaneously in the same system, they each attempt to establish differential pressures based on their own pump curves. Ideally, each circulator in a system will establish a differential pressure and flow rate that is unaffected by the presence of another operating circulator within the system. When this desirable condition is achieved, the circulators are said to be
from each other.
Conversely, the lack of can create very undesirable operating conditions in which circulators interfere with each other. The resulting flows and rates of heat transport within the system can be greatly affected by such interference, often to the detriment of proper heat delivery.
The degree to which two or more operating circulators interact with each other depends on the head loss within the piping path they have in common. This piping path is called the , since it is shared by both circuits. The lower the head loss of the common piping, the less the circulators will interfere with each other.
Consider the system shown in Figure 5-1. In this system, both circuits share common piping. The “spacious” geometry of this common piping creates very low flow velocity through it. As a result, very little head loss can occur across it.
Assume that circulator 1 is operating, and circulator 2 is off. The blue circuit head loss curve shown in Figure 5-2 applies to this situation. The point where the blue circuit head loss curve crosses the orange pump curve for circulator 1 establishes the flow rate in circuit 1.
Next, assume circulator 2 is turned on, while circulator 1 remains on. The flow rate through the common piping increases, and so does the head loss across it. However, because of its spacious geometry, the increase in head loss across the common piping is very small. The system head loss curve that is now “seen” by circulator 1 will steepen, but very slightly. It is shown as the green curve in Figure 5-3.
Very little head loss occursin this portion of the circuits.
common piping circulator 1
circuit 1
circuit 2 circulator 2
00
pump curve(circulator #1)
circuit 1 head loss curve including common piping (circulator #1 on)
circuit operating
00
pump curve(circulator 1)
circuit 1 head loss curve including common piping (both circulators on)
circuit 1 head loss curve including common piping (circulator #1 on)
VERY small decrease in
very small change inhead loss acrosscommon piping
are on
circuit operatingare operating
head
(gai
n or
loss
) (f
eet o
f hea
d)Figure 5-1
Figure 5-2
Figure 5-3
28
The operating point of circuit 1 has moved very slightly to the left and slightly upward. This implies that the flow rate through circuit 1 has decreased very slightly. This very small change in flow rate is indicated in Figure 5-3. Such a small change in circuit flow rate will have virtually no effect on the ability of circuit 1 to deliver heat. Thus, the interference created when circulator 2 was turned on is of no consequence. Therefore, this situation provides acceptable hydraulic separation between the two circulators.
One could imagine a hypothetical situation in which the head loss across the common piping was zero, even with both circuits operating. Because no head loss occurs across the common piping, it would be impossible for either circulator to have any effect on the other circulator. Such a condition would represent “perfect” hydraulic separation and would be ideal. Fortunately, perfect hydraulic separation is not required to ensure that the flow rates through independently operated circuits, each with their own circulator, and each sharing the same low-head-loss common piping, remain reasonably stable, and thus capable of delivering consistent heat transfer. In animated terms, the two simultaneously operating circulators cannot “sense” each other’s presence within the system, and thus operate as if they were each in an independent circuit.
One can think of (and design) circuits that are known to have a high degree of hydraulic separation, as if they were completely independent of each other, as illustrated in Figure 5-4.
The required hydraulic performance of each circuit can be determined as if it were a standalone circuit, unaffected by the other circuits in the system. This is a very powerful concept that simplifies design and troubleshooting.
Having stressed that hydraulic separation is desirable, it is worthwhile to consider a situation in which hydraulic separation is NOT present and observe the consequences.
Consider the horizontal piping system shown in Figure 5-5. The larger circulator is sized to move sufficient flow through the higher flow-resistance circuit including the high-flow-resistance heat source. When operating, the flow created by the large circulator creates a pressure drop of 5 psi between the supply and return headers connected to the heat source.
common piping
circuit 2
circulator 2
circuit 1circulator 1
common piping
Very little head loss occursin this portion of the circuits.
common piping circulator 1
circuit 1
circuit 2 circulator 2
P=22 psi
backseatedcheck valve
P=17psilarge circulator
small circulator
ON
P=12 psi
P=17 psi
OFF
P = 5 psiP=
10
psi
P=16 psi
P=13 psi
heat sourcewith high
Figure 5-4
Figure 5-5
29
The pressures shown in Figure 5-5 are those established when the large circulator is operating and the small circulator is off. Because there is no flow in the circuit containing the small circulator, the 17 psi pressure at the return end of this circuit is present around the circuit. Hence, there is a 17 psi pressure at the discharge port of the smaller circulator. This creates a reverse pressure differential of (17-12) = 5 psi across the small circulator, which forces its internal check valve closed.
Figure 5-6 shows the pump curve for the smaller circulator. Notice that the maximum possible differential pressure this circulator can create is 4 psi.
Because the reverse differential pressure of 5 psi is greater than the maximum forward differential pressure of 4 psi, the circulator cannot create flow, even though its impeller is spinning at normal speed. Its internal check valve remains closed. Under this condition, the circulator is said to be “deadheaded.” It will dissipate its full input power as heat. This heat will be absorbed by the water in the circulator’s volute, as well as be dissipated by the circulator’s body. Although this is not a
condition that should be allowed by proper design, small wet-rotor circulators can usually withstand such operation for several hours. Such situations can be avoided by creating hydraulic separation between the circuits.
Although the term hydraulic separation is relatively new to the North American hydronics industry, the principle of avoiding interaction between simultaneously operating
circulators in the same system is not. During the 1950s, the concept of primary/secondary piping was introduced in North America. It was promoted as a way to provide stable on/off flow control in multiple independently controlled circuits, each with its own circulator. It is based on the use of two very closely spaced tees, as shown in Figure 5-7.
Because the tees are very close together, the pressure drop between them due to head loss is almost zero. Hence, the pressure at the side port of each tee is almost exactly the same. Since there is virtually no pressure differential between the tees, there is very little tendency for flow to develop in the secondary circuit, even though flow is passing through the tees in the primary circuit. However, it is still good practice to install a spring-loaded check valve on the supply side of every secondary circuit to prevent buoyancy-driven flow from developing. The intended flow rate in the secondary circuit is achieved when
P=Head
()
D 144
5
10
15
0
head
add
ed (
feet
)
0
6
4
2
02 4 6 8 10
4 psi
heat source
primarycirculator
secondarycirculator
secondary circuit
purgingvalve
spring-loadedcheck valve
closelyspacedtees
another secondary
circuitprimary loop
Figure 5-6
Figure 5-7
30
the secondary circulator operates. Because the flow created by the primary circulator does not induce flow in the secondary circuit, nor does it have any significant effect on the flow in the secondary circuit when its secondary circulator is operating, these two circuits are hydraulically separated from each other.
This concept can be extended to multiple secondary circuits served by a common primary loop, as shown in Figure 5-8. Each secondary circuit, including the secondary circuit through the boiler, is joined to the primary circuit using a pair of closely spaced tees to provide hydraulic separation. The configuration shown in Figure 5-8 is more precisely called a series primary/secondary system. With this approach, all secondary circuits are arranged in a sequence around the common primary loop.
Although hydraulic separation exists between all circuits, so does an often-undesirable effect—a drop in supply water temperature from one secondary circuit to the next
whenever two or more of the secondary circuits are operating simultaneously. Although there are situations in which this temperature drop doesn’t present a problem, it does add complications that designers must assess and compensate for.
One way to overcome the series temperature drop effect associated with series primary loops is to create a parallel primary loop, as shown in Figure 5-9.
A parallel primary loop is divided into two or more “crossover bridges.” A pair of closely spaced tees within each crossover bridge provides hydraulic isolation between each secondary circuit and the parallel primary loop.
Unlike a system with a series primary loop, a system with a parallel primary loop provides essentially the same supply water temperature to each secondary circuit, regardless of which secondary circuits are operating. This benefit is achieved through more complicated and costly
piping. Notice that each crossover bridge contains a flow-balancing valve. These valves are needed to set the flow through each crossover bridge in proportion to the thermal load served by the secondary circuit supplied from that bridge. If these valves are not present and properly adjusted, there may be problems such as inadequate flows through the crossover bridges located farther away from the primary circulator.
Another important consideration is that both series and parallel primary/secondary systems require a primary circulator. This circulator adds to the installed cost of the system. More importantly, it adds to the system’s operating cost over its entire life. Even one small primary loop circulator in a system can have operating costs that total more than $1,000 over a typical 20-year design life. Larger primary loop circulators can have life-cycle operating costs of several thousand dollars.
For example: Consider a primary loop circulator that must produce a flow rate of 50 gpm, with a corresponding
secondary circuits
primarycirculator
series primary loop
boilercirculator
closely spaced tees
closely spaced tees
closely spaced tees
closely spaced tees
VENT
magneticdirt separator
vertical air separator
Figure 5-8
31
head of 15 feet (which is evidenced by a pressure gain of 6.35 psi across the circulator). Assume the circulator is a typical wet-rotor design and has a wire-to-water efficiency of 25% at these operating conditions. The estimated input power to operate this circulator is:
If this primary loop circulator were to operate for 3000 hours each year, and the local cost of electrical energy was $0.10/kWhr, the annual operating cost would be:
Furthermore, if the cost of electricity were to inflate at 4% each year, the total operating cost of this circulator over a 20-year period would be:
This cost is only for operation of the primary loop circulator. It does not include purchase, installation or maintenance of that circulator over time.
Imagine a situation in which the hydraulic separation benefits of primary/secondary piping, as well as the equal supply water temperatures provided by a parallel primary loop, could be provided without having to construct a primary loop or use a dedicated primary loop circulator.
There are now several modern methods for achieving these benefits without need of constructing primary/secondary piping systems. They are discussed in the next section.
primarycirculator
parallel primary loop
boilercirculator
closely spaced tees
VENT
magneticdirt separator
closely spaced
tees
balancingvalves
Figure 5-9
32
Any component or combination of components with very low head loss, and common to two or more hydronic circuits, can provide hydraulic separation between those circuits.
One way to create low head loss is to keep the flow path through the common piping very short. Another way to create low head loss is to significantly reduce the flow velocity through the common piping.
Examples of devices that use these principles include:
1. A heat source that has very low head loss2. A pair of closely spaced tees3. A buffer tank with specific piping arrangement4. A hydraulic separator5. Specialty components such as a Caleffi HydroLink
Each of these methods can provide hydraulic separation between simultaneously operating circulators, as well as equal supply water temperature to each load circuit.
Figure 6-1 shows an example of a system with a single cast iron sectional boiler supplying 4 zone circulators. Many North American hydronic systems were once piped similar to this. Although the term hydraulic separation was not used at that time to describe the inherent advantage of this approach, these systems performed well with minimal interference between simultaneously operating circulators.
Nearly all cast iron sectional boilers have large chambers through which water moves very slowly as it passes from the boiler’s inlet to its outlet. These slow internal velocities create very low head loss through the boiler, even when all the zone circulators are operating. If this type of boiler is combined with low-head-loss header piping, as discussed in the previous section, the resulting combination creates low-head-loss common piping for the zone circuits. This, along with a very simple piping arrangement, provides the necessary conditions for hydraulic separation.
When modulating/condensing boilers were first introduced to North America, many of them used compact internal heat exchangers that created much higher head loss in comparison to traditional cast iron boilers. Some of these boilers were installed using the same piping arrangement that was common practice with cast iron boilers, as shown in Figure 6-2.
The high head loss of the mod/con boiler significantly increased the overall head loss of the common piping and largely negated the hydraulic separating characteristic attained in systems using the older style, low-head-loss boilers. This created many problem installations, since installers and manufacturers did not immediately recognize the source of the resulting flow problems.
Eventually, the source of the flow problems was traced back to the high head loss of the new style boilers with
VENT
low-head-loss boiler
low-head-losscommon piping
low-head-loss headers
VENT
high-head-loss boiler
Figure 6-1
Figure 6-2
33
their compact heat exchangers. Piping methods were modified to correct this problem. These methods will be discussed shortly.
Today, there are modulating/condensing boilers available with low-head-loss characteristics. When combined with low-temperature distribution systems, they provide the benefit of high thermal efficiency, as well as the benefit of simple piping that provides excellent hydraulic separation between the circulators. Figure 6-3 shows an example of such a system.
Heat sources such as mod/con boilers with compact internal heat exchangers or water-to-water heat pumps tend to have high-head-loss characteristics. Because of this, they should not be part of a common piping assembly that is supposed to have low head loss.
One solution is to couple such heat sources to a generously sized header system using a pair of closely spaced tees, as shown in Figure 6-4.
Because they are positioned as close to each other as possible, there is virtually no head loss between the tees. They form the common piping between the boiler circuit and the headers, and thus provide hydraulic separation between the boiler circulator and any of the circulators on the supply header. The headers have also been sized for low head loss. As such, they provide hydraulic separation between any two or more of the circulators connected to the headers.
A suggested guideline is to size headers for a flow velocity in the range of 2 to 4 feet per second when all the circulators supplied by the header are operating. Low
VENT
manifold station serving
low-temperatureheat emitterslow-head-loss
common piping
modulating/condensing heat source with low-
head-loss characteristic
gasburner
low-head-losscommon piping
closely spaced tees
boiler circulator
VEN
T
boiler with high- head-loss
characteristic
Figure 6-3
Figure 6-4
34
flow velocity creates minimum head loss, while also allowing for air bubble entrainment. The latter is useful when air bubbles need to be forced downward in a vertical header during system commissioning.
Figure 6-5 lists the flow rates corresponding to flow velocities of 2 feet per second and 4 feet per second for type M copper tubing in sizes from 1-inch to 5-inch, and in schedule 40 steel for larger pipe sizes. For other piping materials or sizes, the flow rate corresponding to a given flow velocity can be calculated using Formula 6-1.
Formula 6-1:
Where:v = average flow velocity (ft/sec)f = flow rate (gpm)di = exact inside diameter of pipe (inches)
With proper hydraulic separation, such as shown in Figure 6-4, it is possible to combine circulators with significantly different pump curves on the same header system. It is also possible to combine fixed-speed and variable-speed circulators on the same low-head-loss headers.
Figure 6-6 shows a buffer tank and generously sized headers serving as the low-head-loss common piping that provides hydraulic separation between the heat source circulator and each of the distribution circulators. This demonstrates that hydraulic separation can sometimes be accomplished as an ancillary function to the main purpose of the device (e.g., hydraulic separation is not the main function of the buffer tank).
Figure 6-7 shows an example of a Caleffi ThermoCon tank serving as both a buffer tank and hydraulic separator between a water-to-water geothermal heat pump, a modulating/condensing auxiliary boiler and the associated distribution system.
Tube/pipe size Flow rate at 2 ft/sec
Flow rate at 4 ft/sec
1” M copper 5.5 gpm 10.9 gpm
1.25” M copper 8.2 gpm 16.3 gpm
1.5” M copper 11.4 gpm 22.9 gpm
2” M copper 19.8 gpm 39.6 gpm
2.5” M copper 30.5 gpm 61.1 gpm
3” M copper 43.6 gpm 87.1 gpm
4” M copper 75.9 gpm 152 gpm
5” M copper 118 gpm 236 gpm
6” schd. 40 steel 180 gpm 361 gpm
8” schd. 40 steel 312 gpm 624 gpm
10” schd. 40 steel 492 gpm 984 gpm
12” schd. 40 steel 699 gpm 1397 gpm
buffertank
low-head-losscommon piping
VEN
T
boiler circulator
boiler with high- head-loss
characteristic
Figure 6-5
Figure 6-6
f = v di2
0.408
35
Another method of providing hydraulic separation is by installing a device appropriately called a hydraulic separator. Although relatively new in North America, hydraulic separators have been used in Europe for many years. Figure 6-8 shows a hydraulic separator installed in place of the buffer tank in Figure 6-6. Note the similarity of the piping connections between the systems.
Figure 6-9 shows the external appearance of several Caleffi hydraulic separators. The front portion of the insulation shell has been removed from the two smaller separators. The large, self-supporting hydraulic separator is awaiting site-installed insulation.
Hydraulic separators are sometimes also called or “ ” They create a zone of
low flow velocity within their vertical body. The diameter of the body is typically three times the diameter of the connected piping. This causes the vertical flow velocity in the vertical body to be approximately 1/9th that of the connecting piping, as shown in Figure 6-10. Such low velocity creates very little head loss and very little dynamic pressure drop between the upper and lower connections. Thus, a hydraulic separator provides hydraulic separation in a manner similar to a buffer tank, only smaller.
The reduced flow velocity within a hydraulic separator allows it to perform two additional functions. First, air bubbles can easily rise upward within the vertical body and be captured in the upper chamber. When
Courtesy of Harvey Youker and Danny Gough
boiler circulator
boiler with high- head-loss
characteristic
hydraulicseparator
VEN
T
low-head-loss common piping
VEN
T
Installed separator photo courtesy of Rathe Associates
Figure 6-7
Figure 6-8
Figure 6-9
36
sufficient air collects at the top of the body, the float-type air vent allows it to be ejected from the system. Thus, a hydraulic separator can provide air separation.
Second, the reduced flow velocity inside the hydraulic separator allows dirt particles to drop into a collection chamber at the bottom of the body. A valve at the bottom can be periodically opened to flush out any accumulated dirt. Thus, the hydraulic separator also serves as a dirt removal device.
The efficiency of both air and dirt separation is enhanced through use of a coalescing media in the active flow zones, which are in line with the side ports of the separator. These are shown in Figure 6-11.
High-performance hydraulic separators, such as the Caleffi HydroCal, provide
three functions:
1. Hydraulic separation2. High-performance air separation (equivalent to a Caleffi Discal air separator)3. High-performance dirt separation (equivalent to a Caleffi Dirtcal dirt separator)
This multifunctional ability allows a single high-performance hydraulic separator to provide hydraulic separation, as well as replace a high-performance air separator and high-performance dirt separator, as illustrated in Figure 6-12.
diam
eter
= 2
"
diameter = 6"
area = A
area = 9A
coalescing media
upper coalescing media encouragesair bubbles to form
air bubbles "ride" up
of the coalescing media
zone
media encouragesdirt particle to drop
zone
"STANDARD"hydraulic separator
HIGH PERFORMANCE
hydraulic separator(air & dirt removal
enhanced by coalescing media)
Figure 6-10
Figure 6-11
37
The latest enhancement for high-performance hydraulic separators is the addition of magnetic particle separation. Figure 6-13 shows the Caleffi SEP4 separator, which uses a collar containing strong rare earth magnets in combination with a brass sediment bowl to add the fourth function (e.g., magnetic particle separation) to the product.
The addition of magnetic particle separation makes the SEP4 hydraulic separator especially useful for applications in which an older distribution system—one that may have some accumulated ferrous metal sludge—is connected to a new heat source. Figure 6-14 shows a concept for how a SEP4 hydraulic separator is used to interface the new boiler and high-efficiency circulator to an older distribution system serving cast iron radiators. Notice that each radiator has been equipped with a thermostatic valve that allows for individual heat output control.
heatingload(s)
boiler circuit
distribution system
airseparator
dirtseparator
closelyspacedtees
heatingload(s)
boiler circuitdistribution
system
HydroCal
Figure 6-12
Figure 6-13a Figure 6-13b
38
Figure 6-15 shows another example of a SEP4 circulator providing magnetically enhanced dirt separation in a system using a high-efficiency permanent magnet circulator.
Given the surface area of their bodies, hydraulic separators should always be insulated to minimize heat loss to their surroundings. This is especially true of larger hydraulic separators, which may have more surface area than a modestly sized radiator, and without insulation, would needlessly overheat the mechanical room. Figure 6-15 shows the insulation shell supplied with a Caleffi SEP4 separator installed on the device.
Figure 6-16 shows onsite fabricated insulation covering a large hydraulic separator in an industrial heating system.
Hydraulic separators should also be properly supported. Small units can typically be supported by channel strut, as seen in Figure 6-17, or by using clevis hangers. Large hydraulic separators are designed to be self-supported at their base.
Hydraulic separators are available in pipe sizes from 1-inch to over 12-inch. The “size” of a hydraulic
existing cast iron radiators (converted from steam)
existing piping
mod/con boilerw/ compact heat exchanger
supply temperaturesensor (in well)
ECMpressure-regulatedcirculator
vent
VENT
thermostaticradiatorvalve
(each rad.)
hydraulicseparator
Courtesy of Osborne Company
Courtesy of Tweet / Garot Mechanical, Inc., Greenbay, Wisconsin
Courtesy of Dan Schlicher
Figure 6-14Figure 6-16
Figure 6-15 Figure 6-17
39
separator refers to the nominal pipe size of the 4 side-wall connections.
Selecting an appropriate-size hydraulic separator is easy. It is based on choosing a size that allows the maximum anticipated flow rate into either side of the separator, without exceeding a preferred flow velocity of 4 feet per second. Limiting the flow velocity to this value maintains highly efficient air and dirt separation. The table in Figure 6-18 can be used as a reference.
For example, if the maximum flow rate on the primary side of the hydraulic separator was 290 gpm, and the maximum flow rate on the secondary side of the separator was 400 gpm, the higher flow rate would be the limiting case. Figure 6-16 indicates that a 6” size separator can handle flow rates up to 484 gpm, and thus would be an appropriate selection for this situation.
MIXING AT THE POINT OF HYDRAULIC SEPARATION:Mixing can occur within any component or group of components that provides hydraulic separation. The results of the mixing can be predicted by considering the principles of:
1. Conservation of mass2. Conservation of thermal energy
In essence, the first of these principles states that the total flow rate of an incompressible fluid such as water entering the separator has to equal the total flow rate exiting the separator. The second principal implies that, under steady-state operating conditions, the total thermal energy entering the separator has to equal the total thermal energy leaving the separator.
The temperatures at the two outlet ports of a hydraulic separator (e.g., ports 2 and 3 in Figure 6-19) depend on the temperatures at the two inlet ports (e.g., ports 1 and 4 in Figure 6-19), as well as the flow rates in both the boiler circuit and distribution system.
1" 1.25" 1.5" 2" 2.5" 3" 4" 5" 6" 8" 10" 12"
11 18 26 37(union) 80 124 247 300 484 792 1330 1850
port 2(supply todistribution
system)
port 4(return fromdistribution
system)
port 1( supply from boiler)
port 3(return to boiler)
air vent
sediment drain
T4T3
T2T1
f1 f2
f3 f4
NOTE:
=f1 f3 (always!)
f2 f4=NOTE:
(always!)
In this case only:
T1 T2T3 T4
==
Figure 6-18
Figure 6-19
Figure 6-20
40
There are three possible cases:
1. Flow in the distribution system is equal to flow in the boiler circuit2. Flow in the distribution system is greater than flow in the boiler circuit3. Flow in the distribution system is less than flow in the boiler circuit
This situation tends to be the exception rather than the norm. It is illustrated in Figure 6-20.
The flow and temperature leaving port 2 of the hydraulic separator is the same as the temperature of the hot water entering port 1. Very little internal mixing occurs because the flows are balanced. Because of its buoyancy, the hot water entering port 1 remains near the top of the hydraulic separator. Most of the air bubbles carried into port 1, or that form within the hydraulic separator, rise to the top of the unit and are ejected through the air vent.
A similar situation exists at the lower ports of the separator. Since the flows are balanced, the outlet temperature
returning to the heat source from port 3 equals the temperature returning from the distribution system into port 4. Again, very little mixing takes place within the separator. Dirt particles carried into the separator at port 4 will settle to the bottom of its body, where they can be periodically flushed out through the drain valve.
If a conventional boiler (e.g., one that is not intended to operate with sustained flue gas condensation) is used, the designer should verify that the water temperature on the return side of the distribution system is high enough to prevent sustained flue gas condensation within the boiler. The use of a hydraulic separator in itself does not guarantee that the water temperature entering the boiler will be high enough to prevent sustained flue gas condensation.
Since the flow rates in the boiler circuit and distribution system are not the same, mixing occurs within the hydraulic separator. In this case, a portion of the cooler water returning from the distribution system moves upward through the separator and mixes with the hot water entering from the boiler, as shown in Figure 6-21.
This mixing reduces the water temperature supplied to the distribution system. This is not necessarily a bad thing, but the designer needs to realize it can occur and plan accordingly.
Formula 6-2 can be used to calculate the mixed temperature (T2) supplied to the distribution system under these conditions.
Formula 6-2
Where:f4 = flow rate returning from distribution system (gpm)f1 = flow rate entering from boiler (gpm)T4 = temperature of fluid returning from distribution system (ºF)T1 = temperature of fluid entering from boiler (ºF)
Formula 1 is valid for both water and other system fluids, provided all fluid entering and leaving the hydraulic separator is the same. It can also be used with any consistent set of units for flow and temperature.
Suppose, for example, that a distribution system containing several operating circulators has 25 gallons per minute of total flow. Water returns from the distribution system at 120ºF and enters port 4 of the hydraulic separator. At the
T4T3
T2T1
f1 f2
f3 f4
NOTE:
=f1 f3 (always!)
f2 f4=NOTE:
(always!)
Figure 6-21
T2 =f4 f1( )T4 + f1( )T1
f4
41
same time, the boiler flow rate is 10 gallons per minute, and the water temperature supplied to port 1 is 160ºF. Determine the mixed water temperature leaving port 3. Also, what is the water temperature returning to the boiler?
The mixed water temperature is found using Formula 6-2:
Notice that the water temperature supplied to the distribution system (136ºF) is substantially lower than the water supplied from the boiler (160ºF). This is the result of mixing within the hydraulic separator.
Since no mixing occurs in the bottom portion of the separator, the water temperature returning to the boiler is the same as that returning from the distribution system (e.g., 120ºF).
If the boiler firing rate is to be modulated based on the supply temperature to the distribution system, the temperature sensor providing supply temperature information to the modulating controller should be located within a sensor well in the upper portion of the hydraulic separator, or downstream of the distribution system outlet port (port 2) of the hydraulic separator, as shown in Figure 6-22. If the sensor is strapped to the outer surface of the pipe, it should be firmly secured, then wrapped with insulation to minimize error due to surrounding air temperature.
Again, since the flow rates on opposite sides of the hydraulic separator are not equal, mixing will occur inside the separator. In this case, a portion of the hot water entering from the boiler circuit moves downward through the separator and mixes with cool water entering from the distribution system, as shown in Figure 6-23.
This condition occurs when the boiler heat output rate is (temporarily) higher than the current system load. Under this condition, heat is being injected into the system faster than the load is removing heat. This produces a relatively fast increase in boiler return temperature. If a modulating boiler is being used, this will lead to a relatively fast decrease in firing rate, which usually will result in a reduction in boiler-side flow rate.
Under this scenario, the temperature returning to the boiler (T3) can be calculated using Formula 6-3:
Formula 6-3
boiler
hydraulicseparator
supplytemperaturesensor in well
supplytemperature
sensor strappedto pipe
(& insulated)
T4T3
T2T1
f1 f2
f3 f4
NOTE:
=f1 f3 (always!)
f2 f4=NOTE:
(always!)
Figure 6-22
Figure 6-23
T2 =f4 f1( )T4 + f1( )T1
f4=
25 10( )120 + 10( )16025
= 136ºF
T3 =f1 f2( )T1 + f4( )T4
f1
42
Where:T3 = temperature of fluid returned to the boiler(s) (ºF)f1 = flow rate entering from boiler(s) (gpm)f2, f4 = flow rate of the distribution system (gpm)T1 = temperature of fluid entering from boiler(s) (ºF)T4 = temperature of fluid returning from distribution system (ºF)
Assume the boiler supply temperature is 170ºF, and that boiler flow rate into port 1 of the hydraulic separator is 15 gallons per minute. Water returns from the distribution system and enters port 4 of the hydraulic separator at 100ºF and 10 gallons per minute flow rate. What is the water temperature returned to the boiler?
Substituting these operating conditions into Formula 6-2 yields:
Notice that the boiler inlet temperature is about 23ºF higher than the return temperature of the distribution system. This is caused by mixing within the hydraulic separator.
If the system uses a conventional (non-condensing) boiler, one might consider the boost in boiler return temperature beneficial because it moves the boiler operating condition away from potential flue gas condensation. However, this temperature boost effect can quickly diminish if flow through the distribution system increases (i.e., more load circuits turn on), or if the return temperature of the distribution system drops. Use of a hydraulic separator alone does not prevent flue gas condensation under all circumstances.
Because there is very little head loss across a hydraulic separator, vertically or horizontally, the system’s expansion tank can be teed into the piping near any of the separator’s 4 main ports. The lower ports are preferred because they expose the expansion tank to lower temperature fluids compared to the upper ports. Figure 6-24 shows both of these options.
The system’s expansion tank should not be connected to the bottom of the hydraulic separator. This would allow dirt to migrate from the bottom of the separator into the expansion tank, where it will accumulate on top of the tank’s diaphragm.
VENT
boiler
hydraulicseparator
expansiontank
makeupwater
subsystem
makeupwater
subsystem
boiler
hydraulicseparator
expansiontank
VENT
makeupwater
subsystem
boiler
hydraulicseparator
expansiontank
VENT
OK OK NOT OKFigure 6-24
T3 =f1 f2( )T1 + f4( )T4
f1=
15 10( )170 + 10( )10015
= 123.3ºF
43
Hydraulic separators are ideal for use with multiple boiler systems. Figure 6-25 shows an example.
The headers supplying the boilers should be sized for minimal head loss. A suggested sizing criteria is a flow velocity of 2 to 4 feet per second when all boiler circulators are operating.
The hydraulic separator allows the boiler side flow rate to be significantly different from the distribution side flow
VENT
multiple boiler
system
boiler system controller
hydraulicseparator
outdoortemperature
sensor
to loads
Courtesy of Coffey Plumbing & Heating
chiller #2
rejected heat
chiller #1
VENT
VFD
All chilled-water piping must be insulated and vapor-sealed
to / from chilled-water
cooling system
HydroCal withinsulation shell
purgingvalves
rejected heat
FlowCal valve
motorized ball valve
Figure 6-25
Figure 6-27
Figure 6-26
44
rate. It also allows for efficient air and dirt separation within the system. Figure 6-26 shows an example of this type of system.
Each boiler has its own circulator and check valve. This makes it possible to stop flow through boilers that are not operating, and thus stop unnecessary heat loss. It also allows for partial heat delivery to the hydraulic separator if one of the boilers, or one of the boiler circulators, is not responding.
This piping arrangement is also suitable for multiple chillers in chilled-water cooling systems, as shown in Figure 6-27.
Notice that the chilled water from the chillers flows into the lower side connection of the hydraulic separator. The somewhat warmer “chilled” water returning from the distribution system flows into the upper side connection. This arrangement creates more favorable conditions for air separation at the top of the hydraulic separator and minimizes the potential for dirt being carried into the chillers.
This piping arrangement uses a motorized ball valve on each chiller that opens only when that chiller is active. The variable frequency drive (VFD) operates the chiller circulator as necessary to maintain a nearly constant differential pressure across the headers serving the chillers. This reduces the input power to the chiller circulator under partial load conditions.
Caleffi FlowCal balancing valves are used to maintain the present flow rate through each chiller when it is active.
The principle of hydraulic separation combined with uniform supply water temperature to distribution circuits is desirable in both large and small hydronic systems.
Caleffi Hydro Separators are ideal for medium to large systems. Currently available models range from 1-inch to 12-inch pipe size connections.
For smaller systems, Caleffi offers products that integrate the principle of hydraulic separation with the functionality of distribution headers. One example is the Caleffi HydroLink, shown in Figure 7-1.
The HydroLink provides a chamber to hydraulically separate the boiler circuit from the distribution circuits. It also provides a self-contained manifold station that supplies up to four independently controlled load circuits with the same supply temperature. These features and their equivalent piping are shown in Figure 7-2.
A critical detail within the HydroLink is the hydraulic separation chamber on the left side of the unit. This chamber is separated from the manifold chambers by a baffle plate with two closely spaced openings. Given their size and placement, these openings act similarly to a pair of closely spaced tees, eliminating any significant pressure differential between the upper and lower manifold chambers. This prevents flow in the boiler circuit from inducing flow in any of the distribution circuits connected to the manifold chamber.
The HydroLink is available in several models with differing numbers and placement of the manifold connections. Figure 7-4 shows some of the combinations.
Figure 7-1
45
A typical configuration for the HydroLink has the heat source connected to the “primary” chamber piping on the left side of the unit, along with several load circuits connected to the other “secondary” connections that connect into the manifold chamber. Two additional tapped connections are provided in the top and bottom
of the primary chamber for mounting an air vent and drain valve/makeup water assembly, as shown in Figure 7-5.
The HydroLink product is supplied with a form-fitting insulation shell to minimize heat loss.
closelyspacedtees
THIS
HYDROLINK
vent
drain
closelyspacedtees
hydraulicseparationchamber
replaces
opening
opening
replaces
Figure 7-2
Figure 7-3 Figure 7-4
46
Caleffi also offers distribution manifold stations with integrated hydraulic separation details, an example of which is shown in Figure 7-7.
The small tube that connects the supply and return piping just above the isolation ball valves provides hydraulic separation between the circulator supplying flow from the heat source to the distribution manifold station and the circulator integrated into the distribution manifold station. This allows two or more distribution manifold stations to be piped as shown in Figure 7-8.
Each manifold station is supplied from a common header system. A zone valve opens whenever its associated distribution manifold station requires heat. The Caleffi FlowCal pressure-independent valves maintain the desired flow rate to each manifold
boiler
purgevalves
circulators w/check valves
vent
drain
HydroLink
VENT
hydraulic separation tube
mixingvalve
circulator
Figure 7-5
Figure 7-6
Figure 7-7
47
station. The “crossover” tubes just above the isolation ball valves on each manifold station allow hydraulic separation between the built-in manifold station circulator and the variable-speed pressure-regulated circulator that supplies flow in the headers. This arrangement also allows the option of continuous flow through the distribution circuits connected to the manifold stations. The mixing
valve within each distribution manifold station allows the possibility of high-temperature supply water from the header system. This, in combination with the relatively low return water temperature that is typical of many radiant panel systems, allows a low flow rate between the headers and manifold station, which minimizes pipe size and circulator power requirements.
variable-speedpressure-regulated
circulatorzone valve
FloCal
distribution manifold stationdistribution
manifold station
zone valve
FloCal
purging valve
Figure 7-8
48
This section shows several examples of how air, dirt and hydraulic separation can be applied in modern hydronic heating and cooling systems.
The system shown in Figure 8-1 uses a modulating/condensing boiler to supply two zones of low-temperature radiant panel heating, as well as an indirect domestic water heater.
The limited zoning in this system provides a good match between the modulating output of the boiler and the space-heating loads. Thus, the system is able to operate without a buffer tank.
Upon a demand for heating from either zone thermostat, the Caleffi ZVR103 relay center powers on the associated zone valve and turns on the variable-speed pressure-regulated secondary circulator, as well as the system circulator. The boiler operates based on outdoor reset control and monitors the temperature of the water exiting
the SEP4 separator and flowing onward to the space-heating zones. This allows the boiler to respond to any variations in the water temperature supplied to the distribution system. The secondary circulator operates in a constant differential pressure mode and automatically changes speed as required depending on the number of active space-heating zones. Each zone circuit is equipped with a Caleffi FlowCal balancing valve to assure properly proportioned flow.
Upon a call for domestic water heating, the ZVR103 operates the boiler in setpoint mode to create a higher supply water temperature, which allows for full boiler output to be transferred to the heat exchanger coil inside the indirect water heater. The ZVR103 also turns off the system circulator, temporarily stopping any heat transfer to the space-heating zones.
The SEP4 provides hydraulic separation between the fixed-speed system circulator and the variable-speed secondary circulator. It also provides high-efficiency air and dirt separation, including magnetically enhanced dirt separation. The latter is desirable because of the high-efficiency circulator used in the system.
ZVR103
SEP4secondarycirculator
systemcirculator
prioritycirculator
mod/conboiler
indirect water heater
DHW
CW
ZVR103
SEP4secondarycirculator
systemcirculator
prioritycirculator
mod/conboiler
indirect water heater
Quicksetterbalancing
valves
DHW
CW
outdoortemperature
sensor
Figure 8-1
49
The system shown in Figure 8-2 uses a single modulating/condensing boiler to supply space heating and domestic hot water.
Space heating is supplied by several panel radiators, each of which is equipped with a thermostatic radiator valve allowing it to operate independently of the other panels. Because of the extensive zoning, a small buffer tank is used to prevent boiler short cycling. This buffer tank, when piped as shown, also provides hydraulic separation between the boiler circulator and the variable-speed pressure-regulated distribution circulator.
A vertical Discal air separator is mounted just below the boiler’s outlet port, where the water is hottest and near it lowest pressure. This encourages microbubble formation, capture and elimination from the system.
A float-type air separator is mounted at the top of the buffer tank to prevent air entrapment.
Manual air vents are located in the upper left corner of each panel radiator to expedite air removal at system commissioning.
A DirtMag separator with an integral magnetic collar is mounted on the piping leading into the boiler and boiler circulator. Its use helps ensure that the high-efficiency variable-speed circulator, as well as the small heat exchanger passages inside the boiler, remain clear of ferrous metal particles and other debris.
Domestic hot water is heated by an indirect water heater that is controlled as a priority load by the boiler’s internal control circuitry.
Hydraulic separators can be well-applied in modern geothermal heat pump systems. One example is shown in Figure 8-3.
The HydroCal separator shown in Figure 8-3 provides hydraulic separation between the earth loop circulator and the variable-speed pressure-regulated circulator that provides flow to the heat pumps. This allows for a different flow rate in the earth loop compared to those to the heat pump array. The flow rate to the heat pump array is controlled by the variable-speed pressure-regulated circulator, which responds to the opening and
VENTThermoConbuffer tank
thermostaticradiator valves(TRV) on each
radiator
variable-speedpressure-regulated
distribution circulator
DHW
mod/con boiler
temperaturesensor
(in well)
temperaturesensor
(in well)
indirect water heater
DirtMag
Discal
TRV
TRVTRV
TRV
TRV
Figure 8-2
50
closing of zone valves or motorized ball valves on each heat pump. The earth loop circulator could also vary its speed in response to some control criteria, such as the temperature drop or rise across the earth loop connections to the hydraulic separator. This allows the power required by the earth loop circulator to be reduced as the number of operating heat pumps decreases.
The HydroCal separator also provides high-performance air and dirt removal from the earth loop and heat pump array portions of the system. The latter function is especially useful given the likelihood of dirt and debris entering the earth loop piping during construction.
The system shown in Figure 8-4 uses a Caleffi HydroLink as the “hub” of a multi-temperature/multi-load system.
The conventional boiler supplies heat to the hydraulic separation chamber in the HydroLink. This hydraulically separates the boiler circulator from the other circulators. The water temperature supplied to the boiler is regulated by a Caleffi 3-way ThermoMix boiler protection valve. This ensures the boiler does not operate with low inlet water temperatures that could cause sustained flue gas condensation.
Two of the loads attached to the HydroLink are supplied through Caleffi HydroMixers. These modules include a mixing valve, circulator and differential pressure bypass valve. The mixing valve reduces the water temperature to that required by the low-temperature radiant panel circuits. The differential pressure bypass valve modulates to maintain a reasonably steady differential pressure across
TXV
TXV
TXV
Figure 8-3
51
the manifold station as the manifold valve actuators open and close in response to zone thermostats. The supply water temperature from each HydroMixer can be independently adjusted. The mixing can be done with either a thermostatic valve or motorized 3-way valve.
The HydroLink also supplies hot water directly to the coil of an air handler, which operates as a separate zone.
The indirect water heater is operated as a priority load. It is not connected through the HydroLink. This reduces the amount of piping and water that must be heated during a call for domestic water heating. It also allows
the domestic water heating mode to operate with a single circulator.
To minimize thermal migration, spring-loaded check valves are provided in the piping returning to the boiler from both the indirect water heater and from the HydroLink.
A vertical Discal air separator provides high performance air separation whenever heated water is flowing from the boiler. Likewise, a vertical Dirtcal separator provides dirt separation for all flow about to pass into the boiler.
futureload
to/from zones
medium supply water temperature circuits
low supply water temperature circuits
manifold valve actuators on each circuit
3-way thermostatic mixing valve
vertical Discalair separator
HydroMixers
conventional boiler
integral P bypass valve
indirect water heater
VENT
vertical DirtCal separator
to/from zones
HydroLink
air handler
Figure 8-4
52
The heating loads in large buildings are often supplied from a multiple boiler system. The water temperature required for space heating is determined by the type and size of heat emitters used in the distribution system. When convectors or air handlers are selected as the heat emitters, the water temperature required under design load conditions is relatively high, often in the range of 170º to 190ºF. However, under partial load conditions, the supply water temperature can be reduced using outdoor reset control.
When the water temperature returning from the distribution system is approximately 130ºF or lower, some condensation forms on the combustion side of the boiler heat exchangers. This is beneficial if a modulating/condensing boiler is supplying heat, but must be avoided if a conventional boiler is supplying heat. Thus, when the system is operating at part load with low to medium supply water temperature, it is beneficial to supply the required heat using a modulating/condensing boiler.
However, as outdoor temperature drops, the required supply water temperature increases along with the increasing
load. If modulating/condensing boilers are operating, they will eventually stop condensing and provide almost the same thermal efficiency as conventional boilers.
This situation can be well served by a “hybrid” multiple boiler system that includes both modulating/condensing boilers and conventional boilers. An example of such a system is shown in Figure 8-5.
Under low to medium load conditions, mod/con boilers #1 and #2 provide heat to the system. During this time, the system water temperatures are low enough to allow these boilers to operate with sustained flue gas condensation, and thus high thermal efficiency. As the load and required supply water temperature increases, boiler #3 and eventually boiler #4 are brought online. Boilers #1 and #2 continue to operate, but not in a condensing mode. As such, they contribute heat to the load at approximately the same thermal efficiency as the conventional boilers. This approach reduces overall boiler plant cost because it uses less expensive conventional boilers with efficiency comparable to that of a mod/con boiler operating in non-condensing mode.
boiler #1
VENT
boiler #2
HydroCal
systemcirculator
low-head- loss headers
expansion tank
boiler #3
mixing
boiler #4
mixing
Figure 8-5
53
Figure 8-5 shows how a larger Caleffi HydroCal separator can be used in combination with low-head-loss headers to combine these boilers. The HydroCal unit provides hydraulic separation between the boiler circulators and the system circulator. It also provides high-efficiency air and dirt separation for the system. The low-head-loss headers in combination with the HydroCal separator provide hydraulic separation between the individual boiler circulators.
Note that boilers #3 and #4 include a high-flow-capacity 3-way thermostatic mixing valve. This ensures that the inlet water temperature to these boilers remains above the dewpoint of their exhaust gases, and thus the boilers will operate without sustained flue gas condensation.
The firing order of boilers #1 and #2 can be rotated to allow each boiler to accumulate approximately the same number of run hours over the course of a heating season. This can also be done for boilers #3 and #4.
Figure 8-6 shows an example of a hybrid multiple boiler system using two modulating/condensing boilers as the “lead stages,” and three conventional boilers as stages 3, 4 and 5. The insulating piping above the boiler leads to the hydraulic separator seen wrapped with insulation at the far left of the photo.
Figure 8-7 shows another example of a large (8” pipe size) Caleffi hydraulic separator that has been fully insulated. Large hydraulic separators have several square feet of surface area. Without insulation, this surface area would create a high rate of heat loss and needlessly overheat the mechanical room.
If the hydraulic separator is used for a chilled-water cooling system, or as part of a geothermal earth loop system, the insulation should include a vapor barrier to prevent condensation on the surface of the separator.
For optimal performance, modern hydronic systems require several types of separating devices. These include air separation, dirt separation, and in many cases, hydraulic separation. The latter eliminates undesirable interaction of simultaneously operating circulators. This issue of idronics has discussed the best available technology for providing these functions. When
properly implemented, these functions allow the system to operate without the detrimental effects of entrapped air, accumulating debris and inconsistent flow.
Courtesy of GOES Heating Systems
Courtesy of GOES Heating SystemsFigure 8-6
Figure 8-7
54
circulator
circulator w/
circulator w/
gate valve
globe valves
ball valve
thermostaticradiator valve
thermostaticradiator valve
primary/secondary
cap
hose bibdrain valve
diverter tee
union
swing check valve
spring-loadedcheck valve
purging valve
metered balancing valve
pressure relief valve
brazed- plateheat exchanger
Modulating / condensing boiler
conventional boiler
GENERIC COMPONENTS
indirect water heater (with trim)
pressure & temperature relief valve
CALEFFI COMPONENTS
preventer
pressure- reducingvalve
zone valve(2 way)
zone valve(3 way)
inline check valve
differential pressurebypass valve
Hydro Separator
VENT
DIRTCALdirt separators
high-temperaturesolar DISCAL air separators
high-temperaturesolar pressurerelief valve
high-temperaturesolar air vent
high-temperaturesolar 3-way thermostaticmixing valve
high- temperaturesolar expansiontank
isolar differential temperature controller
FLOCALbalancingvalve
high-temperatureshut-off valve forsolar air vent
solarcirculationstation
mixing units
manifold station with balancing valves
distributionstation
QuickSetterbalancingvalve w/
ThermoBloc™
pressure- reducingvalve (3/4")
motorizedball valve(2 way)
motorizedball valve(3 way)
thermoelectriczone valve(2 way)
geothermalmanifoldstation
DIRTMAGdirt separators
DISCALDIRTair & dirtseparator
DISCALDIRTair & dirtseparator
ThermoConbuffer
tanks (4 sizes)
Starmax Vsolar collector
Comp.
reversingvalve
cond
ense
r
evap
orat
or
TXV
heat
ing
mod
e
reversiblewater-to-waterheat pump
dual isolationvalve forpanel radiators
DISCALDIRTMAGair & dirtseparator
HydroCal Separator
SEP4
HydroCal Separator
55
CALEFFI
FlowCal™ Y-strainer
120 series
Function
The FlowCal™ 120 series Y-strainers include a combination Y-strainer
with integral brass ball valve. Inspection, cleaning and replacing the
strainer cartridge can be done easily without removing the body from
the pipeline. All configurations are available with optional factory-
installed pressure and temperature test ports. Drain valves are also
available as an accessory for installing in the drain port connection.
Product range
120 series FlowCal™ Y-strainer with connections............... 1/2", 3/4", 1", 1-1/4" NPT female union x NPT female union; sweat union x sweat
538202 FD Drain valve for fi eld installation in 1/2", 3/4" 120 series drain port...........................................................connection 1/4" NPT male
538402 FD Drain vlave for fi eld installation in 1", 1-1/4" 120 series drain port...........................................................connection 1/2" NPT male
NA10233 Fast-plug pressure/temperature test port for 120 series Y-strainer, standard length 1-1/2".....................connection 1/4" NPT male
NA10235 Fast-plug pressure/temperature test port for 120 series Y-strainer, extended length 2-1/4".....................connection 1/4" NPT male
Technical specifications
Connections - main: 1/2", 3/4", 1", 1-1/4" NPT female union x
NPT female
1/2", 3/4", 1", 1-1/4" sweat union x sweat
- drain port: 1/2", 3/4" 120 series 1/4" NPTF
1", 1-1/4" 120 series 1/2" NPTF
- PT test ports: 1/4" NPTF
Materials - body: brass
- strainer cartridge: stainless steel
- seals: EPDM
- ball: brass, chrome-plated
- ball and control stem seal: PTFE
- lever: special zinc-plated steel
PerformanceSuitable fl uids: water and non-hazardous glycol solution up to 50%
Max. working pressure: 400 psi (400 WOG)
Working temperature range: 32–212°F
Strainer mesh diameter: 0.87 mm (20 mesh)
Cv: 1/2": 8.0; 3/4" : 8.4; 1" : 19; 1-1/4": 20
Identifi cation: metal plate with ball chain stating mesh size
Dimensions
E
A1/2"3/4"1"
1 1/4"
B6 3/16”6 1/4”8 5/8”
8 11/16”
C1 15/16”1 15/16”3 3/4”3 3/4”
D1 15/16”1 15/16”2 5/8”2 5/8”
A
C
F
B
D
A
E3 15/16”3 15/16”4 3/4”4 3/4”
F1/4"1/4"1/2"1/2"
Code12014 ...12015 ...12016 ...12017 ...
Weight (lb)
3.003.006.006.00
CALE
FFI
56
CALEFFI
® dirt separator
Function
In heating and air conditioning control systems, the circulation of
water containing impurities may result in rapid wear and damage
to components such as pumps and control valves. It also causes
blockages in heat exchangers, heating elements and pipes, resulting in
lower thermal efficiency within the system.
The dirt separator separates off these dirt particles which are mainly
made up of particles of sand and rust, collecting them in a large
collection chamber, from which they can be removed even while the
system is in operation. This device is capable of efficiently removing even
the smallest particles, with very low head loss.
Insulation shells are available separately for field installation on 5462 series
horizontal brass DIRTCAL®.
Product range
5462 series DIRTCAL® dirt separator for horizontal pipes, in brass.....................................connections 3⁄4" to 2" NPT female and 1" to 2" sweat
5465 series DIRTCAL® dirt separator for horizontal pipes, in steel..................................................................connections 2" to 4" ANSI flanged
NA5465 series DIRTCAL® dirt separator for horizontal pipes, in steel, ASME & CRN...........................................connections 2" to 6" ANSI flanged
Technical specifications
Brass DIRTCAL®
- body, dirt collection chamber and top plug: brass
- internal element: glass reinforced nylon PA66G30
- seal: EPDM
- drain valve: brass
Suitable fluids: water, glycol solution
Max. percentage of glycol: 50%
Max. working pressure: 150 psi
Temperature range: 32–250°F
Particle separation efficiency: to 5 μm
- main: 3/4", 1", 1-1/4", 1-1/2" and 2" NPT female
1", 1-1/4", 1-1/2" and 2" sweat
- top: 1/2" F (with plug)
- drain: 3/4" garden hose connection
- vertical: hose connection
Steel DIRTCAL®
- body: epoxy resin painted steel
- internal element: stainless steel
- hydraulic seal: fiber
- drain valve: brass
Suitable fluids: water, glycol solution
Max. percentage of glycol: 50%
Max. working pressure: 150 psi (10 bar)
Temperature range without insulation: 32—250°F (0—120°C)
Particle separation capacity: to 5 μm (0.2 mil)
- flanged: 2"–6" ANSI B16.5 150 CLASS RF
- top: 3/4" M (with plug)
- drain: 1" NPT
- NA5465 series designed and built in accordance
with Section VIII, Division 1 of the AMSE Boiler and Pressure Vessel
Code and tagged and registered with the National Board of Boiler and
Pressure Vessel Inspectors, CRN Registered.
57
Operating principle
The dirt separator operating principle
is based on the combined action of a
number of physical phenomena. The
internal element (1) is composed of a
set of concentric diamond pattern mesh
surfaces. The dirt in the water strikes
these surfaces, separates and drops
into the bottom of the body (2) where
they collect. In addition, the large internal
volume of DIRTCAL® slows down the
velocity of the medium and with the
help of gravity, separates the contained
particles.
The co l l ec ted d i r t can then be
discharged, even with the system
running, by opening the drain valve (3)
with the handle (4).
1
2
3
4
1000
Efficiency50 passages (1.6 f/s)
50201040
20
0
60
80
100
Efficiency (%)Efficiency50 passages (3.2 f/s)
Mic
ropa
rticl
e(Δ
m)
0 5 16 35 63 105
150
250
210
500
Separated quantityInitial quantity
.100%( )
DIRTCALWORKING ZONE
CARTRIDGE FILTER
SPECIAL FILTER
Y-STRAINERS
Particle separation capacity — dirt separator efficiency
Separation efficiency
The capacity for separating the dirt in the medium circulating in the
closed circuits of the hydronic systems depends on three factors:
1. It increases as the size and mass of the dirt particle increases.
The larger and heavier dirt particles drop before the lighter ones.
2. It increases as the fluid velocity decreases. If the velocity decreases,
there is a low-velocity-zone inside the dirt separator and the dirt
particles separate more easily.
3. It increases as the number of recirculations increases. The medium
in the circuit, flowing through the dirt separator a number of times
during operation, is subjected to a continuous separation, until the
dirt particles are completely removed.
The special design of the internal mesh element in the Caleffi DIRTCAL®
dirt separator, is able to completely separate the dirt particles in
the circuit down to a minimum particle size of 5 μm (0.2 mil). The
adjacent graph illustrates how DIRTCAL® quickly separates nearly all
the dirt particles. After only 50 recirculations, approximately one day
of operation, up to 100% is effectively removed from the circuit for
particles of diameter greater than 100 μm (3.9 mil) and on average up
to 80% taking account of the smallest particles. The continual passing
of the medium during normal operation of the system gradually leads to
complete dirt removal.
1¼”
C
2
”
A
B
A
BNPT Sweat
1¼”
C
2
”
Dimensions
C
05A 3⁄4" NPT 45⁄16" 5" 4.2
06A 1" NPT 45⁄16" 5" 4.2
07A 11⁄4" NPT 47⁄8" 6" 5.3
08A 11⁄2" NPT 47⁄8" 6" 6.2
09A 2" NPT 51⁄8" 6" 6.2
28A 1" SWT 51⁄16" 5" 4.2
35A 11⁄4" SWT 53⁄16" 6" 4.2
41A 11⁄2" SWT 53⁄4" 6" 4.9
54A 2" SWT 61⁄8" 6" 5.5
CF
GB
A
D
E
H
K
Tmax 110 CPmax 10 bar
Tmax 105 CPmax 10 bar
BI-DIRECTIONAL
C J*
50A 2" 133⁄4" 1" 143⁄4" 247⁄16" 65⁄8" 3⁄4" 6" 65⁄16" 12" 1.8 29
60A 21⁄2" 133⁄4" 1" 143⁄4" 247⁄16" 65⁄8" 3⁄4" 7" 65⁄16" 12" 1.8 32
80A 3" 183⁄8" 1" 171⁄8" 291⁄8" 85⁄8" 3⁄4" 71⁄2" 75⁄16" 133⁄8" 4.8 51
10A 4" 181⁄2" 1" 171⁄8" 291⁄8" 85⁄8" 3⁄4" 9" 75⁄16" 133⁄8" 4.8 54
50A 2" 133⁄4" 1" 165⁄16" 237⁄8" 65⁄8" 3⁄4" 6" 65⁄16" 12" 1.8 38
60A 21⁄2" 133⁄4" 1" 165⁄16" 237⁄8" 65⁄8" 3⁄4" 7" 65⁄16" 12" 1.8 38
80A 3" 183⁄8" 1" 2011⁄16" 305⁄8" 85⁄8" 3⁄4" 71⁄2" 75⁄16" 133⁄8" 4.8 55
10A 4" 183⁄8" 1" 2011⁄16" 305⁄8" 85⁄8" 3⁄4" 9" 75⁄16" 133⁄8" 4.8 55
12A 5" 25" 1" 233⁄16" 3415⁄16" 123⁄4" 3⁄4" 10" 93⁄8" 173⁄16" 13.7 138
15A 6" 25" 1" 233⁄16" 3415⁄16" 123⁄4" 3⁄4" 10" 93⁄8" 173⁄16" 13.7 148
*This dimension allows for a minimum of 3" wall clearance to accommodate insulation if used.
58
CALEFFI
DISCAL ® air and dirt separator
Function
Air and dirt separators are used to continuously remove the air and debris
contained in the hydronic circuits of heating and cooling systems. The air
discharge of these devices is very high. They are capable of automatically
removing all of the air present in the system down to the micro-bubble
level. The DISCALDIRT®
air and dirt separator also separates any solid
impurities in the system. The impurities collect at the bottom of the device
and can be removed through the drain pipe for the steel versions, to which
a separately sourced drain valve can be mounted, or drain shut-off valve
for the brass version. The circulation of fully de-aerated and cleaned water
enables the equipment to operate under optimum conditions, free from
noise, corrosion, localized or mechanical damage.
Insulation shells are available separately for fi eld installation for the brass
DISCALDIRT®
air and dirt separators.
Product range
5460 series DISCALDIRT®
air and dirt separator in brass..........................................................connections 3/4", 1", 1-1/4" sweat & 1" NPT male
546 series DISCALDIRT®
air and dirt separator in steel with fl anged connections..........................................................connections 2"–6" ANSI
NA546 series DISCALDIRT®
air and dirt separator in steel with fl anged connections...................................................connections 2-1/2"–12" ANSI
*Prefi x NA are designed and built in accordance with Section VIII, Division 1 of the ASME Boiler and Pressure Vessel Code and
tagged and registered with the National Board of Boiler and Pressure Vessel Inspector; CRN registered
Technical specifications
Brass DISCALDIRT®
- body: brass
- dirt separation chamber: brass
- air vent body: brass
- internal element: glass reinforced nylon, PA66GF30
- air vent fl oat: PP
- air vent fl oat guide pin: stainless steel
- air vent fl oat linkages: stainless steel
- spring: stainless steel
- seals: EPDM
- drain shut-off valve: brass
Suitable fl uids: water, glycol solution
Max. percentage of glycol: 50%
Max. working pressure: 150 psi
Temperature range: 32–250°F
Particle separation effi ciency: to 5 μm (0.2 mil)
- main: 3/4", 1", 1-1/4" sweat; 1" NPT male
- drain shut-off valve: hose connection
Steel DISCALDIRT®
- body: epoxy resin painted steel
- air vent body: brass
- internal element: 304 stainless steel
- air vent fl oat: PP
- air vent fl oat guide pin: stainless steel
- air vent fl oat linkages: stainless steel
- spring: stainless steel
- seals: EPDM
- side drain shut-off valve: brass
Suitable fl uids: water, glycol solution
Max. percentage of glycol: 50%
Max. working pressure: 150 psi
Temperature range: 32–250°F
Particle separation effi ciency: to 5 μm (0.2 mil)
- fl anged (ASME & CRN registered):
2"–12" ANSI B16.5 150 CLASS RF
- fl anged: 2"–6" ANSI B16.5 150 CLASS RF
- drain pipe: 2"–6": 1" NPT male
8"–12": 2" NPT male
59
Operating principle
The air and dirt separator uses the
combined action of several physical
principles. The active part is the
internal element (1) and consists of a
glass-reinforced nylon mesh for the
brass DISCALDIRT®, or an assembly
of concentr ic metal mesh ( 304
stainless steel) surfaces for the steel
DISCALDIRT®. These elements create
the whirling movement required to
facilitate the release of micro-bubbles
and their adhesion to these surfaces.
The bubbles, fusing with each other, increase in volume until the
hydrostatic thrust is such as to overcome the adhesion force to the
structure. They rise towards the top of the unit from which they are
released through a float-operated automatic air vent valve.
The DISCALDIRT®
dirt removing element
separates and collects any impurities present
in the system. Impurities in the fluid upon
striking the surfaces of the DISCALDIRT®
internal element (1), get separated and
drop to the bottom of the body in the dirt
collection chamber (2) where they collect.In
addition, the large internal volume of slows
down the velocity of the fluid thus helping, by
gravity, to separate the particles it contains.
The collected impurities are discharged, by
opening the drain valve (3), even with the
system operating.
1
2
3
®
Dimensions
A
BC
F
DE
* Add prefix NA to flanged code number when ordering ASME tagged and registered with the
National Board of Boiler and Pressure Vessel Inspector and CRN registered.
Drawings may not reflect the actual size of the separators.
C
95A Sweat 3⁄4" 73⁄8" 21⁄8" 5" 51⁄2" 123⁄4" 8.3
96A Sweat 1" 73⁄8" 21⁄8" 5" 51⁄2" 123⁄4" 8.3
16A NPT male 1" 73⁄8" 21⁄8" 5" 51⁄2" 123⁄4" 8.3
97A Sweat 11⁄4" 63⁄16" 21⁄8" 5" 51⁄2" 123⁄4" 8.3
B
F
G
AD
E
38552
H
C
J
3 1/8”3 1/
8”
B
F
G
AD
E
38552
H
C
3 1/8”
* Add prefix NA to flanged code number when ordering ASME tagged and registered with the
National Board of Boiler and Pressure Vessel Inspector and CRN registered.
C
050A 2" 133⁄4" 23⁄16" 149⁄16" 281⁄4" 65⁄8" 1" 1311⁄16" 3.6 39.7
060A 21⁄2" 133⁄4" 23⁄16" 149⁄16" 281⁄4" 65⁄8" 1" 1311⁄16" 3.6 41.9
080A 3" 183⁄8" 23⁄16" 17" 341⁄2" 8 5⁄8" 1" 171⁄2" 7.6 72.7
100A 4" 181⁄2" 23⁄16" 17" 341⁄2" 8 5⁄8" 1" 171⁄2" 7.8 77.1
120A 5" 25" 23⁄16" 211⁄16" 4611⁄16" 123⁄4" 1" 255⁄8" 22.4 180.7
150A 6" 25" 23⁄16" 211⁄16" 4611⁄16" 123⁄4" 1" 255⁄8" 23.0 187.3
C J
200A 8" 357⁄16" 23⁄16" 353⁄16" 753⁄8" 20" 2" 433⁄16" 923⁄4" 95 355
250A 10" 413⁄4" 23⁄16" 389⁄16" 8613⁄16" 26" 2" 481⁄4" 1011⁄16" 175 555
300A 12" 467⁄16" 23⁄16" 411⁄8" 9311⁄16" 30" 2" 529⁄16" 1075⁄16" 255 825
60
CALEFFI
Automatic air ventfor heating systems and radiators
Series 501 MINICAL® 5020-5021 5022 - 5023 5026 - 5027 5080
Materials
Body: brass brass brass brass chrome plated brass
Float: stainless steel polypropylene PP PP -
Mechanism stem: stainless steel brass brass - -
Mechanism seal: viton - EPDM silicon rubber -
Seals: EPDM EPDM EPDM EPDM EPDM
Performance
Max working pressure: 230 psi 150 psi 150 psi 150 psi 150 psi
Max venting pressure: 90 psi 40 psi 60 psi 90 psi -
Max working
temperature:250°F
502015A 250°F502115A 230°F
250°F 240°F 212°F
Function
Automatic air vents are designed to remove trapped air that
accumulates in heating and air conditioning systems automatically.
Air removal enhances performance and life of a system by reducing
the affects of:
- corrosion due to the oxygen;
- pockets of air trapped in the heating emitters;
- cavitation in the circulation pumps.
- service check valve allows an easy replacement of air vent without
purging the system (except 5080).
Series 501
Extra high capacity float type automatic air vent designed for use on
large pipes where large quantity of air is required to be released from
the system.
Series 5022 - 5023
High capacity float type automatic air vent designed for use on
manifolds or pipes in sealed heating systems.
Series 5020 - 5021 - 5026 - 5027
Float type automatic air vent designed to vent air that is released from
the water while being heated.
Series 5080
Radiator air vent valve designed to remove automaticall any air
trapped inside the heat emitters both during the filling of the system
and in normal operation.
Product range
501 series Extra high capacity automatic air vent..................................................................................................connections 3/4" NPT female
5020 series `MINICAL® automatic air vent..................................................................................................................connections 1/8" NPT male
5021 series MINICAL® automatic air vent with service check valve............................................................................connections 1/8" NPT male
5022 series High capacity automatic air vent............................................................................................................connections 1/2" NPT male
5023 series High capacity automatic air vent with service check valve.......................................................................connections 1/2" NPT male
5026 series Automatic air vent .......................................................................................................................connections 1/8" - 1/4" NPT male
5027 series Automatic air vent with service check valve...................................................................................connections 1/8" - 1/4" NPT male
5080 series Automatic hygroscopic air vent for radiators...........................................................................................connections 1/8" NPT male
61
C
EB
A
A
E
BCD
F
E
C
B
AF
DB’ E’
A
A
3/8”
B
3/4”
D
3 13/16”
E
6 1/4”
F
5 5/16”
C
1 9/16”
Code
501502A
A
1/8”
1/4”
B
3 1/16”
3 1/16”
D
7/16”
1/2”
E
2 5/8”
2 5/8”
C
1 9/16”
1 9/16”
Code
502610A
502620A
A B’
4 3/4”
D
1/2”
C
2 3/16”
Code
502343AA
1/8”
B
1 1/4”
D
7/16”
E
13/16”
F
9/16”
C
11/16”
Code
508013A
A
1/8”
1/4”
B’
4”
4”
D
1/2”
1/2”
E’
3 3/8”
3 3/8”
C
1 9/16”
1 9/16”
Code
502710A
502720A
DD
C
B
D
A
A
D
B’ E’
E’
3 1/4”
E
A
1/2” NPT
B
4”
D
1/2”
C
2 3/16”
Code
502243A
E
2 1/2”
A
1/8” NPT
B
3 1/8”
D
3/8”
C
1 7/8”
Code
502015A
E
2 3/4”
A
1/8” NPT
B
3 11/16”
D
3/8”
C
1 7/8”
Code
502115A
E’
3 5/16”
1/2” NPT
Operation
The accumulation of air bubbles in the valve
body causes the float to drop so that the air
vent valve opens when the water pressure is
below the maximum venting pressure rating.
Construction details
The service check valve seals off the vent
body with an EPDM O-ring, allowing easy
maintenance by shutting off the water flow
when the vent is removed. This feature also
allows for easy inspection of the air vent.
All MINICAL® models can be equipped with the optional hygroscopic
safety cap, part number R59681. This special cap contains cellulose
fiber discs that form a seal by increasing their volume 50% when
they become wet. This prevents potential damage in case of
leakage.
5026 - 5027Flow rate
3.5
4 .5
4.5
5.5
5.5
6 .5
3.5
2.5
2.5
1.5
1.5
0.5
0
9080706050403020100
(bar
) (
psi)
(SCFM) (Nl/s)
1
0.1
0
0.5
0.90.80.70.6
0.40.30.2
1.2
1.1
5022 - 5023
0
2.5
0.25
0.5
0.75
1
1.25
1.5
1.75
2
2.251
0.1
0
0.5
0.90.80.70.6
0.40.30.2
1.2
1.1
5020 - 5021
Air flow
Flow rate
3.5
4 .5
4.5
5.5
5.5
6 .5
3.5
2.5
2 .5
1.5
1 .5
0.5
0
9080706050403020100
(bar
) (
psi)
SCFM (SCFM) (Nl/s)5
0.5
0
2.5
4.543.53
21.51
1
10
23456789
01
10
23456789
0
501The components used for the
elimination of air such as the
float, sliding guide zones, spring
and mechanism stem are made
of stainless steel. This minimizes
the friction and ensures maximum
reliability.
The venting air is passed through
a forced passage and a filter with
a thin mesh strainer. This prevents
leakage due to debris, that can be
deposited between the seat and
the mechanism.
The size of this air vent makes it
suitable for applications on large
pipes, particularly on horizontal
sections (distribution manifolds in central boilers applications) or
wherever it is required to release large quantities of air from the
system.
(Nl/s)
®
62
CALEFFI
DISCAL® air separator
551 series
Function
Air separators are used to continuously remove the air contained
in the hydronic circuits of heating and cooling systems. The air
discharge capacity of these devices is very high. They are capable of
removing automatically all the air present in the system down to the
micro-bubble level.
The circulation of fully de-aerated water enables the equipment to
operate under optimum conditions, free from noise, corrosion, localized
or mechanical damage. Micro-bubbles, fusing with each other, increase
in volume (get larger) until they become large enough to rise to the top
where they are automatically released.
Product range
551 series DISCAL® air separator for horizontal pipes, in brass with drain.............................................connections 3/4", 1", 1-1/4", 1-1/2" and 2"
551 series DISCAL® air separator for horizontal pipes, in steel with flanged connections and drain......................................connections 2" to 6"
NA551 series DISCAL® air separator for horizontal pipes, in steel with flanged connections with drain, ASME and CRN..........connections 2" to 6"
NA5519 series DISCAL® air separator for vertical pipes, in brass......................................................................connections 3/4" and 1" integral sweat
Technical specifications
Brass air separator
- body: brass
- internal element
(compact & vertical versions): 304 stainless steel
- internal element: glass reinforced nylon PA66GF30
- seal: EPDM
- air vent float guide pin: stainless steel
Suitable fluids: water, glycol solution
Max. percentage of glycol: 50%
Max. working pressure: 150 psi
Temperature range: 32–250°F
- main:
compact series: 3/4" sweat; 3/4" NPT female
horizontal: 3/4", 1", 1-1/4", 1-1/2" and 2" NPT female
1", 1-1/4", 1-1/2" and 2" sweat
vertical: 3/4" and 1" sweat
- drain valve: 1/2" NPT female
Steel air separator
- body: epoxy resin painted steel
- internal element: 304 stainless steel
- seal: EPDM
- air vent float guide pin: stainless steel
Suitable fluids: water, glycol solution
Max. percentage of glycol: 50%
Max. working pressure: 150 psi
Temperature range: 32–250°F
- flanged: 2"– 6" ANSI B16.5 150 CLASS RF
- drain pipe: 1" NPT male
- NA551 series is designed and built in accordance
with Section VIII, Division 1 of the ASME Boiler
and Pressure Vessel Code and tagged and
registered with the National Board of Boiler and
Pressure Vessel Inspector, and CRN registered.
D
B
E
A A AD
B
E
A
F FA
A DE
C C C
B
G
* Add suffix C to sweat and NPT code number when ordering the brass
DISCAL® to ship with expansion tank service check valve, code 561402A.
Dimensions
C
003A* 3⁄4" 31⁄16" 23⁄16" 53⁄8" 67⁄8" 1⁄2" 2.0
022A* 3⁄4" SWT 31⁄16" 23⁄16" 53⁄8" 67⁄8" 1⁄2" 2.0
995 3⁄4" 51⁄16" 23⁄16" NA 93⁄16" 1⁄2" 4.5
996 1" 61⁄16" 23⁄16" NA 99⁄16" 1⁄2" 4.5
63
Operating principles
The DISCAL® air separator
is used to cont inuous ly
remove the air contained in
hydronic circuits of heating
and cooling systems. The air
discharge capacity is very
high. They are capable of
removing automatically all
the air present in the system
down to micro-bubble level
with low head loss due the
special internal shape of
the separator body. Flow
direction of the DISCAL® air
separator is bidirectional; flow
in either direction is permitted.
The a i r s epa ra to r uses t he
combined action of several physical
principles. The active part consists
of an assembly of concentric mesh
surfaces (1). These elements create
the whirling movement required
to facilitate the release of micro-
bubbles and their adhesion to these
surfaces.
The bubbles, fusing with each other,
increase in size until the hydrostatic
thrust overcomes the adhesion force
to the mesh. They rise towards the
top of the unit from which they are
released through a float-operated
automatic air vent, with stainless
steel float guide pin (3).
2
1
3
0
10
20
30
40
50
60
70
80
90
100
0 100
200
300
400
500
600
700
800
900
1000
1100
1200
Tme
(sec
)
14.5 psi29 psi43.5 psi
Air introduced - Air removed - (%)
Air separation efficiency
DISCAL® air separators continuously remove entrapped air in hydronic
systems with very high efficiency. The amount of air removed from a
system varies depending on fluid velocity and system pressures. As
illustrated on the graph, after just 25 recirculations at the 3.2 feet per
second fluid velocity, almost all the air artificially introduced into the
circuit is eliminated by the DISCAL® air separator, with percent removed
varying based on system pressure and fluid temperature.
The small amount which remains is then gradually eliminated during
normal system operation. In conditions where the fluid velocity is slower
or the temperature of the medium is higher, the amount of air separated
is even greater.
F J
CB
AH
DE
F
Tmax 250ϒFPmax 150 psi
Tmax 220ϒFPmax 150 psi
BI-DIRECTIONAL
3846
6.01
G
WA
LL
AD
B
E
A
F
AD
B
E
F
A
C C
** Add prefix NA to flanged code number when ordering ASME tagged and registered with the
National Board of boiler and Pressure Vessel Inspector and CRN registered.
†This dimension allows for a minimum of 3" wall clearance to accommodate insulation if used.
* Add suffix C to sweat and NPT code number when ordering the brass
DISCAL® to ship with expansion tank service check valve, code 561402A.
C J†
** 050A 2" 133⁄4" 1" 143⁄4" 1915⁄16" 65⁄8" 213⁄16" 6" 65⁄16" 34
** 060A 21⁄2" 133⁄4" 1" 143⁄4" 1915⁄16" 65⁄8" 213⁄16" 7" 65⁄16" 35
** 080A 3" 183⁄8" 1" 171⁄8" 237⁄16" 85⁄8" 213⁄16" 71⁄2" 75⁄16" 62
** 100A 4" 181⁄2" 1" 171⁄8" 237⁄16" 85⁄8" 213⁄16" 9" 75⁄16" 67
120A 5" 25" 1" 217⁄16" 301⁄2" 123⁄4" 213⁄16" 10" 93⁄8" 106
150A 6" 25" 1" 217⁄16" 301⁄2" 123⁄4" 213⁄16" 10" 93⁄8" 117
1.8 1.8 4.8 4.8 13.7 13.7
C
005A* 3⁄4" 45⁄16" 23⁄16" 53⁄4" 71⁄2" 1⁄2" 3.7
006A* 1" 45⁄16" 23⁄16" 53⁄4" 71⁄2" 1⁄2" 3.7
007A* 11⁄4" 47⁄8" 23⁄16" 69⁄16" 81⁄4" 1⁄2" 4.9
008A* 11⁄2" 47⁄8" 23⁄16" 69⁄16" 81⁄4" 1⁄2" 4.9
009A* 2" 51⁄8" 23⁄16" 69⁄16" 81⁄4" 1⁄2" 5.5
028A* 1" SWT 51⁄16" 23⁄16" 53⁄4" 71⁄2" 1⁄2" 3.7
035A* 11⁄4" SWT 53⁄16" 23⁄16" 65⁄16" 81⁄4" 1⁄2" 3.7
041A* 11⁄2" SWT 53⁄4" 23⁄16" 69⁄16" 81⁄4" 1⁄2" 4.9
054A* 2" SWT 61⁄8" 23⁄16" 69⁄16" 81⁄4" 1⁄2" 5.5
Dimensions
64
CALEFFITech ref: 01076
Hydro separator
548 and NA548 series
Function
The Caleffi 548 and NA548 series hydraulic separator creates a zone
with a low pressure loss, which enables primary and secondary circuits
connected to it to be hydraulically independent of each other;
This device
consists of several different functional components, each of which
meets specifi c requirements, typical of the circuits used in heating and
air-conditioning systems.
- To keep connected hydronic circuits totally
independent from each other.
- To permit the separation and collection of any
impurities present in the circuits. Provided with a valved connection
with discharge piping.
- For automatic venting of any air
contained in the circuits. Provided with a valved connection for
maintenance purposes.
Product range
548 series Hydro separator in steel with union connections, drain and insulation..........................................................connections 1" to 2"
548 series Hydro separator in steel with fl anged connections, drain and insulation.............................................connections 2" to 4" ANSI
NA548 series Hydro separator in steel with fl anged connections, drain and insulation ASME and CRN....................connections 2" to 4" ANSI
NA548 series Hydro separator in steel with fl anged connections and drain, ASME and CRN...............................connections 5" to 12" ANSI*
*Larger sizes available, consult factory
Technical specifications
Threaded and sweat connections- main: 1", 1¼", 1½", 2" NPT female union
1", 1¼", 1½", 2" sweat union
- drain valve: ¾" garden hose thread
- thermo well trap: ½" straight thread female
- separator body: epoxy resin painted steel
- air vent body: brass
- shut off and drain valve body: brass
Suitable fl uids: water and non-hazardous glycol solution up to 50%
Max. operating pressure: 150 psi
Working temperature range with insulation: 32–210°F
Working temperature range without insulation: 32–250°F
Materials: double density closed cell expanded PEX
Thickness: 3/4" Density: - internal part: 2 lb/ft
- external part: 3 lb/ft
Thermal conductivity: 32°F: 9 BTU/in
-40°F: 11 BTU/in
Coeffi cient of resistance to the diffusion of vapor: >1,300 Temperature range: 32–210°F
Reaction to fi re (DIN4102): class B 2
Flanged connections- main: 2"-12"ANSI B16.5 150 CLASS RF
- drain valve: 2 — 6": 1¼" NPT female
8 — 12": 2" NPT female
- thermo well trap (8 — 12" only):
- front center: ¾" NPT female
- inlet/outlet fl anges: ½" NPT female
- separator body: epoxy resin painted steel
- air vent body: brass
- shut off and drain valve body: brass
- internal baffl e: stainless steel
Suitable fl uids: water and non-hazardous glycol solution up to 50%
Max. operating pressure: 150 psi
Working temperature range with insulation: 32–210°F
Working temperature range without insulation (vessel): 32–270°F
Materials: rigid closed cell expanded polyurethane foam
Thickness: 2 3/8"
Density: 3 lb/ft
Thermal conductivity: 6 BTU/in
Temperature range: 32–220°F
Materials: embossed aluminum
Thickness: 7.0-mil
Reaction to fi re (DIN 4102): class 1
Heat formed materials: PS
65
Code548052A548062A548082A548102ANA548120A*NA548150A*
FB
CD
EA
HYDRO SEPARATORSerie 548
Tmax 120 CPmax 10 bar
Tmax 105 CPmax 10 bar
A
A2”
2 1/4”
3”4”5”6”
B1 1/4”
1 1/4”
1 1/4”
1 1/4”
1 1/4”
1 1/4”
C13”13”15”15”15”15”
D13”13”18”18”22”22”
E15”15”17”17”19”19”
E14”14”18”18”25”25”
Weight (lb)
7582
112117220231
Flow (gpm)
4080
124247300484
Vol. (gal)
4.04.08.08.0
22.523.2
Dimensions
Operating principle
When a single system contains a primary production circuit, with its
own pump, and a secondary user circuit, with one or more distributions
pumps, operating conditions may arise in the system whereby the pumps
interact, creating abnormal variations in circuit flow rates and pressures.
The hydraulic separator creates a zone with a low pressure loss, which
enables the primary and secondary circuits connected to it to be
hydraulically independent of each other;
In this case, the flow rate in the respective circuits depends exclusively
on the flow rate characteristics of the pumps, preventing reciprocal
influence caused by connection in series.
Therefore, using a device with these characteristics means that the flow
in the secondary circuit only circulates when the relevant pump is on,
permitting the system to meet the specific load requirements at that time.
Gprimary = Gsecondary
Primary Secondary
Gp Gs
Gp Gs
primary secondary
Gprimary > Gsecondary
Primary Secondary
Gp Gs
Gprimary < Gsecondary
Primary Secondary
Gp Gs
When the secondary pump is off, there is no circulation in the secondary
circuit; the whole flow rate produced by the primary pump is by-passed
through the separator.
With the hydraulic separator, it is therefore possible to have a primary
production circuit with a constant flow rate and a secondary distribution
circuit with a variable flow rate; these operating conditions are typical of
modern heating and cooling systems.
* without insulation
NA prefix indicates ASME tagged and registered with the National Board of Boiler
and Pressure Vessel Inspectors.
Add NA prefix to 2” to 4” flanged connection for ASME approved.
For larger ASME sizes consult with factory.
A1”
1 1/4”
1 1/2”
2”
B8 3/4”
9 3/8”
10 7/8”
12”
C6 1/4”
7 3/8”
7 3/4”
10 1/8”
Code 548006A/96A 548007A/97A 548008A/98A 548009A/99A
Weight (lb)
13172527
DE
C
B
AA
Tmax 120 CPmax 10 bar
Tmax 105 CPmax 10 bar
HYDRO SEPARATOR
D8 5/8”
9 1/2”
10 1/4”
11 7/8”
D8”
8 3/8”
8 3/4”
9 1/2”
Flow (gpm)
11182634
Vol. (gal)
0.50.71.33.5
A8”
10”12”
CodeNA548200ANA548250ANA548300A
F
DC
EA
A
B2”2”2”
C39 3/8”
43 5/16”
47 1/4”
D33 7/8”
35 7/8”
37 7/8”
E27 1/2”
30”31 1/2”
D35 1/2”
41 3/4”
47 3/4”
Weight (lb)
520725
1,100
Flow (gpm)
7921,3301,850
Vol. (gal)
95175255
HYDRO-SEPARATORSerie 548
Tmax 110 C Pmax 10 bar
38...
B
66
CALEFFI
HydroCal™ combination hydraulic, air and dirt separator549 and NA549 series
Function
The Caleffi HydroCal™ combination hydraulic, air and dirt separator
is a device that combines high performance air and dirt removal with
hydraulic separation. Primary and secondary circuits connected to it
become hydraulically decoupled thus eliminating pump conflict.
A proven, time tested stainless steel internal coalescing element
continuously and automatically eliminates all entrained air, including
microbubbles, in the system. Air discharge capacity is very high. Over
time, dirt particles as tiny as 5 microns are captured and collected
away from the flow stream.
The 3-in-1 high performance functionality of the HydroCal™ saves
system installation and maintenance cost as there is no need to include
separate air and dirt separators. It can be used on either hot or chilled
water systems.
Product range
549 series HydroCal™ hydraulic, air and dirt separator in steel with flanged connections insulation.......................................connections 2–4" ANSI
NA549 series HydroCal™ hydraulic, air and dirt separator in steel with flanged connections, insulation, ASME and CRN......... connections 2–4" ANSI
NA549 series HydroCal™ hydraulic, air and dirt separator in steel with flanged connections ASME and CRN.........................connections 6–12" ANSI*
*Larger sizes are available, consult factory
FB
CD
EA
A
Tmax 250ϒFPmax 150 psi
Tmax 220ϒFPmax 150 psi
3871
1
BI-DIRECTIONAL
2–6”
8–12”
HYDRO
Technical specifications
- flanged: 2–12" ANSI B16.5 150 CLASS RF
- drain valve: 2–6": 1-1/4" NPT female
8–12": 2" NPT female
- thermometer pockets (8–12" only):
front center: 3/4" NPT female
inlet/outlet flanges: 1/2" NPT female
- separator body: epoxy resin painted steel body
- air vent body brass
- shut-off and drain valve body: brass
- internal element: stainless steel
- air vent seal: VITON
- air vent float: stainless steel
Suitable fluids: water and non-hazardous glycol solutions up to 50%
Max. operating pressure: 150 psi
Working temperature range with insulation: 32–220°F
Working temperature range without insulation (vessel): 32–270°F
Particle separation capacity: to 5 μm
Series NA549 is designed and built in accordance with Section VIII,
Division 1 of the ASME Boiler and Pressure Vessel Code and tagged
and registered with the National Board of Boiler and Pressure Vessel
Inspector, and CRN registered.
Technical specifications of insulation up to 4"
Material: rigid closed cell expanded polyurethane foam
Thickness: 2-3/8"
Density: 3 lb/ft3
Conductivity (ISO 2581): 0.16 BTU·in/hr·ft2·°F (0.023 W/(m·K)
Temperature range: 32–220°F
Material: embossed aluminium
Thickness: 7-mil (0.70 mm)
Fire resistance (DIN 4102): class 1
Heat formed material: PS
Dimensions
A B C D E F
549052A 2" 11⁄4" 13" 13" 15" 14" 73 37.3 4.0
549062A 21⁄2" 11⁄4" 13" 13" 15" 14" 79 63 4.0
549082A 3" 11⁄4" 15" 173⁄4" 17" 18" 108 95.5 8.0
549102A 4" 11⁄4" 15" 173⁄4" 17" 18" 117 149 8.0
NA549150A* 6" 11⁄4" 15" 22" 19" 25" 231 380 23.2
NA549200A* 8" 2" 337⁄8" 393⁄8" 271⁄2" 351⁄2" 520 625 95.0
NA549250A* 10" 2" 337⁄8" 435⁄16" 30" 413⁄4" 725 1,030 175
NA549300A* 12" 2" 337⁄8" 471⁄4" 311⁄2" 473⁄4" 1100 1,650 255
*Without insulation
NA prefix indicates ASME tagged and registered with the National Board of Boiler and Pressure
Vessel Inspectors and CRN registered.
Add NA prefix to 2" to 4" flanged connection for ASME approved, CRN registered.
Tech ref: 01178
67
The air vent (A), replacement part number 501502A, is isolated
manually, using a shut-off ball valve (B), replacement part number
NA39589.
The HydroCal™ dirt removing
element separates and collects
any impu r i t i e s p resen t i n
the system.
These impurities are removed by
the drain valve (C) replacement
par t number NA39588 fo r
connection sizes 2–6"; NA59600
for connection size 8–12", which
can be connected to a discharge
pipe, at the bot tom of the
separator.
T h e H y d r o C a l ’s i n t e r n a l
element (1) creates the whirling
movement required to facilitate
the release of microbubbles and
their adhesion to the internal
element surfaces. The bubbles,
fusing with each other, increase
in size until the hydrostatic thrust
overcomes the adhesion force
to the mesh. They rise towards
the top of the unit from which
they are released through a float-
operated automatic air vent.
Impurit ies in the f luid upon
str iking the surfaces of the
HydroCal’s internal element (1),
get separated and drop to the
bottom of the body (2) where
they collect.
In addition, the large internal
volume of HydroCal™ slows
down the flow speed of the
fluid thus helping, by gravity, to
separate the particles it contains.
The collected impurit ies are
discharged, by opening the drain
valve (3) with the handle (4), even
with the system operating.
Operating principle
When a single system contains a primary production circuit, with its
own pump, and a secondary user circuit, with one or more distribution
pumps, operating conditions may arise in the system whereby the
pumps interact, creating abnormal variations in circuit flow rates and
pressures. The hydraulic separator creates a zone with a low pressure
loss, which enables the primary and secondary circuits connected to it
to be hydraulically independent of each other;
In this case, the flow rate in the respective circuits depends exclusively
on the flow rate characteristics of the circuit pumps, preventing
reciprocal influence caused by connection in series. Therefore, using a
device with these characteristics means that the flow in the secondary
circuit only circulates when the relevant pump is on, permitting the
system to meet the specific load requirements at that time.
When the secondary pump is off, there is no circulation in the secondary
circuit; the whole flow rate produced by the primary pump is by-passed
through the separator. With the hydraulic separator, it is therefore
possible to have a primary production circuit with a constant flow rate
and a secondary distribution circuit with a variable flow rate; these
operating conditions are typical of modern heating and cooling systems.
Three possible hydraulic balance situations are shown below.
Primary Secondary
Gp Gs
Primary Secondary
Gp Gs
Primary Secondary
Gp Gs
rimary = econdary rimary > econdary rimary < econdary
2
3
4
1
C
Construction details
68
The SEP4™ combination hydraulic, air, dirt and magnetic separator
is a device that, incorporates high performance air and magnetic and
non-magnetic dirt removal functionality into the hydraulic separation
function which makes the primary and secondary circuits connected
to it hydraulically independent, and can be used on hot or chilled water
systems.
The SEP4™ features an HDPE internal element that combines to
continuously and automatically eliminate air micro-bubbles with the
simultaneous removal of dirt particles as tiny as 5 microns. The air
discharge capacity is very high, with the capability of automatically
removing all the air present in the system down to the micro-bubble level.
The 4-in-1 high performance functionality of the SEP4™ saves system
installation and maintenance costs as there is no need to include separate
air and dirt separators. In addition to removing sand and rust impurities,
the added powerful removable external magnetic ring around the lower
body removes up to 95% of the ferrous oxide particles that can form in a
hydronic system.
Code A SEP4™ hydraulic, air, dirt and magnetic separator connections .............................................1", 1¼", 1½", 2" NPT female union
Code A SEP4™ hydraulic, air, dirt and magnetic separator connections .................................................... 1", 1¼", 1½", 2" sweat union
Product range
CALEFFI
SEP ™ combination hydraulic, air,dirt and magnetic separator5495 series
Technical specifications
- body: epoxy resin coated steel
- union nuts: NPTF tailpiece, galvanized metal
sweat tailpiece, brass
- air vent body: brass EN 12165 CW617N
- air vent hydraulic seal: EPDM
- air vent fl oat: PP
- air vent fl oat link & guide pin: stainless steel
- int. element: HDPE
- drain valve body: brass EN 12165 CW617N
- magnet: neodymium rare-earth
Suitable fl uids: water, glycol solution
Max. percentage of glycol: 50%
Max. working pressure: 150 psi
Working temperature range: without insulation 32 – 230°F
with insulation 32 – 210°F
Particle separation capacity: to 5 μm (0.2 mil)
Magnetic particle separation effi ciency: up to 95% removal
Main connections: 1", 1¼", 1½", 2" NPT F brass unions
1", 1¼", 1½", 2" sweat brass unions
Thermowell tap connection: ½" F straight thread
Drain valve: ¾" hose
Material: closed-cell expanded PE-X
Thickness: 13/16"
Density: - inner insulation: 1.9 lb/ft3
- outer skin: 5.0 lb/ft3
Conductivity (ISO 2581): at 32°F; .16 BTU/in
at 105°F; .26 BTU/in
Water vapor resistance coeffi cient (DIN 52615): > 1,300
Temperature range: 32–212°F
Fire resistance (DIN 4102): class B2
DE
C
B
AA
Dimensions
C
06A/96A 1" 83⁄4" 65⁄8" 8 5⁄8" 6" 15 11 0.5
07A/97A 11⁄4" 93⁄4" 65⁄8" 91⁄2" 57⁄8" 19 18 0.7
08A/98A 11⁄2" 11" 65⁄8" 101⁄4" 67⁄8" 27 26 1.3
09A/99A 2" 123⁄8" 63⁄8" 117⁄8" 65⁄8" 29 37 3.5
A: NPT female union connections. A: sweat union connections.
69
Primary Secondary
Gp Gs
Primary Secondary
Gp Gs
Primary Secondary
Gp Gs
rimary = econdary rimary > econdary rimary < econdary
Gp Gs
primary secondary
Operating principle
When a single system contains a primary production circuit, with its
own pump, and a secondary user circuit, with one or more distribution
pumps, operating conditions may arise in the system whereby the pumps
interact, creating abnormal variations in circuit fl ow rates and pressures.
The hydraulic separator creates a fl ow path with a low pressure loss,
which enables the primary and secondary circuits connected to it to be
hydraulically independent of each other;
In this case, the fl ow rate in the respective
circuits depends exclusively on the fl ow rate characteristics of the circuit
pumps, preventing reciprocal infl uence caused by connection in series.
Therefore, using a device with these characteristics means that the fl ow
in the secondary circuit only circulates when the relevant pump is on,
permitting the system to meet the specifi c load requirements at that
time.
When the secondary pump is off, there is no circulation in the secondary
circuit; the whole fl ow rate produced by the primary pump is by-passed
through the separator. With the hydraulic separator, it is therefore
possible to have a primary production circuit with a constant fl ow rate
and a secondary distribution circuit with a variable fl ow rate; these
operating conditions are typical of modern heating and cooling systems.
Three possible hydraulic balance situations are shown below.
Impurities in the fl uid upon striking
the surfaces of the SEP4’s internal
dirt separation element (2), get
separated and drop to the bottom
of the body (3) where they collect.
In addition, the large internal
volume of SEP4™ slows down the
fl ow speed of the fl uid thus helping,
by gravity, to separate the particles
it contains.
The col lected impuri t ies are
discharged, by opening the drain
valve (4) with the handle (5), even
with the system operating.
The SEP4’s internal air separation element (1) creates the whirling
movement required to facilitate the release of micro-bubbles and their
adhesion to the internal element surfaces. The bubbles, fusing with
each other, increase in size until the hydrostatic thrust overcomes the
adhesion force to the mesh. They rise towards the top of the unit from
which they are released through a fl oat-operated automatic air vent.
The SEP4™ incorporates a fourth separation function by removing both
magnetic and non-magnetic particles continuously. The SEP4™ features
a powerful removable external rare-earth magnet around the body below
the fl ow line for fast and effective capture of ferrous particles. The SEP4™
magnetic particle separation function causes no added system pressure
drop since the magnet is positioned externally and not inside the fl ow path.
Dirt separation
Air separation
Magnetic removal of ferrous particles
Hydraulic separation
3
70
CALEFFI
® and DISCAL ™
magnetic dirt separator
Technical specifications
Brass DIRTMAG®, DISCALDIRTMAG™ - body: brass
- dirt separation chamber: brass
- top plug(5463): brass
- air vent body (5461): brass
- internal element: glass reinforced nylon, PA66GF30
- air vent fl oat (5461): PP
- air vent fl oat guide pin (5461): stainless steel
- air vent fl oat linkages (5461): stainless steel
- spring (5461): stainless steel
- seals: EPDM
- drain shut-off valve: brass
- magnet: neodymium rare-earth
Suitable fl uids: water, glycol solution
Max. percentage of glycol: 50%
Max. working pressure: 150 psi
Temperature range: 32–250°F
Particle separation effi ciency: to 5 μm (0.2 mil)
Magnetic particle separation effi ciency: up to 95% removal
- main(5461): 3/4", 1", 1-1/4" sweat; 1" NPT male
- main(5463): 1", 1-1/4";1-1/2"; 2" sweat and NPTF
- drain shut-off valve: hose connection
DIRTMAG® (NA5453 series)
Body: glass reinforced nylon PA66G30
Dirt separator cover: glass reinforced nylon PA66G30
Top plug: brass EN 12164 CW614N
Drain screw: brass EN 12164 CW614N
Tee pipe fi tting: brass EN 1982 CB 753S
Locking nut for tee pipe fi tting: brass EN 12420 CW617N
Internal element: HDPE
Hydraulic seals: EPDM
Drain valve: brass EN 12165 CW617N
Suitable Fluids: water, glycol solutions
Max. percentage of glycol: 30%
Max. working pressure: 45 psi
Working temperature range: 32–195°F
Magnets: neodymium rare earth
Magnetic particle separation effi ciency: up to 95% removal
Main connections: 3/4” and 1” NPT male union
3/4” and 1” sweat union
3/4” press
Lay length (press connection): 5 7/16”
Drain valve: hose connection
Function
Air, dirt and magnetic separators are used to continuously remove the
air and debris contained in the hydronic circuits of heating and cooling
systems. Caleffi offers several versions of air, dirt and hydraulic separators
that also feature magnetic particle removal.
The DIRTMAG® magnetic dirt separator and DISCALDIRTMAG™
magnetic air and dirt separator removes both magnetic and non-
magnetic particles, featuring a powerful removable external magnet
around the body that removes up to 95% of the ferrous oxide particles
that can form in a hydronic system. The 5461 series and the 5463 series
brass versions are available with NPT threaded or sweat connections in
versions for horizontal pipes only. Insulation shells are available separately
for fi eld installation.
The body of the patent pending NA5453 series separator is made
of glass reinforced nylon specifi cally designed for use in heating and
cooling systems. It also is especially versatile as it can be installed on
either horizontal or vertical piping with the rotating brass base mount. It
is available with conventional NPT and sweat union connections. Also
available for size ¾”, the Presscon™ copper tailpiece with union nut
makes installation and maintenance fast, easy and effi cient. Special slots
in the EPDM O-ring allows fl uid to leak during system testing if unpressed
and provide a perfect leak proof seal when completely pressed.
NA54530 series DIRTMAG® dirt separator with magnet for horizontal and vertical pipes...............................connections ¾” & 1” NPT male union
NA54539 series DIRTMAG® dirt separator with magnet for horizontal and vertical pipes.....................................connections ¾” & 1” sweat union
NA54536 series DIRTMAG® dirt separator with magnet for horizontal and vertical pipes.......................................................connections ¾” press
54611 series DISCALDIRTMAG™ air and dirt separator with magnet in brass...............................................................connections 1" NPT male
54619 series DISCALDIRTMAG™ air and dirt separator with magnet in brass..................................................connections 3/4", 1", 1-1/4" sweat
5463 series DIRTMAG® magnetic dirt separator for horizontal pipes, in brass..........................................................connections 1" to 2" sweat
71
1
Operating principle
The DISCALDIRTMAG™ air, dirt, and
magnetic separator uses the combined
action of several physical principles.
The active part is the internal element
(1) and consists of a glass-reinforced
nylon mesh. These elements create the
whirling movement required to facilitate
the release of micro-bubbles and their
adhesion to these surfaces.
The bubbles, fusing with each other,
increase in volume until the hydrostatic
thrust is such as to overcome the
adhesion force to the structure. They
rise towards the top of the unit from
which they are released through a fl oat-
operated automatic air vent valve.
The DIRTMAG® and DISCALDIRTMAG™ dirt
removing element separates and collects any
impurities present in the system.
Impurities in the fl uid upon striking the surfaces
of the DIRTMAG® and DISCALDIRTMAG™’s
internal element (1), get separated and drop
to the bottom of the body in the dirt collection
chamber (2) where they collect.
In addition, the large internal volume of slows
down the velocity of the fl uid thus helping, by
gravity, to separate the particles it contains.
The collected impurities are discharged, by
opening the drain valve (3), even with the system
operating.
2
3
2
3
1
Locknut
Brass TeePipe Fitting
EngineeredPolymer Body
1
2
3
4
The special design of the internal mesh element in the Caleffi DIRTMAG®
and DISCALDIRTMAG™, is able to completely separate the dirt particles
in the circuit down to a minimum particle size of 5 μm (0.2 mil). After
only 50 recirculations, approximately one day of operation, up to 100%
is effectively removed from the circuit for particles of diameter greater
than 100 μm (3.9 mil) and on average up to 80% taking account of the
smallest particles. The continual passing of the medium during normal
operation of the system gradually leads to complete dirt removal.
® ®®
A
BNPT
A
BSweat
1¼”
C
2”
1¼”
C
2”
C
06A 1" NPT 45⁄16" 5" 4.2
28A 1" SWT 51⁄16" 5" 4.2
07A 11⁄4" NPT 47⁄8" 6" 5.3
35A 11⁄4" SWT 53⁄16" 6" 4.2
08A 11⁄2" NPT 47⁄8" 6" 6.2
41A 11⁄2" SWT 53⁄4" 6" 4.9
09A 2" NPT 51⁄8" 6" 6.2
54A 2" SWT 61⁄8" 6" 5.5
A
2¼”
C5½
”
B
C95A 3⁄4" SWT 73⁄8" 5" 8.5
96A 1" SWT 73⁄8" 5" 8.5
16A 1" NPT M 73⁄8" 5" 8.5
97A 1¼" SWT 73⁄8" 5" 8.5
15/8"
B
31/2"
C7"
C
NA545305 ¾” NPT 6 7/8” 3 7/16” 4.5
NA545395 ¾” SWT 6 5/8” 3 5/16” 4.5
NA545365 ¾” press 7 1/4” 3 5/8” 4.5
NA545306 1” NPT 7 1/2” 3 3/4” 4.5
NA545396 1” SWT 7 5/8” 3 7/8” 4.5
Dimensions
The DIRTMAG® and DISCALDIRTMAG™
removes both magnetic and non-magnetic
part ic les cont inuously. The DIRTMAG®
and DISCALDIRTMAG™ feature a powerful
removable external rare-earth magnet around
the body below the fl ow line for fast and effective
capture of ferrous particles. The DIRTMAG®
and DISCALDIRTMAG™ magnetic particle
separation function causes no added system
pressure drop since the magnet is positioned
externally and not inside the fl ow path.
Ferrous oxide forms in hydronic systems when iron or steel corrodes.
The abrasive, extremely fi ne sediment is diffi cult to remove and can
deposit onto heat exchange surfaces and accumulate in pump cavities
causing reduced effi ciency and premature wear. The DIRTMAG® and
DISCALDIRTMAG™ accomplish 2 1/2 times the ferrous oxide removal
performance of standard dirt separation function, delivering up to
95% elimination effi ciency. Captured impurities are easily fl ushed by
unclamping the collar and purging - even with the system still operating.
www.caleffi .us - Milwaukee, WI USA
Components for today's modern hydronic systems
Magnetic SeparationRemoves 95% of ferrous impurities
Heating & Cooling
Ferrous oxide forms in hydronic systems when iron or steel corrodes. This abrasive, extremely fine sediment is difficult to remove; it can deposit onto heat exchanger surfaces and accumulate in pump cavities causing reduced efficiency and premature wear. Caleffi magnetic dirt separators accomplish 2½ times the ferrous oxide removal performance of standard dirt separators, delivering up to 95% elimination efficiency.