TSTCC Computer Controlled Heat Transfer Series

COMPUTER CONTROLLED HEAT TRANSFER SERIES - TSTCC

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The Computer Controlled Heat Transfer Series, "TSTCC", has been designed by EDIBON to study and compare different types of heat transfer on a small scale.

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일반적인 설명

The Computer Controlled Heat Transfer Series, "TSTCC", has been designed by EDIBON to study and compare different types of heat transfer on a small scale. It allows a wide range of heat transfer demonstrations and study the factors affecting and problems associated with different types of heat transfer.

The minimum supply consists of two main elements: Control Interface for TSTCC (Common for all "TXC" type modules), "TSTCC/CIB",and at least one of the required elements described below.

Each heat transfer module can be individually connected to the Control Interface for TSTCC (Common for all "TXC" type modules) "TSTCC/CIB", which provides the necessary electrical supply and instrumentation connections for the study of the different types of heat transfer.

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Practices to be done with the Linear Heat Conduction Module (TXC/CL):

  1. Conduction through a simple bar.
  2. Conduction through a compound bar.
  3. Determination of the thermal conductivity "k" of different materials (conductors and insulators).
  4. The thermal conductivity properties of insulators may be found by inserting paper or other elements between the heating and cooling sections.
  5. Insulation effect.
  6. Determination of the thermal contact resistance Rtc.
  7. Effect of the crossing sectional area.
  8. Understanding the use of the Fourier equation in determining rate of heat flow through solid materials.
  9. Sensors calibration.

Practices to be done with the Radial Heat Conduction Module (TXC/CR):

  1. Radial conduction.
  2. Determination of the thermal conductivity "k".
  3. Determination of the thermal contact resistance Rtc.
  4. Insulation effect.
  5. Understanding the use of the Fourier equation in determining rate of heat flow through solid materials.
  6. Sensors calibration.

Practices to be done with the Radiation Heat Transfer Module (TXC/RC):

  1. Inverse of the distant square law for the radiation.
  2. Stefan Boltzmann Law.
  3. Emission power I.
  4. Emission power II.
  5. Kirchorff Law.
  6. Area factors.
  7. Inverse of the distant square law for the light.
  8. Lambert´s Cosine Law.
  9. Lambert Law of Absorption.
  10. Sensors calibration.

Practices to be done with the Combined Free and Forced Convection and Radiation Module (TXC/CC):

  1. Demonstration of the combined heat transfer effect by radiation and convection on the surface of the cylinder. Determination of the combined heat transfer effect by forced convection and radiation.
  2. Demonstration of the influence of air flow in the heat transfer. Determination of the combined heat transfer effect by forced convection and radiation.
  3. Demonstration of the influence of input power in the heat transfer. Determination of the combined heat transfer effect by forced convection and radiation.
  4. Demonstration of the combined heat transfer effect of the radiation and convection on the surface of the cylinder. Determination of the combined heat transfer effect by free convection and radiation.
  5. Sensors calibration.
  6. Determination of the airflow.

Practices to be done with the Extended Surface Heat Transfer Module (TXC/SE):

  1. Heat transfer from a Fin.
  2. Effect of cross section shape in heat transfer from a Fin.
  3. Heat transfer from Fins of two different materials.
  4. Measuring the temperature distribution along an extended surface.
  5. Sensors calibration.

Practices to be done with the Radiation Errors in Temperature Measurement Module (TXC/ER):

  1. Radiation errors in temperature measurement.
  2. Measurement the errors in thermocouples in function of its painting, material of its capsules, size.
  3. Effect of air velocity on measurement error.
  4. Sensors calibration.

Practices to be done with the Unsteady State Heat Transfer Module (TXC/EI):

  1. Predicting temperature at the center of a cylinder using transient conduction with convection.
  2. Predicting the conductivity of a similar shape constructed from a different material.
  3. Conductivity and temperature dependence on volume.
  4. Conductivity and temperature dependence on surrounding temperature T∞.
  5. Sensors calibration.

Practices to be done with the Thermal Conductivity of Liquids and Gases Module (TXC/LG):

  1. Obtaining of the curve of thermal conductivity of the air.
  2. Thermal conductivity in vacuum.
  3. Water thermal conductivity determination.
  4. Thermal conductivity determination of a mineral oil.
  5. Calibration of the Unit.
  6. Sensors calibration.
  7. Dry air thermal conductivity under atmospheric pressure.

Practices to be done with the Free and Forced Convection Heat Transfer Module (TXC/FF):

  1. Demonstration of the basic principles of free and forced convection.
  2. Comparison between free and forced convection.
  3. Free convection in flat surfaces.
  4. Forced convection in flat surfaces.
  5. Dependence of the heat transfer with the temperature.
  6. Dependence of the heat transfer with the speed of the fluid.
  7. Dependence of the heat transfer with the exchanger geometry (finned or pinned surface).
  8. Temperature distribution in the additional surfaces.
  9. Study of the advantage of using pinned and finned surfaces in heat transfer in free convection.
  10. Study of the advantage of using pinned and finned surfaces in heat transfer in forced convection.
  11. Comparative study between the free convection of a horizontal surface and vertical surface.
  12. Sensors calibration.

Practices to be done with the Three Axes Heat Transfer Module (TXC/TE):

  1. Determination of the thermal conductivity "k".
  2. Conduction through a simple bar.
  3. Conduction through three axes.
  4. Sensors calibration.

Practices to be done with the Metal to Metal Heat Transfer Module (TXC/MM):

  1. Conduction in a simple bar.
  2. Determination of the thermal conductivity "k".
  3. Determination of the thermal contact resistance.
  4. Sensors calibration.

Practices to be done with the Ceramic Heat Transfer Module (TXC/TC):

  1. Conduction in a simple bar.
  2. Determination of the thermal conductivity "k".
  3. Conduction through a compound bar.
  4. Determination of the thermal contact resistance.
  5. Sensors calibration.

Practices to be done with the Insulating Material Heat Transfer Module (TXC/TI):

  1. Determination of the thermal conductivity "k".
  2. Calculation of the heat transfer properties of different specimens.
  3. Conduction through a compound bar.
  4. Insulation effect.
  5. Sensors calibration.
더보기

장비로 수행 할 수있는 더 많은 실용적 연습

  1. Many students view results simultaneously. To view all results in real time in the classroom by means of a projector or an electronic whiteboard.
  2. Open Control, Multicontrol and Real Time Control. This unit allows intrinsically and/or extrinsically to change the span, gains, proportional, integral, derivative parameters, etc, in real time.
  3. The Computer Control System with SCADA and PID Control allow a real industrial simulation.
  4. This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices.
  5. This unit can be used for doing applied research.
  6. This unit can be used for giving training courses to Industries even to other Technical Education Institutions.
  7. Control of the TSTCC unit process through the control interface box without the computer.
  8. Visualization of all the sensors values used in the TSTCC unit process.
  9. By using PLC-PI additional 19 more exercises can be done.
  10. Several other exercises can be done and designed by the user.

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