KR101456878B1 - Control Method of Performance Test System for Heat Pump - Google Patents

Abstract

The present invention relates to a control method of a heat pump performance evaluation system, comprising: a step (S110) of operating a heat pump to be a performance evaluation; and a step of circulating a first constant temperature fluid stored in a first thermostat through a first circulation pipe Exchanges heat with the heat pump refrigerant in the first heat exchanger (evaporator) of the heat pump, and circulates the second constant temperature fluid stored in the second thermostat through the second circulation pipe, so that the heat in the second heat exchanger (condenser) Circulating the first thermostatic fluid in the first thermostatic chamber through the first subordinate circulation pipe and circulating the second thermodynamic fluid in the second thermostatic chamber through the second subordinate circulation pipe, (S130) of exchanging heat with each other in the thermostatic fluid heat exchanger; and controlling the temperature of the first thermostatic fluid in the first subcirculation pipe, which has passed through the thermostatic fluid heat exchanger, And adjusting the temperature of the second thermostatic fluid of the second auxiliary circulation pipe passing through the thermostatic fluid heat exchanger to a desired predetermined temperature of the second thermostat (S150) .

Description

TECHNICAL FIELD [0001] The present invention relates to a control method for a heat pump performance evaluation system,

The present invention relates to a control method of a heat pump performance evaluation system for evaluating the performance of a heat pump. More specifically, by reducing the amount of energy supplied from the outside required to maintain the constant temperature fluid in each of the two thermostats used in the heat pump performance evaluation system at a desired temperature, energy required for heat pump performance evaluation can be reduced To a control method of a heat pump performance evaluation system.

Recently, as utilization of heat pump increases, performance evaluation system for evaluating heat pump performance for accurately evaluating the performance of heat pump is increasing. A general heat pump performance evaluation system is described in "Performance Tests of Air Conditioners and Heat Pumps [I] - Presented at the Facility Engineering Publications, Vol. 15, No. 2, pp. 163 to 168, "(Min.

A general heat pump performance evaluation system is schematically shown in FIG. Referring to FIG. 1, the heat pump performance evaluation system includes two first thermostats 11 and a second thermostat 12. The first thermostatic chamber 11 is connected to the first thermostatic fluid which is heat-exchanged with the heat pump refrigerant in the first heat exchanger 21 of the heat pump 20 (the evaporator in the case of the heat pump circulation direction of the heat pump 1) And the second thermostatic chamber 12 is provided for controlling the temperature of the second constant temperature fluid to be heat-exchanged with the heat pump refrigerant in the second heat exchanger 22 (the condenser in the case of the heat pump refrigerant circulation direction in FIG. 1) Is maintained at a predetermined temperature. For reference, the temperature of the first thermostatic fluid and the required predetermined temperature of the second thermostatic fluid are expressed as the same 'predetermined temperature' in the expressions, but they are different temperatures. This is the same in the embodiments of the present invention described below.

On the other hand, the first thermostatic chamber 11 stores the first thermostatic fluid, which is heat-exchanged with the heat pump refrigerant in the first heat exchanger (21, evaporator) while the heat pump 20 is operating, The temperature is lowered. Therefore, the first thermostatic chamber 11 must receive heat from the outside in order to raise the lowered temperature, and the heat is supplied by the electric heater 41 provided for this purpose.

The second thermostatic chamber 12 stores the second constant temperature fluid which is heat-exchanged with the heat pump refrigerant in the second heat exchanger (condenser) 22 during operation of the heat pump 20, Therefore, the temperature rises. Therefore, the second thermostat 12 must radiate heat to the outside in order to lower the elevated temperature. To this end, the second thermostatic chamber 12 has a structure for exchanging heat with the second refrigerator 32.

1, the first heat exchanger 21 serves as a condenser, and the second heat exchanger 22 serves as a condenser, The first thermostatic chamber 11 must emit heat to the outside and the second thermostatic chamber 12 must receive heat from the outside. To this end, the first thermostatic chamber 11 has a structure in which the first constant temperature fluid exchanges heat with the first refrigerator 31, and the second thermostatic chamber 12 has a structure of receiving heat by the electric heater 42.

In order to maintain the temperature of the first and second thermostats 11 and 12 constant at a predetermined temperature as the capacity of the heat pump to be evaluated is increased, The first and second refrigerators 31 and 32 and the electric heaters 41 and 42 having capacity larger than the capacity of the second heat exchanger 22 and the condenser 21 of the first heat exchanger 20 and the first heat exchanger 21 .

In this case, there is a problem that the installation cost is increased due to the enlargement of the first and second refrigerator 31, 32 and the electric heaters 41, 42, and the operation cost such as the electric consumption is increased during performance evaluation.

In order to solve the problems of the conventional heat pump performance evaluation system, the present invention provides an apparatus for evaluating the performance of a conventional heat pump, in which the amount of energy supplied from the outside required to maintain the constant temperature fluid in two thermostats, And to provide a control method of a heat pump performance evaluation system that can minimize the heat pump performance.

In order to achieve the above object, the present invention relates to a control method of a heat pump performance evaluation system, comprising: a step (S110) of operating a heat pump to be a performance evaluation; Exchanging the heat with the heat pump refrigerant in the first heat exchanger (evaporator) of the heat pump, and circulating the second constant temperature fluid stored in the second thermostat through the second circulation pipe to circulate through the circulation pipe to perform the second heat exchange (S120) of circulating the first thermostatic fluid of the first thermostat through the first sub-circulation pipe, and circulating the second thermostatic fluid of the second thermostatic chamber through the second sub- (S130) circulating through the circulating piping and mutually exchanging heat in the constant temperature fluid heat exchanger (S130); and controlling the temperature of the first constant temperature fluid in the first auxiliary circulation pipe passing through the constant temperature fluid heat exchanger (S140) of adjusting the temperature of the second thermostatic fluid in the second auxiliary circulation pipe passing through the thermostatic fluid heat exchanger to a desired predetermined temperature of the second thermostatic chamber Step (150).

 A control method of a heat pump performance evaluation system according to the present invention having such a configuration includes a first constant temperature fluid to be heat-exchanged in an evaporator of a heat pump to be subjected to performance evaluation and a second constant temperature fluid to be heat-exchanged in a condenser of the heat pump, By allowing heat exchange with each other in the thermostatic fluid heat exchanger, the energy supplied from the outside can be reduced in order to set the first thermostatic fluid and the second thermostatic fluid respectively to the required predetermined temperatures.

1 is a schematic view of a conventional heat pump performance evaluation system.
2 is a view showing an embodiment of a heat pump performance evaluation system to which the control method of the present invention is applied.
Fig. 3 is a view showing the action of the embodiment of Fig. 2. Fig.
4 is a view showing a control method of a heat pump performance evaluation system according to the present invention.
5 is a view showing step S140 of FIG. 4 in more detail.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a heat pump performance evaluation system and a control method thereof according to the present invention will be described in detail with reference to the accompanying drawings.

<Embodiment>

First, an embodiment of a heat pump performance evaluation system to which the control method of the present invention is applied will be described with reference to FIG. The heat pump performance evaluation system to which the control method of the present invention is applied includes a heat pump 100 to be roughly evaluated for performance, a first thermostat 200, a second thermostat 400, a thermostatic fluid heat exchanger 300, And a freezer 500.

The heat pump 100 to be subjected to the performance evaluation basically comprises a compressor 110 for compressing the heat pump refrigerant, a four-way valve 120 for switching the circulation direction of the heat pump refrigerant, a first heat exchanger A second heat exchanger (130, a condenser) for heat-exchanging the heat pump refrigerant, and an expansion device (140) for expanding the heat pump refrigerant.

3, the first heat exchanger 150 serves as an evaporator, the second heat exchanger 130 serves as an evaporator, and the first heat exchanger 150 serves as an evaporator. Serves as a condenser. The heat pump refrigerant flows through the heat pump refrigerant pipe L100 connecting the compressor 110, the four-way valve 120, the first heat exchanger 150, the second heat exchanger 130 and the expansion device 140 do.

The first thermostat 200 stores the first constant temperature fluid at a predetermined temperature for heat exchange with the heat pump refrigerant in the first heat exchanger (evaporator) 150 of the heat pump 100. The first thermostat (200) is provided with a temperature sensor (201) for measuring the temperature of the first thermostatic fluid stored in the first thermostat (200).

The first constant temperature fluid stored in the first thermostat 200 passes through the first heat exchanger 150 (evaporator) while flowing along the first circulation pipe L200. That is, the first circulating pipe L200 is a pipe connected to the first thermostatic chamber 200 so that the first thermostatic fluid passes through the first thermostat 200 (the evaporator), and then enters the first thermostatic chamber 200 again.

The circulation pump 210 and the flow meter 220 are installed in the first circulation pipe L200. Therefore, it is possible to control the flow rate of the first thermostatic fluid flowing through the first circulation pipe L200 by using the circulation pump 210 and also to control the flow rate of the first thermostatic fluid flowing through the first circulation pipe L200 using the flow meter 220 Can be measured.

A temperature sensor 231 and a temperature sensor 232 are installed at the inlet and outlet of the first circulation pipe L200 so that the first circulation pipe L200 passes through the first heat exchanger 150 The temperature of the first constant temperature fluid is measured. Based on the measured temperature difference of the first constant temperature fluid and the flow rate circulating through the first circulation pipe L200 measured by the flow meter 220, the heat pump refrigerant in the first heat exchanger (150, evaporator) The heat exchange amount of the constant temperature fluid can be measured.

The second thermostat 400 stores the second thermostatic fluid, which is heat-exchanged with the heat pump refrigerant, in the second heat exchanger (condenser) 130 of the heat pump 100 at a predetermined temperature. The second thermostatic chamber 400 is provided with a temperature sensor 401 for measuring the temperature of the second thermostatic fluid stored in the second thermostatic chamber 400.

The second constant temperature fluid stored in the second thermostat 400 passes through the second heat exchanger 130 (condenser) while flowing along the second circulation pipe L400. That is, the second circulating pipe L400 is a pipe connected to the first thermostatic chamber 400 so that the first thermostatic fluid passes through the second thermostat 400, the second thermostat 130, the condenser, and then into the second thermostatic chamber 400.

The circulation pump 410 and the flow meter 420 are installed in the second circulation pipe L400. Therefore, the circulation pump 410 can be used to regulate the flow rate of the second constant temperature fluid flowing through the second circulation pipe L400, and the flow rate of the second constant temperature fluid flowing through the second circulation pipe L400 using the flow meter 420 Can be measured.

A temperature sensor 431 and a temperature sensor 432 are provided at the inlet and outlet of the second circulation pipe L400 and the second heat exchanger 130 and the condenser, The temperature of the second constant temperature fluid is measured. Based on the measured temperature difference of the second constant temperature fluid and the flow rate circulating through the second circulation pipe L400 measured by the flow meter 420, the heat pump refrigerant in the second heat exchanger (130, condenser) The heat exchange amount of the constant temperature fluid can be measured.

The thermostatic fluid heat exchanger 300 is a heat exchanger in which the first thermostatic fluid of the first thermostat 200 and the second thermostatic fluid of the second thermostatic chamber 400 exchange heat with each other. A first auxiliary circulation pipe (L210) through which the first constant temperature fluid flows and a second auxiliary circulation pipe (L410) through which the second constant temperature fluid flows are passed through the constant temperature fluid heat exchanger (300).

Specifically, the first auxiliary circulation pipe L210 has a structure for allowing the first thermostatic fluid to flow from the first thermostatic chamber 200 to the first thermostatic chamber 200 via the thermostatic fluid heat exchanger 300, 2 auxiliary circulation pipe L410 has a structure in which the second thermostatic fluid is allowed to flow from the second thermostat 400 through the thermostatic fluid heat exchanger 300 to the second thermostatic chamber 400 again.

The circulation pump 240 for circulating the first constant temperature fluid is provided in the first auxiliary circulation pipe L210 and the first constant temperature fluid is supplied to the first thermostatic chamber 200 through the constant temperature fluid heat exchanger 300, The first electric heater 250 is installed at a position where the first electric heater 250 is introduced. The circulation pump 240 can change the flow rate of the first constant temperature fluid circulated by the inverter or the like. In addition, the first electric heater 250 functions to regulate the temperature of the first constant temperature fluid by heating the first constant temperature fluid flowing into the first thermostatic chamber 200.

The circulation pump 440 for circulating the second constant temperature fluid is installed in the second auxiliary circulation pipe L410 and the second constant temperature fluid is supplied to the second thermostat 400 through the thermostatic fluid heat exchanger 300 And a second electric heater 450 is installed at a point where it flows. The circulation pump 440 can change the flow rate of the second constant temperature fluid circulated by the inverter or the like. The second electric heater 450 also functions to regulate the temperature of the second constant temperature fluid by heating the second constant temperature fluid flowing into the second constant temperature chamber 400.

The refrigerator 500 includes a refrigerant refrigerant pipe L500 through which the refrigerant refrigerant flows. The refrigerator 500 further includes an auxiliary heat exchanger 520 for exchanging heat with the second constant temperature fluid flowing through the second auxiliary circulation pipe L410.

In arranging the auxiliary heat exchanger 520 to pass the second auxiliary circulation pipe L410, the second constant temperature fluid is arranged to pass through the auxiliary heat exchanger 520 after passing through the constant temperature fluid heat exchanger 300 .

A temperature sensor 211 for measuring the temperature of the first thermostatic fluid is provided between the thermostatic fluid heat exchanger 300 and the first electric heater 250 in the first subordinate circulation pipe L210, A temperature sensor 411 is provided between the auxiliary heat exchanger 520 and the second electric heater 450 in the circulation pipe L410 to measure the temperature of the second constant temperature fluid.

Meanwhile, it is preferable that the capacity of the refrigerator 500 is adjusted according to the capacity of the heat pump 100. Specifically, the refrigerator 500 may include a plurality of small-capacity freezers to operate some of the freezers to correspond to the required capacity, and a capacity variable type freezer may be employed.

A control method of the heat pump performance evaluation system according to the embodiment having such a configuration will be described.

The heat pump 100 to be subjected to the performance evaluation is operated so as to have the operation mode in which the heat pump refrigerant circulates in the direction as shown in Fig. 3 (S110 in Fig. 4). In this case, the second heat exchanger 130 serves as a condenser and the first heat exchanger 150 serves as an evaporator.

Thereafter, the circulation pump 210 is operated to circulate the first constant temperature fluid of the first thermostat 200 through the first circulation pipe L200, and the circulation pump 410 is operated to operate the second thermostatic chamber 400, To circulate through the second circulation pipe L400 (S120 in FIG. 4).

In this case, in the second heat exchanger 130 (condenser), heat is transferred from the heat pump refrigerant flowing through the heat pump refrigerant pipe L100 to the second constant temperature fluid flowing through the second circulation pipe L400 (Q2). As a result, the temperature of the second thermostatic fluid flowing through the second circulation pipe L400 rises, and as a result, the temperature of the second thermostatic fluid of the second thermostatic chamber 400 rises.

In the first heat exchanger 150 (evaporator) serving as an evaporator of the heat pump 100, the heat pump refrigerant flowing through the heat pump refrigerant pipe L100 generates heat from the first constant temperature fluid flowing through the first circulation pipe L200 Receive (Q1). As a result, the temperature of the first thermostatic fluid flowing through the second circulation pipe L200 is lowered, and as a result, the temperature of the first thermostatic fluid of the first thermostatic chamber 200 is lowered.

The amount of heat exchanged in the condenser (the second heat exchanger 130) of the heat pump 100 is larger than the amount of heat exchanged in the evaporator (the first heat exchanger 150) (Q2> Q1). Because the first and second thermostatic fluids must each maintain a desired predetermined temperature, it is necessary to raise the temperature of the first thermostatic fluid through the first heat exchanger 150 as much as the lowered temperature , And for the second constant temperature fluid, it is necessary to lower the temperature by the elevated temperature while passing through the second heat exchanger (130).

To this end, first and second auxiliary circulating pipes (L210 and L410) are connected to the first thermostatic fluid whose temperature has been lowered by the operation of the heat pump (100) and the second thermostatic fluid whose temperature has been raised, (Q3) (S130 in FIG. 4). As a result, the temperature of the first thermostatic fluid passing through the thermostatic fluid heat exchanger 300 is raised, and the temperature of the second thermostatic fluid is lowered.

Thereafter, the temperature of the first thermostatic fluid discharged from the thermostatic fluid heat exchanger 300 is adjusted to a desired temperature of the first thermostatic chamber 200 (S140 in FIG. 4). Specifically, first, the flow rate of the first constant temperature fluid flowing through the first auxiliary circulation pipe L210 is determined based on the flow rate of the first constant temperature fluid flowing through the first circulation pipe L200 (S141 in FIG. 5). The flow rate of the first constant temperature fluid flowing through the first auxiliary circulation pipe L210 is equal to the flow rate of the first constant temperature fluid flowing through the first circulation pipe L200 measured using the flow meter 220 installed in the first circulation pipe L200 Is set equal to or smaller than the flow rate of the fluid. The reason is that if the flow rate of the first constant temperature fluid flowing through the first auxiliary circulation pipe L210 becomes excessively larger than the flow rate of the first constant temperature fluid flowing through the first circulation pipe L200, This is because the temperature of the first constant temperature fluid flowing through the first auxiliary circulation pipe L210 can not be precisely controlled. The flow rate of the first constant temperature fluid flowing through the first auxiliary circulation pipe L210 can be controlled by the circulation pump 240 installed in the first auxiliary circulation pipe L210.

Next, the flow rate of the second constant temperature fluid flowing through the second auxiliary circulation pipe (L410) is adjusted so that heat is exchanged with the second constant temperature fluid in the constant temperature fluid heat exchanger (300) 1 The temperature of the constant temperature fluid is adjusted (S142 in FIG. 5). Specifically, the circulation pump 440 is operated to control the flow rate of the second constant temperature fluid flowing through the second subsidiary circulation pipe L410 to flow through the first auxiliary circulation pipe L210 via the constant temperature fluid heat exchanger 300, The temperature of the first thermostatic fluid stored in the thermostatic chamber 200 is measured by the temperature sensor 201 so that the temperature of the first thermostatic fluid is adjusted to the required temperature of the first thermostatic chamber 200, And the flow rate is determined as the flow rate of the second constant temperature fluid flowing through the second auxiliary circulation pipe (L410).

On the other hand, since the variation of the amount of heat exchange in the constant temperature fluid heat exchanger 300 is not linear in accordance with the variation of the capacity of the circulation pump 440, the capacity of the circulation pump 440 is varied as described above, By adjusting the amount of heat exchange in the thermostatic fluid heat exchanger 300 by adjusting the flow rate of the second thermostatic fluid flowing through the pipe L410, the temperature of the first thermostatic fluid flowing through the first subordinate circulation pipe L210 is required It may be difficult to precisely adjust the temperature to a predetermined temperature.

In this case, the temperature of the first thermostatic fluid discharged from the thermostatic fluid heat exchanger 300 in the first auxiliary circulation pipe L210 is measured by the temperature sensor 211, and the temperature of the first thermostatic fluid is measured by the temperature of the first thermostatic chamber 200 The first electric heater 250 may be operated to accurately set the predetermined temperature of the first thermostatic chamber 200 to the first thermostatic chamber 200. When the temperature of the first thermostatic chamber 200 is lower than the predetermined temperature, Specifically, in determining the flow rate of the second thermostatic fluid circulated through the second sub-circulation pipe L410 by the circulation pump 440, the temperature of the second thermostatic fluid in the thermostatic fluid heat exchanger 300 Determines the flow rate of the second thermostatic fluid flowing through the second sub-circulation pipe (L410) such that the temperature of the first thermostatic fluid is lower than the required predetermined temperature of the first thermostatic chamber (200) The temperature of the first thermostatic fluid discharged from the thermostatic fluid heat exchanger 300 and the difference between the predetermined temperature required by the first thermostatic chamber 200 and the temperature by the first electric heater 250 Let's fit it. In this case, since the first electric heater 250 can linearly supply heat according to the amount of electric energy to be supplied, the temperature can be precisely controlled, so that the temperature of the first constant temperature fluid can be precisely controlled It has an advantageous advantage.

Next, the temperature of the second thermostatic fluid, which is heat-exchanged in the thermostatic fluid heat exchanger 300 and then flows into the second thermostatic chamber 400, is adjusted to a desired temperature of the second thermostatic chamber 400 S150). Since the second thermostatic fluid that is heat-exchanged in the thermostatic fluid heat exchanger 300 and then flows into the second thermostatic chamber 400 is higher than the required temperature of the second thermostatic chamber 400, Exchanges heat with the refrigerant refrigerant flowing through the refrigerant pipe (L500) to lower the temperature to a desired temperature. Specifically, as shown in FIG. 3, the refrigerator 500 is operated to allow refrigerant refrigerant to pass through the auxiliary heat exchanger 520, so that the second auxiliary refrigerant passing from the auxiliary heat exchanger 520 through the constant temperature fluid heat exchanger 300 And the temperature is lowered by heat exchange with the second constant temperature fluid of the circulation pipe (L410).

At this time, the capacity of the refrigerator 500 is determined by measuring the temperature of the second thermostatic fluid that has passed through the auxiliary heat exchanger 520 with the temperature sensor 411, . The second thermostatic fluid passing through the auxiliary heat exchanger (520) is heated by the second electric heater (450) to precisely match the required temperature of the second thermostat (400). Since the second electric heater 450 can supply heat linearly according to the amount of energy of electricity to be supplied, the temperature can be precisely controlled. Therefore, when such a method is used, the second electric heater 450, which has passed through the auxiliary heat exchanger 520 The temperature of the second thermostatic fluid can be precisely adjusted to the required predetermined temperature of the second thermostatic chamber 400. [

As described above, the control method of the heat pump performance evaluation system according to the present invention includes the first constant temperature fluid subjected to heat exchange in the evaporator (first heat exchanger 150) of the heat pump 100 to be subjected to the performance evaluation, (Second heat exchanger 130) of the first constant temperature fluid and the second constant temperature fluid in the constant temperature fluid heat exchanger 300 by exchanging the first constant temperature fluid and the second constant temperature fluid with each other, It is possible to reduce the energy supplied from the outside in order to adjust the temperature to a predetermined temperature.

The control method of the heat pump performance evaluation system according to the present invention is a method for controlling the performance of the heat pump fluid performance evaluation system according to the present invention by adjusting the temperature of the first thermostatic fluid to the required temperature of the first thermostatic chamber 200, Since heat exchange with the fluid or heat exchange with the second constant temperature fluid in the constant temperature fluid heat exchanger 300 is compensated by using the first electric heater as much as the insufficient temperature, The movable energy of the heater) can be reduced and the temperature can be adjusted more precisely.

In order to adjust the temperature of the second thermostatic fluid to the required temperature of the second thermostat 400, the second thermostatic fluid in the thermostatic fluid heat exchanger 300 is thermally exchanged with the first thermostatic fluid, 500 to make the temperature of the second thermostat 400 lower than the required temperature of the second thermostat 400 and the second thermostatic fluid that has passed through the auxiliary heat exchanger 520 to the second electric heater 450 The energy supplied from the outside (the movable energy of the refrigerator and the second electric heater) can be reduced, and the temperature can be adjusted more precisely.

100: Heat pump 130: Second heat exchanger
150: first heat exchanger 200: first thermostat
250: first electric heater 300: constant temperature fluid heat exchanger
400: second thermostat 450: second electric heater
500: refrigerator 520: auxiliary heat exchanger

Claims (6)

A step S110 of operating a heat pump to be a performance evaluation,
The first thermostatic fluid stored in the first thermostat is circulated through the first circulation pipe to heat exchange with the heat pump refrigerant in the first heat exchanger (evaporator) of the heat pump, and the second thermostatic fluid stored in the second thermostatic chamber is circulated through the second circulation (S120) circulating the refrigerant through the piping and performing heat exchange with the heat pump refrigerant in the second heat exchanger (condenser) of the heat pump,
Circulating the first thermostatic fluid of the first thermostat through the first subordinate circulation pipe and circulating the second thermostatic fluid of the second thermostat through the second subordinate circulation pipe and performing heat exchange with each other in the thermostatic fluid heat exchanger )Wow,
(S140) of adjusting a temperature of the first thermostatic fluid of the first sub-circulation pipe passing through the thermostatic fluid heat exchanger to a predetermined temperature of the first thermostatic chamber,
(150) the temperature of the second thermostatic fluid of the second subcirculation line passing through the thermostatic fluid heat exchanger to a desired predetermined temperature of the second thermostatic thermostat,
The step (S140)
Determining (S 141) a flow rate of the first constant temperature fluid flowing through the first auxiliary circulation pipe based on a flow rate of the first constant temperature fluid flowing through the first circulation pipe,
Adjusting the flow rate of the second constant temperature fluid flowing through the second auxiliary circulation pipe to adjust the temperature of the first constant temperature fluid entering the first constant temperature chamber after performing heat exchange with the second constant temperature fluid in the constant temperature fluid heat exchanger (S 142) And controlling the temperature of the heat pump. delete The method according to claim 1,
Wherein the flow rate of the first constant temperature fluid flowing through the first auxiliary circulation pipe is set to be equal to or smaller than the flow rate of the first constant temperature fluid flowing through the first circulation pipe in the step S141. Method of controlling the system. The method according to claim 1,
Wherein the temperature of the first thermostatic fluid flowing into the second thermostatic fluid after heat exchange with the second thermostatic fluid in the thermostatic fluid heat exchanger is lower than the flow rate of the second thermodynamic fluid flowing through the second thermostatic fluid flowing in the second thermostatic fluid at the step (S142) Heating the first thermostatic fluid entering the first thermostat after heat exchange with the second thermostatic fluid in the thermostatic fluid heat exchanger is set to be smaller than a required temperature of the first thermostatic chamber by the first electric heater Wherein the temperature of the heat pump is controlled to a predetermined value. The method according to claim 1,
Wherein the step (150) is for heat-exchanging the second thermostatic fluid entering the second thermostat after heat exchange in the thermostatic fluid heat exchanger with the refrigerant refrigerant in the freezer in the subsidiary heat exchanger. The method of claim 5,
Wherein the capacity of the refrigerator is set such that the temperature of the second thermostatic fluid passed through the auxiliary heat exchanger is lower than the required predetermined temperature of the second thermostatic chamber, And heating the heat pump with an electric heater.

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