KR20230024623A - Modular education system for refrigeration and heat pump equipment - Google Patents

Abstract

The present invention relates to a refrigeration and heat pump equipment modular training system comprising: a practice table; a compressor module in which a compressor connected to a liquid separator is mounted on a compressor bracket; an evaporator module making an evaporator connected to an expansion valve and an evaporator fan mounted in a transparent evaporation chamber opened and closed by a damper; a condenser module making a condenser and a condenser fan mounted in a transparent condensation chamber; a first heat exchanger module making a first heat exchanger connected to a first expansion valve and a first heat exchange fan mounted in a transparent first heat exchange chamber opened and closed by a damper; a second heat exchanger module making a second heat exchanger connected to a second expansion valve and a second heat exchange fan mounted in a transparent second heat exchange chamber; a refrigeration-only receiver module making a receiver, which is connected with a filter dryer, sight glass, and an electromagnetic valve, mounted on a receiver bracket; a heat pump-specific receiver module making a receiver, which is connected with a filter dryer, sight glass, an electromagnetic valve, and check valves, mounted on the receiver bracket; and a four-way valve module making a four-way valve mounted on a four-way valve bracket. According to the present invention, easy understanding is possible.

Description

Modular education system for refrigeration and heat pump equipment}

The present invention is a technology related to an educational system that acquires facility configuration ability by modularizing parts of cold/hot heat source devices such as vapor compression refrigeration facilities and heat pump facilities, and allowing trainees to arrange and install modules as needed. .

In general, vapor compression refrigeration equipment and heat pump equipment are widely used in industrial settings. In order to construct these vapor compression refrigeration facilities and heat pump facilities, the ability to understand and design the principles and functions of cold/hot heat source devices is essential.

However, since most of the vapor compression refrigeration equipment and heat pump equipment are large and concealed, it is difficult and limited in practice to understand and design the principles and functions of the cold/hot heat source device.

An object of the present invention is to compose a vapor compression refrigeration cycle to easily understand the change of the heat pump facility according to the switching action of heating and cooling through the operation of the four-way valve as well as the installation practice of the refrigeration facility and the control of the refrigeration sequence. It is to provide a modular education system for refrigeration and heat pump facilities.

Refrigeration and heat pump equipment modular education system according to the present invention for achieving the above object is a practice table, a compressor module equipped with a compressor connected to a liquid separator on a compressor bracket, and a transparent evaporation chamber opened and closed by a damper Expansion An evaporator module equipped with an evaporator and an evaporator fan connected with a valve, a condenser module equipped with a condenser and a condenser fan in a transparent condensation chamber, and a first expansion valve connected to a transparent first heat exchange chamber opened and closed by a damper. A first heat exchanger module equipped with a heat exchanger and a first heat exchange fan, a second heat exchanger module equipped with a second heat exchanger and a second heat exchange fan connected to a second expansion valve in a transparent second heat exchange chamber, a filter dryer, A receiver module dedicated to refrigeration in which a receiver connected to a sight glass and an electronic valve is mounted on a receiver bracket, and a receiver module dedicated to a heat pump equipped with a receiver connected to a filter dryer, sight glass, electronic valve, and check valves to a receiver bracket , including the four-way valve module in which the four-way valve is mounted on the four-way valve bracket,

It is possible to configure a refrigeration practice facility by combining a compressor module, a condenser module, an evaporator module, and a receiver module exclusively for refrigeration on the practice table,

A heat pump training facility can be configured by combining a compressor module, a first heat exchanger module, a second heat exchanger module, a receiver module dedicated to a heat pump, and a four-way valve module on a practice table.

According to the present invention, the parts of the cold/hot heat source device such as the vapor compression refrigeration facility and the heat pump facility are modularized, and the practice of installing the refrigeration facility and the refrigeration sequence control are achieved by arranging and installing the module as necessary. Of course, it makes it easy to understand the change of heat pump equipment according to the switching action of heating and cooling. As a result, practitioners can learn a sense of practice and increase adaptability to the field.

1 is a block diagram of a modular education system for refrigeration and heat pump facilities according to an embodiment of the present invention.
2 is a configuration diagram showing an example of a refrigeration practice facility.
3 is a configuration diagram showing an example of a heat pump practice facility.
4 is a perspective view of the compressor module.
5 is a perspective view of an evaporator module.
6 is a cross-sectional view of FIG. 5 .
7 is a perspective view of the condenser module.
8 is a perspective view of the first heat exchanger module.
9 is a perspective view of the second heat exchanger module.
10 is a perspective view of a receiver module exclusively for refrigeration.
11 is a perspective view of a receiver module dedicated to a heat pump;
12 is a perspective view of a four-way valve module.
13 is a system diagram of a refrigeration practice facility.
14 is a system diagram during cooling of the heat pump practice facility.
15 is a system diagram during heating of a heat pump practice facility.
16 is a diagram illustrating an example of a control panel.
17 is a control circuit diagram of a refrigeration practice facility.
18 is a control circuit diagram of a heat pump practice facility.

The present invention will be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same components, and repeated descriptions and detailed descriptions of well-known functions and configurations that may unnecessarily obscure the gist of the present invention are omitted. Embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clarity.

1 is a block diagram of a modular education system for refrigeration and heat pump facilities according to an embodiment of the present invention. 2 is a configuration diagram showing an example of a refrigeration practice facility. 3 is a configuration diagram showing an example of a heat pump practice facility.

1 to 3, a refrigeration and heat pump equipment modular education system 100 according to an embodiment of the present invention includes a practice table 101, a compressor module 110, an evaporator module 120, , the condenser module 130, the first heat exchanger module 140, the second heat exchanger module 150, the refrigeration-only receiver module 160, the heat pump-only receiver module 170, and everywhere A valve module 180 is included.

The practice table 101 makes it possible to configure a refrigeration practice facility or a heat pump practice facility on the upper side. The practice table 101 may be formed in a form in which aluminum profiles are arranged side by side at intervals on the upper surface.

The practice table 101 includes a compressor module 110, an evaporator module 120, a condenser module 130, a first heat exchanger module 140, a second heat exchanger module 150, The receiver module 160 for exclusive use of refrigeration, the receiver module 170 for exclusive use of heat pump, and the four-way valve module 180 can be easily fastened by bolting.

As shown in FIG. 4 , the compressor module 110 mounts the compressor 111 to which the liquid separator 112 is connected to the compressor bracket 113 . The compressor 111 sucks and compresses the low-temperature, low-pressure gaseous refrigerant evaporated by absorbing heat from the object to be cooled in the evaporator 121 to increase the pressure to close the distance between the molecules and raise the temperature to the condenser 131 at room temperature. ) so that it can be easily liquefied.

That is, the compressor 111 serves to send heat obtained while refrigerant evaporates from a low heat source (evaporator) to a high heat source (condenser) at high temperature and high pressure. In addition, the compressor 111 also serves to circulate the refrigerant in the refrigeration equipment by means of compression.

The liquid separator 112 serves as a storage tank for temporarily accommodating the oil-liquid refrigerant mixture, and allows the mixture to return to the compressor 111 at a safe rate. The liquid separator 112 is disposed close to the compressor 111 and is installed in a bypass line or a suction line.

A pressure switch and a pressure gauge may be connected to the compressor 111 . The pressure switch may be a dual pressure switch (D.P.S) in which high/low pressure switches are attached to one body. The pressure gauge displays low/high pressure so that the practitioner can check it.

Service valves are connected to the compressor 111 and the liquid separator 112 to charge the refrigerant. The compressor 111 may include temperature sensors for measuring refrigerant suction temperature and refrigerant discharge temperature.

The compressor module 110 may include a compressor controller. The compressor bracket 113 is bolted to the training table 101 so that the compressor module 110 can be easily installed. The compressor bracket 113 may be made of a material such as stainless steel.

5 and 6, the evaporator module 120 includes an evaporator 121 connected to an expansion valve 126 in a transparent evaporation chamber 123 opened and closed by a damper 124 and an evaporator fan 122 Equip

The evaporator 121 cools by absorbing latent heat of evaporation of a low-temperature, low-pressure liquid refrigerant whose temperature and pressure are away from the expansion valve 126. The evaporator 121 may be made of a finned tube air-cooled heat exchanger. An electrothermal defrost heater may be disposed between the fins and the coil of the evaporator 121 .

The electric defrost heater removes the frost between the pins during long-term freezing experiments. The evaporator 121 may have a temperature sensor and a service valve installed at the refrigerant entrance. A charging nipple may be connected to the evaporator 121 . The filling nipple is used with the manifold gauge during airtight test, vacuum test, refrigerant charge, and refrigerant transfer during refrigeration practice.

The transparent evaporation chamber 123 allows the practitioner to see the configuration of the evaporator 121 and the evaporator fan 122 mounted therein. The transparent evaporation chamber 123 may be made of transparent plastic, for example, transparent acrylic.

The air outlet of the transparent evaporation chamber 123 is opened and closed by a damper 124. The air discharge port discharges air cooled by the evaporator 121 during operation of the refrigeration training facility. The transparent evaporation chamber 123 is configured to be separable into the main chamber 123a and the rear cover 123b, so that the evaporator 121 and the evaporator fan 122 can be easily repaired and replaced.

The rear cover 123b may be installed to open and close the back door 125 in the rear opening. The back door 125 allows outside air to flow into the transparent evaporation chamber 123 in a fully opened and closed state to perform a load change experiment.

In the transparent evaporation chamber 123, an opening is formed at the boundary between the main chamber 123a and the rear cover 123b, and rotates according to the operation of the middle knob 123c by the practitioner to control the opening and closing of the air flow through the opening. Wings can be installed. The transparent evaporation chamber 123 may be fastened to the practice table 101 by bolting via a bracket.

The damper 124 may include a damper member rotatably connected around the air outlet by a hinge to open and close the air outlet, and a damper driver that rotates the damper member. The damper member may be made of transparent plastic, such as transparent acrylic.

The damper actuator may be configured to transfer the rotational force of the motor to the damper member through a rack and pinion. The damper 124 adjusts the opening rate of the air discharge port in several stages in the range of 0 to 100% for precise load control so that a load change experiment can be performed.

The evaporator fan 122 sends cooled/heated air around the evaporator 121 to the air outlet of the transparent evaporation chamber 123 . Therefore, the practitioner can experience the generation of cold air while operating the refrigeration training facility. The evaporator fan 122 is load adjustable with speed control.

The expansion valve 126 decompresses the high-temperature, high-pressure liquid refrigerant from the condenser 131 to a state in which it is easy to evaporate to secure an optimal flow rate inside the evaporator 121 and to increase or decrease the cooling load of the compressor 111 that changes. The superheat of the refrigerant gas is maintained within a certain range according to the capacity.

Expansion valve 126 may be configured as a manual expansion valve. The practitioner adjusts the manual expansion valve 126 to arbitrarily change the evaporation pressure during the operation of the refrigeration training facility to verify and compare the performance accordingly.

As another example, the expansion valve 126 may be configured as a positive pressure type expansion valve. The constant pressure type expansion valve closes when the evaporation pressure increases and opens when the evaporation pressure decreases to keep the evaporation pressure constant. The constant pressure type expansion valve is operated only by evaporation pressure regardless of the fluctuation of the refrigeration load, so it is suitable for capacity with little load fluctuation. The expansion valve 126 may include a pressure sensor at an outlet and a temperature sensor at an inlet.

As shown in FIG. 7 , the condenser module 130 mounts a condenser 131 and a condenser fan 132 in a transparent condensation chamber 133 .

The condenser 131 releases and condenses the heat of the high-temperature, high-pressure refrigerant gas discharged from the compressor 111 into the air at room temperature. That is, the condenser 131 is a device for condensing and liquefying high-temperature and high-pressure gaseous refrigerant discharged from the compressor 111 by exchanging heat with surrounding air or cooling water to release heat of the gaseous refrigerant.

The condenser 131 may be composed of a finned tube air-cooled heat exchanger. The condenser 131 may have a temperature sensor and a service valve installed at the refrigerant entrance. A charging nipple may be connected to the condenser 131 . The condenser fan 132 flows air around the condenser 131 to promote condensation. The condenser fan 132 can increase or decrease the load by speed control.

The transparent condensation chamber 133 allows the practitioner to see the configuration of the condenser 131 and the condenser fan 132 mounted therein. The transparent condensation chamber 133 may be made of transparent plastic, for example, transparent acrylic. The transparent condensation chamber 133 may be fastened to the practice table 101 by bolting through a bracket.

As shown in FIG. 8, the first heat exchanger module 140 is a first heat exchanger 141 connected to a first expansion valve 146 in a transparent first heat exchange chamber 143 opened and closed by a damper, and a first heat exchanger 141. 1 Install the heat exchange fan (142). The load of the first heat exchanging fan 142 can be increased or decreased by speed control. The configuration of the first heat exchanger module 140 except for the configuration of the manifold 147 may be the same as that of the evaporator module 120 described above.

The manifold 147 of the first heat exchanger module 140 is configured to be connected to the first expansion valve 146 and the receiver module 170 dedicated to the heat pump. The first heat exchanger module 140 serves as an evaporator during the cooling operation of the heat pump training facility and serves as a condenser during the heating operation of the heat pump training facility. Practitioners can experience the generation of cold/warm air during the cooling/heating operation of the heat pump practice facility.

As shown in FIG. 9 , the second heat exchanger module 150 includes a second heat exchanger 151 connected to a second expansion valve 156 in a transparent second heat exchange chamber 153 and a second heat exchange fan 152 ) is installed. The load of the second heat exchanging fan 152 can be increased or decreased by speed control. The configuration of the second heat exchanger module 150 may be the same as that of the condenser module 130 described above except for the configuration of the second expansion valve 156 and the manifold 157.

The second expansion valve 156 is used together with the first expansion valve 146 during cooling and heating operation of the heat pump practice facility. The manifold 157 of the second heat exchanger module 150 is configured to be connected to the second expansion valve 156 and the receiver module 170 for exclusive use of the heat pump. The second heat exchanger module 150 serves as a condenser during the cooling operation of the heat pump training facility and serves as an evaporator during the heating operation of the heat pump training facility.

As shown in FIG. 10, in the receiver module 160 for exclusive use of refrigeration, the receiver 161 to which the filter dryer 162, the sight glass 163, and the solenoid valve 164 are connected is mounted on the receiver bracket 165 do.

The receiver 161 is a container for temporarily storing the refrigerant liquefied in the condenser 131 before sending it to the expansion valve 126. The receiver 161 keeps the liquid always remaining even if the amount of refrigerant in the evaporator 121 changes according to the change in the operating state of the facility, thereby smoothing the operation of the facility. The receiver 161 serves to recover (pump down) the refrigerant in the facility when the facility is repaired or stopped for a long period of time.

The filter dryer 162 is installed in the liquid pipe between the expansion valve 126 and the receiver 161 to prevent various adverse effects on the refrigeration facility when moisture and foreign substances exist in the refrigerant system of the facility. Remove moisture and foreign matter from the

The sight glass 163 allows the practitioner to visually check the flow of the refrigerant. The solenoid valve 164 serves to change the refrigerant flow direction. The electromagnetic valve 164 may be formed of a solenoid valve. The receiver bracket 165 is bolted to the practice table 101 so that the receiver module 160 for refrigeration can be easily installed.

As shown in FIG. 11, the receiver module 170 for exclusive use of the heat pump includes a receiver 171 to which a filter dryer 172, a sight glass 173, an electronic valve 174, and a check valve 175 are connected. It is mounted on the base bracket (176).

The configuration of the receiver module 170 for exclusive use of the heat pump except for the check valves 175 and the manifold 177 may be the same as that of the receiver module 160 for exclusive use of refrigeration described above. The check valve 175 is a valve that blurs the fluid only in the forward direction and automatically blocks the flow in the reverse direction. The check valve 175 prevents reverse flow when the facility is stopped.

The manifold 177 of the receiver module 170 for exclusive use of the heat pump includes first distribution pipes 178 branched from the inlet of the receiver 171 and connected to the first and second heat exchangers 141 and 151, Second distribution pipes 179 branched from the outlet of the filter dryer 172 and connected to the first and second expansion valves 146 and 156 may be included. Accordingly, the receiver module 170 for exclusive use of the heat pump may be connected to the first heat exchanger module 140 and the second heat exchanger module 150 to form a heat pump practice facility.

As shown in FIG. 12, the four-way valve module 180 mounts the four-way valve 181 to the four-way valve bracket 182. The four-way valve 181 causes a cooling operation cycle when power is supplied in the heat pump training equipment and current flows, and a heating operation cycle when power is cut off and current does not flow.

That is, the four-way valve 181 functions to switch the flow direction of the refrigerant so that the cooling and heating cycles can be performed according to whether or not power is supplied in the heat pump training equipment. The four-way valve bracket 182 is bolted to the practice table 101 so that the four-way valve module 180 can be easily installed. The four-way valve bracket 182 may be made of a material such as stainless steel.

A processor may be provided and mounted on the practice table 101 . The processor is loaded with software for testing and diagnosing facility performance. The processor enables equipment performance tests and diagnosis by communicating with laptops and computers.

The refrigeration and heat pump facility modular education system 100 of this embodiment includes a compressor module 110, a condenser module 130, an evaporator module 120, and a receiver module 160 dedicated to refrigeration on a practice table 101. By combining them, it is possible to construct a refrigeration practice facility.

Referring to FIG. 13 together with FIG. 2, the compressor 111 is piped to the condenser 131, and the condenser 131 is piped to the expansion valve 126 through the receiver 161 and the filter dryer 162 in sequence. The sight glass 163 and the solenoid valve 164 are sequentially piped between the filter dryer 162 and the expansion valve 126, the expansion valve 126 is piped to the evaporator 121, and the evaporator 121 By being piped to the compressor 111 via the liquid separator 112, a refrigeration practice facility can be configured.

Here, the pipe used for the piping of the refrigeration practice facility may be made of copper pipe. The copper tube may be cut by a cutting operation, bent by a bending operation, and a nut may be attached to the end of the tube by a flaring operation. The practitioner can practice piping through the flare nut fastening method directly to configure the refrigeration practice facility.

In this refrigeration practice facility, the refrigerant is a compressor 111, condenser 131, receiver 161, filter dryer 162, sight glass 163, solenoid valve 164, expansion valve 126, evaporator 121 ), it flows sequentially through the liquid separator 112 and returns to the compressor 111 to form a standard refrigerating cycle. Here, the evaporator 121 generates cool air around.

In addition, the refrigeration and heat pump facility modular education system 100 of this embodiment is a compressor module 110, a first heat exchanger module 140, a second heat exchanger module 150 and a heat exchanger module on a practice table 101 A heat pump practice facility can be configured by combining the receiver module 170 dedicated to the pump and the four-way valve module 180.

Referring to FIGS. 14 and 15 together with FIG. 3, the compressor 111 is piped with a four-way valve 181 at the refrigerant outlet side and piped with the liquid separator 112 at the refrigerant inlet side, and the four-way valve 181 is connected to the second heat exchange It is connected to the group 151, the second heat exchanger 151 is piped to the first heat exchanger 141 via the first and second expansion valves 146 and 156, and the receiver 171 has two check valves 175 are piped to the first heat exchanger 141 and the second heat exchanger 151, respectively, and sequentially pass through the filter dryer 172, the sight glass 173, and the solenoid valve 174, and the first and second It is piped between the expansion valves 146 and 156, and the first heat exchanger 141 is connected to the four-way valve 181, so that a heat pump practice facility can be configured.

Here, the pipe used for the piping of the heat pump practice facility may be made of copper pipe. Practitioners can practice by piping directly through the flare nut fastening method to configure the heat pump practice facility.

In this heat pump practice facility, during cooling operation, the refrigerant is supplied to the compressor 111, the four-way valve 181, the second heat exchanger 151, the check valves 175, the receiver 171, the filter dryer 172, the site Glass 173, solenoid valve 174, first and second expansion valves 146, 156, first heat exchanger 141, and liquid separator 112 are sequentially flowed and returned to compressor 111. forming a cooling cycle that Here, the first heat exchanger 141 generates cold air around.

In addition, in the heat pump practice facility, during heating operation, the refrigerant is supplied to the compressor 111, the four-way valve 181, the first heat exchanger 141, the check valves 175, the receiver 171, the filter dryer 172, The sight glass 173, the solenoid valve 174, the first and second expansion valves 146 and 156, the second heat exchanger 151, and the liquid separator 112 are sequentially flowed and returned to the compressor 111. It forms a circulating heating cycle. Here, the first heat exchanger 141 functions as a condenser to generate warm air around.

On the other hand, the refrigeration and heat pump facility modular education system 100 may include a control panel 190 enabling control practice of the refrigeration practice facility and the heat pump practice facility.

Referring to FIG. 16 together with FIG. 1, the control panel 190 includes a switch module 191 including a push button switch, a temperature control switch, and a toggle switch, a lamp module 192a including a power lamp and a yellow lamp, and a buzzer. (192b), overcurrent breaker 193, magnetic contactor 194a, thermal relay 194b, relay 195, current meter 196a, voltage meter 196b, pressure switch ( 197), a terminal block module 198, and the like.

As shown in FIG. 17, the control panel 190 enables control practice by configuring a circuit by connecting the refrigeration practice facility to the terminal block module with a banana jack or the like.

Here, L1, L2 are line voltage, PB is a push button switch, MC is a magnetic contactor coil, N.F.B is an overcurrent circuit breaker, YL is a yellow lamp, COMP is a compressor motor, MC-a is a magnetic contactor "a" contact, Ry- a is relay "a" contact, PL is power lamp, SV is solenoid valve, Ry-b is relay "b" contact, CFM is condenser fan, EFM is evaporator fan, Ry is relay coil, TC is temperature control switch .

In addition, as shown in FIG. 18, the control panel 190 enables control practice by configuring a circuit by connecting a heat pump practice facility to a terminal block module with a banana jack or the like.

Here, L1 and L2 are line voltage, PB is a push button switch, B is a buzzer, N.F.B is an overcurrent breaker, TC is a temperature control switch, TS is a toggle switch, MC-a is the contact "a" of the magnetic contactor, and Ry-a is Relay "a" contact, 4way valve is a four-way valve, THR is a thermal relay, Ry-b is a relay "b" contact, HE1 is the 1st heat exchange fan (evaporator fan), COMP is a compressor motor, Ry is a relay coil, HE2 denotes a second heat exchange fan (condenser fan), SV denotes a solenoid valve, MC denotes an electromagnetic contactor coil, PL denotes a power lamp, and YL denotes a yellow lamp.

In addition, the control panel 190 can practice various circuit configurations such as switch circuit configuration, electrical and electronic basic circuit configuration, relay circuit configuration, electromagnetic contactor circuit configuration, relay configuration, temperature switch temperature setting operation, and pressure switch pressure setting operation. make it possible

In this way, according to the refrigeration and heat pump facility modular education system 100 of the present embodiment, the parts of the cold/hot heat source device such as the vapor compression refrigeration facility and the heat pump facility are modularized, so that the practitioner can use the module as needed. By having them install after placement, it is easy to understand the changes in the heat pump facility according to the switching action of heating and cooling as well as the installation practice of the refrigeration facility and the control of the refrigeration sequence. As a result, practitioners can learn a sense of practice and increase adaptability to the field.

Although the present invention has been described with reference to an embodiment shown in the accompanying drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. You will be able to. Therefore, the true protection scope of the present invention should be defined only by the appended claims.

101.. Lab table 110.. Compressor module
120.. evaporator module 130.. condenser module
140.. First heat exchanger module 150.. Second heat exchanger module
160.. Receiver module for exclusive use of refrigeration 170.. Receiver module for exclusive use of heat pump
180.. four-way valve module 190.. control panel

Claims (3)

A compressor module equipped with a practice table and a compressor connected to a liquid separator on a compressor bracket, an evaporator module equipped with an evaporator and an evaporator fan connected to an expansion valve in a transparent evaporation chamber opened and closed by a damper, and a condenser in a transparent condensation chamber. A condenser module equipped with a condenser fan, a first heat exchanger module equipped with a first expansion valve connected to a first expansion valve in a transparent first heat exchange chamber opened and closed by a damper, a first heat exchange module equipped with a first heat exchange fan, and a transparent second heat exchange chamber A second heat exchanger module equipped with a second heat exchanger and a second heat exchange fan to which a second expansion valve is connected inside, a receiver module dedicated to refrigeration equipped with a receiver connected to a filter dryer, a sight glass, and a solenoid valve to a receiver bracket, , Including a receiver module dedicated to a heat pump equipped with a filter dryer, a sight glass, a receiver connected to a solenoid valve and a check valve, mounted on a receiver bracket, and a four-way valve module equipped with a four-way valve on a four-way valve bracket,
It is possible to configure a refrigeration practice facility by combining a compressor module, a condenser module, an evaporator module, and a receiver module exclusively for refrigeration on the practice table,
Refrigeration and heat pump characterized in that it is possible to configure a heat pump practice facility by combining a compressor module, a first heat exchanger module, a second heat exchanger module, a receiver module dedicated to a heat pump, and a four-way valve module on a practice table Facility modular training system. According to claim 1,
The receiver module for exclusive use of the heat pump includes first distribution pipes branched from the inlet of the receiver and connected to the first and second heat exchangers, and second distribution pipes branched from the outlet of the filter dryer and connected to the first and second expansion valves. Refrigeration and heat pump facility modular training system, characterized in that it comprises. According to claim 1,
Refrigeration and heat pump facility modular education system, characterized in that it comprises a control panel that enables control practice of the refrigeration practice facility and the heat pump practice facility.

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