Stand Alone PV System Using PVSyst
-
Upload
shubham-mishra -
Category
Documents
-
view
160 -
download
14
description
Transcript of Stand Alone PV System Using PVSyst
PVSyst TUTORIAL
1 | P a g e
STAND ALONE SOLAR PV SYSTEM
What is a stand alone solar system?
This is a type of system which is not connected to electric grid. We have a PV array to
convert sunlight into electricity and then we store this energy in a battery as chemical energy.
This stored energy is then utilized when needed. This system is also known as off-grid system.
What are the components of stand alone system?
We will take a look at the processes involved. We have to convert sunlight into electricity
so, we need a PV array. This electricity has to be stored, so we use a battery. We cannot directly
feed electricity from PV module to battery. There is a component which keeps both PV module
and battery happy, that is a charge controller. This ensures that our battery is not overcharged
and at the same time operates our PV module at its maximum efficiency (not all charge control-
lers).
Are these the only components used? The answer is NO. We have a big task of powering
all our appliances. We hardly have any DC powered appliance at home. All our appliances like
TV, Computers, and Microwave etc. are AC powered. So, we have to convert DC electricity
from battery into AC by using an inverter.
Applications of stand alone systems:
Some commonly found systems are calculators, wristwatches, cell phone towers, road
signals, street lights, road signs, water pumping system, ATM machines, portable systems to
name a few.
Our objective is to learn how to design this system using PVSyst and I will stick to that
while providing occasional references and examples. If you don’t have PVSyst installed in your
computer, please use this link http://www.pvsyst.com/en/download and download a demo ver-
sion.
PVSyst TUTORIAL
2 | P a g e
Introduction:
Open PVSyst and in the main screen, you will find three options,
1. Preliminary design,
2. Project design, and
3. Tools
1. Preliminary design:
This helps you design a system with fewer options like type of system, location, tilt angle
etc. In our case of stand-alone system you can choose only location, tilt angle and load. It will
compute and tell you how big a system you will need. This is just like choosing the color of your
car interiors. You have very few options (forgive me for poor example).
2. Project design:
Using this option you can modify various properties of your system. You can choose the
type of module, make, peak watt, battery type, module orientation, shading etc. this is like an op-
tion to choose the color of your car interiors along with fabric type, type of cushion, seat belt etc.
3. Tools:
This section is used to feed user data’s like adding a new site, module, inverter etc. We
will discuss this section in detail at later stages as this is very vital.
Fig1. Main Screen
PVSyst TUTORIAL
3 | P a g e
Design:
We will start with project design option. When we learn to use all features then it is easier
to use the simple options. Preliminary design will only give you an approximate overall picture
of your project and does not help much in learning phase.
Step1. Choose Project design under Option and then click on Stand alone under System. Click
OK and you will be taken to next screen.
Step2. In this screen you will see options like,
1. Project,
2. Orientation,
3. Horizon,
4. Near Shadings,
5. System,
6. Module layout,
7. Simulation, and
8. Exit
Fig2. Design screen
PVSyst TUTORIAL
4 | P a g e
1. Project:
Click on the project button you see in the design screen. This screen lets you feed basic
details about our project. It includes details of location, solar irradiance, customer name, project
name etc.
Fig.3 Project details screen
Step1. Use the New project button to create a new project.
Step2. You will be prompted to enter project’s name, customer name, and other miscellaneous
details. When you are done with this step, please press Site and Meteo
Step3. Now choose the country for which you want to design PV system from drop down list
box.
Step4. Now choose site from the other drop down list box. Once you have selected your site,
please check the meteo file’s name.
Step5. If your site is not listed, you should add them from tools option as I mentioned earlier. I
will demonstrate how to add new sites at the end of this document.
PVSyst TUTORIAL
5 | P a g e
Site selection is to feed PVSyst with geographical coordinates of the location. For
detailed analysis we need hourly irradiance values. This hourly value is stored in
Meteo file.
Step6. Once you finish feeding values in this page, please click next. Now you will reach albedo
value page. Albedo value is the reflecting power of the surface. You can see a table on
the right side of the same page. Depending on the surface where your PV modules are lo-
cated, albedo value change. If you are not sure, better take the default value of 0.20.
Fig4. Albedo screen
Step7. Once you finish albedo value, move onto Site-dependent design parameters. You will see
4 different temperatures. What are these? Why should we consider these? How will these
affect our design?
“We all know that temperature affects power output of PV modules. Temperature
coefficient determines this loss percentage and varies for different modules. The
above indicated temperatures are the location ’s temperature.
Lower temperature for VmaxAbs limit:
This is the lowest temperature that you will have in your site. This value is
usually a historic value. When module temperature is low, it performs better. We
PVSyst TUTORIAL
6 | P a g e
will get higher voltage from the module at lower temperatures. We should make
sure that inverter’s or charge controller’s maximum input voltage is greater than
this value.
E.g.) We have 3 modules connected in series. They have a voltage output of
40volts each at -10˚ C. So when you connect these modules in series you will pr o-
duce a maximum of 120 volts. Maximum input voltage range of your inverter or
charge controller should be more than 120 volts. This is one aspect of system si z-
ing.
Winter operating temperature:
This is same as the above but it is not historic lowest temperature of the
region. Instead it is average temperature during winter .
Summer operating temperature:
This temperature is the opposite of winter operating temperature. It is the
maximum temperature of the location in summer. Rise in temperature results in
significance decrease in output voltage. This reduced voltage from the PV array
should not go below the minimum input voltage of inverter or charge controller.
E.g.) We have 3 modules connected in series. They have a voltage output of 25
volts each at 60˚ C. So when you connect these modules in series you will produce
a maximum of 75 volts. Minimum input voltage range of your inverter or charge
controller should be less than 75 volts. This is one aspect of system sizing.
Usual operating temperature:
This temperature is the average ambient temperature of the location. You
should also understand that temperature of PV module is not same as ambient
temperature. These are just like us; our body temperature is not same as ambient
temperature. We can calculate the module temperature from ambient temper a-
ture and measure the loss due to temperature. I will cover this in detail in Array
loss section.
Step8. After you enter all the values, click OK and save your project.
Stpe9. Click OK or next in all the screens that appear until you reach the design screen like Fig2.
Step10. Now choose orientation option. These features will help you position your modules the
way you want and also check their performance.
PVSyst TUTORIAL
7 | P a g e
2. Orientation:
In this section you can determine the tilt angle, type of orientation, and check the perfor-
mance instantly.
Fig5. Orientation tools window
Before adjusting the parameters in this window, it is necessary to know what they mean.
Different field types are,
1. Fixed tilted plane,
2. Seasonal tilt adjustment,
3. Tracking 2 axis,
4. Tracking 2 axis, NS frame,
5. Tracking 2 axis, EW frame,
6. Tracking tilted or horizontal, NS frame,
7. Tracking, horizontal EW axis,
8. Tracking, vertical axis,
9. Tracking, sun shields,
10. Double orientation,
11. Unlimited sheds, and
12. Unlimited sun shields
PVSyst TUTORIAL
8 | P a g e
What is tilt angle?
It is the angle which our PV module makes with the surface. I have explained the necessi-
ty for tilted module in my video.
What is azimuth angle?
Azimuth angle indicates us, the location of sun in east west axis. It is the angle which sun
makes with the line connecting South and North Pole.
In the case of PV module, if the module surface is exactly facing South or North Pole,
then azimuth is said to be zero. Else, it is whatever angle the surface makes with South or North
Pole.
1. Fixed tilted plane:
This type of orientation is very common. This does not have any tracking mechanism.
You fix both tilt and azimuth angle during installation. You can use the optimization option to
make the system suitable for summer, winter or year round performance. If you want to use this
option, use steep angle for winter as sun remains lower in the sky and use lower angles for sum-
mer as sun reaches high in summer. If you want year round performance, use latitude of the loca-
tion as your tilt angle (equatorial regions).
As you change the tilt angle and azimuth angle you can see the performance in meteo
yield section in the window. Use this to determine the optimum tile and azimuth angle.
2. Seasonal tilt adjustment:
This type lets you choose two tilt angles. Lower angles for summer and steep angles for
winter. Everything else is same as previous type. You can choose your winter months using the
check boxes provided.
3. Two axis tracking:
Dual axis tracking follows both altitude and azimuth angle of sun and adjusts’ PV mod-
ules tilt and azimuth angle respectively. By doing this we can get rid of incidence angle losses. I
will cover this loss in detail in later sections. You can set the angle for lower and upper limit for
rotation of PV module.
I am looking for more solid explanations for backtracking and concentration arrays. I will
cover this in next material as I don’t want to overload with lot of details.
PVSyst TUTORIAL
9 | P a g e
4. Tracking two axis, NS frame:
Tracking method is similar to dual axis tracking. Here you have more than one PV mod-
ule and you can set the tilt angle of the entire frame. Imagine your modules are placed in a slope.
You can feed that slope angle of the surface as frame tilt angle. Also, the modules are arranged in
North-South axis which means PV module will be facing either North Pole (site in southern
hemisphere) or South Pole (site in northern hemisphere).
5. Tracking two axis, EW frame:
This orientation is similar to the above but PV modules are placed in East-West axis.
6. Tracking tilted or horizontal, NS frame:
In this tracking system, Tilt angle is kept constant and only azimuth angle of the PV
module arrangement varies according to sun’s azimuth angle. You can setup azimuth rotation
limits using the options provided in the window.
7. Tracking, horizontal EW axis:
In this tracking system, azimuth angle is kept constant and only tilt angle of the PV mod-
ule arrangement varies according to sun’s altitude angle. You can setup tilt angle rotation limits
using the options provided in the window.
8. Tracking, vertical axis:
In this tracking system, Tilt angle is kept constant and only azimuth angle of the PV
module arrangement varies according to sun’s azimuth angle. You can setup azimuth rotation
limits using the options provided in the window.
9. Tracking, sun shields:
In this we have only one angle to adjust. That is the angle made by façade with wall or
side of the building. You can also set the tilting angle limits.
10. Double orientation:
In this a single solar farm is divided into two separate sections. The only differences be-
tween the sections are their tilt and azimuth angle. These are fixed orientations and no tracking is
used.
11. Unlimited sheds:
This is fixed tilt and azimuth angle arrangement but widely used in designing solar farms.
You can define the number of rows of PV modules, using number of sheds option. In shed pa-
PVSyst TUTORIAL
10 | P a g e
rameters, you can feed the distance between two rows using pitch option. Collector band width
defines the height of PV module. Remember, larger the module height, larger the shadow length.
Inactive band defines the portion of the structure which is not covered by PV module.
Fig6. Unlimited sheds orientation
Loss due to shadow effects is not dependent on the percentage of PV module that is shad-
ed. If you want more accurate shadow analysis, use the electrical effect. Electrical effect in shad-
ing calculates loss based on the arrangement of cells in the module. If one cell is shaded in a
string, this considers the entire string to be shaded. You can define the size of each cell and also
the number of strings in a module. Click on the show optimization button and check the shadow
loss percentage. This value is instantaneous and the annual shadow loss percentage will be more
or less the same.
12. Unlimited sun shields
This is similar to unlimited sheds but only the orientation is different. Use all the parame-
ters as explained above.
PVSyst TUTORIAL
11 | P a g e
Fig7. Electrical effect shading
Fig8. Shadow optimization graph
PVSyst TUTORIAL
12 | P a g e
I will cover Horizon and Near shading section in a separate file. It is good to have them
as a separate section.
5. System:
In this section we will define our loads. I will explain each and every section of this win-
dow.
Fig9. Daily use of energy
Consumption definition:
You can feed loads as common for the entire year, depending on the season as we con-
sume more energy during winter and also based on months. For instance, we consume more en-
ergy during summer breaks as we stay home long, and tend to use some appliance. You can also
define weekend system or just regular system.
Model:
If you have a predefined energy consumption (load) file, which you created and saved,
you can import them using load option and selecting the appropriate file.
PVSyst TUTORIAL
13 | P a g e
Daily consumptions:
Analyze your daily usage and fill this section. As we know, we will not operate big appli-
ances like, electric stove, electric heater, and air conditioners from stand alone PV systems. Try
not to include them as these will lead to enormous array size.
Hourly distribution:
We can use the hourly distribution to set the power consumption for each and every hour.
If you check the evening usage option, it will set TV and lighting usage to maximum in the even-
ing than during the day. This helps in determining the wear and tear of the battery.
After you feed all details, please press next to select the type of module, battery etc.
Fig10. System design
In the top section of this page you can enter battery voltage, LOLP, and number of backup days.
Battery voltage:
This determines the voltage of battery bank. Depending on the load and applications we
choose this battery voltage.
PVSyst TUTORIAL
14 | P a g e
LOLP:
This is Loss of Load Probability. This defines what percentage of load cannot be supplied
by this PV system. This depends on the application of your system. If you are designing system
for a rural hospital, then there is zero tolerance, so LOLP is set to 1%.
Backup days:
This defines the number of days, you need backup. Suppose your daily consumption is
200Wh, and you need backup for 3 days, then your system should produce 600 Wh in a single
day. This increases the size of PV array and also battery bank.
Battery set:
This is used to select the battery that you want to use. You know how much Amp hours
we need. So based on that value, number of batteries increase. You should arrange battery bank
using basic series, parallel connection. Remember, in series connection voltage adds up and in
parallel connection, current adds up. So, even if we don’t have enough amp hour battery, we can
connect them in parallel and make it possible.
Module selection:
Select the module from the drop down list box. If you don’t find the module which you
want, you can add them to database by using tools option. Depending on the peak watt and volt-
age of the module, PVSyst will calculate the number of modules required and the series, parallel
connections.
Regulator:
Now click next to choose the charge controller (regulator). If you know the type of
charge controller you are going to use, select them from drop down list, else simply choose de-
fault regulator.
If you choose any type of regulator, operating mode is updated from inbuilt data. If you
choose default regulator, you have to choose from either of three options. More information will
be added for this.
Please leave generator section, empty. We are not going to include any backup generator, for
now.
Array losses:
This will be explained in next document. This should be studied in detail.
PVSyst TUTORIAL
15 | P a g e
Please press ok. Now press the simulation button, and press simulation again. Once the simula-
tion is complete you can view the report or even print and analyze the system performance.
Fig11. Simulation page
Videos:
1. Adding new site to PVSyst from TMY3 data.
2. Explanation of various sun angles
3. Reasons for inclined module orientation.
Exercise1.
Design a system for your room and mail me the doubts you have. I will try my best to clarify be-
fore we move to next topic. M mail id: [email protected]