TICB Heat exchanger Training System

HEAT EXCHANGER TRAINING SYSTEM - TICB

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The Heat exchanger Training System, "TICB", has been designed by EDIBON to study and compare different types of small-scale heat exchangers working with parallel or counterflow arrangements.

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Heat exchangers are widely used in refrigeration, air conditioning, heating, energy generation, chemical processing, etc. They have many applications in engineering and, as a consequence, there are many models adapted to each application to obtain an efficient heat transfer.

The Heat exchanger Training System, "TICB", has been designed by EDIBON to study and compare different types of small-scale heat exchangers working with parallel or counter flow arrangements.

The complete unit consists of two main elements: the base service unit and the required elements (at least one) (Not included).

The Base Service Unit, "TIUSB", is common for the required elements (at least one) (Not included). Its functions are:

  • Heating water in a thermostatic bath.
  • Pumping the hot water.
  • Regulation and measurement of the cold water and hot water flows.
  • Measurement of the inlet and outlet temperatures of the cold water and the hot water.
  • Measurement of the pressure drop in the exchanger.

Required elements (at least one) (Not included):

  • TITCB. Concentric Tube Heat Exchanger for TICB: It has been designed to study the heat transfer between hot water flowing through an internal tube and cold water flowing through the annular area between the internal and the external tubes.
  • TITCAB. Extended Concentric Tube Heat Exchanger for TICB: It has been designed to study the heat transfer between hot water flowing through an internal tube and cold water flowing through the annular area between the internal and the external tubes.
  • TIPLB. Plate Heat Exchanger for TICB: It has been designed to study the heat transfer between hot water and cold water flowing through alternate channels formed between parallel plates.
  • TIPLAB. Extended Plate Heat Exchanger for TICB: It has been designed to study the heat transfer between hot water and cold water flowing through alternate channels formed between parallel plates.
  • TICTB. Shell and Tube Heat Exchanger for TICB: It consists of a series of tubes inside the heat exchanger where hot water flows. The cooling water flows through the space between the inner tubes and the shell.
  • TIVEB. Jacketed Vessel Heat Exchanger for TICB: Allows the study of heat transfer between hot water flowing through a jacket and the cold water contained in a vessel.
  • TIVSB. Coil Vessel Heat Exchanger for TICB: Allows the study of heat transfer between hot water flowing through a coil and cold watercontained in the vessel.
  • TIFTB. Turbulent Flow Heat Exchanger for TICB: Let us study the heat transfer between hot water that circulates through an internal tube and cold water that flows through the annular zone between the internal and the external tube.
  • TICFB. Cross Flow Heat Exchanger for TICB: Designed to study heat transfer between two fluids in cross flow configuration. Hot water flow coming from the base unit enters and leaves a radiator perpendicular to an air current, which is generated by a fan.

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Practices to be done with the Concentric Tube Heat Exchanger for TICB (TITCB):

  1. Global energy balance in the heat exchanger and the study of losses.
  2. Exchanger effectiveness determination. NTU Method.
  3. Study of the heat transfer under counter-current and co-current flow conditions.
  4. Flow influence on the heat transfer. Reynolds number calculation.

Practices to be done with the Extended Concentric Tube Heat Exchanger for TICB (TITCAB):

  1. Global energy balance in the heat exchanger and the study of losses.
  2. Exchanger effectiveness determination. NTU Method.
  3. Study of the heat transfer under counter-current and co-current flow conditions.
  4. Flow influence on the heat transfer. Reynolds number calculation.

Practices to be done with the Plate Heat Exchanger for TICB(TIPLB):

  1. Global energy balance in the heat exchanger and the study of losses.
  2. Exchanger effectiveness determination. NTU Method.
  3. Study of the heat transfer under counter-current and co-current flow conditions.
  4. Flow influence on the heat transfer. Reynolds number calculation.

Practices to be done with the Extended Plate Heat Exchanger for TICB(TIPLAB):

  1. Global energy balance in the heat exchanger and the study of losses.
  2. Exchanger effectiveness determination. NTU Method.
  3. Study of the heat transfer under counter-current and co-current flow conditions.
  4. Flow influence on the heat transfer. Reynolds number calculation.

Practices to be done with the Shell and Tube Heat Exchanger for TICB (TICTB):

  1. Global energy balance in the heat exchanger and the study of losses.
  2. Exchanger effectiveness determination. NTU Method.
  3. Study of the heat transfer under counter-current and co-current flow conditions.
  4. Flow influence on the heat transfer. Reynolds number calculation.

Practices to be done with the Jacketed Vessel Heat Exchanger for TICB (TIVEB):

  1. Global balance of energy in the heat exchanger and losses study.
  2. Determination of the exchanger effectiveness. NTU Method.
  3. Influence of the flow on the heat transfer. Calculation of the number of Reynolds.
  4. Influence of the vessel stirring on the heat transfer when operating in batches.
  5. Influence of the vessel's water volume on the heat transfer when operating in batches.

Practices to be done with the Coil Vessel Heat Exchanger for TICB (TIVSB):

  1. Global balance of energy in the heat exchanger and the study of losses.
  2. Determination of the exchanger effectiveness. NTU Method.
  3. Influence of the flow on the heating transfer. Calculation of Reynolds number.
  4. Influence of the stirring vessel on the heat transfer with operation in batches.
  5. Influence of the water volume in the vessel on the heat transfer with operation in batches.

Practices to be done with the Turbulent Flow Heat Exchanger for TICB (TIFTB):

  1. Global energy balance in the heat exchanger and losses study.
  2. Determination of the exchanger effectiveness. NTU Method.
  3. Study of the heat transfer in counter-current and co-current flow conditions.
  4. Flow influence on heat transfer. Reynolds number calculation.
  5. Obtaining of the correlation that relates Nusselt number with Reynolds number and Prandtl number.
  6. Obtaining of the heat transfer coefficients by convection.

Practices to be done with the Cross Flow Heat Exchanger for TICB (TICFB):

  1. Introduction to the concept of psychometric properties.
  2. Effect of temperature differential on the heat transfer coefficient.
  3. Familiarization with cross flow heat exchanger.
  4. Overall energy balance in the heat exchanger and study of losses.
  5. Determination of the exchanger effectiveness (NTU method).
  6. Influence of air and water flow on the heat transfer. Reynolds number calculation.
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