CN115167559B - Control method and control system of temperature control system and temperature control system - Google Patents

Abstract

The invention relates to the technical field of semiconductor manufacturing, in particular to a control method and a control system of a temperature control system and the temperature control system, wherein the control method of the temperature control system comprises the following steps: acquiring an instruction for the temperature control system to enter an operation state from a shutdown state; starting the compressor and the circulating device; opening a first valve body connected to a first refrigerant pipe between an outlet of the compressor and an inlet of a heat absorption passage of the evaporator; after the first preset time is continuously operated, the first valve body is closed. The liquid refrigerant can be effectively prevented from migrating into the evaporator and the compressor during shutdown, and the starting state of the temperature control device is improved. Meanwhile, the control logic when the temperature control system is started is optimized, and the risks of overhigh discharge pressure and liquid impact of the compressor are reduced under the condition that a large amount of liquid refrigerant exists on the low-pressure side.

Description

Control method and control system of temperature control system and temperature control system

Technical Field

The present invention relates to the field of semiconductor manufacturing technologies, and in particular, to a control method and system for a temperature control system, and a temperature control system.

Background

In the temperature control device for the semiconductor, the temperature control device for the etching equipment adopts the electronic fluorinated liquid with ultrahigh insulativity as the cooling liquid, and the electronic fluorinated liquid has poor heat conduction performance, so that in the design of the temperature control device for the semiconductor manufacturing, the heat exchange efficiency of the evaporator is improved by increasing the heat exchange area of the evaporator. In addition, in order to ensure continuous high-precision temperature control and rapid temperature control, the temperature control device increases the heat exchange area of the evaporator and simultaneously controls the compressor to continuously operate during the operation of the temperature control device. And the start and stop of the temperature control device are controlled by the wafer processing equipment, and when the wafer processing equipment sends a shutdown instruction to the temperature control device, the circulation system of the temperature control device must stop running immediately. Due to the characteristics of the temperature control device, when the temperature control device is changed from the running state to the shutdown state, firstly, the refrigerating system is changed from the high-load state to the shutdown state, more unevaporated refrigerant is stored in the evaporator, secondly, the circulating liquid capacity in the evaporator is more, and the circulating liquid stops flowing during the shutdown period, so that the inside of the evaporator is in a low-temperature state for a long time, the low-pressure side of the refrigerating system is always in a low-temperature low-pressure state, and the pressure difference is formed before and after the expansion valve. A large amount of liquid refrigerant is transferred from the condenser and the accumulator to the evaporator, the gas component and the compressor, so that when the temperature control device is restarted, a large amount of accumulated refrigerant liquid on the low pressure side can quickly flow into the compressor and enter the compression structure, thereby leading the compressor to compress with liquid. This causes on the one hand compressor slugging and possibly damage to the compression structure and on the other hand flooding of large volumes of liquid, which causes a very rapid rise in the pressure in the discharge line and triggers a high pressure alarm.

At present, a method for preventing refrigerant migration in a stop state is used in the refrigeration field, and one side-by-side electric valve is added between inlet and outlet pipelines of a compressor, the compressor is continuously operated after the temperature reaches a set value, a refrigerant is stored in a condenser, and when the subsequent refrigeration is needed, the compressor stops and an expansion valve is opened to control the temperature, and the refrigerant is released. The other is to collect the temperature of the heat exchange medium of the evaporator and the condenser, judge through certain conditions, adjust the opening degree of the expansion valve and control the migration of the refrigerant. Or a stop device is added between the compressor and the condenser and between the condenser and the throttling device, so that the stop device is closed when the compressor is stopped, and the refrigerant cannot migrate. Or two bypass branches which flow in one direction are arranged in front and behind the throttling device, and the opening or closing of the two branches is controlled according to the running state of the system.

However, the above solution for preventing the refrigerant migration cannot solve the problem that the evaporator is in a low temperature state for a long time, and the refrigerant liquid still enters the evaporator and other low pressure areas in a shutdown state. Meanwhile, part of schemes are required to additionally add hardware on the structure of the existing temperature control device for the semiconductor. In addition, the above methods are mainly applicable to the field of air conditioning and heat pump water heater, and are not completely applicable unlike the temperature control device for semiconductor manufacturing.

Disclosure of Invention

The invention provides a control method, a control system and a temperature control system of a temperature control system, which are used for solving the problem that the temperature in an evaporator of the temperature control system is in a low-temperature state for a long time in the prior art, and the defect that a refrigerant enters the evaporator and other low-pressure areas still exists in a shutdown state, so that the effect that the refrigerant is effectively prevented from migrating into the evaporator and a compressor when the temperature control system is shut down and the state when the temperature control system is started is improved on the premise that the hardware structure of the temperature control system is not increased.

The invention provides a control method of a temperature control system, which comprises the following steps:

acquiring an instruction for the temperature control system to enter an operation state from a shutdown state;

starting the compressor and the circulating device;

opening a first valve body connected to a first refrigerant pipe between an outlet of the compressor and an inlet of a heat absorption passage of the evaporator;

after the first preset time is continuously operated, the first valve body is closed.

The control method of the temperature control system provided by the invention further comprises the following steps:

acquiring an instruction for the temperature control system to enter a shutdown state from an operation state;

determining that the temperature control system does not send alarm information or the alarm information sent by the temperature control system allows the compressor to continue to operate;

closing a second valve body on a second refrigerant pipeline connected between a heat absorption passage of the evaporator and a heat release passage of the condenser, and stopping the operation of the circulating device;

maintaining the running state of the compressor and opening the first valve body;

stopping the operation of the compressor and keeping the first valve body open;

the first valve body is closed.

According to the control method of the temperature control system provided by the invention, after the step of keeping the running state of the compressor and opening the first valve body, the control method further comprises the following steps:

and continuously running for a second preset time or detecting that the temperature of circulating liquid in the evaporator is increased to a preset temperature.

According to the control method of the temperature control system provided by the invention, after the step of stopping the operation of the compressor and keeping the first valve body open, the control method further comprises the following steps:

and continuously running for a third preset time until the pressures at the two ends of the second valve body are balanced.

According to the control method of the temperature control system provided by the invention, after the step of acquiring the shutdown state of the temperature control system from the running state, the control method further comprises the following steps:

determining that the alarm information sent by the temperature control system does not allow the compressor to continue to operate;

closing the second valve body to stop the operation of the circulating device and the compressor;

and opening the first valve body, and keeping the power off or the next starting up of the machine.

The invention also provides a control system, which is controlled by the control method of the temperature control system, comprising the following steps:

the start-stop controller is suitable for acquiring a conversion instruction of the start-stop state of the temperature control system;

the alarm information detector is suitable for judging whether the temperature control system sends out alarm information or not, or the temperature control system sends out alarm information allowing the compressor to continue to operate;

a controller adapted to open a first valve body connected to a first refrigerant line between an outlet of the compressor and an inlet of a heat absorption path of the evaporator; and after the control is continuously operated for a first preset time, closing the first valve body.

The invention also provides a temperature control system, which is controlled by the control method of the temperature control system, and comprises a refrigerating device and a circulating device, wherein the refrigerating device comprises a refrigerating loop formed by sequentially communicating a heat release passage of a condenser, a heat absorption passage of an evaporator and a compressor, a second valve body is arranged on a second refrigerant pipeline communicated with the heat release passage of the condenser and the heat absorption passage of the evaporator, an outlet of the compressor is communicated with an inlet of the heat release passage of the evaporator through a first refrigerant pipeline, and a first valve body and a capillary tube are sequentially arranged on the first refrigerant pipeline along the flowing direction of a refrigerant; the heat release passage of the evaporator is communicated with the circulating device to form a circulating loop of circulating liquid.

According to the control method of the temperature control system, when the temperature control system is switched from a stop state to an operation state, namely, the compressor starts to operate, and the circulating pump of the circulating device is started, the first valve body is opened, the state is operated for a first preset time, and the first valve body is closed after the first preset time is operated. Therefore, in the control mode, in the initial time of starting the temperature control system, the first valve body and the capillary tube are opened to conduct the first refrigerant pipeline to serve as a hot gas bypass branch, so that the condition that a proper amount of high-pressure refrigerant gas discharged from the compressor returns to the evaporator through the first valve body and the capillary tube can be controlled, the high-pressure is reduced, and the pressure overload alarm is reduced.

According to the invention, the first valve body is opened and the capillary tube is communicated with the first refrigerant pipeline in the initial operation stage of the temperature control system, and the capillary tube controls the flow rate passing through the first refrigerant pipeline, so that the pressure is relieved, and the phenomenon that the refrigerating device cannot cool due to the fact that the evaporation temperature is too high can be prevented. According to the invention, on one hand, the first refrigerant pipeline is communicated with the high-pressure pipeline and the low-pressure pipeline, so that the exhaust pressure is prevented from exceeding an alarm value, and on the other hand, part of hot gas is controlled to enter the evaporator, so that the hot gas can exchange heat with circulating liquid in the evaporator, the refrigerant liquid at the low-pressure side is quickly gasified, the liquid impact risk of the compressor is reduced, and the problems of liquid impact or high-pressure alarm of the compressor can not occur even if a large amount of liquid exists at the low-pressure side of the refrigerating device during starting.

When the temperature control system is started, a large amount of liquid refrigerant accumulated in the evaporator and an outlet pipeline thereof during shutdown can be effectively prevented from rushing into the compressor in a short time, and the state of the temperature control device during starting is improved. Meanwhile, the control logic when the temperature control system is started is optimized, and the risks of overhigh discharge pressure and liquid impact of the compressor are reduced under the condition that a large amount of liquid refrigerant exists on the low-pressure side.

In addition to the technical problems, features of the constituent technical solutions and advantages brought by the technical features of the technical solutions described above, other technical features of the present invention and advantages brought by the technical features of the technical solutions will be further described with reference to the accompanying drawings or will be understood through practice of the present invention.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic flow chart of a control method of a temperature control system according to the present invention;

FIG. 2 is a second flow chart of a control method of the temperature control system according to the present invention;

FIG. 3 is a schematic diagram of a temperature control system according to the present invention;

reference numerals:

100. a refrigerating device; 110. a condenser; 120. an evaporator; 130. a compressor; 150. a second valve body; 170. a first valve body; 180. a first refrigerant line; 190. a capillary tube;

200. a circulation device; 210. a water tank; 220. a circulation pump; 230. a load member; 240. a temperature sensor.

Detailed Description

Embodiments of the present invention are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the invention but are not intended to limit the scope of the invention.

In the description of the embodiments of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the embodiments of the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the embodiments of the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In describing embodiments of the present invention, it should be noted that, unless explicitly stated and limited otherwise, the terms "coupled," "coupled," and "connected" should be construed broadly, and may be either a fixed connection, a removable connection, or an integral connection, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in embodiments of the present invention will be understood in detail by those of ordinary skill in the art.

In embodiments of the invention, unless expressly specified and limited otherwise, a first feature "up" or "down" on a second feature may be that the first and second features are in direct contact, or that the first and second features are in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

Furthermore, in the description of the embodiments of the present invention, unless otherwise indicated, the meaning of "a plurality of", "a plurality of" means two or more, and the meaning of "a plurality of", "a plurality of" means one or more ".

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the embodiments of the present invention. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

As shown in fig. 1 and fig. 3, a control method of a temperature control system provided by an embodiment of the present invention includes:

s101, acquiring an instruction of the temperature control system from a shutdown state to an operation state;

s102, starting the compressor 130 and the circulating device 200;

s103, opening a first valve 170 connected to a first refrigerant pipe between an outlet of the compressor 130 and an inlet of a heat absorption passage of the evaporator 120;

s104, after the first preset time is continuously operated, the first valve body 170 is closed.

In the control method of the temperature control system according to the embodiment of the present invention, when the temperature control system enters the operation state from the shutdown state, that is, the compressor 130 starts to operate, and when the circulation pump 220 of the circulation device 200 is started, the first valve body 170 is opened, and the operation in this state continues for a first preset time, and after the operation for the first preset time, the first valve body 170 is closed. Therefore, in the control mode, during the initial time of starting the temperature control system, by opening the first valve 170 and the capillary tube 190 and then conducting the first refrigerant pipeline as a hot gas bypass branch, a proper amount of high-pressure refrigerant gas discharged from the compressor 130 can be controlled to return to the evaporator 120 through the first valve 170 and the capillary tube 190, so that the high-pressure is reduced, and the pressure overload alarm is reduced.

In the invention, the first valve 170 and the capillary tube 190 are opened to conduct the first refrigerant pipeline in the initial operation stage of the temperature control system, and the capillary tube 190 controls the flow rate passing through the first refrigerant pipeline, so that the pressure is relieved and the phenomenon that the refrigerating device 100 cannot be cooled due to the fact that the evaporating temperature is too high can be prevented. According to the invention, on one hand, the first refrigerant pipeline is communicated with the high-pressure pipeline and the low-pressure pipeline, so that the exhaust pressure is prevented from exceeding an alarm value, and on the other hand, part of hot gas is controlled to enter the evaporator 120, so that the hot gas can exchange heat with circulating liquid in the evaporator 120, the refrigerant liquid at the low-pressure side is quickly gasified, the liquid impact risk of the compressor 130 is reduced, and the problem of liquid impact or high-pressure alarm of the compressor 130 is avoided even if a large amount of liquid exists at the low-pressure side of the refrigerating device 100 during starting.

When the temperature control system of the embodiment is started, a large amount of liquid refrigerant accumulated in the evaporator 120 and the outlet pipeline thereof during shutdown can be effectively prevented from rushing into the compressor 130 in a short time, and the state of the temperature control device during startup is improved. At the same time, the control logic at start-up of the temperature control system is optimized, reducing the risk of discharge pressure overshooting and compressor 130 tapping in the presence of a large amount of liquid refrigerant on the low pressure side.

In this embodiment, after the first valve 170 is opened for a first preset time, a proper amount of high-pressure refrigerant gas discharged from the compressor 130 is controlled to return to the evaporator 120 through the first valve 170, so as to reduce the high-pressure, reduce the pressure overload alarm, and then close the first valve 170, i.e. when the temperature control system is in an operation state, the first valve 170 is kept closed. The refrigeration device 100 of the temperature control system enters a normal refrigeration operation mode, and the high-pressure refrigerant discharged from the compressor 130 enters the condenser 110 to be cooled down and then enters the heat absorption path of the evaporator 120.

In this embodiment, the first preset time may be determined by corresponding debugging according to the device configuration of the temperature control system and different set values of the circulating liquid outlet temperature value of the circulating device 200.

As shown in fig. 2, according to an embodiment of the present invention, the control method of the temperature control system of the present invention further includes:

s100, acquiring an instruction of the temperature control system from an operation state to a stop state;

s200, determining that the temperature control system does not send alarm information or the alarm information sent by the temperature control system allows the compressor 130 to continue to operate;

s300, closing a second valve body 150 on a second refrigerant pipeline connected between a heat absorption passage of the evaporator 120 and a heat release passage of the condenser 110, and stopping the operation of the circulation device 200;

s400, maintaining the operation state of the compressor 130, and opening the first valve 170;

s500, stopping the operation of the compressor 130, and keeping the first valve 170 open;

s600, the first valve body 170 is closed.

In this embodiment, when the temperature control system keeps the normal operation state, the temperature control system is controlled to enter the shutdown state from the operation state, so as to control the states of the compressor 130 and the first valve body 170, solve the problem of refrigerant migration during and after the shutdown of the temperature control system, and further improve the state of the temperature control device when the temperature control device is started.

When the temperature control system enters a shutdown state from an operation state, detecting an alarm state of the temperature control system at the same time, and when no alarm information or alarm information is determined to allow the compressor 130 to continue to operate, closing the second valve body 150 of the refrigeration device 100, and stopping the operation of the circulation pump 220 of the circulation device 200; the compressor 130 maintains an operating state, the first valve body 170 is opened, after continuing the operation in this state, the compressor 130 is stopped, and after continuing the operation, the first valve body 170 is closed. Therefore, in the control mode, after the temperature control system is stopped, in the time when both the compressor 130 and the first valve 170 are opened, the high-temperature refrigerant exhaust gas of the compressor 130 continuously enters the heat absorption channel of the evaporator 120 through the first valve 170 to exchange heat with the circulating liquid in the heat release channel, and meanwhile, the circulating liquid in the evaporator 120 does not flow due to the stopping of the circulating pump 220, so that the temperature of the circulating liquid in the evaporator 120 can be quickly raised by the refrigerant hot gas. Then, after the compressor 130 is stopped, the first valve body 170 is still kept in an open state, and the hot gas in the exhaust section continuously enters the low-pressure side evaporator 120, so that the front and rear pressures of the second valve body 150 are balanced. Thus, no significant amount of refrigerant migrates into evaporator 120 during the temperature control system downtime.

Compared with the prior art, the invention can effectively prevent the refrigerant from migrating into the evaporator 120 and the compressor 130 when the temperature control system is stopped, and improve the state when the temperature control system is started. After the temperature control system is determined to receive the shutdown command and enter the shutdown state, the compressor 130 delays shutdown, the first valve body 170 delays closing, the temperature in the evaporator 120 is increased, the front pressure and the rear pressure of the second valve body 150 tend to be balanced, and the high-temperature measured refrigerant is prevented from migrating to the low-temperature side. According to the invention, the start-stop of the compressor 130 and the opening and closing of the first valve body 170 are determined according to the stop state and the alarm information state of the temperature control system, so that the problem of refrigerant migration after the temperature control system stops is solved, and the state of the temperature control system when the temperature control system is started is improved.

According to an embodiment of the present invention, in S400, after the step of maintaining the operation state of the compressor 130 and opening the first valve body 170, the method further includes:

s401, continuously operating for a second preset time, or detecting that the temperature of the circulating fluid in the evaporator 120 is raised to a preset temperature.

In this embodiment, the operation state of the compressor 130 is maintained, the first valve 170 is opened, the operation is continued for a second preset time, so that the high-temperature refrigerant exhaust of the compressor 130 continuously passes through the first valve 170 and enters the heat absorption channel of the evaporator 120 to exchange heat with the circulating liquid in the heat release channel, the temperature of the circulating liquid in the evaporator 120 can be quickly raised by the hot refrigerant gas, or the operation of the compressor 130 is stopped after the temperature of the circulating liquid in the evaporator 120 is raised to the preset temperature, or the operation is continued for the second preset time, so as to maintain the open state of the first valve 170.

The second preset time and the preset temperature may be determined by corresponding debugging according to the device configuration of the temperature control system and different set values of the circulating liquid outlet temperature value of the circulating device 200.

According to an embodiment of the present invention, after stopping the operation of the compressor 130 and maintaining the opening of the first valve body 170 in S500, the method further includes:

s501, the third preset time is continuously operated until the pressures at both ends of the second valve body 150 are balanced.

In this embodiment, the operation of the compressor 130 is stopped, the open state of the first valve body 170 is maintained, and the operation is continued for a third preset time, so that hot gas of high temperature refrigerant can continuously enter the low pressure side evaporator 120, the front and back pressure of the refrigerant pipeline where the second valve body 150 is located is balanced, and a large amount of refrigerant does not migrate into the evaporator 120 in the shutdown time of the temperature control system. After a second preset time of operation, the first valve body 170 is closed.

The third preset time is correspondingly determined by debugging according to the device configuration of the temperature control system and different set values of the circulating liquid outlet temperature value of the circulating device 200.

According to an embodiment of the present invention, after the step of obtaining that the temperature control system enters the shutdown state from the operation state in S100, the method further includes:

s201, determining that alarm information sent by a temperature control system does not allow the compressor 130 to continue to operate;

s202, closing the second valve body 150, and stopping the circulation device 200 and the compressor 130;

s203, the first valve 170 is opened, and the power is cut off or the next power is started until the machine is started.

In this embodiment, when the temperature control system enters a shutdown state from an operation state, it is detected that alarm information exists in the temperature control system, and when the start of the compressor 130 is not allowed in the alarm information, the second valve body 150 is closed, the circulation pump 220 of the circulation device 200 stops running, and the compressor 130 is shut down; the first valve 170 is opened and kept until the machine is powered off or turned on next time. Thus, in the control mode, after the temperature control system is stopped and the compressor 130 is stopped, the second valve body 15 is closed, and the first valve body 170 is kept in an open state, so that the front and rear pressures of the second valve body 150 on the refrigerant pipeline are balanced, and further, during the long-term stopping of the temperature control system, the refrigerant liquid cannot migrate into the low-pressure side evaporator 120 through the first valve body 170. In the arrangement of the temperature control system, the hot gas branch point on the exhaust line is controlled to be higher than the condenser 110, and the amount of accumulation in the evaporator 120 is smaller when the refrigerant migrates through the first refrigerant line, mainly in the form of gas, through the first valve body 170 than in the form of liquid, through the second valve body 150.

In this embodiment, the start-stop of the compressor 130 and the opening and closing of the first valve 170 are determined according to the shutdown state and the alarm information state of the temperature control system, which can effectively prevent the liquid refrigerant from migrating into the evaporator 120 and the compressor 130 during shutdown and improve the state of the temperature control system when the temperature control system is started, compared with the prior art.

The embodiment of the invention also provides a control system, which is controlled by the control method of the temperature control system, comprising a start-stop controller, an alarm information detector and a controller; the start-stop controller is suitable for acquiring a conversion instruction of the start-stop state of the temperature control system; the alarm information detector is adapted to determine whether the temperature control system emits alarm information or whether the temperature control system emits alarm information allowing the compressor 130 to continue to operate; the controller is adapted to open a first valve body 170 on a first refrigerant line 180 connected between an outlet of the compressor 130 and an inlet of a heat absorption passage of the evaporator 120; after the control continues to operate for the first preset time, the first valve body 170 is closed.

In this embodiment, the control system is configured to prevent migration of the refrigerant after the temperature control system is stopped, the start-stop controller detects a state of the temperature control system, the state of the temperature control system may be divided into an operation state and a stop state, the alarm information detector detects an alarm state of the temperature control system, and when alarm information exists, whether the compressor 130 is allowed to operate is determined according to the type of the alarm information, the controller receives signals of the start-stop controller and the alarm information detector, and generates a corresponding control scheme according to the acquired signal processing, so as to perform start-stop control on the compressor 130, the circulation pump 220, the first valve body 170 and the second valve body 150 in the temperature control system.

As shown in fig. 3, the embodiment of the present invention further provides a temperature control system, which is controlled by a control method for preventing refrigerant migration after shutdown in application, and includes a refrigeration device 100 and a circulation device 200, where the refrigeration device 100 includes a refrigeration circuit formed by sequentially communicating a heat release passage of a condenser 110, a heat absorption passage of an evaporator 120, and a compressor 130, a second valve body 150 is disposed on a second refrigerant pipeline in which the heat release passage of the condenser 110 is communicated with the heat absorption passage of the evaporator 120, an outlet of the compressor 130 is communicated with an inlet of the heat release passage of the evaporator 120 through a first refrigerant pipeline 180, and a first valve body 170 and a capillary tube 190 are sequentially disposed on the first refrigerant pipeline 180 along a refrigerant flow direction; the heat release path of the evaporator 120 communicates with the circulation device 200 to form a circulation loop of the circulating fluid.

In this embodiment, the refrigeration apparatus 100 mainly includes a compressor 130, a condenser 110, a valve body 150, an evaporator 120, and a first refrigerant pipeline 180 and a second refrigerant pipeline connected thereto, and the circulation apparatus 200 mainly includes a water tank 210, a circulation pump 220, a heater, a temperature sensor 240, a load member 230, and a circulation liquid pipeline connected thereto. The temperature control system continuously provides a circulating fluid of constant temperature to the load member 230, i.e., controls the temperature at the temperature sensor 240 to be constant. According to the difference between the temperature value of the circulating fluid outlet of the circulating device 200 detected by the temperature sensor 240 and the set value, the opening degree of the second valve body 150 is adjusted by using a PID control algorithm, and the sensitive adjustment of the heat exchange amount in the evaporator 120 is realized by controlling the flow rate of the low-temperature refrigerant fluid of the second valve body 150. The first valve 170 and the capillary tube 190 are sequentially arranged on the first refrigerant pipeline 180, so that the state of the temperature control system when in starting is improved, and the capillary tube 190 controls the flow rate passing through the first refrigerant pipeline 180, so that the pressure can be relieved, and the phenomenon that the refrigerating device 100 cannot be cooled due to the fact that the evaporation temperature is too high is prevented.

In use, the first valve 170 and the second valve 150 may be electronic expansion valves, or shut-off valves, electric valves, solenoid valves, or other types of valves that can be opened or closed.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (6)

1. A control method of a temperature control system is characterized in that: comprising the following steps:

acquiring an instruction for the temperature control system to enter an operation state from a shutdown state;

starting the compressor and the circulating device;

opening a first valve body connected to a first refrigerant pipe between an outlet of the compressor and an inlet of a heat absorption passage of the evaporator;

after continuously running for a first preset time, closing the first valve body;

acquiring an instruction for the temperature control system to enter a shutdown state from an operation state;

determining that the temperature control system does not send alarm information or the alarm information sent by the temperature control system allows the compressor to continue to operate;

closing a second valve body on a second refrigerant pipeline connected between a heat absorption passage of the evaporator and a heat release passage of the condenser, and stopping the operation of the circulating device;

maintaining the running state of the compressor and opening the first valve body;

stopping the operation of the compressor and keeping the first valve body open;

the first valve body is closed.

2. The control method of a temperature control system according to claim 1, characterized in that: after the step of maintaining the operation state of the compressor and opening the first valve body, the method further comprises the steps of:

and continuously running for a second preset time or detecting that the temperature of circulating liquid in the evaporator is increased to a preset temperature.

3. The control method of a temperature control system according to claim 2, characterized in that: after the step of stopping the operation of the compressor and keeping the first valve body open, the method further comprises:

and continuously running for a third preset time until the pressures at the two ends of the second valve body are balanced.

4. The control method of a temperature control system according to claim 1, characterized in that: after the step of obtaining the temperature control system to enter the shutdown state from the operation state, the method further comprises the following steps:

determining that the alarm information sent by the temperature control system does not allow the compressor to continue to operate;

closing the second valve body to stop the operation of the circulating device and the compressor;

and opening the first valve body, and keeping the power off or the next starting up of the machine.

5. A control system, characterized by: control method for controlling a temperature control system according to any one of claims 1 to 4, comprising:

the start-stop controller is suitable for acquiring a conversion instruction of the start-stop state of the temperature control system;

the alarm information detector is suitable for judging whether the temperature control system sends out alarm information or not, or the temperature control system sends out alarm information allowing the compressor to continue to operate;

a controller adapted to open a first valve body connected to a first refrigerant line between an outlet of the compressor and an inlet of a heat absorption path of the evaporator; and after the control is continuously operated for a first preset time, closing the first valve body.

6. A temperature control system, characterized in that the control method of the temperature control system according to any one of claims 1 to 4 is used for control, and the temperature control system comprises a refrigerating device and a circulating device, wherein the refrigerating device comprises a heat release passage of a condenser, a heat absorption passage of an evaporator and a refrigerating circuit formed by sequentially communicating a compressor, a second valve body is arranged on a second refrigerant pipeline communicated with the heat release passage of the condenser and the heat absorption passage of the evaporator, an outlet of the compressor is communicated with an inlet of the heat release passage of the evaporator through the first refrigerant pipeline, and a first valve body and a capillary tube are sequentially arranged on the first refrigerant pipeline along the flowing direction of a refrigerant; the heat release passage of the evaporator is communicated with the circulating device to form a circulating loop of circulating liquid.