BRANCH-E&TC ENGINEERING

SEM – 3Rd

SUBJECT-EMI

CHAPTER-06 – transducer & sensor

TOPIC- temperature transducer

Ay-2021-2022 ,winter-2021

FACULTY-ER V BEHERA.(LECTURER e & tc engg Dept)

Presentation On

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Temperature Transducer

Temperature Transducer:-

• Temperature transducers can be divided into four main categories.
• Resistance temperature detectors (RTD).
• Thermocouples.
• Thermistors.
• Ultrasonic thermometer.

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Temperature Transducer(cont’d):-� 1. Resistance temperature detectors (RTD):-

• Detectors of resistance temperatures commonly employ platinum, nickel, or resistance wire elements, whose resistance variation with temperature has a high intrinsic accuracy.

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• They are available in many configurations and sizes and as shielded or open units for both immersion and surface applications.

Temperature Transducer(cont’d):-� 1. Resistance temperature detectors (RTD):-

• The relationship between temperature and resistance of conductors can be calculated from the equation.

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Where

R = The resistance of the conductor at temperature t (°C)

R_o = The resistance at the reference temperature, usually 20°C

= The temperature coefficient of resistance

T = The difference between the operating and the reference

Temperature

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Temperature Transducer(cont’d):-� 1. Resistance temperature detectors (RTD):-

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• EXAMPLE:-

A platinum resistance thermometer has a resistance of 150 at 20^oC. Calculate its resistance at 50`C ( ₂₀ =0.00392).

Solution:-

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Temperature Transducer(cont’d):-� 2. Thermocouples:-

• One the most commonly used methods of measuring temperature in science and industry depends on the thermocouple effect.

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• When a pair of wires made of different metals are joined together at one end, temperature difference between this end and the other end of the wires produces a voltage between the wires Fig. (9).

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Temperature Transducer(cont’d):-� 2. Thermocouples:-

• The magnitude of this voltage depends on the materials used for the wires and the amount of temperature difference between the joined ends and the other ends.

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• The junction of the two wires of the thermocouple is called the sensing junction. In normal use this junction is placed in or on the material being tested, and the other ends of the wire are connected to the voltage-measuring equipment.

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Temperature Transducer (cont’d):-� 2. Thermocouples:-

• Since the temperature difference between this sensing junction and the other ends is the critical factor, the other ends are either kept at a constant reverence temperature or, when the cost of the equipment is very low, simply maintained at room temperature.

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• When the other ends are kept at room temperature, the temperature is monitored and the thermocouple output voltage readings are corrected for any changes in room temperature.

Temperature Transducer (cont’d):-� 2. Thermocouples:-

• Because the temperature at this end of the thermocouple wires is a reference tempera­ture, the junction here with the equipment terminals or with other connecting wires is known as the reference junction.

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• It is also quite often referred to as the co/d junction. Because the thermocouple is frequently used for measuring high temperatures, the reference junction it such cases is indeed the colder of the two junctions.

Temperature Transducer (cont’d):-� 2. Thermocouples:-

• Since any junction of dissimilar metals will produce some thermocouple voltage, the wires and any metal terminals between the sensing junction and the rest of the equipment must be carefully controlled.

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• Usually this means that the wires between the sensing junction and the reference junction are of specific materials provided by the thermocouple supplier, and the wires from the reference junction to the measuring equipment are copper.

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Temperature Transducer (cont’d):-� 2. Thermocouples:-

• Thermocouples are made from a number of difference metals or metal alloys covering a wide range of temperatures from as low as -270^°C(-418°F) to as high as 2700`C (about 5000°F).

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Fig (9) Schematic representation of a thermocouple assembly.

Temperature Transducer (cont’d):-� 2. Thermocouples:-

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• The magnitude of the thermal emf depends on the wire materials used on the temperature difference between the junctions. Figure (11) shows thermal emfs for some common thermocouple materials. The values shown are based on a reference temperature of 32°F. The effective emf of thermocouple is given as

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Where

• c and k =constants of the thermocouple materials
• T₁ =the temperature of the "hot" junction
• T₂ =the temperature of the "cold" or "reference" junction

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Temperature Transducer (cont’d):-� 2. Thermocouples:-

Fig (10) Thermocouples and thermocouple assemblies. (a) Uninsu­lated thermocouple. (b) Insulated thermocouple. (c) Probe assembly. (d) Thermocouple well.

Temperature Transducer (cont’d):-� 2. Thermocouples:-

Fig (11) Calibration curves for several thermocouple combi­nations.

Temperature Transducer (cont’d):-� 2. Thermocouples:-

• EXAMPLE :-

During experiments with a copper- constantan thermocouple it was found that c = 3.75 x 10^-2 mV/°C and k =4.50x10^-5 mV/°C². If T₁ =100°C and the cold junction T₂ is kept in ice, compute the resultant electromotive force.

Solution:-

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Temperature Transducer (cont’d):-� 3. Thermistors.:-

• The electrical resistance of most materials changes with the temperature. By choosing materials that are very sensitive to temperature, we can make devices that are useful in temperature control circuits as well as in tempera­ture measurement.

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• A thermistor is a semiconductor made by sintering mixtures of metallic oxide, such as oxides of manganese, nickel, cobalt, copper, and uranium. Thermistors have a negative temperature coefficient. That is, their resis­tance decreases as their temperature rises.

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Temperature Transducer (cont’d):-� 3. Thermistors.:-

• Resistance at 25'C for typical commercial units ranges from the 100 to over 1 M . A graph showing resistance versus temperature for a family of Thermistors is given in Fig (12). The resistance value marked at the bottom end of each curve is the value at 25°C.

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• In addition to the choice of resistance values, choices of power rating, physical size and shape, resistance tolerance, and thermal time constant are also available.

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Temperature Transducer (cont’d):-� 3. Thermistors.:-

Fig (12) Typical thermistor resistance-versus-temperature curves. (Courtesy Fenwal Electronics, Framingham, Mass.)

Temperature Transducer (cont’d):-� 3. Thermistors.:-

• Thermistors can be connected in series-parallel arrangements for applica­tions requiring greater power-handling capability.

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• High-resistance units find application in measurements that employ wires or cables with small quantities of lead. Thermistors are chemically stable and can be used in nuclear environments.

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• Their wide range of characteristics also permits them to be used in limiting and regulation circuits, as time delays, for the integration of power pulses, and as-memory units.

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Temperature Transducer (cont’d):-� 3. Thermistors.:-

• Typical thermistor configurations are shown in Fig. (13) and the electri­cal symbol of the device is depicted in the same figure.

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Fig (13) thermistor configuration and the electrical symbol for a thermistor. (Courtesy Yellow Springs Instrument Company, Yellow Springs, Ohio.)

Temperature Transducer (cont’d):-� 3. Thermistors.:-

• A thermistor in one leg of a Whetstone bridge circuit will provide pre temperature information. In most applications accuracy is limited only by readout device.

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• Thermistors are nonlinear over a temperature range, although units today are available with a better than 0.2% linearity over a temperature range of to 100^°C. The typical sensitivity of a thermistor is approximately 3 mV/°C at 200°C.

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Temperature Transducer (cont’d):-� 3. Thermistors.:-

• EXAMPLE :-

The circuit of Fig. (14) is to be used for temperature measurement. thermistor is a 4-k type identified in Fig. 11-16. The meter is a 50-mA ammeter with a resistance of 3 , R_c is set to 17 , and the supply voltage V_T is 15 V. What will the meter readings at 77^°F and at 15^oF be?

Fig (14) Basic thermistor cir­cuit for measuring.

Temperature Transducer (cont’d):-� 3. Thermistors.:-

• Solution:-

The graph for the 4-k thermistor in Fig. ( ) shows that its resistant at 77^oF is 4 . Therefore, the current at 77°F is

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• At 150^°F the graph shows the thermistor resistance to be 950. The meter reading at this temperature, therefore, should be

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Temperature Transducer (cont’d):-� 4. Ultrasonic Temperature Transducers:-

• Ultrasonics, which are sound vibrations above 20.000 Hz. can be useful when we are concerned wish rapid temperature fluctuations.

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• Temperature extremes. limited access, nuclear, and other severe environmental conditions and when we must measure the temperature distribution inside solid bodies.

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Temperature Transducer (cont’d):-� 4. Ultrasonic Temperature Transducers:-

• The need to measure simultaneously the distribution of parameters other than temperature (e.g., flow) may also justify an ultrasonic approach.

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• Ultrasonics also offers possibilities of remote sensing and sometimes can prevent pene­tration of the system (nonintrusive) as shown in fig (15).

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Fig (15) (a) Schematic and oscillogram illustrating ultrasonic temperature profiling. (y) Ultrasonic thermometer.

7. Piezoelectric Transducers:

• When a mechanical pressure is applied to a crystal of the Rochelle salt quartz, or tourmaline type, a displacement of the crystals causes a potential difference to occur.

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• This property is used in piezoelectric transducers: in these transducers a crystal is placed between a solid base and force-summing member, as shown in Fig. (16).

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Piezoelectric Transducers (cont’d):-

• Externally applied forces exert pressure to the top of the crystal. This produces an electromotive force across the crystal proportional to the magnitude of the applied pressure.

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Fig (16) Elements of a piezoelectric transducer.

Piezoelectric Transducers (cont’d):-

• For a piezoelectric element under pressure, part of the energy will be converted to an electric potential that will appear on opposite faces of the element, analogous to the charge on the plates of a capacitor.

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• The rest of the applied energy is converted to mechanical energy, analogous to that of a compressed spring: When the pressure is removed, the piezoelectric element will return to its original shape and also lose its electric charge.

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Piezoelectric Transducers (cont’d):-

• From these relationships the following formulas have been derived for the coupling coefficient k.

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Piezoelectric Transducers (cont’d):-

• An alternating voltage applied to a crystal causes it to vibrate at its natural resonance frequency. Since the frequency is a very stable quantity, piezoelectric crystals are used principally in high - frequency accelerometers.

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• The output voltage is typically on the order of 1 to 30 mV per gram of acceleration. The device needs no external power source and is therefore self-generating.

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• The principal disadvantage of this transducer is that voltage will be generated only as long as the pressure applied to the piezo electric element is changing.

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Piezoelectric Transducers (cont’d):-

• EXAMPLE :-

A certain crystal has a coupling coefficient of 0.32. How much electrical energy must be applied to produce an output of 1 in of mechanical energy?

Solution:-

1 in. = in. x

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= 7.06 x 10^-3 J

THANK YOU