JP2002013781A - Air-conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To stably operate a system without any need for cooling a refrigerant in advance when an operation is started. SOLUTION: This air-conditioning system is provided with a cooling source 1, a liquid refrigerant pump 2, an indoor air conditioner 5, a compressor 3, and a control valve 4 by bypassing the compressor 3. Also, at piping near the suction opening of the liquid refrigerant pump 2, a temperature detector 7 for detecting the temperature of the liquid refrigerant and a pressure detector 8 for detecting the pressure of the liquid refrigerant are provided. Further, a control device 6 is provided, which calculates the degree of supercooling of the liquid refrigerant based on a detection signal from the temperature detector 7 and the pressure detector 8. Then, at the start of operation, the control device 6 first drives the compressor 3, and drives the liquid refrigerant pump after the degree of supercooling reaches the stable operation level of the liquid refrigerant pump.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an air conditioning system, and more particularly to an air conditioning system in which ice or the like is stored in a cooling source and a cooling operation is performed using the cooling source.

[0002]

2. Description of the Related Art As an air conditioning system using a cooling source, for example, ice is stored in a cooling source with low-cost nighttime electric power.
A typical example is an ice storage type air conditioning system that cools a room using the cold heat during the day. In such an air conditioning system, a cooling source that stores ice, an indoor air conditioner that cools indoor air with a refrigerant cooled by the cooling source, and a refrigerant that constantly circulates in a liquid state between the cooling source and the indoor air conditioner And a liquid refrigerant pump to be operated. The method of circulating the refrigerant in the liquid state is more efficient than the method of circulating the refrigerant in the gas state by the compressor, because there is no need to compress the gas.

[0003]

By the way, when the air conditioning system is stopped, the refrigerant is usually heated by the outside temperature and is in a gaseous state. Even if the operation is started in such a state, the liquid refrigerant pump cannot suck the refrigerant because the refrigerant is in a gaseous state inside the liquid refrigerant pump and also in the pipe near the liquid refrigerant pump suction port. . In order to avoid this, it is necessary to cool the liquid refrigerant pump and the piping near the liquid refrigerant pump suction port in advance, and liquefy the refrigerant to make it a liquid refrigerant.

[0004] Further, during the circulation of the refrigerant by the liquid refrigerant pump, depending on the state of the refrigerant, not only the predetermined ability cannot be obtained due to the occurrence of cavitation and the like, but also the liquid refrigerant pump itself may be damaged.

Japanese Patent Application Laid-Open No. 11-62844 proposes operating an air conditioner by detecting the occurrence of foaming in a liquid refrigerant and reducing the discharge flow rate of a liquid refrigerant pump. However, in this case, foaming has already occurred in the liquid refrigerant, and this foaming causes cavitation and the like.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an air conditioning system which does not need to cool the refrigerant before starting the operation, and can suppress the occurrence of foaming in the liquid refrigerant during the operation.

[0007]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a cooling source for cooling a refrigerant, a liquid refrigerant pump for pumping a liquid refrigerant cooled by the cooling source, and a liquid refrigerant pump. An indoor heat exchanger that cools the indoor air with the liquid refrigerant from the compressor, a compressor that pressurizes the refrigerant after the indoor air cooling from the indoor heat exchanger and returns the refrigerant to a cooling source, and a compressor that bypasses the compressor. A control valve for controlling the refrigerant flowing to the compressor;
At the start of the cooling operation, control means is provided for causing the refrigerant to circulate by the compressor first, and thereafter shifting to refrigerant circulation by the liquid refrigerant pump.

[0008] According to the above configuration, since the refrigerant is circulated by the compressor at the start of the cooling operation, the degree of supercooling of the refrigerant near the suction port of the liquid refrigerant pump increases, and the refrigerant in the gaseous state becomes the liquid refrigerant. can do. Then, after the degree of supercooling becomes sufficiently large to allow the liquid refrigerant pump to operate stably, the liquid refrigerant pump is started to cause the liquid refrigerant pump to circulate the refrigerant.

After shifting to the refrigerant circulation by the liquid refrigerant pump,
Stop the compressor and open the control valve. With this configuration, the refrigerant circulates through the control valve, and a normal air-conditioning operation using the cooling source can be performed.

If a detecting means for detecting at least one of the temperature and the pressure of the liquid refrigerant near the suction port of the liquid refrigerant pump is provided, a supercooled state of the liquid refrigerant is obtained based on a detection signal from the detecting means. According to the result, the driving of the compressor and the liquid refrigerant pump can be controlled.

If a detection means for detecting the outside air temperature is provided, a switching time from the refrigerant circulation by the compressor to the refrigerant circulation by the liquid refrigerant pump is obtained based on the detection signal from the detection means. Can be transferred to the refrigerant circulation by the liquid refrigerant pump based on the above.

Further, the present invention provides a cooling source for cooling a liquid refrigerant, a liquid refrigerant pump for pumping the liquid refrigerant cooled by the cooling source, and an indoor room for cooling indoor air with the liquid refrigerant from the liquid refrigerant pump. A heat exchanger, a compressor that pressurizes the refrigerant after the indoor air cooling from the indoor heat exchanger and returns the refrigerant to a cooling source, and a control valve that is provided to bypass the compressor and controls the refrigerant flowing to the compressor. Detecting means for detecting at least one of the temperature and the pressure of the liquid refrigerant near the liquid refrigerant pump suction port, and after the cooling operation starts, during normal cooling operation in which the compressor is stopped and the refrigerant circulates through the control valve. Based on the detection signal from the detecting means, it is determined whether the liquid refrigerant in the vicinity of the liquid refrigerant pump suction port is in a sufficiently supercooled state. Reduce the liquid refrigerant pressure near the refrigerant pump suction port. Control for raising, and among the control for reducing the rotational speed of the liquid refrigerant pump, it is characterized in that a control means for performing at least one control.

According to the above configuration, during normal cooling operation,
Determines whether the liquid refrigerant near the liquid refrigerant pump suction port is in a sufficiently supercooled state, and if not, drives the compressor to increase the liquid refrigerant pressure near the liquid refrigerant pump suction port. Or reduce the rotation speed of the liquid refrigerant pump. This makes it possible to suppress the foaming by setting the liquid refrigerant in a supercooled state, and to stabilize the operation of the liquid refrigerant pump. Note that both the driving of the compressor and the reduction of the rotation speed of the liquid refrigerant pump may be performed simultaneously.

Further, even if the rotational speed of the liquid refrigerant pump is reduced to a predetermined value, if a supercooled state sufficient for stable operation of the liquid refrigerant pump cannot be obtained, the liquid refrigerant pump is stopped and the compressor is driven. . Thereby, normal air conditioner operation can be performed.

[0015]

Embodiments of the present invention will be described below with reference to the drawings. Embodiment 1 FIG. 1 shows a configuration of an air conditioning system according to Embodiment 1 of the present invention. This air conditioning system
A cooling source 1, a liquid refrigerant pump 2, an indoor air conditioner (indoor heat exchanger) 5, and a compressor 3 are sequentially connected to form a refrigerant circulation flow path. The control valve 4 bypasses the compressor 3.
Is provided. The cooling source 1 stores ice generated by a refrigeration cycle (not shown).

A pipe near the suction port of the liquid refrigerant pump 2 is provided with a temperature detector 7 for detecting the temperature of the liquid refrigerant inside the pipe and a pressure detector 8 for detecting the pressure of the liquid refrigerant. Further, a control device 6 is provided, and the liquid refrigerant pump 2, the compressor 3, the control valve 4, the temperature detector 7, and the pressure detector 8 are electrically connected to the control device 6. Note that the indoor air conditioner 5 may be an indirect heat exchanger having a load ahead of it. Further, a temperature detector 7 and a pressure detector 8 may be provided in the liquid refrigerant pump 2 to detect the temperature and the pressure of the liquid refrigerant in the liquid refrigerant pump 2.

Next, in the air conditioning system having the above configuration,
When the cooling operation using the cooling source 1 is started, even if the liquid refrigerant pump 2 is to be driven suddenly, since the bubbles are generated in the refrigerant in the pipe at the time of the previous stop, the liquid refrigerant pump 2 The refrigerant cannot be sucked. Therefore, in the present embodiment, first, the compressor 3 is driven. This operation procedure will be described with reference to FIG.

The temperature detector 7 and the pressure detector 8 detect the temperature and pressure of the liquid refrigerant near the suction port of the liquid refrigerant pump 2, respectively, and the detection signals are input to the control device 6. Then, the control device 6 calculates the saturation temperature from the measured pressure value detected by the pressure detector 8 (Step S10). The relationship between the pressure and the saturation temperature is known for each type of refrigerant as shown in FIG. 11, for example, and the relationship is stored in the control device 6 as a database. Next, the control device 6 starts the compressor 3 (step S11). When the compressor 3 starts, the refrigerant pressure near the suction port of the liquid refrigerant pump 2 changes and the refrigerant temperature also changes. The refrigerant temperature is detected by the temperature detector 7, and the data of the refrigerant temperature that changes every moment when the compressor 3 is started is input to the control device 6,
Calculates the degree of supercooling by subtracting the refrigerant temperature from the saturation temperature calculated in step S10. Since the refrigerant temperature changes every moment, the degree of supercooling also changes every moment, and it is determined whether the degree of supercooling has become positive (step S1).
2). If the degree of supercooling is negative, the liquid refrigerant pump 2 cannot be started because foaming has occurred in the refrigerant, but if the degree of supercooling is positive, no foaming has occurred in the refrigerant, and The refrigerant pump 2 can be started.

When it is determined in step S12 that the degree of supercooling has become positive, the liquid refrigerant pump 2 is started (step S13). When the liquid refrigerant pump 2 is started, the refrigerant flows in the order of the indoor air conditioner 5, the compressor 3, the cooling source 1, and the liquid refrigerant pump 2. At this time, the refrigerant is cooled by the cooling source 1, so that the degree of subcooling is further increased. Changes to Then, it is determined whether or not the degree of supercooling has become larger than a predetermined value (step S14). This predetermined value is determined by the liquid refrigerant pump 2
Is a value sufficient for stable operation and is set in the control device 6 in advance.

When it is determined in step S14 that the degree of supercooling has become larger than the predetermined value, the control valve 4 is opened and the compressor 3 is stopped (step S1).
5). Thereby, the refrigerant flows through the control valve 4, and the cooling operation using the cooling source 1 can be continued.

In the air conditioning system having the above configuration,
If the liquid refrigerant pump 2 does not operate normally for some reason, the operation of the compressor 3 can be quickly switched. The operation procedure is shown in FIG. In FIG. 3, step S
Steps S1 to S15 are the same as those in FIG.
6 to S18 are added.

Whether the liquid refrigerant pump 2 is operating normally is determined by whether the degree of supercooling has become smaller than a predetermined value (step S16). This predetermined value is determined in step S1.
4 is the same as the predetermined value. When it is determined that the degree of supercooling has become smaller than the predetermined value, the control device 6
Stops the liquid refrigerant pump 2 and closes the control valve 4 (step S17), and determines whether or not the cooling operation using the cooling source 1 is possible (step S18).
If the cooling operation using the cooling source 1 is possible, the process returns to step S11 and the compressor 3 is restarted.
When the cooling operation using the air conditioner cannot be performed, the operation shifts to a normal air conditioner operation without using the cooling source 1. In the case of normal air conditioner operation, the compressor 1 is driven to operate the cooling source 1 as a condenser and the indoor air conditioner 5 as an evaporator.

As described above, when the liquid refrigerant pump 2 does not operate normally, the liquid refrigerant pump 2 is immediately stopped, thereby avoiding the occurrence of cavitation and increasing the life and reliability of the liquid refrigerant pump 2. it can.

(Embodiment 2) In the air-conditioning system shown in FIG. 1, when the cooling operation using the cooling source 1 is performed, the temperature detector 7 and the pressure detector 8 The temperature and the pressure of the liquid refrigerant in the pipe are detected, and the detected data is input to the control device 6. In the present embodiment, the control device 6 calculates the degree of supercooling of the liquid refrigerant from the detection data, and if the degree of supercooling is not sufficient for the stable operation of the liquid refrigerant pump 2, the compressor 3 is driven auxiliary. Like that. The operation procedure is shown in FIG.

During the cooling operation using the cooling source 1, the controller 6 determines whether the degree of supercooling has become smaller than a predetermined value (step S20). This predetermined value is the same as the predetermined value in step S14 in FIG. When the degree of supercooling becomes smaller than the predetermined value, the compressor 3 is started (Step S21). When the compressor 3 is started, the pressure of the liquid refrigerant at the suction port of the liquid refrigerant pump 2 increases, so that the degree of supercooling increases, and the compressor 3 is driven until the degree of supercooling becomes larger than a predetermined value. (Step S22). Then, when the degree of supercooling becomes larger than the predetermined value, the compressor 3 is stopped (step S2).
3).

According to the present embodiment, since the compressor 3 is used as a backup for the liquid refrigerant pump 2, it is economical without consuming a large amount of power.

(Embodiment 3) In this embodiment, FIG.
In the air conditioning system shown in (1), when the degree of supercooling is not sufficient for stable operation of the liquid refrigerant pump 2, the rotation speed of the liquid refrigerant pump 2 is reduced instead of driving the compressor 3. The operation procedure is shown in FIG.

During the cooling operation using the cooling source 1, the controller 6 determines whether the degree of supercooling has become smaller than a predetermined value (step S30). This predetermined value is the same as the predetermined value in step S14 in FIG. Then, when the degree of subcooling becomes smaller than the predetermined value, the rotation speed of the liquid refrigerant pump 2 is reduced (step S31).

Next, it is determined whether or not the reduced rotation speed of the liquid refrigerant pump 2 is higher than the lower limit of reliability (step S32). If it is higher, the degree of supercooling is larger than a predetermined value. It is determined whether or not it has become (step S33).
This predetermined value is also the same as the predetermined value in step S14 in FIG. If the degree of supercooling does not increase, the process returns to step S31 to further reduce the rotation speed of the liquid refrigerant pump 2. If the rotation speed of the liquid refrigerant pump 2 is decreased, the rotation speed may be reduced to a rotation speed lower than the lower limit of reliability. If the rotation speed is excessively reduced, the liquid refrigerant pump 2 is stopped. Then (step S36), the operation shifts to normal air conditioner operation.

If it is determined in step S33 that the degree of supercooling has become larger than the predetermined value, the rotational speed of the liquid refrigerant pump 2 is increased (step S34). When the number of rotations of the liquid refrigerant pump 2 is increased, the degree of supercooling decreases. However, it is determined in step S35 whether the degree of supercooling has become too small below a predetermined value. Is maintained within a range in which is maintained stably.

This embodiment can be used in combination with the second embodiment. For example, if the number of rotations of the liquid refrigerant pump 2 is reduced, the amount of the circulating refrigerant for the air conditioning load may be insufficient. At this time, if the compressor 3 is driven in an auxiliary manner, a sufficient amount of the circulating refrigerant can be secured. it can. Furthermore, when used together, the backup amount of the compressor 3 with respect to the liquid refrigerant pump 2 is smaller than in the case of the second embodiment, so that the power consumption for the backup can be further reduced.

(Embodiment 4) FIG. 6 shows the configuration of an air conditioning system according to Embodiment 4 of the present invention. In the present embodiment, an ambient temperature detector 9 for detecting the ambient temperature (outside air temperature) of the air conditioning system is provided, and the temperature of the liquid refrigerant pump 2 determined from the detected ambient temperature and the refrigerant pipe length given in advance. Switching from the compressor 3 to the liquid refrigerant pump 2 is controlled depending on the time until the stable operation condition is reached.

The refrigerant piping used in the air conditioning system is determined at the time of design, and its specifications are standardized. Also,
Since the heat insulation treatment of the pipes and the like are determined in the construction document, there is no significant difference in these physical property values for each construction. And the compressor 3
The flow rate of the refrigerant carried by the cooling source 1 and the heat amount / temperature range given to the refrigerant from the cooling source 1, that is, the degree of supercooling (= saturation temperature−refrigerant temperature) of the outlet refrigerant of the cooling source 1 is known as a design point. Therefore, what is unknown as an installation site-specific condition is
It can be mainly concentrated only on the refrigerant pipe length and the ambient temperature.

The type of refrigerant used in the air conditioning system is specific to the system, and the physical properties are known. For example, the specific weight γ [Kg / m ³ ] can determine its state value from temperature.

When the operation is stopped, the refrigerant temperature in the pipe is the ambient temperature t.
_近似 Approximately [° C] and is in a saturated state. When the refrigerant pipe length L [m] from the refrigerant source to the liquid refrigerant pump is given when using the refrigerant pipe having the inner diameter d [m], the refrigerant amount g inside the pipe at the time of stop is given.
₁ [Kg] is the specific weight γ _∞ [Kg / m at the ambient temperature _t∞ [° C].
^3] _{will, g 1 = γ ∞ × (} πd 2/4) is a × L.

On the other hand, the lowest value obtained as the refrigerant temperature in this section is the temperature at the outlet of the cooling source, which is known as described above. The temperature at this time is t
_{When it is set to max} [° C.], a specific weight γ _max [Kg / m ³ ] is obtained. By using the maximum value γ _max [Kg / m ³ ] as the specific weight, it is possible to calculate the maximum refrigerant amount g ₂ [Kg] when the inside of the refrigerant pipe having the length of L [m] is filled with the liquid refrigerant. . _{g 2 = γ max × (πd} 2/4) × L

The amount of refrigerant g that filled the pipe in the initial state
₁ and maximum refrigerant amount g ₂ which can satisfy is the L [m] each time discharged from the length of the refrigerant in the pipe T _{1 [sec],} T ₂
[sec] is obtained as T ₁ = g ₁ / G T ₂ = g ₂ / G from the flow rate G [Kg / s] of the refrigerant conveyed by the compressor. The sum of T ₁ [sec] and T ₂ [sec] is
It can be used as an index of the operation of the liquid refrigerant pump as an approximation of the time required for the liquid refrigerant that has exited the cooling source to reach the liquid refrigerant pump. Actually, the temperature of the refrigerant rises due to the invading heat, and the saturation temperature decreases due to the pressure loss due to the friction in the piping. Thus, it can be estimated more practically. Of course, a more stable operation can be performed by allowing a sufficient margin for the switching time.

The above operation procedure is shown in FIG. In FIG. 7, the control device 6 calculates a starting time and a switching time from the ambient temperature detected by the ambient temperature detector 9 (step S4).
0). The relationship between the ambient temperature and the start time and the relationship between the ambient temperature and the switching time are known for each type of refrigerant, and the relationship is stored in the control device 6 as a database. Here, the starting time is a time until the degree of supercooling becomes zero.

Next, the control device 6 starts the compressor 3 (step S41), and determines whether or not the operation time from the start of the compressor 3 exceeds the start time calculated in step S40 (step S42). ). If the operation time exceeds the start time, the liquid refrigerant pump 2 is started because no foaming has occurred in the refrigerant (step S43).

The liquid refrigerant pump 2 is started, and it is determined whether or not the operation time has exceeded the switching time calculated in step S40 (step S44). If the operation time exceeds the switching time, it is in a state sufficient to stably operate the liquid refrigerant pump 2, so that the control valve 4 is opened and the compressor 3 is stopped (step S45). .

When an existing signal for controlling an outdoor unit is used as the ambient temperature, the installation of the ambient temperature detector 9 can be omitted, and the maximum ambient temperature and the pressure loss ( If the maximum refrigerant pipe length capable of obtaining a predetermined degree of subcooling is assumed and the time required for stable operation is determined in advance in consideration of the decrease in the saturation temperature) and the temperature increase, the control device 6 Does not need to have a function of determining the ambient temperature or calculating the time required for stable operation, and can be replaced with a simple timer function.

According to the present embodiment, there is no need for a means for detecting the temperature and pressure of the refrigerant near the suction port of the liquid refrigerant pump 2.
Since only the ambient temperature detector 9 needs to be installed, the configuration of the air conditioning system becomes very simple.

(Embodiment 5) FIG. 8 shows the configuration of an air conditioning system according to Embodiment 5 of the present invention. In the present embodiment, a heat exchanger 10 is provided in series with the compressor 3. Other configurations are the same as those in FIG.

With this configuration, the high-temperature refrigerant discharged from the compressor 3 is not sent directly to the cooling source 1 but is cooled in advance through the heat exchanger 10 and then to the cooling source 1. Can be sent. The medium that exchanges heat with the heat exchanger 10 may be of any type, for example, outside air or river water, as long as the temperature is lower than the temperature of the refrigerant discharged from the compressor 3. The operation procedure is the same as in FIGS.

According to the present embodiment, the load on the cooling source 1 can be reduced. The configuration in which the heat exchanger 10 is installed as in the present embodiment can be applied to other embodiments of the present invention.

(Embodiment 6) FIG. 9 shows the configuration of an air conditioning system according to Embodiment 6 of the present invention. In the present embodiment, a cooling source 1 'is provided in the circulation channel of the refrigerant,
This cooling source 1 ′ is indirectly cooled by the main refrigerant source 1. Other configurations are the same as those in FIG.

With this configuration, if a large-capacity cooling source 1 is installed, the cooling operation can be continuously performed for a long time. The configuration in which the cooling source 1 'and the main refrigerant source 1 are installed as in the present embodiment can be applied to other embodiments of the present invention.

(Embodiment 7) FIG. 10 shows the configuration of an air conditioning system according to Embodiment 7 of the present invention. In the present embodiment, the control valve 4 ′ bypasses the liquid refrigerant pump 2.
The opening and closing of the control valve 4 ′ is controlled by the control device 6. Other configurations are the same as those in FIG.

In the above configuration, when the compressor 3 is started at the start of the cooling operation using the cooling source 1, the liquid refrigerant circulates through the control valve 4 '. And the liquid refrigerant pump 2
When it is determined that the operating condition has been reached, the control valve 4 'is closed and the liquid refrigerant pump 2 is operated. further,
When the state is stabilized, the control valve 4 is opened and the compressor 3 is stopped to switch the power.

According to the present embodiment, the liquid refrigerant pump 2 can be bypassed when the refrigerant is circulated by the compressor 3 when a liquid refrigerant pump 2 that does not easily run idle is employed. The configuration provided with the control valve 4 'as in the present embodiment can be applied to other embodiments of the present invention.

[0051]

As described above, according to the present invention,
The air conditioning system can be started easily and reliably without cooling the piping near the liquid refrigerant pump suction port at the start of operation.

Further, it is possible to suppress the occurrence of bubbling in the liquid refrigerant during the normal operation, and to stabilize the operation of the air conditioning system.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an air conditioning system according to a first embodiment of the present invention.

FIG. 2 is a flowchart at the time of starting a cooling operation of the air conditioning system.

FIG. 3 is a flowchart of a normal cooling operation after the start of operation.

FIG. 4 is a flowchart showing the second embodiment of the present invention, in a case where the compressor is driven auxiliary during a normal cooling operation.

FIG. 5 shows the third embodiment of the present invention and is a flowchart in a case where the rotation speed of the liquid refrigerant pump is changed during a normal cooling operation.

FIG. 6 is a configuration diagram of an air conditioning system according to Embodiment 4 of the present invention.

FIG. 7 is a flowchart when the cooling operation of the air conditioning system shown in FIG. 6 is started.

FIG. 8 is a configuration diagram of an air conditioning system according to Embodiment 5 of the present invention.

FIG. 9 is a configuration diagram of an air conditioning system according to Embodiment 6 of the present invention.

FIG. 10 is a configuration diagram of an air conditioning system according to Embodiment 7 of the present invention.

FIG. 11 is a diagram showing a relationship between a saturation temperature and a saturation pressure.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1, 1 'Cooling source 2 Liquid refrigerant pump 3 Compressor 4, 4' Control valve 5 Indoor air conditioner 6 Control device 7 Temperature detector 8 Pressure detector 9 Ambient temperature detector 10 Heat exchanger

Continued on the front page (72) Inventor Mikio Suzuki 508-8 Juyoni, Kashiwa-shi, Chiba Pref. Inside the Ritsumeikan Air-Conditioning System Environmental Technology Research Center Co., Ltd. Inside Hitachi Machinery Research Laboratory (72) Inventor Kenji Hirako 502 Kandamachi, Tsuchiura City, Ibaraki Prefecture Inside Machinery Research Laboratories Co., Ltd. F-term in the mechanical laboratory (reference) 3L060 AA01 CC05 CC08 CC16 CC16 EE33 EE34 EE41

Claims (6)

[Claims] A cooling source for cooling the refrigerant, a liquid refrigerant pump for pumping the liquid refrigerant cooled by the cooling source, an indoor heat exchanger for cooling indoor air with the liquid refrigerant from the liquid refrigerant pump, A compressor that pressurizes the refrigerant after the indoor air cooling from the indoor heat exchanger and returns the refrigerant to the cooling source, a control valve that is provided to bypass the compressor and controls the refrigerant flowing to the compressor, and starts a cooling operation. An air conditioning system, comprising: a control unit for causing the compressor to circulate the refrigerant first, and then shifting to a refrigerant circulation by the liquid refrigerant pump. 2. The air conditioning system according to claim 1, wherein the control unit controls the liquid refrigerant by stopping the compressor and opening the control valve after shifting to refrigerant circulation by the liquid refrigerant pump. An air conditioning system characterized by circulating through a valve. 3. The air conditioning system according to claim 1, further comprising detection means for detecting at least one of a temperature and a pressure of the liquid refrigerant near the liquid refrigerant pump suction port, and wherein the control means detects the temperature and pressure of the liquid refrigerant from the detection means. An air conditioning system characterized in that a supercooled state of a liquid refrigerant is obtained based on the detection signal of the above, and the driving of the compressor and the liquid refrigerant pump is controlled based on the result. 4. The air conditioning system according to claim 1, further comprising: a detecting unit for detecting an outside air temperature, wherein the control unit detects the outside air temperature from the refrigerant circulation by the compressor based on a detection signal from the detecting unit. An air conditioning system characterized in that a switching time to a refrigerant circulation by a liquid refrigerant pump is calculated, and a transition to a refrigerant circulation by the liquid refrigerant pump is performed based on the calculation result. 5. A cooling source for cooling the refrigerant, a liquid refrigerant pump for pumping the liquid refrigerant cooled by the cooling source, an indoor heat exchanger for cooling indoor air with the liquid refrigerant from the liquid refrigerant pump, A compressor that pressurizes the refrigerant after the indoor air cooling from the indoor heat exchanger and returns the refrigerant to the cooling source; a control valve that is provided to bypass the compressor and controls a refrigerant flowing to the compressor; Detecting means for detecting at least one of the temperature and the pressure of the liquid refrigerant near the pump suction port, and after the start of the cooling operation, during a normal cooling operation in which the compressor is stopped and the refrigerant circulates through the control valve, Based on the detection signal from the detection means, it is determined whether the liquid refrigerant near the liquid refrigerant pump suction port is in a sufficiently supercooled state, and if not in a supercooled state, the compressor is driven. Near the liquid refrigerant pump suction port An air conditioning system comprising: control means for executing at least one of a control for increasing a liquid refrigerant pressure and a control for decreasing a rotation speed of the liquid refrigerant pump. 6. The air conditioning system according to claim 5, wherein the control means sets a supercooled state sufficient for stable operation of the liquid refrigerant pump even if the rotation speed of the liquid refrigerant pump is reduced to a predetermined value. When the air conditioner cannot be obtained, the liquid refrigerant pump is stopped and the compressor is driven to perform a normal air conditioner operation.