CN114719355B - Temperature adjusting system and calculating method - Google Patents

Abstract

The invention belongs to the technical field of energy utilization and discloses a temperature adjusting system. The temperature adjusting system comprises an air conditioning unit, a water collector, a water temperature adjusting unit and a water distributor, wherein the air conditioning unit comprises a plurality of groups of air conditioning tail ends, the plurality of groups of air conditioning tail ends correspond to a plurality of heat points to be heated respectively, outlet ends of the plurality of groups of air conditioning tail ends are communicated with an inlet end of the water collector respectively, an inlet end of the water temperature adjusting unit is communicated with an outlet end of the water collector, the water temperature adjusting unit can heat or refrigerate liquid flowing out of the water collector, an inlet end of the water distributor is communicated with an outlet end of the water temperature adjusting unit, and outlet ends of the water distributor are communicated with inlet ends of the plurality of groups of air conditioning tail ends respectively. By using the temperature adjusting system, the water temperature adjusting unit can heat the liquid and refrigerate the liquid, so that the applicability and the universality of the whole temperature adjusting system are improved, the cyclic utilization of temperature adjustment can be realized, and the reliability is improved.

Description

Temperature adjusting system and calculating method

Technical Field

The invention relates to the technical field of energy utilization, in particular to a temperature adjusting system and a calculating method.

Background

At present, building heating is mainly achieved through a coal-fired boiler or a gas-fired boiler, the former has the problems of high energy consumption, low heat efficiency, serious pollution and the like, and the latter has the problems of unstable fuel supply, high operating cost, high nitrogen oxide emission and the like. In recent years, with the increasing severity of the situation of the atmospheric environment and the increasing emphasis on environmental problems in China, relevant national departments put forward strict restriction requirements on coal-fired boilers. The building air conditioner is generally satisfied by a split air conditioner or a water chilling unit, the former has the problems of high installation cost, low energy efficiency ratio, high operation cost and the like, and the latter can only refrigerate and cannot heat.

Disclosure of Invention

The invention aims to provide a temperature adjusting system which is used for at least solving the problem that the existing temperature adjusting device cannot simultaneously refrigerate and heat.

In order to achieve the purpose, the invention adopts the following technical scheme:

a temperature regulation system comprising:

the air conditioning unit comprises a plurality of groups of air conditioning tail ends, and the plurality of groups of air conditioning tail ends respectively correspond to a plurality of heat points to be heated;

the outlet ends of the tail ends of the air conditioners are respectively communicated with the inlet end of the water collector;

the inlet end of the water temperature adjusting unit is communicated with the outlet end of the water collector, and the water temperature adjusting unit can heat or refrigerate the liquid flowing out of the water collector;

and the inlet end of the water separator is communicated with the outlet end of the water temperature adjusting unit, and the outlet end of the water separator is respectively communicated with the inlet ends of the tail ends of the air conditioners.

In some embodiments of the present invention, the water temperature adjusting unit includes a waste heat recovery unit and a first driving pump, a first inlet end of the waste heat recovery unit is used for communicating with a waste heat generating device, a second inlet end of the waste heat recovery unit is communicated with an outlet end of the first driving pump, an outlet end of the waste heat recovery unit is communicated with the water separator, and an inlet end of the first driving pump is communicated with the water collector.

In some embodiments of the invention, the water temperature adjusting unit comprises a first air source heat pump and a second drive heat pump, the second drive heat pump is located between the water collector and the first drive heat pump, an inlet end of the second drive heat pump is communicated with the water collector, a first outlet end of the second drive heat pump is communicated with an inlet end of the first drive heat pump, a second outlet end of the second drive heat pump is communicated with an inlet end of the first air source heat pump, and an outlet end of the first air source heat pump is communicated with the water separator.

In some embodiments of the present invention, the water temperature adjusting unit includes a first water source heat pump, a first water storage tank, and a second air source heat pump, an outlet end of the water collector communicates with an inlet end of the condensing portion of the first water source heat pump, an outlet end of the condensing portion of the first water source heat pump communicates with the water separator, an outlet end of the evaporating portion of the first water source heat pump communicates with an inlet end of the second air source heat pump through the first water storage tank, and an outlet end of the second air source heat pump communicates with an inlet end of the evaporating portion of the first water source heat pump through the first water storage tank.

In some embodiments of the invention, a third driving pump is arranged between the first water source heat pump and the water collector, a fourth driving pump is arranged between the first water storage tank and the second air source heat pump, and a fifth driving pump is arranged between the first water storage tank and the first water source heat pump.

In some embodiments of the present invention, the water temperature adjusting unit includes a third air source heat pump and a sixth driving heat pump, an inlet end of the sixth driving heat pump is communicated with the water collector, an outlet end of the sixth driving heat pump is communicated with an inlet end of the third air source heat pump, an outlet end of the third air source heat pump is communicated with the water separator, and the third air source heat pump can heat or refrigerate the liquid flowing out of the water collector.

In some embodiments of the present invention, the water temperature adjusting unit includes a second water source heat pump and a first cooling tower, an outlet end of the water collector communicates with an inlet end of an evaporation portion of the second water source heat pump, an outlet end of the evaporation portion of the second water source heat pump communicates with the water separator, an inlet end of the first cooling tower communicates with an outlet end of a condensation portion of the second water source heat pump, and an outlet end of the first cooling tower communicates with an inlet end of the condensation portion of the second water source heat pump.

In some embodiments of the invention, a seventh driving pump is arranged between the first cooling tower and the second water source heat pump.

In some embodiments of the invention, the water temperature regulating unit comprises a fourth air source heat pump, a third water source heat pump and a second water storage tank, the outlet end of the water collector is communicated with the inlet end of the condensing part of the third water source heat pump, the outlet end of the condensing part of the third water source heat pump is communicated with the water separator, the outlet end of the evaporating part of the third water source heat pump is communicated with the inlet end of the fourth air source heat pump through the second water storage tank, and the outlet end of the fourth air source heat pump is communicated with the inlet end of the evaporating part of the third water source heat pump through the second water storage tank.

In some embodiments of the invention, an eighth driving pump is arranged between the third water source heat pump and the water collector, a ninth driving pump is arranged between the second water storage tank and the fourth air source heat pump, and a tenth driving pump is arranged between the second water storage tank and the third water source heat pump.

In some embodiments of the present invention, the water temperature adjusting unit includes a fourth water source heat pump and a second cooling tower, an outlet end of the water collector communicates with an inlet end of an evaporation part of the fourth water source heat pump, an outlet end of the evaporation part of the fourth water source heat pump communicates with the water separator, an inlet end of the second cooling tower communicates with an outlet end of a condensation part of the fourth water source heat pump, and an outlet end of the second cooling tower communicates with an inlet end of the condensation part of the fourth water source heat pump.

In some embodiments of the present invention, a first water pump is disposed between the water collector and the fourth water source heat pump, and a second water pump is disposed between the second cooling tower and the fourth water source heat pump.

The invention also provides a calculation method of the numerical value of the loading machine of the air source heat pump, which is implemented according to the temperature regulation system and is characterized by comprising the following steps of:

respectively acquiring heating load and refrigerating load of an air source heat pump;

and obtaining the numerical value of the machine loading platform of the air source heat pump according to the heating load and the refrigerating load.

The invention also provides a calculation method of the outlet water temperature of the air source heat pump, which is implemented according to the temperature regulation system and is characterized by comprising the following steps:

respectively acquiring the outlet water temperature and the ambient temperature of a plurality of groups of air source heat pumps;

obtaining an actual input power model of the air source heat pump according to the outlet water temperature and the environment temperature of the multiple groups of air source heat pumps;

respectively acquiring the outlet water temperatures of a plurality of groups of air source heat pumps;

obtaining an actual heating quantity model of the water source heat pump according to the outlet water temperatures of the multiple groups of air source heat pumps;

establishing an optimized operation model according to an actual power input model of the air source heat pump and an actual heating quantity model of the water source heat pump;

acquiring the actual environment temperature;

and calculating the outlet water temperature of the air source heat pump according to the actual environment temperature and the optimized operation model.

The invention has the beneficial effects that:

by using the temperature regulating system, the tail ends of a plurality of groups of air conditioners of the air conditioning unit can act on a plurality of heat points to be heated, the area for supplying temperature is improved, liquid with temperature supplied by the tail ends of the plurality of groups of air conditioners can flow to the water collector respectively to be converged, and flows to the water temperature regulating unit at the downstream from the water collector in a centralized manner, the water temperature regulating unit can heat the liquid and refrigerate the liquid, the applicability and the universality of the whole temperature regulating system are improved, the heated or refrigerated liquid can flow to the water separator at the downstream, and then flows to the tail ends of the air conditioners at all positions from the water separator respectively, so that the temperature is supplied again, the circulation is realized, and the reliability is improved.

Drawings

FIG. 1 is a schematic view of the overall construction of the temperature regulation system of the present invention;

FIG. 2 is a schematic structural view of a first embodiment of the temperature regulation system of the present invention;

FIG. 3 is a schematic structural view of a second embodiment of the temperature regulation system of the present invention;

FIG. 4 is a schematic structural view of a third embodiment of the temperature regulation system of the present invention;

FIG. 5 is a schematic structural view of a fourth embodiment of the temperature regulation system of the present invention;

FIG. 6 is a schematic structural view of a fifth embodiment of the temperature regulation system of the present invention;

FIG. 7 is a schematic structural view of a sixth embodiment of the temperature regulation system of the present invention;

FIG. 8 is a schematic structural view of a seventh embodiment of the temperature regulation system of the present invention;

fig. 9 is a schematic structural view of an eighth embodiment of the temperature adjustment system of the present invention.

In the figure:

100: a temperature regulation system;

10. an air conditioning unit;

20. a water collector;

31. a waste heat recovery unit; (ii) a 321. A first air source heat pump; 322. a second air source heat pump; (ii) a 323. A third air source heat pump; 324. a fourth air source heat pump; 331. a first water source heat pump; 3311. a condenser of the first water source heat pump; 3312. an evaporation part of the first water source heat pump; 332. a second water source heat pump; 3321. a condenser of the second water source heat pump; 3322. an evaporation part of the second water source heat pump; 333. a third water source heat pump; 3331. a condenser of a third water source heat pump; 3332. an evaporation part of the third water source heat pump; 341. a first water storage tank; 3411. a float valve; 342. a second water storage tank; 351. a first cooling tower; 3511. a first backwash filter; 3512. a second water pump; 352. a second cooling tower; 3521. a second backwash filter; 3522. a fourth water pump;

40. a water separator;

51. a first water replenishing device; 52. a second water replenishing device; 53. a third water replenishing device; 54. a fourth water replenishing device;

60. a control valve;

71. a first drive pump; 72. a second drive pump; 73. a third drive pump; 74. a fourth drive pump; 75. a fifth drive pump; 76. a sixth drive pump; 77. a seventh drive pump; 78. an eighth drive pump; 79. a ninth drive pump; 710. a tenth drive pump;

81. a first water pump; 82. and a second water pump.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not to be construed as limiting the invention. It should be further noted that, for the convenience of description, only some structures related to the present invention are shown in the drawings, not all of them.

In the description of the present invention, unless otherwise explicitly specified or limited, the terms "connected," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature "on," "above" and "over" the second feature may include the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

In the description of the present embodiment, the terms "upper", "lower", "right", etc. are used based on the orientations or positional relationships shown in the drawings for convenience of description and simplicity of operation, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used only for descriptive purposes and are not intended to have a special meaning.

Fig. 1 is a schematic view of the overall structure of the temperature regulation system of the present invention. As shown in fig. 1, the temperature adjusting system of the present invention includes an air conditioning unit 10, a water collector 20, a water temperature adjusting unit and a water separator 40, wherein the air conditioning unit 10 includes a plurality of air conditioning terminals, the air conditioning terminals correspond to a plurality of points to be heated, respectively, outlet ends of the air conditioning terminals are communicated with an inlet end of the water collector 20, respectively, an inlet end of the water temperature adjusting unit is communicated with an outlet end of the water collector 20, the water temperature adjusting unit can heat or refrigerate liquid flowing out of the water collector 20, an inlet end of the water separator 40 is communicated with an outlet end of the water temperature adjusting unit, and outlet ends of the water separator 40 are communicated with inlet ends of the air conditioning terminals, respectively.

By using the temperature regulating system of the invention, the tail ends of a plurality of groups of air conditioners of the air conditioning unit 10 can act on a plurality of points to be heated, the area for supplying temperature is improved, liquid with temperature supplied by the tail ends of the plurality of groups of air conditioners can flow to the water collector 20 respectively to be converged, and flows to the water temperature regulating unit at the downstream from the water collector 20 in a centralized manner, the water temperature regulating unit can heat the liquid and refrigerate the liquid, the applicability and the universality of the whole temperature regulating system are improved, the heated or refrigerated liquid can flow to the water separator 40 at the downstream, and then flows to the tail ends of the air conditioners at all positions from the water separator 40 respectively, so that the temperature supplying operation is carried out again, the circulation is carried out in sequence, the recycling of temperature regulation can be realized, and the reliability is improved.

In the first embodiment of the present invention, as shown in fig. 2, the water temperature adjusting unit includes a heat recovery unit 31 and a first driving pump 71, a first inlet end of the heat recovery unit 31 is used for communicating with a heat generating device (e.g. an industrial boiler), a second inlet end of the heat recovery unit 31 communicates with an outlet end of the first driving pump 71, an outlet end of the heat recovery unit 31 communicates with the water separator 40, and an inlet end of the first driving pump 71 communicates with the water collector 20. In this embodiment, a combination form of the water collector 20, the air conditioning unit 10, the water separator 40 and the waste heat recovery unit 31 is adopted, the waste heat recovery unit 31 can produce hot water of 45 ℃ by the waste heat generating equipment, and the hot water is distributed by the water separator 40 to supply heat to the tail ends of multiple downstream air conditioners for producing hot air for heating, when the water temperature at the tail ends of the multiple air conditioners is reduced to 40 ℃, the hot water returns to the water collector 20, the return water collected by the water collector 20 returns to the waste heat recovery unit 31 again, the waste heat energy of the waste heat recovery unit 31 is reheated to 45 ℃ again, and the hot water enters the water separator 40 again, and the circulation is performed, so that the waste heat energy of the waste heat generating equipment can be reused by the waste heat recovery unit 31, and the utilization rate of energy is improved. In this embodiment, the waste heat utilization heating mode is used, and the air conditioning unit 10 is heated only by the waste heat recovery unit 31.

Specifically, in this embodiment, as shown in fig. 2, the water temperature adjusting unit further includes a first water replenishing device 51, an outlet end of the first water replenishing device 51 is communicated with an outlet end of the water collector 20, when the pressure at the constant pressure point between the water collector 20 and the first driving pump 71 changes (the cause is that the water body expands and contracts due to temperature fluctuation and leaks), the first water replenishing device 51 is automatically opened, the water is softened water, and the water is prepared by the softened water device, so that the pressure balance of the system water path in this embodiment can be ensured, and the reliability is improved.

Specifically, in the present embodiment, as shown in fig. 2, control valves 60 are disposed between the water collector 20 and the air conditioning unit 10, between the water collector 20 and the first driving pump 71, at the outlet end of the first water replenishing device 51, between the heat recovery unit 31 and the water separator 40, and between the water separator 40 and the air conditioning unit 10, and the control valves 60 can control on/off of each passage, so as to facilitate switching between the modes.

In a second embodiment of the present invention, as shown in fig. 3, based on the first embodiment, the water temperature regulating unit further includes a first air source heat pump 321 and a second driving heat pump 72, the second driving heat pump 72 is located between the water collector 20 and the first driving heat pump 71, an inlet end of the second driving heat pump 72 is communicated with the water collector 20, a first outlet end of the second driving heat pump 72 is communicated with an inlet end of the first driving heat pump 71, a second outlet end of the second driving heat pump 72 is communicated with an inlet end of the first air source heat pump 321, and an outlet end of the first air source heat pump 321 is communicated with the water separator 40. In this embodiment, a combination form of the first air source heat pump 321 and the waste heat recovery unit 31 is adopted, the waste heat recovery unit 31 and the first air source heat pump 321 respectively flow the prepared hot water at 45 ℃ into the water separator 40, distribute the ends of the multiple air conditioners of the air conditioning unit 10 to prepare hot air for heating, and return the hot water to the water collector 20 when the water temperature is reduced to 40 ℃. After the backwater collected by the collector is pressurized by the second driving pump 72, one part of the backwater returns to the condenser of the first air source heat pump 321 to absorb the heat in the refrigerant, the temperature of the backwater rises to 45 ℃ and then enters the water separator 40, the other part of the backwater returns to the waste heat recovery unit 31 after being pressurized by the first driving pump 71, the backwater is heated to 45 ℃ by the waste heat energy and then enters the water separator 40, and the circulation can realize the reutilization of the waste heat energy of the waste heat generation equipment by the waste heat recovery unit 31, improve the utilization rate of energy, and also can utilize the first air source heat pump 321 to supply heat to the air conditioning unit 10, thereby improving the heat supply efficiency of the whole temperature regulating system. In this embodiment, a heating mode of the waste heat utilization coupling air source heat pump is adopted, and a combined structure of the waste heat recovery unit 31 and the first air source heat pump 321 is adopted to heat the air conditioning unit 10.

Specifically, as shown in fig. 3, in the present embodiment, control valves 60 are respectively disposed between the outlet end of the first air source heat pump and the water separator 40, and between the inlet end of the first air source heat pump and the second drive heat pump 72, and the control valves 60 can control on/off of each passage, so as to facilitate switching between each mode.

In a third embodiment of the present invention, as shown in fig. 4, the water temperature adjusting unit includes a first water source heat pump 331, a first water storage tank 341, and a second air source heat pump 322, an outlet end of the water collector 20 communicates with an inlet end of the condensing part 3311 of the first water source heat pump, an outlet end of the condensing part 3311 of the first water source heat pump communicates with the water separator 40, an outlet end of the evaporating part 3312 of the first water source heat pump communicates with an inlet end of the second air source heat pump 322 through the first water storage tank 341, and an outlet end of the second air source heat pump 322 communicates with an inlet end of the evaporating part 3312 of the first water source heat pump through the first water storage tank 341. In this embodiment, a combination of the first water source heat pump 331, the first water storage tank 341 and the second air source heat pump 322 is adopted, and the hot water at 45 ℃ respectively produced by the condensation part of the water source heat pump and the waste heat recovery unit 31 enters the water separator 40 and is distributed to the ends of the air conditioners of the air conditioning units 10 to produce hot air for heating, and the hot water returns to the water collector 20 when the temperature of the water is reduced to 40 ℃. After the collected return water is pressurized by the third driving pump 73, one part of the collected return water returns to the condensing part of the water source heat pump to absorb heat in the refrigerant, the temperature of the collected return water rises to 45 ℃ and then enters the water separator 40, the other part of the collected return water returns to the waste heat recovery unit 31 after being pressurized by the first driving pump 71, the collected return water is heated to 45 ℃ by the waste heat and then enters the water separator 40, and the circulation can realize the reutilization of the waste heat energy of the waste heat generation equipment by the waste heat recovery unit 31, so that the utilization rate of energy is improved, the water source heat pump can be used for supplying heat to the air conditioning unit 10, and the heat supply efficiency of the whole water temperature adjusting unit is improved. In this embodiment, a waste heat utilization coupling cascade heat pump heating mode is adopted, and a combined structure of the waste heat recovery unit 31, the first water source heat pump 331, the first water storage tank 341 and the second air source heat pump 322 is adopted to heat the air conditioning unit 10.

Specifically, as shown in fig. 4, the low-temperature heat source of the first water source heat pump 331 is obtained by the second air source heat pump 322, and on the side of the second air source heat pump 322, the water in the first water storage tank 341 is pressurized by the fourth driving heat pump 74 and then enters the condenser of the second air source heat pump 322 to absorb the heat in the refrigerant, and the temperature is raised by 5 ℃ and then returned to the first water storage tank 341, and the process is repeated. On the first waterhead heat pump 331 side, the water in the first reservoir 341 is pressurized by the fifth driving pump 75 and then enters the evaporator of the first waterhead heat pump 331, releases heat to the refrigerant, and returns to the first reservoir 341 after the temperature is reduced by 5 ℃.

Specifically, in the present embodiment, as shown in fig. 4, a third driving pump 73 is disposed between the first water source heat pump 331 and the water collector 20, a fourth driving pump 74 is disposed between the first water tank 341 and the second air source heat pump, and a fifth driving pump 75 is disposed between the first water tank 341 and the first water source heat pump 331. The driving pump can drive liquid, so that the whole temperature adjusting system circulates, and the reliability is improved.

Specifically, in this embodiment, as shown in fig. 4, the water temperature adjusting unit further includes a second water replenishing device 52, an outlet end of the second water replenishing device 52 is respectively communicated with an outlet end of the water collector 20 and the first water storage tank 341, when the pressure at the constant pressure point between the water collector 20 and the third driving pump 73 changes (the cause is that the water body expands and contracts due to temperature fluctuation and leaks), or when the water level of the first water storage tank 341 falls below a set value, the ball float valve 3411 in the first water storage tank 341 is automatically opened, the second water replenishing device 52 is automatically opened, and the water is softened water and is prepared by the softened water device.

Specifically, in this embodiment, as shown in fig. 4, control valves 60 are respectively disposed between the second water replenishing device 52 and the first water storage tank 341, the outlet end and the inlet end of the condensation portion 3311 of the first water source heat pump, the inlet end and the outlet end of the evaporation portion 3312 of the first water source heat pump, the outlet end and the inlet end of the first water storage tank 341, and the outlet end and the inlet end of the second air source heat pump 322, so as to control the on-off states of the respective passages and ports, facilitate the switching of the modes, and improve the reliability.

In a fourth embodiment of the present invention, as shown in fig. 5 and 6, the water temperature adjusting unit includes a third air source heat pump 323 and a sixth driving heat pump 76, an inlet end of the sixth driving heat pump 76 is communicated with the water collector 20, an outlet end of the sixth driving heat pump 76 is communicated with an inlet end of the third air source heat pump, an outlet end of the third air source heat pump is communicated with the water separator 40, and the third air source heat pump can heat or cool the liquid flowing out of the water collector 20. In this embodiment, as shown in fig. 5, the hot water of 45 ℃ produced by the third air source heat pump 323 enters the water separator 40, is distributed to the ends of a plurality of air conditioners to produce hot air for heating, and returns to the water collector 20 after the temperature is reduced to 40 ℃. The collected return water is pressurized by the sixth driving pump 76 and then returns to the condenser of the third air source heat pump 323 to absorb heat in the refrigerant, and enters the water separator 40 after the temperature is raised to 45 ℃, so that the third air source heat pump 323 can be used for supplying heat to the air conditioning unit 10, and the heat supply efficiency of the whole water temperature adjusting unit is improved. The present embodiment may be an air source heat pump heating mode, and the third air source heat pump 323 is used to heat the air conditioning unit 10.

Further, as shown in fig. 6, the cold water of 7 ℃ produced by the third air source heat pump 323 enters the water separator 40, is distributed to the ends of a plurality of air conditioners, is used for producing cold air for air conditioning, and returns to the water collector 20 after the temperature rises to 15 ℃, the collected return water returns to the evaporator of the third air source heat pump 323 after being pressurized by the sixth driving heat pump 76, releases heat to the refrigerant, and enters the water separator 40 after the temperature drops to 7 ℃, and by such circulation, the air conditioning unit 10 can be refrigerated by using the third air source heat pump 323, and the heating efficiency of the whole water temperature adjusting unit is improved. In this embodiment, the air-source heat pump air conditioning mode may also be adopted, and the third air-source heat pump 323 is used to cool the air conditioning unit 10.

Specifically, as shown in fig. 5 and 6, the temperature adjusting system in this embodiment further includes a third water replenishing device 53, and an outlet end of the third water replenishing device 53 is communicated with an inlet end of the water collector 20. When the pressure at the constant pressure point between the sump 20 and the sixth driving pump 76 is changed (the reason is that the water body expands and contracts due to temperature fluctuation and leakage occurs), the third water replenishing device 53 is automatically turned on, and the water is softened water and is prepared by the softened water device.

Specifically, in this embodiment, as shown in fig. 5 and 6, control valves 60 are disposed between the water collector 20 and the air conditioning unit 10, between the air conditioning unit 10 and the water separator 40, at the outlet end of the third water replenishing device 53, between the water collector 20 and the third air source heat pump, and between the third air source heat pump and the water separator 40, and the control valves 60 can control on and off of respective passages and ports, so as to switch different modes, thereby improving reliability.

In a fifth embodiment of the present invention, as shown in fig. 7, in addition to the fourth embodiment, the water temperature adjusting unit further includes a second water source heat pump 332 and a first cooling tower 351, an outlet end of the water collector 20 communicates with an inlet end of an evaporation portion 3322 of the second water source heat pump, an outlet end of the evaporation portion 3322 of the second water source heat pump communicates with the water separator 40, an inlet end of the first cooling tower 351 communicates with an outlet end of a condensation portion 3321 of the second water source heat pump, and an outlet end of the first cooling tower 351 communicates with an inlet end of the condensation portion 3321 of the second water source heat pump. In this embodiment, the cold water at 7 ℃ produced by the second water source heat pump 332 and the third air source heat pump 323 enters the water separator 40, is distributed to the ends of multiple groups of air conditioners and is used for producing cold air for air conditioners, the cold water returns to the water collector 20 after the temperature is raised to 15 ℃, a part of collected return water returns to the evaporation part 3322 of the second water source heat pump after being pressurized by the sixth water pump, heat is released to the refrigerant, the cold water enters the water separator 40 after the temperature is lowered to 7 ℃, the other part of the return water returns to the evaporator of the third air source heat pump 323, heat is released to the refrigerant, the cold water enters the water separator 40 after the temperature is lowered to 7 ℃, and by circulating the above steps, the air conditioning unit 10 can be refrigerated by using the second water source heat pump 332, the first cooling tower 351 and the third air source heat pump 323, and the refrigeration efficiency of the whole water temperature adjusting unit is improved. In this embodiment, a water source heat pump and air source heat pump coupled air conditioning mode may be adopted, and a combined structure of the second water source heat pump 332, the first cooling tower 351 and the third air source heat pump 323 is adopted to refrigerate the air conditioning unit 10.

Specifically, in the present embodiment, as shown in fig. 7, the effluent of the first cooling tower 351 is pressurized by the first air-driven pump, enters the condensation portion 3321 of the second water-source heat pump, absorbs heat in the refrigerant, rises in temperature by 5 ℃, returns to the first cooling tower 351, and circulates in this way.

Specifically, in the present embodiment, as shown in fig. 7, a sixth driving pump 76 is provided between the sump 20 and the second water source heat pump 332, and a seventh driving pump 77 is provided between the first cooling tower 351 and the second water source heat pump 332. The structure of water pump can drive liquid, and then makes whole temperature regulation system circulate, has promoted the reliability.

Specifically, in this embodiment, as shown in fig. 7, a first backwash filter 3511 is further disposed at an inlet end of the first cooling tower 351, so as to remove suspended matters and particles in the water body, reduce turbidity, purify the water quality, and reduce system dirt, bacteria, algae, rust and the like, thereby improving the water quality and protecting the normal operation of the equipment.

Specifically, in the present embodiment, as shown in fig. 7, control valves 60 are disposed at the inlet end and the outlet end of the third air source heat pump, the inlet end and the outlet end of the first cooling tower 351, the outlet end and the inlet end of the condensation portion 3321 of the second water source heat pump, the outlet end and the inlet end of the evaporation portion 3322 of the second water source heat pump, between the water separator 40 and the air conditioning unit 10, and between the air conditioning unit 10 and the water collector 20, and the control valves 60 can control the on-off of the respective passages and ports, thereby switching between different modes and improving reliability.

In the sixth embodiment of the present invention, as shown in fig. 8, the water temperature adjusting unit includes a fourth air-source heat pump 324, a third water-source heat pump 333 and a second water storage tank 342, an outlet end of the water collector 20 communicates with an inlet end of the condensing portion 3331 of the third water-source heat pump, an outlet end of the condensing portion 3331 of the third water-source heat pump communicates with the water separator 40, an outlet end of the evaporating portion 3332 of the third water-source heat pump communicates with an inlet end of the fourth air-source heat pump 324 through the second water storage tank 342, and an outlet end of the fourth air-source heat pump 324 communicates with an inlet end of the evaporating portion 3332 of the third water-source heat pump through the second water storage tank 342. In this embodiment, the hot water of 45 ℃ prepared by the third water source heat pump 333 enters the water separator 40, is distributed to the ends of a plurality of groups of air conditioners, is used for preparing hot air for heating, returns to the water collector 20 after the temperature is reduced to 40 ℃, returns to the condensation part of the water source heat pump after the collected backwater is pressurized by the eighth driving pump 78, absorbs heat in the refrigerant, and enters the water separator 40 after the temperature is increased to 45 ℃, and by such circulation, the third water source heat pump 333, the second water storage tank 342 and the fourth air source heat pump can be used for supplying heat to the air conditioning unit 10, so that the heat supply efficiency of the whole water temperature adjusting unit is improved. The present embodiment may be a cascade heat pump heating mode, and the air conditioning unit 10 is heated by using a combination structure of the fourth air source heat pump 324, the second water storage tank 342, and the third water source heat pump 333.

Specifically, in the present embodiment, as shown in fig. 8, the low-temperature heat source of the third water-source heat pump 333 is obtained by the fourth air-source heat pump 324, and on the side of the fourth air-source heat pump 324, the water in the second water storage tank 342 is pressurized by the ninth driving pump 79 and then enters the condenser of the fourth air-source heat pump 324, absorbs the heat in the refrigerant, and after the temperature is raised by 5 ℃, the water returns to the second water storage tank 342, and in this way, on the side of the third water-source heat pump 333, the water in the second water storage tank 342 enters the evaporator of the third water-source heat pump 333 after being pressurized by the tenth driving pump 710, releases the heat to the refrigerant, and after the temperature is lowered by 5 ℃, the water returns to the second water storage tank 342, and in this way, the cycle is performed.

Specifically, as shown in fig. 8, when the water level of the second water storage tank 342 drops below the set value, the ball float 3411 in the second water storage tank 342 is automatically turned on, the third water replenishing device 53 is automatically turned on, and the water is softened and is prepared by the softened water device.

In the present embodiment, as shown in fig. 8, an eighth driving pump 78 is provided between the third water source heat pump 333 and the water collector 20, a ninth driving pump 79 is provided between the second water tank 342 and the fourth air source heat pump, and a tenth driving pump 710 is provided between the second water tank 342 and the third water source heat pump 333. The structure of the driving pump can drive liquid, so that the whole temperature adjusting system is circulated, and the reliability is improved.

Specifically, in this embodiment, as shown in fig. 8, the outlet end and the inlet end of the fourth air source, the inlet end and the outlet end of the condensation portion 3331 of the third water source heat pump, and the inlet end and the outlet end of the evaporation portion 3332 of the third water source heat pump are all provided with control valves 60, and the control valves 60 can control the on-off of the respective passages and ports, so as to switch different modes, thereby improving reliability.

Specifically, in this embodiment, as shown in fig. 8, the temperature adjustment system further includes a fourth water supply device 54, an outlet end of the fourth water supply device 54 is communicated with an outlet end of the water collector 20, when the pressure at the constant pressure point between the water collector 20 and the eighth water pump changes (the cause is that firstly, the water body expands and contracts due to temperature fluctuation, and secondly, leakage occurs), the fourth water supply device 54 is automatically opened, and the water supply is softened water and is prepared by the softened water device.

In the seventh embodiment of the present invention, as shown in fig. 9, the water temperature adjusting unit includes a fourth water source heat pump and a second cooling tower 352, an outlet end of the water collector 20 communicates with an inlet end of an evaporation part of the fourth water source heat pump, an outlet end of the evaporation part of the fourth water source heat pump communicates with the water separator 40, an inlet end of the second cooling tower 352 communicates with an outlet end of a condensation part of the fourth water source heat pump, and an outlet end of the second cooling tower 352 communicates with an inlet end of the condensation part of the fourth water source heat pump. In this embodiment, the cold water of 7 ℃ produced by the fourth water source heat pump enters the water separator 40, is distributed to the ends of a plurality of air conditioners, is used for producing cold air for air conditioners, returns to the water collector 20 after the temperature is increased to 15 ℃, returns to the evaporation part of the fourth water source heat pump after the collected return water is pressurized by the first water pump 81 (the action is the same as that of the driving pump), releases heat to the refrigerant, and enters the water separator 40 after the temperature is reduced to 7 ℃, and by such circulation, the air conditioning unit 10 can be refrigerated by using the fourth water source heat pump and the second cooling tower 352, so that the refrigeration efficiency of the whole water temperature adjusting unit is improved. The present embodiment may be in a water source heat pump air conditioning mode, and the combined structure of the fourth water source heat pump and the second cooling tower 352 is adopted to cool the air conditioning unit 10.

Specifically, in the present embodiment, as shown in fig. 9, the effluent of the second cooling tower 352 is pressurized by the second water pump 82 (the function is the same as that of the driving pump), enters the condensation portion of the fourth water-source heat pump, absorbs heat in the refrigerant, rises in temperature by 5 ℃, returns to the cooling tower, and circulates in this way.

Specifically, in this embodiment, as shown in fig. 9, the temperature adjustment system further includes a fifth water replenishing device, and when the pressure at the constant pressure point between the water collector 20 and the first water pump 81 changes (the cause is that the expansion and contraction of the water body due to temperature fluctuation occurs, and the leakage occurs, the fifth water replenishing device is automatically turned on, and the water is softened water and is prepared by the softened water replenishing device.

Specifically, in the present embodiment, as shown in fig. 9, a first water pump 81 is provided between the water collector 20 and the fourth water source heat pump, and a second water pump 82 is provided between the second cooling tower 352 and the fourth water source heat pump. The structure of water pump can drive liquid, and then makes whole temperature regulation system circulate, has promoted the reliability.

Specifically, in this embodiment, as shown in fig. 9, a second backwashing filter 3521 is further disposed at an inlet end of the second cooling tower 352, so as to remove suspended matters and particles in the water body, reduce turbidity, purify the water, and reduce system dirt, bacteria, algae, corrosion, etc. to improve the water quality and protect the normal operation of the equipment.

Specifically, in this embodiment, as shown in fig. 9, control valves 60 are disposed at the inlet end and the outlet end of the second cooling tower 352, the outlet end of the fifth water replenishing device, the outlet end and the inlet end of the condensation portion of the fourth water source heat pump, the outlet end and the inlet end of the evaporation portion of the fourth water source heat pump, between the water separator 40 and the air conditioning unit 10, and between the air conditioning unit 10 and the water collector 20, and the control valves 60 can control the on-off of the respective passages and ports, so as to switch different modes, thereby improving reliability.

Furthermore, the system of the invention is operated in the way that the boot load rate and the number of boot devices are determined, guidance is provided for the operation strategy, and the system is guaranteed to give full play to the advantages.

When heating is needed, a heating mode of Yu Feire is preferably used. When the residual waste heat resources are insufficient, a Yu Feire coupling cascade heat pump heating mode is selected. When the residual waste heat resources are insufficient and the water source heat pump fails, a heating mode of Yu Feire by utilizing the coupled air source heat pump is selected. When no residual waste heat resource exists, a cascade heat pump heating mode is selected. When no residual waste heat resource exists and the water source heat pump fails, an air source heat pump heating mode is selected.

When refrigeration is needed, the water source heat pump air conditioning mode is preferably selected. When the water source heat pump is in failure, an air source heat pump air conditioning mode is selected. When extreme weather (the ambient temperature is higher than the outdoor calculated temperature of the air conditioner in summer), the air conditioning mode of coupling the water source heat pump with the air source heat pump is selected.

Specifically, the installed capacity of the water source heat pump is matched with a plurality of units according to the design load, the total installed heating capacity is equal to or slightly larger than the heating design heat load, and the total installed refrigerating capacity is equal to or slightly larger than the air conditioner design cold load.

The invention also provides a method for calculating the numerical value of the loading machine of the air source heat pump, which is implemented according to the temperature regulation system and is characterized by comprising the following steps:

respectively acquiring heating load and refrigerating load of an air source heat pump;

and obtaining the numerical value of the machine loading platform of the air source heat pump according to the heating load and the refrigerating load.

Specifically, the reasonable configuration of the system is to reasonably determine the capacity and the number of the devices, provide a model selection basis for design, and is the basis for fully exerting the advantages of the system. The key of the reasonable configuration of the system is to determine the installed capacity and the number of the air source heat pumps and the water source heat pumps. The calculation method is applicable to any one of the above embodiments with an air source heat pump.

Heating design heat load:

Q _{heat generation} ＝q _{Heat generation} ×S _{Heat generation}

Wherein: q _{Heat generation} Designing heat load, kW, for heating; q. q.s _{Heat generation} Is a heating heat index of kW/m ² ；S _{Heat generation} M is the area of the building to be heated ² 。

Designing a cold load of the air conditioner:

Q _cold ＝q _Cold ×S _Cold

Wherein: q _{Cooling by cooling} Designing a cooling load, kW, for the air conditioner; q. q.s _Cold Is an index of air conditioner cooling, kW/m ² ；S _Cold Is the building area of the air-conditioned building, m ² 。

The installed capacity of the water source heat pump is matched with a plurality of units according to the design load, the total installed heating capacity is equal to or slightly larger than the heating design heat load, and the total installed refrigerating capacity is equal to or slightly larger than the air conditioner design cold load.

On one hand, the air source heat pump needs to ensure that heat required by heating is prepared in an air source heat pump heating mode, on the other hand, the low-temperature heat source heat required by a water source heat pump is prepared in a cascade heat pump heating mode, on the other hand, the cold required by air conditioning is prepared in an air source heat pump air conditioning mode, and then the air source heat pump is provided with the following units:

wherein: n is the number of the air source heat pumps; q _{Nominal heat} The nominal heating capacity of a single air source heat pump is kW; beta is the lowest room corresponding to the operation of the air source heat pump in the heating modeThe air source heat pump heating capacity correction coefficient under the external temperature; 1-2, considering equipment maintenance and overhaul, and reserving 1-2 devices; gamma is the heating performance coefficient of the water source heat pump in the cascade heat pump heating mode; calculating a heating capacity correction coefficient of the air source heat pump at the heating outdoor temperature; q _{Nominally, cold} The nominal refrigerating capacity is kW of a single air source heat pump; _η refrigerating capacity correction coefficient of air source heat pump for outdoor calculation temperature of air conditioner

The total nominal heating capacity of the air source heat pump is as follows:

Q _{nominal, heat, total} ＝N×Q _{Nominal heat}

The total nominal refrigerating capacity of the air source heat pump is as follows:

Q _{nominal, cold, total} ＝N×Q _{Nominally, cold}

The invention also provides a calculation method of the outlet water temperature of the air source heat pump, which is implemented according to the temperature regulation system and is characterized by comprising the following steps:

respectively acquiring the outlet water temperature and the ambient temperature of a plurality of groups of air source heat pumps;

obtaining an actual input power model of the air source heat pump according to the outlet water temperature and the environment temperature of the multiple groups of air source heat pumps;

respectively acquiring the outlet water temperatures of a plurality of groups of air source heat pumps;

obtaining an actual heating quantity model of the water source heat pump according to the outlet water temperatures of the multiple groups of air source heat pumps;

establishing an optimized operation model according to an actual power input model of the air source heat pump and an actual heating quantity model of the water source heat pump;

acquiring the actual environment temperature;

and calculating the outlet water temperature of the air source heat pump according to the actual environment temperature and the optimized operation model.

Specifically, in this embodiment, first, through simulation calculation or experiment, the actual heating input power W of the air source heat pump at different ambient temperatures T and different water outlet temperatures T is obtained _{In fact} . Then obtaining W through data curve fitting _{Empty, actual} (T，t)。

Secondly, obtaining the actual heating quantity Q of the water source heat pump under different low-temperature heat source temperatures (namely the water outlet temperature t of the air source heat pump) through simulation calculation or experiments _{Water, practice} Actual heating input power W _{Water, reality} The total power consumption W of the sixth drive pump 76 and the seventh drive pump 77 _{Water pump} . And then obtaining Q water, actual (t), W water and actual (t) through data curve fitting, and further obtaining the cascade heat pump COP _{Multiple folding} (T，t)＝Q _{Water, reality} (t)/(W _{Empty, actual} (T，t)+W _{Water, reality} (t)+W _{Water pump} )＝f(t)。

Finally, an optimized operation model is established, and the objective function is max f (t); constraint condition is t _{Lower part} <t<t _{On the upper part} . Wherein: t is t _{Lower part} The lowest outlet water temperature of the air source heat pump is determined through simulation calculation or experiments; t is t _{On the upper part} The maximum water inlet temperature of the water source heat pump is determined through simulation calculation or experiments.

Accordingly, the optimal outlet water temperature T of the air source heat pump under different environmental temperatures T can be calculated and obtained.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Numerous obvious variations, adaptations and substitutions will occur to those skilled in the art without departing from the scope of the invention. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (9)

1. A method for calculating the outlet water temperature of an air source heat pump is implemented according to a temperature regulation system,

the temperature regulation system includes:

the heat supply system comprises an air conditioning unit (10), wherein the air conditioning unit (10) comprises a plurality of groups of air conditioning tail ends, and the plurality of groups of air conditioning tail ends respectively correspond to a plurality of heat points to be supplied;

the outlet ends of the tail ends of the air conditioners are respectively communicated with the inlet end of the water collector (20);

the inlet end of the water temperature adjusting unit is communicated with the outlet end of the water collector (20), and the water temperature adjusting unit can heat or refrigerate the liquid flowing out of the water collector (20);

the inlet end of the water distributor (40) is communicated with the outlet end of the water temperature adjusting unit, and the outlet end of the water distributor (40) is respectively communicated with the inlet ends of the tail ends of the air conditioners;

the water temperature adjusting unit comprises a third air source heat pump and a sixth driving heat pump (76), the inlet end of the sixth driving heat pump (76) is communicated with the water collector (20), the outlet end of the sixth driving heat pump (76) is communicated with the inlet end of the third air source heat pump, the outlet end of the third air source heat pump is communicated with the water separator (40), and the third air source heat pump can heat or refrigerate liquid flowing out of the water collector (20);

the water temperature adjusting unit comprises a second water source heat pump (332) and a first cooling tower (351), wherein the outlet end of the water collector (20) is communicated with the inlet end of the evaporation part of the second water source heat pump (332), the outlet end of the evaporation part of the second water source heat pump (332) is communicated with the water separator (40), the inlet end of the first cooling tower (351) is communicated with the outlet end of the condensation part of the second water source heat pump (332), and the outlet end of the first cooling tower (351) is communicated with the inlet end of the condensation part of the second water source heat pump (332);

a seventh driving pump (77) is arranged between the first cooling tower (351) and the second water source heat pump (332);

it is characterized by comprising:

respectively acquiring the outlet water temperature and the ambient temperature of a plurality of groups of air source heat pumps;

obtaining an actual input power model of the air source heat pump according to the outlet water temperature and the environment temperature of the multiple groups of air source heat pumps;

respectively acquiring the outlet water temperatures of a plurality of groups of air source heat pumps;

obtaining an actual heating quantity model of the water source heat pump according to the outlet water temperatures of the multiple groups of air source heat pumps;

establishing an optimized operation model according to an actual power input model of the air source heat pump and an actual heating quantity model of the water source heat pump;

the actual heating quantity Q of the water source heat pump at different low-temperature heat source temperatures, namely the outlet water temperature t of the air source heat pump is obtained through simulation calculation or experiments _{Water, reality} Actual heating input power W _{Water, reality} The total power consumption W of the sixth drive pump (76) and the seventh drive pump (77) _{Water pump} (ii) a And then obtaining Q water, actual (t), W water and actual (t) through data curve fitting, and further obtaining the cascade heat pump COP _{Multiple folding} (T，t)=Q _{Water, reality} (t)/(W _{Empty, actual} (T，t)+W _{Water, reality} (t)+W _{Water pump} )=f(t)；

Establishing an optimized operation model with an objective function of max f (t); constraint condition is t _{Lower part} <t<t _{On the upper part} (ii) a Wherein: t is t _{Lower part} The lowest outlet water temperature of the air source heat pump is determined through simulation calculation or experiments; t is t _{On the upper part} The maximum water inlet temperature of the water source heat pump is determined through simulation calculation or experiments;

acquiring the actual environment temperature;

and calculating the outlet water temperature of the air source heat pump according to the actual environment temperature and the optimized operation model.

2. The method for calculating the outlet water temperature of the air source heat pump according to claim 1, wherein the water temperature adjusting unit comprises a waste heat recovery unit (31) and a first driving pump (71), a first inlet end of the waste heat recovery unit (31) is used for being communicated with a waste heat generating device, a second inlet end of the waste heat recovery unit (31) is communicated with an outlet end of the first driving pump (71), an outlet end of the waste heat recovery unit (31) is communicated with the water separator (40), and an inlet end of the first driving pump (71) is communicated with the water collector (20).

3. The method for calculating the leaving water temperature of an air source heat pump according to claim 2, wherein the water temperature adjusting unit comprises a first air source heat pump (321) and a second drive heat pump (72), the second drive heat pump (72) is located between the water collector (20) and the first drive heat pump (71), the inlet end of the second drive heat pump (72) is communicated with the water collector (20), the first outlet end of the second drive heat pump (72) is communicated with the inlet end of the first drive heat pump (71), the second outlet end of the second drive heat pump (72) is communicated with the inlet end of the first air source heat pump (321), and the outlet end of the first air source heat pump (321) is communicated with the water separator (40).

4. The method for calculating the leaving water temperature of an air source heat pump according to claim 2, wherein the water temperature regulating unit comprises a first water source heat pump (331), a first water storage tank (341) and a second air source heat pump (322), the outlet end of the water collector (20) is communicated with the inlet end of the condensation part of the first water source heat pump (331), the outlet end of the condensation part of the first water source heat pump (331) is communicated with the water separator (40), the outlet end of the evaporation part of the first water source heat pump (331) is communicated with the inlet end of the second air source heat pump (322) through the first water storage tank (341), and the outlet end of the second air source heat pump (322) is communicated with the inlet end of the evaporation part of the first water source heat pump (331) through the first water storage tank (341).

5. The method for calculating the leaving water temperature of the air source heat pump according to claim 4, wherein a third driving pump (73) is arranged between the first water source heat pump (331) and the water collector (20), a fourth driving pump (74) is arranged between the first water storage tank (341) and the second air source heat pump, and a fifth driving pump (75) is arranged between the first water storage tank (341) and the first water source heat pump (331).

6. The method for calculating the leaving water temperature of an air source heat pump according to claim 1, wherein the water temperature adjusting unit comprises a fourth air source heat pump (324), a third water source heat pump (333) and a second water storage tank (342), the outlet end of the water collector (20) is communicated with the inlet end of the condensing part of the third water source heat pump (333), the outlet end of the condensing part of the third water source heat pump (333) is communicated with the water separator (40), the outlet end of the evaporating part of the third water source heat pump (333) is communicated with the inlet end of the fourth air source heat pump (324) through the second water storage tank (342), and the outlet end of the fourth air source heat pump (324) is communicated with the inlet end of the evaporating part of the third water source heat pump (333) through the second water storage tank (342).

7. The method for calculating the leaving water temperature of an air source heat pump according to claim 6, characterized in that an eighth driving pump (78) is arranged between the third water source heat pump (333) and the water collector (20), a ninth driving pump (79) is arranged between the second water storage tank (342) and the fourth air source heat pump, and a tenth driving pump (710) is arranged between the second water storage tank (342) and the third water source heat pump (333).

8. The method for calculating the leaving water temperature of an air source heat pump according to claim 1, wherein the water temperature regulating unit comprises a fourth water source heat pump and a second cooling tower (352), the outlet end of the water collector (20) is communicated with the inlet end of the evaporation part of the fourth water source heat pump, the outlet end of the evaporation part of the fourth water source heat pump is communicated with the water separator (40), the inlet end of the second cooling tower (352) is communicated with the outlet end of the condensation part of the fourth water source heat pump, and the outlet end of the second cooling tower (352) is communicated with the inlet end of the condensation part of the fourth water source heat pump.

9. The method for calculating the leaving water temperature of the air source heat pump according to claim 8, characterized in that a first water pump (81) is arranged between the water collector (20) and the fourth water source heat pump, and a second water pump (82) is arranged between the second cooling tower (352) and the fourth water source heat pump.

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