TICC Computer Controlled Heat Exchangers Training System

9.7.- HEAT EXCHANGERS
COMPUTER CONTROLLED HEAT EXCHANGERS TRAINING SYSTEM - TICC

INNOVATIVE SYSTEMS

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

See general description

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General Description

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

The minimum supply consists of two main elements: the Base Service Unit, "TIUS", and at least one of the required elements described below.

The Base Service Unit, "TIUS", has the following functions:

  • Heating water in a computer controlled 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):

  • TITC. Concentric Tube Heat Exchanger for TICC: It has been designed by EDIBON 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.
  • TITCA. Extended Concentric Tube Heat Exchanger for TICC: It has been designed by EDIBON 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.
  • TIPL. Plate Heat Exchanger for TICC: It has been designed by EDIBON to study the heat transfer between hot water and cold water flowing through alternate channels formed between parallel plates.
  • TIPLA. Extended Plate Heat Exchanger for TICC: It has been designed by EDIBON to study the heat transfer between hot water and cold water flowing through alternate channels formed between parallel plates.
  • TICT. Shell and Tube Heat Exchanger for TICC, designed by EDIBON, 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.
  • TIVE. Jacketed Vessel Heat Exchanger for TICC, designed by EDIBON, allows the study of heat transfer between hot water flowing through a jacket and the cold water contained in a vessel.
  • TIVS. Coil Vessel Heat Exchanger for TICC, designed by EDIBON, allows the study of heat transfer between hot water flowing through a coil and cold watercontained in the vessel.
  • TIFT. Turbulent Flow Heat Exchanger for TICC designed by EDIBON, Let us study the heat transfer between hot water that circulates through an internal tubeand cold water that flows through the annular zone between the internal and the external tube.
  • TICF. Cross Flow Heat Exchanger for TICC, designed by EDIBON, 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.

This Computer Controlled Unit is supplied with the EDIBON Computer Control System (SCADA), and includes: The unit itself + aControl Interface Box + a Data Acquisition Board + Computer Control, Data Acquisition and Data Management Software Packages, for controlling the process and all parameters involved in the process.

Accessories

CONCENTRIC TUBE HEAT EXCHANGER FOR TICC - TITC
  • TITC
Available
9.7.- HEAT EXCHANGERS
TITC
Concentric Tube Heat Exchanger for TICC
The Concentric Tube Heat Exchanger for TICC, "TITC", designed by EDIBON, allows for the study of heat transfer between two fluids: the hot water flowing through the inner tube and the cold water flowing through the annular zone between the inner...
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EXTENDED CONCENTRIC TUBE HEAT EXCHANGER FOR TICC - TITCA
  • TITCA
Available
9.7.- HEAT EXCHANGERS
TITCA
Extended Concentric Tube Heat Exchanger for TICC
The Expanded Concentric Tube Heat Exchanger for TICC, "TITCA", designed by EDIBON, allows for detailed study of heat transfer between two fluids: the hot water flowing through an inner tube and the cold water circulating in the annular space...
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PLATE HEAT EXCHANGER FOR TICC - TIPL
  • TIPL
Available
9.7.- HEAT EXCHANGERS
TIPL
Plate Heat Exchanger for TICC
The Plate Heat Exchanger for TICC, "TIPL", designed by EDIBON, allows the study of heat transfer between hot and cold water flowing through alternate channels formed between parallel plates. This unit enables the analysis of how heat transfer...
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EXTENDED PLATE HEAT EXCHANGER FOR TICC - TIPLA
  • TIPLA
Available
9.7.- HEAT EXCHANGERS
TIPLA
Extended Plate Heat Exchanger for TICC
The Expanded Plate Heat Exchanger for TICC, "TIPLA", designed by EDIBON, enables detailed study of heat transfer between hot and cold water flowing through alternate channels formed between parallel plates.This unit facilitates analysis of heat...
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SHELL & TUBE HEAT EXCHANGER FOR TICC - TICT
  • TICT
Available
9.7.- HEAT EXCHANGERS
TICT
Shell & Tube Heat Exchanger for TICC
The Shell and Tube Heat Exchanger for TICC, "TICT", designed by EDIBON, provides a comprehensive environment for the study of heat transfer. It allows analysis of the overall energy balance, heat losses in parallel and counterflow configurations,...
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JACKETED VESSEL HEAT EXCHANGER FOR TICC - TIVE
  • TIVE
Available
9.7.- HEAT EXCHANGERS
TIVE
Jacketed Vessel Heat Exchanger for TICC
The Jacketed Vessel Heat Exchanger for TICC, "TIVE", designed by EDIBON, provides a comprehensive environment for the detailed study of heat transfer between two non-mixing fluids. In this unit, hot water flows through a jacket, transferring heat...
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COIL VESSEL HEAT EXCHANGER FOR TICC - TIVS
  • TIVS
Available
9.7.- HEAT EXCHANGERS
TIVS
Coil Vessel Heat Exchanger for TICC
The Coil Vessel Heat Exchanger for TICC, "TIVS", designed by EDIBON, provides a comprehensive environment for the detailed study of heat transfer between two non-mixing fluids. In this unit, hot water circulates through a coil, transferring heat...
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TURBULENT FLOW HEAT EXCHANGER FOR TICC - TIFT
  • TIFT
Available
9.7.- HEAT EXCHANGERS
TIFT
Turbulent Flow Heat Exchanger for TICC
Heat exchangers with turbulent flow are widely used in various industries such as chemical, food, pharmaceutical, and energy generation. These devices play a fundamental role in heating and cooling fluids, as well as in cooling systems for...
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CROSS FLOW HEAT EXCHANGER FOR TICC - TICF
  • TICF
Available
9.7.- HEAT EXCHANGERS
TICF
Cross Flow Heat Exchanger for TICC
The Cross-Flow Heat Exchanger for TICC, "TICF", designed by EDIBON, provides an effective thermal research tool by enabling the study of heat transfer between two fluids in a cross-flow configuration. In this system, a stream of hot water from the...
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Exercises and guided practices

GUIDED PRACTICAL EXERCISES INCLUDED IN THE MANUAL

Practices to be done with the Concentric Tube Heat Exchanger for TICC (TITC):

  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.

Additional practical possibilities:

  1. Sensors calibration.
  2. Study of the hysteresis of the flow sensor.

Practices to be done with the Extended Concentric Tube Heat Exchanger for TICC (TITCA):

  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.

Additional practical possibilities:

  1. Sensors calibration.
  2. Study of the hysteresis of the flow sensor.

Practices to be done with the Plate Heat Exchanger for TICC (TIPL):

  1. Study of the hysteresis of the flow sensor.
  2. Global energy balance in the heat exchanger and the study of losses.
  3. Exchanger effectiveness determination. NTU Method.
  4. Study of the heat transfer under counter-current and co-current flow conditions.
  5. Influence of the flow in heat transfer. Calculation of Reynolds number.

Additional practical possibilities:

  1. Sensors calibration.
  2. Study of the hysteresis of the flow sensor.

Practices to be done with the Extended Plate Heat Exchanger for TICC (TIPLA):

  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.

Additional practical possibilities:

  1. Sensors calibration.
  2. Study of the hysteresis of the flow sensor.

Practices to be done with the Shell and Tube Heat Exchanger for TICC (TICT):

  1. Global energy balance in the heat exchanger and the study of losses.
  2. Obtainment and representation of the temperature distribution in a shell and tube exchanger.
  3. Calculation of the LMTD for a shell and tube exchanger.
  4. Calculation of the overall heat transfer coefficient in a shell and tube exchanger.
  5. Exchanger effectiveness determination. NTU Method.
  6. Influence of the flow in the heat transfer. Calculation of Reynolds number in the side of the tubes.
  7. Influence of the flow in the heat transfer. Calculation of Reynolds number in the side of the shell.
  8. Obtainment of Prandtl number for the tubes side.
  9. Obtainment of Prandtl number for the shell side.
  10. Obtainment of Nusselt number and the heat transfer coefficient by convection (hi) for the side of the tubes.
  11. Obtainment of Nusselt number and the heat transfer coefficient by convection (ho) for the side of the shell.

Additional practical possibilities:

  1. Sensors calibration.
  2. Study of the heat transfer under counter-current and co-current flow conditions.
  3. Flow influence on the heat transfer. Reynolds number calculation.
  4. Study of the hysteresis of the flow sensor.

Practices to be done with the Jacketed Vessel Heat Exchanger for TICC (TIVE):

  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’s water volume on the heat transfer when operating in batches.

Additional exercises and practical possibilities

  1. Sensors calibration.
  2. Influence of the vessel stirring on the heat transfer when operating in batches.
  3. Study of the hysteresis of the flow sensor.

Practices to be done with the Coil Vessel Heat Exchanger for TICC (TIVS):

  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 water volume in the vessel on the heat transfer with operation in batches.

Additional exercises and practical possibilities

  1. Sensors calibration.
  2. Study of the hysteresis of the flow sensor.
  3. Influence of the stirring vessel on the heat transfer with operation in batches.

Practices to be done with the Turbulent Flow Heat Exchanger for TICC (TIFT):

  1. Global energy balance in the heat exchanger and loss 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.

Additional practical possibilities:

  1. Sensors calibration.
  2. Study of the hysteresis in the flow sensors.

Practices to be done with the Cross Flow Heat Exchanger for TICC (TICF):

  1. Overall energy balance in the heat exchanger and study of losses.
  2. Determination of the exchanger effectiveness (NTU method).
  3. Influence of air and water flow on the heat transfer. Reynolds number calculation.

Additional practical possibilities:

  1. Sensors calibration.
  2. Introduction to the concept of psychometric properties.
  3. Effect of temperature differential on the heat transfer coefficient.
  4. Familiarization with cross flow heat exchanger.
  5. Study of the hysteresis in the flow sensors.
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MORE PRACTICAL EXERCISES TO BE DONE WITH THE UNIT

  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/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 unit process through the control interface box without the computer.
  8. Visualization of all the sensors values used in the 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

SIMILAR UNITS AVAILABLE

HEAT EXCHANGER TRAINING SYSTEM - TICB
  • TICB
Available
9.7.- HEAT EXCHANGERS
TICB
Heat exchanger Training System
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...
View Unit
COMPUTER CONTROLLED HEAT EXCHANGERS BASIC UNIT - TICC/SS
  • TICC/SS
Available
9.7.- HEAT EXCHANGERS
TICC/SS
Computer Controlled Heat Exchangers Basic Unit
The Computer Controlled Basic Heat Exchangers Unit (TICC/SS) has been designed by Edibon to study and compare different types of small-scale heat exchangers working with parallel or counterflow arrangements.The complete unit consists of two main...
View Unit

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