CN220524251U - Air conditioner and temperature regulating system thereof - Google Patents

Air conditioner and temperature regulating system thereof Download PDF

Info

Publication number
CN220524251U
CN220524251U CN202321575155.9U CN202321575155U CN220524251U CN 220524251 U CN220524251 U CN 220524251U CN 202321575155 U CN202321575155 U CN 202321575155U CN 220524251 U CN220524251 U CN 220524251U
Authority
CN
China
Prior art keywords
outlet
heat exchanger
temperature
bypass branch
valve
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN202321575155.9U
Other languages
Chinese (zh)
Inventor
宋斌
刘翔
吴刚
杨斌
梁健泮
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Shenzhen Envicool Technology Co Ltd
Original Assignee
Shenzhen Envicool Technology Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Shenzhen Envicool Technology Co Ltd filed Critical Shenzhen Envicool Technology Co Ltd
Priority to CN202321575155.9U priority Critical patent/CN220524251U/en
Application granted granted Critical
Publication of CN220524251U publication Critical patent/CN220524251U/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Landscapes

  • Other Air-Conditioning Systems (AREA)

Abstract

The utility model discloses an air conditioner and a temperature regulating system thereof, wherein the temperature regulating system comprises a circulation loop, a first heat exchanger and a second heat exchanger which are connected in the circulation loop, and further comprises: a first bypass branch, a second bypass branch, a third bypass branch, a first valve, a second valve, and a third valve; the second heat exchanger, the inlet of the second bypass branch, the outlet of the first bypass branch, the outlet of the second bypass branch and the outlet of the third bypass branch are sequentially arranged in sequence. The temperature-regulating refrigeration system provided by the utility model adopts a bidirectional energy-saving temperature compensation and multistage temperature control mode to ensure the requirements on temperature precision and stability, and can realize rapid temperature regulation, thereby being beneficial to energy saving.

Description

Air conditioner and temperature regulating system thereof
Technical Field
The utility model relates to the field of air conditioning equipment, in particular to a temperature regulating system. In addition, the utility model also relates to an air conditioner comprising the temperature regulating system.
Background
Referring to fig. 1, a first outlet of a first heat exchanger 01 is connected with a first inlet of a second heat exchanger 02, a first outlet of the second heat exchanger 02 is connected with the first inlet of the first heat exchanger 01 through a heater 03 and a thermal buffer 04 in sequence, the first heat exchanger 01 is a terminal heat exchanger, after exchanging heat with the external environment or equipment, the medium temperature in the terminal heat exchanger is increased, the medium with high temperature flows back to the second heat exchanger 02, is re-cooled in the second heat exchanger 02, and flows into the first heat exchanger 01 again to cool the external environment or equipment through the functions of the heater 03 and the thermal buffer 04.
In the field of high-precision temperature control air conditioner cooling, in order to achieve accurate temperature adjustment, the medium temperature is generally reduced to a temperature slightly lower than a target temperature value through a heat exchanger, then the medium temperature is slowly heated through electric heating to achieve high-precision temperature adjustment, namely when the temperature is reduced to a required temperature close to a critical temperature, an electric heater is electrified to generate heat to conduct micro heat conduction, and accordingly the standard reaching of the temperature and small fluctuation are achieved rapidly.
However, the prior art uses electric heating for temperature adjustment, which has the following disadvantages: firstly, the electric heater is adopted as a power consumption device, so that the loss of the whole system is increased, and the energy saving is not facilitated by a simple electric heating mode along with the increasing requirement on energy efficiency in the future, so that the energy consumption is not facilitated to be reduced; secondly, when the temperature of the system is higher than the target temperature value in an electric heating mode, callback cannot be realized at the moment, and only part of heat can be bypassed or transmitted to a load end, so that the load temperature fluctuates; thirdly, if the load of the system is increased rapidly, the unidirectional compensation mode is not easy to realize rapidly, the subsequent system circulation is needed, the system can be realized after the evaporation end entering the heat exchanger obtains low temperature, and the response speed is slow.
Therefore, how to quickly implement temperature compensation is a technical problem that needs to be solved by those skilled in the art.
Disclosure of Invention
The utility model aims to provide a temperature regulating system capable of rapidly realizing temperature supplementation. Another object of the present utility model is to provide an air conditioner comprising the above temperature-regulating refrigeration system.
In order to achieve the above purpose, the present utility model provides the following technical solutions:
a temperature regulating system comprising a circulation loop and a first heat exchanger and a second heat exchanger connected in the circulation loop, further comprising:
the inlet of the first bypass branch is connected with the first inlet of the second heat exchanger, and the outlet of the first bypass branch is connected with the first outlet of the second heat exchanger;
the inlet of the second bypass branch is connected with the first outlet of the second heat exchanger, and the outlet of the second bypass branch is connected with the first inlet of the first heat exchanger;
the inlet of the third bypass branch is communicated with the inlet of the first bypass branch, and the outlet of the third bypass branch is connected with the outlet of the second bypass branch;
the second heat exchanger, the inlet of the second bypass branch, the outlet of the first bypass branch, the outlet of the second bypass branch and the outlet of the third bypass branch are sequentially arranged in sequence;
the first valve is arranged on the first bypass branch, the second valve is arranged on the second bypass branch, and the third valve is arranged on the third bypass branch.
Preferably, the heat exchanger further comprises a first temperature sensor arranged between the first outlet of the second heat exchanger and the inlet of the second bypass branch; the second temperature sensor is arranged between the outlet of the first bypass branch and the outlet of the second bypass branch; the first valve and the third valve are respectively arranged as flow regulating valves.
Preferably, the first temperature sensor has a precision of ±0.3 degrees and less, the second temperature sensor has a precision of ±0.1 degrees and less, and the first valve, the second valve and the third valve have a precision of 1% and less.
Preferably, the system further comprises a third temperature sensor or a first pressure sensor for monitoring a change in the load of the first heat exchanger, and/or a fourth temperature sensor or a second pressure sensor; the third temperature sensor or the first pressure sensor is arranged at the first inlet of the first heat exchanger, and the fourth temperature sensor or the second pressure sensor is arranged at the first outlet of the first heat exchanger.
Preferably, the system further comprises a first mixer and a second mixer, wherein the outlet of the first bypass branch and the first outlet of the second heat exchanger are both connected with the inlet of the first mixer, and the outlet of the first mixer is connected with the outlet of the second bypass branch; the outlet of the third bypass branch and the outlet of the second bypass branch are connected with the inlet of the second mixer, and the outlet of the second mixer is connected with the first inlet of the first heat exchanger.
Preferably, a thermal buffer is also included, connected between the first inlet of the first heat exchanger and the outlet of the second mixer.
Preferably, a third heat exchanger is also included; the outlet medium of the first bypass branch can be mixed with the first outlet medium of the second heat exchanger to form a first mixed medium, the first inlet of the third heat exchanger can be used for the inflow of the first mixed medium, and the first outlet of the third heat exchanger is connected with the outlet of the second bypass branch.
Preferably, the second heat exchanger comprises a first cooling pipeline, the third heat exchanger comprises a second cooling pipeline, an inlet of the second cooling pipeline is connected with an inlet of the first cooling pipeline, and an outlet of the second cooling pipeline is connected with an outlet of the first cooling pipeline.
Preferably, a fourth valve is provided on the second cooling line.
The utility model also provides an air conditioner comprising the temperature regulating system.
According to the temperature regulating system provided by the utility model, the first bypass branch, the second bypass branch and the third bypass branch are introduced, and each bypass branch is provided with a valve, when the temperature of the medium at the first outlet in the second heat exchanger is lower than a target temperature value, the high-temperature medium from the first outlet in the first heat exchanger is introduced through the first bypass branch to form a first mixed medium, and the medium at the first outlet in the first heat exchanger can be heated due to the fact that the temperature of the medium at the first outlet in the first heat exchanger is higher; when the temperature of the first mixed medium is higher than a target temperature value, introducing a low-temperature medium from a first outlet in the second heat exchanger through the second bypass branch, wherein the temperature of the first mixed medium can be reduced due to the fact that the temperature of the medium at the first outlet in the second heat exchanger is lower, so that a second mixed medium is formed; the temperature of the medium subjected to primary temperature rise and primary temperature reduction is close to a target temperature value, at this time, in order to further accurately regulate the temperature of the second mixed medium, the temperature precision of the second mixed medium can reach the target temperature value of the target precision, the high-temperature medium in the first bypass branch can be introduced through the third bypass branch, and the temperature precision of the second mixed medium is further regulated to form a third mixed medium, wherein the temperature precision of the third mixed medium can be regulated to be within +/-0.1 ℃ and optimally, the temperature precision of the third mixed medium can be regulated to be within +/-0.03 ℃; the temperature-regulating refrigerating system adopts a bidirectional temperature compensation mode and a multistage compensation mode, namely, a first-stage high-temperature compensation utilizes a high-temperature heat source wasted in the system, a first-stage low-temperature compensation utilizes a low-temperature cold source in the system, and a second-stage high-temperature compensation mode is preferentially carried out after the first-stage low-temperature compensation, so that the requirements on temperature precision and stability are met, meanwhile, the rapid temperature regulation can be realized, and the energy conservation is facilitated.
In a preferred embodiment, a third heat exchanger is also included; the outlet medium of the first bypass branch can be mixed with the first outlet medium of the second heat exchanger to form a first mixed medium, the first inlet of the third heat exchanger can be used for the inflow of the first mixed medium, and the first outlet of the third heat exchanger is connected with the outlet of the second bypass branch. According to the arrangement, when the temperature of the first mixed medium is higher than the target temperature value, the low-temperature medium introduced into the first outlet of the second heat exchanger through the second bypass branch can be selected to realize cooling, or the third heat exchanger can be used for introducing an external medium to cool, or both cooling modes are used simultaneously; by the mode, the accuracy, efficiency and stability of medium temperature regulation can be further improved.
The air conditioner provided by the utility model is provided with the temperature regulating system, and the temperature regulating system has the technical effects, so that the air conditioner provided with the temperature regulating system also has the corresponding technical effects.
Drawings
In order to more clearly illustrate the embodiments of the utility model 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 utility model, 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 diagram of a prior art refrigeration system;
fig. 2 is a schematic structural diagram of an embodiment of a temperature-regulating refrigeration system according to the present utility model;
wherein: a first heat exchanger 1; a second heat exchanger 2; a first temperature sensor 21; a second temperature sensor 22; a first bypass branch 3; a first valve 31; a flow sensor 32; a second bypass branch 4; a second valve 41; a first mixer 5; a third heat exchanger 6; a fourth valve 61; a thermal buffer 7; a second mixer 8; a third bypass branch 81; a third valve 82; and a circulation pump 9.
Detailed Description
The core of the utility model is to provide a temperature-regulating refrigerating system which has low energy consumption, quick response, high temperature regulation precision and good stability. Another core of the present utility model is to provide an air conditioner comprising the above temperature-regulating refrigeration system.
The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.
According to the temperature-regulating refrigeration system provided by the utility model, the first bypass branch 3, the second bypass branch 4 and the third bypass branch 81 are introduced to introduce the high-temperature medium at the first outlet of the first heat exchanger 1 into the first outlet of the second heat exchanger 2 so as to be mixed to form a first mixed medium, or the low-temperature medium at the first outlet of the second heat exchanger 2 is introduced into the first mixed medium so as to be mixed to form a second mixed medium, or after bidirectional high-low temperature regulation, the high-temperature medium at the first outlet of the first heat exchanger 1 can be introduced to perform secondary temperature regulation, so that bidirectional temperature compensation and multistage temperature control in the system are realized, the regulation cost of the system is saved, the control precision is further improved, the temperature precision of the medium can be regulated to within +/-0.1 degree, optimally, the temperature precision of the medium can be regulated to within +/-0.03 degree, and finally the medium with a target temperature value is conveyed into the first inlet of the first heat exchanger 1, and the circulation loop in the temperature-regulating system can refer to the conventional cooling system structure.
Referring to fig. 2, fig. 2 is a schematic structural diagram of an embodiment of a temperature-adjusting refrigeration system according to the present utility model.
In this embodiment, the temperature-regulating refrigeration system includes a circulation circuit and a first heat exchanger 1 and a second heat exchanger 2 connected in the circulation circuit, and further includes:
a first bypass branch 3, a second bypass branch 4, and a third bypass branch 81;
the inlet of the first bypass branch 3 is connected with the first inlet of the second heat exchanger 2, and the outlet of the first bypass branch 3 is connected with the first outlet of the second heat exchanger 2 to be mixed to form a first mixed medium; an inlet of the second bypass branch 4 is connected with a first outlet of the second heat exchanger 2, an outlet of the second bypass branch 4 is connected with a first inlet of the first heat exchanger 1, and a medium in the second bypass branch 4 is mixed with a first mixed medium to form a second mixed medium; an inlet of the third bypass branch 81 is communicated with the first bypass branch 3, an outlet of the third bypass branch 81 is connected with an outlet of the second bypass branch 4, and the medium in the third bypass branch 81 and the second mixed medium are mixed into a third mixed medium which flows into the first heat exchanger 1; wherein, the inlet of the second heat exchanger 2, the inlet of the second bypass branch 4, the outlet of the first bypass branch 3, the outlet of the second bypass branch 4 and the outlet of the third bypass branch 81 are sequentially arranged in sequence.
Further, the valve further comprises a first valve 31, a second valve 41 and a third valve 82, wherein the first valve 31 is arranged on the first bypass branch 3, the second valve 41 is arranged on the second bypass branch 4, and the third valve 82 is arranged on the third bypass branch 81; and, a controller may be further included, which may be used to control the opening and closing of the first, second and third valves 31, 41 and 82, respectively, the first, second and third valves 31, 41 and 82 being electronic valves, although the first, second and third valves 31, 41 and 82 may also be opened and closed manually, and in this case, the first, second and third valves 31, 41 and 82 may be mechanical valves, preferably, the opening and closing of the first, second and third valves 31, 41 and 82 may be controlled by the controller.
May further comprise a first temperature sensor 21, the first temperature sensor 21 being arranged between the first outlet of the second heat exchanger 2 and the inlet of the second bypass branch 4; and a second temperature sensor 22, the second temperature sensor 22 is disposed between the outlet of the first bypass branch 3 and the outlet of the second bypass branch 4, it should be noted that the second temperature sensor 22 should be disposed on a pipe line after the outlet medium of the first bypass branch 3 and the first outlet medium of the second heat exchanger 2 are mixed, and the second temperature sensor 22 is used for detecting the temperature of the first mixed medium; the first valve 31 and the third valve 82 are flow regulating valves, and since the medium temperature of the first inlet of the second heat exchanger 2 is different from the medium temperature of the first outlet thereof, that is, the medium temperature of the first inlet of the second heat exchanger 2 is relatively high, the flow rates of the first bypass branch 3 and the third bypass branch 81 can be made smaller by using the first valve 31 and the third valve 82 as the flow regulating valves with adjustable opening degrees, for example, the medium flow rate of the first bypass branch 3 can be (0.1-10)% of the medium flow rate of the first outlet of the first heat exchanger 1, and the medium flow rate of the third bypass branch 81 can be (0.1-10)% of the medium flow rate of the first bypass branch 3, so that the medium can be slowly mixed with the medium of the first outlet of the second heat exchanger 2 through the smaller flow rate, thereby achieving the purpose of precisely regulating the temperature, wherein the medium temperature accuracy can be regulated to within ±0.1 degrees, and optimally, and the medium temperature accuracy can be regulated within ±0.03 degrees.
The temperature of the medium at the first outlet of the second heat exchanger 2 is not different from the temperature of the first mixed medium mixed by the first bypass branch 3, so that the second valve 41 is only required to be a common valve, and the second valve 41 can be also provided with a flow regulating valve with an adjustable opening degree for precise temperature regulation, so that the purpose of precise temperature regulation can be further realized.
Alternatively, in order to achieve high-precision temperature adjustment, the precision of the first temperature sensor 21 is ±0.3 degrees and less, the precision of the second temperature sensor 22 is ±0.1 degrees and less, the precision of the first valve 31, the second valve 41 and the third valve 82 is 1% and less, wherein, preferably, the precision of both the first temperature sensor 21 and the second temperature sensor 22 is ±0.03 degrees and less; so that the accuracy of each temperature sensor and valve matches the accuracy of the temperature control of the system.
When the first temperature sensor 21 detects that the medium temperature at the first outlet of the second heat exchanger 2 is lower than the target temperature value, the opening of the first valve 31 is controlled to bypass the high-temperature medium at the first inlet of the second heat exchanger 2 to the outlet of the first bypass branch 3 and mix the high-temperature medium with the low-temperature medium at the first outlet of the second heat exchanger 2, so that the medium at the first outlet of the second heat exchanger 2 is heated to reach the target temperature value.
When the second temperature sensor 22 detects that the temperature of the first mixed medium is higher than the target temperature value, the second valve 41 is controlled to be opened or the opening degree of the second valve 41 is controlled, so that the low-temperature medium at the first outlet of the second heat exchanger 2 bypasses to the outlet of the second bypass branch 4 and is mixed with the first mixed medium, and the first mixed medium is cooled to form the second mixed medium, so that the temperature of the second mixed medium reaches the target temperature value.
After the bidirectional high-low temperature adjustment, the third valve 81 can be controlled to be opened, so that the high-temperature medium in the first bypass branch 3 bypasses the outlet of the third bypass branch 81 and is mixed with the second mixed medium to form a third mixed medium, the precision of the medium is further adjusted, and the precision of the medium temperature can reach a target temperature value of target precision.
In addition, since the load of the first heat exchanger 1 is changed according to the actual application scenario, for example, the temperature requirement is increased or decreased, a third temperature sensor or a first pressure sensor for monitoring the change of the load of the first heat exchanger 1 and/or a fourth temperature sensor or a second pressure sensor are also provided; the third temperature sensor or the first pressure sensor is arranged at the first inlet of the first heat exchanger 1, and the fourth temperature sensor or the second pressure sensor is arranged at the first outlet of the first heat exchanger 1; therefore, when the load changes, the temperature or the pressure of the first inlet and the first outlet of the first heat exchanger 1 can change, and therefore, the pressure or the temperature change of the first inlet is monitored, or/and the pressure or the temperature change of the first outlet is/are monitored, the accuracy of the target temperature value and the target temperature value of the system can be updated in real time, and the heat exchange quantity of each heat exchanger can be updated at the same time, so that the medium temperature of the whole temperature regulating system is matched with the actual use.
When the first heat exchanger 1 radiates heat to equipment with high-precision radiating requirement, the precision requirement on the temperature of the medium is higher, the medium cools the equipment through the first heat exchanger 1, and after passing through the first heat exchanger 1, the medium at the first outlet of the first heat exchanger has higher temperature and needs to flow through the second heat exchanger 2 for cooling. Meanwhile, a circulating pump is arranged in the circulating loop to provide power for the flow of the medium in the circulating loop; the circulation circuit may be provided with a pressure sensor, a flow rate sensor 32, a temperature sensor, and the like, and information such as pressure, flow rate, and temperature in the circulation circuit may be monitored.
In some embodiments, the first bypass branch 3 is provided with a first flow sensor 32, and the controller is connected to the first flow sensor 32, specifically, the first flow sensor 32 is used for detecting the flow in the first bypass branch 3, the controller controls the opening of the first primary valve 31 according to the temperature of the first outlet of the second heat exchanger 2, so as to change the flow in the first bypass branch 3, and the first flow sensor 32 may feed back the flow data in the first bypass branch 3 to the controller.
In some embodiments, further comprising a first mixer 5, the outlet of the first bypass branch 3 and the first outlet of the second heat exchanger 2 being connected to an inlet of the first mixer 5, the outlet of the first mixer 5 being connected to an outlet of the second bypass branch 4; through the setting of first blender 5, the even mixing of acceleration temperature promotes whole energy-conserving cooling system's efficiency and precision.
In some embodiments, the second mixer 8 is further included, the outlet of the third bypass branch 81 and the outlet of the second bypass branch 4 are both connected to the inlet of the second mixer 8, or the outlet of the first mixer 5 and the outlet of the third bypass branch 81 may be both connected to the inlet of the second mixer 8, the outlet of the second mixer 8 is connected to the first inlet of the first heat exchanger 1; through the setting of the second mixer 8, the uniform mixing of temperature is accelerated, and the efficiency and the precision of the whole energy-saving cooling system are improved.
Specifically, both the first mixer 5 and the second mixer 8 may be mixers, or mixing pipes, or components or structures capable of mixing media with different temperatures. At least one baffle component is arranged in the mixer, and a gap is arranged between the baffle component and the inner wall of the mixer. That is, the barrier member is in a semi-closed state, and by providing the barrier member, the fluid in the mixer is guided and the flow path in the mixer is prolonged, so that the mixing thereof is more uniform. The baffle component is particularly a baffle plate, and has low cost and convenient processing.
In some embodiments, a thermal buffer 7 is also included, the thermal buffer 7 being connected between the first inlet of the first heat exchanger 1 and the outlet of the second mixer 8. Specifically, through the setting of thermal buffer 7 to adjust the stability of temperature, make through the high accuracy fine setting of first bypass branch road 3, second bypass branch road 4 and third bypass branch road 81 realization temperature after, the temperature is further stable, and provide the first import of first heat exchanger 1 with the medium of temperature stability, realize accurate control.
In some embodiments, the circulating pump 9 and the pressure sensor are also included, and the circulating pump 9 and the pressure sensor are both disposed in the circulating loop. That is, a circulation pump 9 is arranged in the circulation loop to provide power for the flow of the medium in the circulation loop; the circulation circuit may be provided with a pressure sensor, a flow rate sensor 32, a temperature sensor, and the like, and information such as pressure, flow rate, and temperature in the circulation circuit may be monitored.
In some embodiments, the first outlet of the second heat exchanger 2 is provided with a first temperature sensor 21, the outlet of the first mixer 5 is provided with a second temperature sensor 22, and both the first temperature sensor 21 and the second temperature sensor 22 are connected to a controller. Specifically, the controller is configured to control the first valve 31 based on the temperature of the first temperature sensor 21 and also to control the second valve 41 based on the temperature of the second temperature sensor 22.
In some embodiments, a third heat exchanger 6 is also included; the outlet medium of the first bypass branch 3 can be mixed with the first outlet medium of the second heat exchanger 2 to form a first mixed medium, the first inlet of the third heat exchanger 6 can be used for the inflow of the first mixed medium, and the first outlet of the third heat exchanger 6 is connected with the outlet of the second bypass branch 4. In the above arrangement, by introducing the third heat exchanger 6, when the temperature of the first mixed medium is higher than the target temperature value, the medium introduced into the first outlet of the second heat exchanger 2 through the second bypass branch 4 can be selected to realize cooling, or the external medium can be introduced into the third heat exchanger 6 to realize cooling, or both cooling modes can be used simultaneously; by the mode, the accuracy, efficiency and stability of medium temperature regulation can be further improved.
In some embodiments, the second heat exchanger 2 comprises a first cooling circuit, the third heat exchanger 6 comprises a second cooling circuit, the inlet of the second cooling circuit is connected with the inlet of the first cooling circuit, the outlet of the second cooling circuit is connected with the outlet of the first cooling circuit, that is, the third heat exchanger 6 and the second heat exchanger 2 select the same cooling circuit to reduce the arrangement cost of the device, and of course, a separate cooling circuit can also be adopted for the third heat exchanger 6.
In some embodiments, the second cooling pipe is provided with a fourth valve 61, i.e. the controller is further configured to control the fourth valve 61 according to the temperature of the second temperature sensor 22, that is, when the second temperature sensor 22 detects that the medium temperature in the first mixer 5 is lower than the target temperature value, the temperature of the medium entering the first heat exchanger 1 may be reduced by opening the second valve 41, or by opening the fourth valve 61, or both the second valve 41 and the fourth valve 61 may be simultaneously opened, and by adjusting the flow rates of the second valve 41 and the fourth valve 61.
Of course, in order to save the installation cost of the third heat exchanger 6, a heat exchange branch may be directly arranged on the outlet pipeline of the first mixer 5, a heat exchange part is arranged on the heat exchange branch, the heat exchange part is close to the pipeline at the outlet of the first mixer 5 so as to perform heat exchange on the pipeline at the outlet of the first mixer 5, the inlet of the heat exchange branch is connected with the inlet of the second cooling circuit, the outlet of the heat exchange branch is connected with the outlet of the second cooling circuit, and a fourth valve 61 is arranged on the heat exchange branch; the controller is also used to control the fourth valve 61 in dependence of the outlet temperature of the first mixer 5; the above solution makes it possible to replace the installation of the third heat exchanger 6 without changing the structure and the position of the piping at the outlet of the first mixer 5. Further, the heat exchange part is a spiral tubular heat exchange part so as to improve the heat exchange efficiency.
In some embodiments, in order to facilitate the control of the first valve 31, the second valve 41, the fourth valve 61 and/or the third valve 82 by the controller, the first valve 31, the second valve 41, the fourth valve 61 and/or the third valve 82 are adjusting valves, and of course, the first valve 31, the second valve 41, the fourth valve 61 and/or the third valve 82 may be cut-off valves without considering the adjustment accuracy, which is lower in cost.
In addition to the temperature-adjusting refrigeration system, the utility model also provides an air conditioner comprising the temperature-adjusting refrigeration system, and other parts of the air conditioner refer to the prior art, and are not repeated herein.
In the present specification, each embodiment is described in a progressive manner, and each embodiment is mainly described in a different point from other embodiments, and identical and similar parts between the embodiments are all enough to refer to each other.
The temperature-regulating refrigeration system provided by the utility model is described in detail above. The principles and embodiments of the present utility model have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present utility model and its core ideas. It should be noted that it will be apparent to those skilled in the art that various modifications and adaptations of the utility model can be made without departing from the principles of the utility model and these modifications and adaptations are intended to be within the scope of the utility model as defined in the following claims.

Claims (10)

1. A temperature regulating system comprising a circulation circuit and a first heat exchanger (1) and a second heat exchanger (2) connected in the circulation circuit, characterized in that it further comprises:
a first bypass branch (3), wherein an inlet of the first bypass branch (3) is connected with a first inlet of the second heat exchanger (2), and an outlet of the first bypass branch (3) is connected with a first outlet of the second heat exchanger (2);
the inlet of the second bypass branch (4) is connected with the first outlet of the second heat exchanger (2), and the outlet of the second bypass branch (4) is connected with the first inlet of the first heat exchanger (1);
a third bypass branch (81), wherein an inlet of the third bypass branch (81) is communicated with the first bypass branch (3), and an outlet of the third bypass branch (81) is connected with an outlet of the second bypass branch (4);
the second heat exchanger (2), the inlet of the second bypass branch (4), the outlet of the first bypass branch (3), the outlet of the second bypass branch (4) and the outlet of the third bypass branch (81) are sequentially arranged in sequence;
a first valve (31) provided in the first bypass passage (3); a second valve (41) provided in the second bypass branch (4); and a third valve (82) provided in the third bypass passage (81).
2. Tempering system according to claim 1, further comprising a first temperature sensor (21) arranged between the first outlet of the second heat exchanger (2) and the inlet of the second bypass branch (4); a second temperature sensor (22) arranged between the outlet of the first bypass branch (3) and the outlet of the second bypass branch (4); the first valve (31) and the third valve (82) are respectively provided as flow rate regulating valves.
3. Temperature regulating system according to claim 2, wherein the accuracy of the first temperature sensor (21) is within ±0.3 degrees and the accuracy of the second temperature sensor (22) is within ±0.1 degrees, and the accuracy of the first valve (31), the second valve (41) and the third valve (82) is within 1% and.
4. Tempering system according to claim 1, further comprising a third temperature sensor or a first pressure sensor for monitoring a change in the load of the first heat exchanger (1), and/or a fourth temperature sensor or a second pressure sensor; the third temperature sensor or the first pressure sensor is arranged at the first inlet of the first heat exchanger (1), and the fourth temperature sensor or the second pressure sensor is arranged at the first outlet of the first heat exchanger (1).
5. Tempering system according to claim 1 further comprising a first mixer (5) and a second mixer (8), the outlet of the first bypass branch (3) and the first outlet of the second heat exchanger (2) being both connected to the inlet of the first mixer (5), the outlet of the first mixer (5) being connected to the outlet of the second bypass branch (4); the outlet of the third bypass branch (81) and the outlet of the second bypass branch (4) are connected with the inlet of the second mixer (8), and the outlet of the second mixer (8) is connected with the first inlet of the first heat exchanger (1).
6. Temperature regulating system according to claim 5, further comprising a thermal buffer (7), said thermal buffer (7) being connected between the first inlet of the first heat exchanger (1) and the outlet of the second mixer (8).
7. Tempering system according to any one of claims 1 to 6, further comprising a third heat exchanger (6); the outlet medium of the first bypass branch (3) can be mixed with the first outlet medium of the second heat exchanger (2) to form a first mixed medium, the first inlet of the third heat exchanger (6) can be used for the inflow of the first mixed medium, and the first outlet of the third heat exchanger (6) is connected with the outlet of the second bypass branch (4).
8. Temperature regulating system according to claim 7, wherein the second heat exchanger (2) comprises a first cooling circuit, the third heat exchanger (6) comprises a second cooling circuit, an inlet of which is connected to an inlet of the first cooling circuit, and an outlet of which is connected to an outlet of the first cooling circuit.
9. Tempering system according to claim 8, wherein a fourth valve (61) is provided on said second cooling line.
10. An air conditioner comprising a temperature regulating system, characterized in that the temperature regulating system is a temperature regulating system according to any one of claims 1 to 9.
CN202321575155.9U 2023-06-19 2023-06-19 Air conditioner and temperature regulating system thereof Active CN220524251U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202321575155.9U CN220524251U (en) 2023-06-19 2023-06-19 Air conditioner and temperature regulating system thereof

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202321575155.9U CN220524251U (en) 2023-06-19 2023-06-19 Air conditioner and temperature regulating system thereof

Publications (1)

Publication Number Publication Date
CN220524251U true CN220524251U (en) 2024-02-23

Family

ID=89938643

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202321575155.9U Active CN220524251U (en) 2023-06-19 2023-06-19 Air conditioner and temperature regulating system thereof

Country Status (1)

Country Link
CN (1) CN220524251U (en)

Similar Documents

Publication Publication Date Title
CN109582057A (en) A kind of environmental wind tunnel temperature control system
US20120125022A1 (en) Cooling system
TW200846614A (en) Constant temperature controller
CN112078806B (en) Helicopter liquid cooling integrated control system
CN207230985U (en) The water circulation cooling device of high accuracy temperature control
CN203687437U (en) Refrigerating system with refrigerating capacity adjusting function and environmental laboratory
CN110440505A (en) A kind of wind-tunnel temperature control system of Two-way Cycle refrigerating medium Collaborative Control
CN206862631U (en) A kind of constant-temperaturetest test device of engine water cold type charge air cooler
TWI675263B (en) Liquid temperature control device and method
CN110822544A (en) Fixed-frequency air conditioning system for improving indoor comfort
CN220524251U (en) Air conditioner and temperature regulating system thereof
CN111023414B (en) Air conditioning system and dehumidification control method
CN110986405B (en) Heat exchange assembly, heat exchange system and air conditioning equipment
CN220524250U (en) Air conditioner and two-way temperature-regulating energy-saving system thereof
CN116538604A (en) Air conditioner and temperature regulating system thereof
CN111810396A (en) Low-temperature detection system and method for hydraulic pump
CN220338600U (en) Temperature control system and air conditioner
CN116518485A (en) Air conditioner and two-way temperature-regulating energy-saving system thereof
CN217160292U (en) Liquid cooling system capable of simultaneously adjusting liquid supply pressure, flow and liquid supply temperature
CN220355606U (en) Temperature control system and air conditioner
CN213747100U (en) High-precision constant-temperature constant-humidity air conditioner
CN111929088B (en) High-efficiency energy-saving air source heat pump water chilling unit testing system and method
CN220355607U (en) Temperature control system and air conditioner
CN207849746U (en) A kind of air-source air-heater
CN220624330U (en) High-precision temperature control system

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant