Chapter 2: External Environment Chapter 2 External Environment.
CHAPTER 2 -Transducer_2
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Transcript of CHAPTER 2 -Transducer_2
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EET 204– Instrumentation and Measurement
Concept and Principles of Transducers and Sensors
Content:1. Introduction2. Temperature Sensor3. Optical Sensor4. Other Sensor
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Lesson Outcomes
At the end of the lesson, students should beable to:
define basic concept of transducers and sensors
apply in-depth knowledge in transducer's and sensor’s application
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Objectives:1. To get familiarize with several types of
transducers and selection criteria.
2. Able to apply basic principles of operation
and application of common transducer.
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Introduction
Content:1. Definition of Transducer2. Types of Transducers3. Application of Transducers4. Advantage of Electrical 5. Transducers6. Classification Of Transducers 7. Selecting A Transducers8. Parameter
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DEFINITION OF TRANSDUCER & SENSORSTransducer - device that converts one form of energy into
another form of energysensor - device that measures a physical quantity
and converts it into a signal which can be read by an observer or by an instrument.
Sound > Electric
Electrical > Sound
Mechanical motion > Electrical Signal
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Electrical Transducers Converts the input measurand into an electrical
voltage/current
Mechanical Transducers Converts the input measurand into a mechanical
energy
TYPES OF TRANSDUCERS
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Electrical Sensor Device that capable to detect electrical signal and
sent it to another
APPLICATION OF TRANSDUCERS
measurand electrical output
excitation
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Electrical amplification and attenuation can be easily done
Mass-inertia effects are minimized
Effect of friction are minimized
ADVANTAGES OF ELECTRICAL TRANSDUCERS
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The output can be indicated and recorded remotely at a distance from the sensing medium
The output can be modified to meet the requirements of indicating or controlling units
ADVANTAGES OF ELECTRICAL TRANSDUCERS
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The signal can be conditioned or mixed to obtain any combination with outputs of similar transducers or control signal
ADVANTAGES OF ELECTRICAL TRANSDUCERS
"Strive always to excel in virtue and truth." (Bukhari)
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Active Transducer Do not requires external power produce an analog
voltage
CLASSIFICATION OF TRANSDUCERS
measurand electrical output
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Passive Transducer Require external power source to operate
CLASSIFICATION OF TRANSDUCERS
measurand electrical output
external power
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Operating Range Maintain range requirements and good resolution
Sensitivity Sensitivity enough to allow sufficient output
Environment Compatibility Ability to make it applicable and interactions
Accuracy Subject to repeatability and calibration error
Physical Condition Depend on its usageElectrical Length and type of cable is
required
SELECTING A TRANDUCER
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Linearity Relationship between physical parameter and resulting electrical signal must be linear
Sensitivity Defined as the electrical output per unit change in physical parameter
Dynamic Range Operating range should be wide to permit it use under wide range of measurement condition
Repeatability Input or output relationship for a transducer should be predictable over a long period of time
Physical Size Minimum weight and volume
PARAMETER
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Potentiometer
Electromechanical device containing a resistance element that is contacted by a movable slider
The motion of the movable slider may be translatory or rotational.
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The output voltage of the position of the movable slider and is
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Example: A displacement transducer with a shaft stroke of 30 cm is applied to the circuit. The total resistance of the potentiometer is 5k Ω . The applied voltage VS is 5V. Calculate the output voltage when the wiper is 9cm from B.
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Example:
A potentiometer transducer with a shaft stroke of 8.0cm is used in circuit below. The applied voltage is 10V. The total resistance of potentiometer R1 and R2 is 6 kΩ. The total resistance of the potentiometer R3 and R4 is 4 kΩ. The initial position to be used as a reference point is set such that R1 is 4.5 cm and R3 is 3.5 cm of the shaft stroke length (from point A).
i. Calculate the values of R1, R3 and VE at initial position
ii. Calculate the displacements of potentiometer R3 and R4 in the case that VE =0.Then identify the direction of the displacement
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"Strive always to excel in virtue and truth." (Bukhari)
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Exercise: A displacement transducer with a shaft of 2.0mm is used in the circuit as shown in figure below. The total resistance of the potentiometer R1 and R2 is 5000Ω and the applied voltage is 5.0V. The total resistance of the potentiometer R3 and R4 is also 5000Ω.The initial position to be used as reference point is set such that R1 = R2 (i.e. when the shaft is at mid-stroke). Initially, potentiometer R3 and R4 is adjusted so that the bridge is balanced (i.e. VE = 0). Assuming the shaft of the potentiometer R3 and R4 will be moved 0.5mm towards A, what is the value of VE?
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Potentiometer senses displacement by means of sensing shaft, which is mechanically connected to the point or objects whose displacement, is to be measured.
Example: Petrol-tank level indicator.In this case, potentiometer is used to indicate/sense the petrol level in a tank as shown in Figure below. The output signal (voltage) is proportional to the petrol level,v
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Advantages & Disadvantages of Potentiometer
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Capacitive transducerA capacitor consists of two parallel plates
separated by an air space or by a dieletric (insulating material) as shown in figure below
The capacitance of the pair of plates is measure of the amount of charge that can be transferred before a certain voltage is reached.
If the capacitance is large, more charge is needed to establish a given voltage difference
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The equation for capacitance of a parallel plate capacitor is given by:-
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the capacitive transducer works on the principle of changing of capacitance which may caused by:
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Advantages :1. Required extremely small forces to operate them
and hence are very useful for use in small systems.2. Extremely sensitive.3. A good frequency response as high as 50kHz and
useful for dynamic studies.4. High input impedance therefore the loading effects
are minimum.5. The force requirements is very small and therefore
require small power to operates themDisadvantages:1. The metallic parts of the transducer must be
insulated from each other in order to reduce the effects of stray capacitance, the frames must be earthen.
2. The output impedance of the capacitive transducers tends to be high on account of their small capacitance value this leads to loading effects.
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Uses of Capacitive Transducer1. It can be used for measurement of both
linear and angular displacements.2. It can be used for measurement of force
and pressure. The force and pressure to be measured are first converted to displacement which caused a change in capacitance.
3. It can be used for measurement of humidity in gases since the dielectric constant of gases changes with change in humidity thereby producing a change in capacitance.
4. It is commonly used in conjunction with mechanical modifiers for measurement of volume, density, liquid level, weight and etc.
"Strive always to excel in virtue and truth." (Bukhari)
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Capacitive sensor is used to detect the presence of boxes on the conveyor belt
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Example: A capacitive transducer is used for the measurement of linear displacement, X, as shown in below. The parallel plate has a dimension of 5.0cm X 5.0cm and is separated by a distance of 1.0cm. The space between the plates is filled with a dielectric material of 1.0cm thick, which has a dielectric constant of 4.0. If the dielectric constant for air is 1.0cm, determine the value of the capacitance when x is equal to:
(i) 0.0cm(ii) 2.0cm
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Exercise:Figure below shows a capacitive transducer used for measurement of linear displacement, x. the parallel plates have a dimension of (4.0 cm x 4.0cm) and separated by a distance of 10 mm. the space between plates is filled with a dielectric material with constant of 3.0.If the dielectric constant for air is 1.0, determine the value of the capacitance when x is equal to:
i) 0.0 cmii) 2.0 cmiii) 4.0 cmWhat is the effect of capacitance when the
displacement of dielectric is increased? Given εo = 8.854 x 10-12 F/m.
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ThermocoupleThermocouple -thermal transducer.It consists of a pair of wire made of
different metals that joined together at one end as shown in below.
When there is a temperature difference between the two ends of wire, a voltage will be produced between the two wires – Seeback effect
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The magnitude of voltage depends on :i) the materials used for the wiresii) the temperature difference between the joined ends and the other ends.
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The voltage of the thermocouple is given as
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Normally the cold / reference temperature is set to 0oC as shown in figure below:
Cold junction compensation
Thermocouple tables give the relationship between the voltage for a particular type of thermocouple and the measured temperature when the reference junction is at a particular reference temperature
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ThermistorThermistors - THERMally sensitive resISTOR
are non-metallic resistors(semiconductor material) made by sintering mixtures of metallic oxides such as manganese, nickel, cobalt, copper and uranium.
Thermistor - type of resistance thermometer, uses the change in the electrical resistance to determine the temperature.
Thermistors have a Negative Temperature Coefficient (NTC) – resistance decrease as temperature rises as shown in below.
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"Strive always to excel in virtue and truth." (Bukhari)
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Strain gaugeStrain gauge - passive transducer that uses
the variation in electrical resistance in wires to sense the strain produced by force on wires.
It is used for measuring weight, pressure, mechanical force and displacement.
A bonded strain gauge consists of a fine wire looped back and forth on a mounting plate which is usually cemented to the member undergoing stress as shown below
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Bonded strain gauge
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Strain gauge is generally uses as one arm of a bridge is shown Figure below.
This method is capable to measure the change in resistance when the wire is under strain.
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In some cases, strain gauges are used in pairs (active gauge and dummy gauge) to provide temperature compensation as in Figure below. However, only the active gauge will respond to stress.
The dummy gauge is mounted in an insensitive orientation to provide some compensation for temperature effects.
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Strain gauge 1 is stretchStrain gauge 2 is compressed
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APPLICATION OF STRAIN GAUGE
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EXAMPLE OF STRAIN GAUGE
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The strain will cause:i) The change in length ΔLii) The change in gauge resistance ΔR
"Strive always to excel in virtue and truth." (Bukhari)
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Linear Variable Differential Transformer
-Inductive position sensor When an AC excitation signal is applied to the Primary
Coil (P), voltages are induced in the two Secondary Coils (S). The MAGNETIC CORE inside the COIL WINDING ASSEMBLY provides the magnetic flux path linking the Primary and secondary Coils.
Since the two voltages are of opposite polarity, the Secondary Coils are connected series opposing in the center, or Null Position. The output voltages are equal and opposite in polarity and, therefore, the output voltage is zero. The Null Position of an LVDT is extremely stable and repeatable.
When the MAGNETIC CORE is displaced from the Null Position, an electromagnetic imbalance occurs. This imbalance generates a differential AC output voltage across the Secondary Coils which is linearly proportional to the direction and magnitude of the displacement.
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As shown in the figure, when the MAGNETIC CORE is moved from the Null Position, the induced voltage in the Secondary Coil, toward which the Core is moved, increases while the induced voltage in the opposite Secondary Coil decreases.
LVDTs possess the inherent ruggedness and durability of a transformer and truly provide infinite resolution in all types of environments. As a result of the superior reliability and accuracy of LVDTs, they are the ideal choice for linear motion control.
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Advantages -LVDT compared to a resistive potentiometer are that its linearity, that is its voltage output to displacement is excellent, very good accuracy, good resolution, high sensitivity as well as frictionless operation and is sealed against hostile environments
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Example An AC LVDT has the following data. Input = 6.3V, output=5.2V
range +/- 0.5 in. Determine:a) Calculate the output voltage vs core position for a core
movement going from +0.45 in to -0.30in.b)The output voltage when the core is -0.25in from the centre.Solution
a)0.5 in core displacement produces 5.2V,therefore a 0.45 in core movement produces(0.45x5.2)/0.5 = 4.68V
At -0.30 in core movement produces (-0.30x-5.2)/(-0.5) = -3.12Vb) -0.25 in core movement produces (-0.25x-5.2)/(-0.5) = -2.6V
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Resistive Temperature Detectors (RTD).
RTD's are precision temperature sensors made from high-purity conducting metals such as platinum, copper or nickel wound into a coil and whose electrical resistance changes as a function of temperature, similar to that of the thermistor
Also available are thin-film RTD's. These devices have a thin film of platinum paste is deposited onto a white ceramic substrate.
They have poor sensitivity, that is a change in temperature only produces a very small output change for example, 1Ω/oC.
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RTD is a resistive device - need to pass a current through them and monitor the resulting voltage.
Any variation in resistance due to self heat of the resistive wires as the current flows through it, I2R, (Ohms Law) causes an error in the readings.
To avoid - RTD is usually connected into a Whetstone Bridge network which has additional connecting wires for lead-compensation and/or connection to a constant current source.
Relationship between temperature and resistance of conductors :-
• Rt=Rref(1+αΔt)Rt – resistance of conductor at temperature t degreeRref – resistance of the reference temperture,
usually 0 degreeα – temperature coefficient of resistanceΔt – difference between operating and reference
temperature
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Exercise
A platinum resistance thermometer has resistance of 180Ω at 20 degree Celsius. Calculate its resistance at 60 degree Celsius. (α20 = 0.00392) ans:151.78 Ω
A platinum resistance thermometer has a resistance of 100 Ω at 23 degree Celsius. Find its resistance at 50 degree Celsius. The resistance temperature coefficient of platinum is 0.00392 Ω/ Ω celsius. If the thermometer has a resistance of 200 Ω, calculate the value of temperature.