CN209101601U - Based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU) - Google Patents

Based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU) Download PDF

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Publication number
CN209101601U
CN209101601U CN201821985631.3U CN201821985631U CN209101601U CN 209101601 U CN209101601 U CN 209101601U CN 201821985631 U CN201821985631 U CN 201821985631U CN 209101601 U CN209101601 U CN 209101601U
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heat
compressor
exchanging part
heat exchanging
htu
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Inventor
李越峰
张娣
袁竹
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Sichuan Jia Gang Technology Co Ltd
Sichuan Changhong Air Conditioner Co Ltd
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Sichuan Jia Gang Technology Co Ltd
Sichuan Changhong Air Conditioner Co Ltd
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Abstract

The utility model discloses the indoor temperature control systems in parallel with heat transfer unit (HTU) of the air-conditioning based on double-compressor, including outdoor unit, indoor unit and heat transfer unit (HTU), outdoor unit includes the first compressor, first liquid storage device, first four-way valve, second compressor, second liquid storage device, second four-way valve and outdoor heat exchanger, outdoor heat exchanger includes the first heat exchanging part and the second heat exchanging part, first compressor of indoor unit and outdoor unit, first liquid storage device, first four-way valve, first heat exchanging part connects to form flow cycle one, second compressor of heat transfer unit (HTU) and outdoor unit, second liquid storage device, second four-way valve, second heat exchanging part connects to form flow cycle two.The utility model forms two independent flow cycles using double-compressor, can avoid noise and system reliability reduces, it is precisely controlled capacity, heat preservation dehumidifying, heat preservation defrosting and quickly heat exchange is realized, flow cycle is also changed by control valve and triple valve and realizes more efficient independent heat exchange.

Description

Based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU)
Technical field
The utility model belongs to air-conditioning technical field, and in particular to based on the air-conditioning of double-compressor room in parallel with heat transfer unit (HTU) Interior temperature control system.
Background technique
Since traditional compressor only has a liquid storage device, therefore an only compressor inlet, and in air conditioner indoor unit In the indoor temperature control system in parallel with heat transfer unit (HTU), exchanged heat using indoor heat exchanger and heat transfer unit (HTU) independent control to interior Or dehumidifying movement, but when the interior temperature control system enters dehumidification mode, the evaporating temperature of indoor heat exchanger is needed due to dehumidifying Lower than the dew-point temperature of room air, such as 8 DEG C or lower, and under normal indoor refrigeration mode, indoor heat exchanger and heat transfer dress The evaporating temperature set is higher, and such as 18 DEG C or higher (because the heat exchange area of heat transfer unit (HTU) is larger, exchange heat quickly, so evaporation temperature It spends higher);Based on the above circumstances, on the one hand, when the system enters the room dehumidification mode, if setting indoor heat exchanger and heat transfer The evaporating temperature of device is different, then will appear the refrigerant outlet pressure of indoor heat exchanger pipeline far below heat transfer unit (HTU) pipeline The case where refrigerant outlet pressure, the refrigerant circuit of two kinds of different pressures can generate mixing pulsation, to generate noise or shadow Ring pipe-line system functional reliability;On the other hand, what dehumidification mode refrigerant was walked is refrigeration cycle, the temperature of indoor heat exchanger at For evaporating temperature, and what heating mode refrigerant was walked is heating circulation, and the temperature of indoor heat exchanger becomes condensation temperature, due to room Refrigerant flow direction in external heat exchanger cannot be on the contrary, can not be achieved refrigerant a part with the same compressor walks refrigeration cycle A part walks heating circulation, naturally also just cannot achieve and maintains room temperature in dehumidifying, results in current air-conditioning system in this way System is wanted to realize dehumidification mode, will necessarily room temperature be reduced, cause the sense of discomfort of user's cold.Since different steamings are arranged Hair temperature can cause variety of problems as described above, and such interior temperature control system can not be only by the temperature of the system, humidity The advantages of vertical dual control, effectively plays.
As for being proposed before using duplex cylinder compressor+bis- liquid storage devices mode, although two kinds of different evaporations may be implemented Temperature, but due to being compressed using the same compressor, the swept volume of compressor first be it is certain, dehumidifying It needs for refrigerant to be divided into two parts in the process to respectively enter in indoor heat exchanger and heat transfer unit (HTU), although can pass through herein Respective throttling set realizes different evaporating temperatures, but can cause energy waste using insufficient due to refrigerant.
Specifically, the double liquid storage devices of twin-tub are by sucking the refrigerant of different evaporating pressures in two cylinders, then cooperate twin-tub Swept volume Bizet be able to achieve again under the compression of same electric machine frequency, capacity is certain, and refrigerant enters subsequent cycle, but presses What the twin-tub swept volume of contracting machine was usually fixed at the very start, therefore swept volume is fixed and invariable than also, it can not be according to two It is that the actual ratio of condensation temperature changes to cooperate, such as preferably dehumidifies that a evaporating temperature even one, which is evaporating temperature one, Evaporating temperature be 8 DEG C, refrigeration evaporator temperature be 18 DEG C, when practically necessary indoor unit evaporating temperature be 5 DEG C, refrigeration evaporator temperature When degree is 18 DEG C, since actual evaporation temperature causes evaporating pressure than different than difference, the twin-tub swept volume of regular collocation is just Capacity demand at this time cannot be met again, will cause that pressure at expulsion is excessive or too small influence capacity, so influence dehumidifying or Refrigeration effect;May capacity excessively be resulted in waste of resources if improving electric machine frequency, if keeping the constant possibility of electric machine frequency So that capacity deficiency is to form target evaporating temperature.
Utility model content
For the deficiency in the presence of the prior art, the utility model provides a kind of only using double-compressor composition two Vertical refrigerant flow cycle, the refrigerant that can avoid different pressures, which mix, causes noise and system reliability to reduce, can be accurate Control capacity, while avoid energy waste, can be realized heating using low evaporating temperature as indoor dehumidification, can be realized interior Quickly heat exchange, realize heat preservation dehumidifying, realize heat preservation defrosting, realize the more efficient air-conditioning based on double-compressor individually to exchange heat with Heat transfer unit (HTU) indoor temperature control system in parallel.
Based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU), including outdoor unit, indoor unit list Member and heat transfer unit (HTU), the outdoor unit include the first compressor, the first liquid storage device, the first four-way valve, the second compressor, the Two liquid storage devices, the second four-way valve and outdoor heat exchanger, the outdoor heat exchanger includes the first heat exchanging part and the second heat exchanging part, described Indoor unit includes indoor heat exchanger, the first compressor, the first liquid storage device, of the indoor unit and outdoor unit One four-way valve, the first heat exchanging part connect to form refrigerant flow cycle one, the second pressure of the heat transfer unit (HTU) and outdoor unit Contracting machine, the second liquid storage device, the second four-way valve, the second heat exchanging part connect to form refrigerant flow cycle two, the refrigerant circulation Circuit one and refrigerant flow cycle two respectively use one group of throttling set.
Further, it is equipped with connecting line between first heat exchanging part and the second heat exchanging part, is set on the connecting pipeline There is the control valve for being connected to and separating between the first heat exchanging part of control and the second heat exchanging part;First heat exchanging part and the first four-way valve Between pipeline be equipped with third triple valve, the branch C of the third triple valve is connected on the export pipeline of the second heat exchanging part, Branch A is connected to the first heat exchanging part, and branch B is connected to the first four-way valve;Company between the first heat exchanging part and the second heat exchanging part When taking over road connection, the branch A of the third triple valve is connected with C, branch B partition;When the first heat exchanging part and the second heat exchanging part Between connecting line partition when, the branch A of the third triple valve is connected with B, branch C separate.
Further, the heat transfer unit (HTU) includes capillary network radiating system and coupled heat exchanger, heat-transfer pipe and heat pipe coupling One of which in clutch, heat-transfer pipe.
Further, the displacement of second compressor is greater than the displacement of the first compressor.
Compared with the prior art, the utility model has the following beneficial effects:
The application is by using two compressors simultaneously in the air conditioner indoor unit indoor temperature control system in parallel with heat transfer unit (HTU) Outdoor heat exchanger is divided into two independent heat exchanging part, two heat exchanging part correspond respectively with indoor unit and heat transfer unit (HTU) Connection forms two independent flow cycles so that the refrigerant in two flow cycles independently circulates System realizes quickly heat exchange mode, individually heat exchange mode, heat preservation dehumidification mode and the operation for keeping the temperature the various modes such as defrosting mode. The effect specifically obtained is as follows:
1. noise caused by the refrigerant for avoiding different pressures mixes and system reliability reduce;2. can be according to reality The electric machine frequency for separately adjustable two compressors of evaporating temperature that border needs realizes accurately capacity;3. passing through exclusive use The compressor of certain swept volume provides refrigerant for indoor unit, adjusts exhaust outlet of compressor pressure as needed to have Effect avoids energy waste;4. can be realized heat transfer unit (HTU) while heating, indoor unit is removed using low evaporating temperature as interior It is wet;5. can be formed simultaneously using two compressors overall big when indoor unit and heat transfer unit (HTU) need heat supply simultaneously Capacity meets indoor quickly heat exchange;6. the heat preservation for carrying out outdoor unit heat exchanger defrosting in the state of keeping the temperature indoors may be implemented Defrosting mode guarantees the experience of user.The temperature for the indoor temperature control system that can make air conditioner indoor unit in parallel with heat transfer unit (HTU) in this way The characteristics of degree, humidity separate double control, can preferably play.In addition, the utility model also passes through setting control valve and third threeway Valve further improves independent heat exchange mode, and two heat exchanging part are connected and it is allowed to exchange heat jointly, hence it is evident that increase heat exchange Area effectively increases heat exchange efficiency.
Detailed description of the invention
Fig. 1 is the structural schematic diagram of the utility model embodiment 1;
Fig. 2 is the structural schematic diagram of the utility model embodiment 2.
Wherein, 1 outdoor unit, 101 first compressors, 102 first liquid storage devices, 103 first four-way valves, 104 first change Hot portion, 111 second compressors, 112 second liquid storage devices, 113 second four-way valves, 114 second heat exchanging part, 115 control valves, 116 Three triple valves, 20 indoor units, 201 indoor heat exchangers, 202 first throttling devices, 21 heat transfer unit (HTU)s, 211 coupled heat exchangers, 212 water pumps, 213 first triple valves, 214 second triple valves, 215 second throttling devices.
Specific embodiment
In order to which the technical means, creative features, achievable purpose and effectiveness for realizing utility model are easy to understand, below In conjunction with being specifically illustrating, the utility model is further described.
As shown in Figure 1, based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU), including outdoor unit 1, indoor unit 20 and heat transfer unit (HTU) 21, outdoor unit 1 include the first compressor 101, the first liquid storage device the 102, the 1st Port valve 103, the second compressor 111, the second liquid storage device 112, the second four-way valve 113 and outdoor heat exchanger, the outdoor heat exchanger Including the first heat exchanging part 104 and the second heat exchanging part 114, the indoor unit includes indoor heat exchanger 201, the indoor unit list Member 20 connects with the first compressor 101 of outdoor unit 1, the first liquid storage device 102, the first four-way valve 103, the first heat exchanging part 104 It connects to form refrigerant flow cycle one, the second compressor 111, the second liquid storage device of the heat transfer unit (HTU) 21 and outdoor unit 1 112, the second four-way valve 113, the connection of the second heat exchanging part 114 form refrigerant flow cycle two, the refrigerant flow cycle one One group of throttling set is respectively used with refrigerant flow cycle two.Heat transfer unit (HTU) can be heat-transfer pipe in this system, be also possible to Heat-transfer pipe and heat pipe coupler, can also be coupled heat exchanger and capillary network radiating system.
When system enters heat preservation dehumidification mode, two compressors start work, and indoor heat exchanger and heat transfer are filled Settable different evaporating temperature is set, the first heat exchanging part and the second heat exchanging part of outdoor heat exchanger are divided into two by throttling set Independent flow pipe, the first compressor, the first liquid storage device, the first four-way valve, the first heat exchanging part of outdoor heat exchanger and interior Machine unit constitutes independent loop dehumidification one, the second compressor, the second liquid storage device, the second four-way valve, outdoor heat exchanger second Heat exchanging part is connected with heat transfer unit (HTU) ties up temperature loops two in forming chamber.Two circuits undertake interior respectively with different evaporating temperatures and remove Work that is wet and maintaining room temperature constant.
When system enters individually heat exchange mode, the second compressor start works, and has refrigerant circulation in the second heat exchanging part, Second compressor provides refrigerant for coupled heat exchanger, and indoor radiation heat transfer device provides duration heat exchange for room air.Separately It can also individually be exchanged heat using refrigerant flow cycle one outside.
So the refrigerant for not only avoiding different pressures, which mixes caused noise and system reliability, to be reduced;Also Can separately adjustable two compressors of evaporating temperature according to actual needs electric machine frequency, realize accurately capacity;Lead to again It crosses and the compressor of certain swept volume is used alone provides refrigerant for indoor unit, adjust exhaust outlet of compressor as needed Pressure is to effectively avoid energy waste;Also it can be realized heat transfer unit (HTU) while heating, indoor unit is with low evaporation temperature Degree is indoor dehumidification;In addition, two compressors can be used simultaneously when indoor unit and heat transfer unit (HTU) need heat supply simultaneously It forms overall big capacity and meets indoor quickly heat exchange.
As a further optimization of the scheme , as shown in Fig. 2, being equipped with connection between first heat exchanging part and the second heat exchanging part Pipeline, the connecting pipeline are equipped with the control valve for being connected to and separating between the first heat exchanging part of control and the second heat exchanging part;It is described Pipeline between first heat exchanging part and the first four-way valve is equipped with third triple valve, and the branch C of the third triple valve is connected to On the export pipeline of second heat exchanging part, branch A is connected to the first heat exchanging part, and branch B is connected to the first four-way valve;Described 3rd 3 Port valve can be such that branch A connects with B or connect branch A with C.Connecting line between the first heat exchanging part and the second heat exchanging part When connection, the branch A of the third triple valve is connected with C, branch B partition;When between the first heat exchanging part and the second heat exchanging part When connecting line separates, the branch A of the third triple valve is connected with B, branch C partition.
When system enters individually heat exchange mode, the work of the second compressor start, the first heat exchanging part and the second heat exchanging part it Between connecting line connect, the branch A of third triple valve connects with C, and branch B separates, and the second compressor mentions for coupled heat exchanger For refrigerant, indoor radiation heat transfer device provides duration heat exchange for room air.This programme is by increasing control valve and third Triple valve can be realized the more efficient independent heat exchange mode of scheme compared with before.Although scheme before is also able to achieve individually Heat exchange mode, but outdoor heat exchanger only one of which heat exchanging part is operating, and can be by two heat exchanging part after utilization this programme It connects and it is allowed to exchange heat jointly, hence it is evident that increase heat exchange area, effectively increase heat exchange efficiency.
Embodiment 1:
As shown in Figure 1, based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU), including outdoor unit 1, indoor unit 20 and heat transfer unit (HTU) 21, outdoor unit 1 include the first compressor 101, the first liquid storage device the 102, the 1st Port valve 103, the second compressor 111, the second liquid storage device 112, the second four-way valve 113 and outdoor heat exchanger, the outdoor heat exchanger Including the first heat exchanging part 104 and the second heat exchanging part 114, the indoor unit includes indoor heat exchanger 201, the indoor unit list Member 20 connects with the first compressor 101 of outdoor unit 1, the first liquid storage device 102, the first four-way valve 103, the first heat exchanging part 104 It connects to form refrigerant flow cycle one, the second compressor 111, the second liquid storage device of the heat transfer unit (HTU) 21 and outdoor unit 1 112, the second four-way valve 113, the connection of the second heat exchanging part 114 form refrigerant flow cycle two, the refrigerant flow cycle one It further include first throttling device 202, the refrigerant flow cycle two further includes second throttling device 215.Institute in the present embodiment Heat transfer unit (HTU) is stated using capillary network radiating system and coupled heat exchanger.
The refrigerant flow cycle one is connected by such as under type: the first compressor 101 connects the first liquid storage device 102, the One four-way valve 103 respectively with first compressor 101, the first liquid storage device 102, indoor heat exchanger 201 and the first heat exchanging part 104 one end connection, 104 other end of the first heat exchanging part are connected to indoor heat exchanger 201 by first throttling device 202.
The refrigerant flow cycle two is connected by such as under type: the second compressor 111 connects the second liquid storage device 112, the Two four-way valves 113 respectively with second compressor 111, the second liquid storage device 112, coupled heat exchanger 211 and the second heat exchanging part 114 one end connection, 114 other end of the second heat exchanging part are connected to coupled heat exchanger 211 by second throttling device 215; The coupled heat exchanger 211 is connected to the first triple valve 213 by water pump 212, and the first triple valve 213 is radiated by capillary network The second triple valve 214 is connected to after system, second triple valve 214 is connected to coupled heat exchanger 211.
Wherein, the circulating direction of refrigerant is solid arrow direction shown in Fig. 1 in refrigeration mode, is made in heating mode The circulating direction of cryogen is dotted arrow direction shown in Fig. 1.
Embodiment 2:
As shown in Fig. 2, on the basis of 1 scheme of embodiment, between first heat exchanging part 104 and the second heat exchanging part 114 Equipped with connecting line, the connecting pipeline, which is equipped between the first heat exchanging part 104 of control and the second heat exchanging part 114, to be connected to and separates Control valve 115;Pipeline between first heat exchanging part 104 and the first four-way valve 103 is equipped with third triple valve 116, institute The branch C for stating third triple valve 116 is connected on the export pipeline of the second heat exchanging part 114;When the first heat exchanging part 104 and second is changed When connecting line between hot portion 114 is connected, the branch A of the third triple valve 116 is connected with C, branch B partition;When first When connecting line between heat exchanging part 104 and the second heat exchanging part 114 separates, the branch A of the third triple valve 116 is connected with B, Branch C partition.System enters individually heat exchange mode, the second compressor of the heat transfer unit (HTU) 21 and outdoor unit 1 at this time 111, the second liquid storage device 112, the second four-way valve 113, the second heat exchanging part 114, the first heat exchanging part 104, control valve the 115, the 3rd 3 The connection of port valve 116 forms refrigerant flow cycle three.
The refrigerant flow cycle three is connected by such as under type: the second compressor 111 connects the second liquid storage device 112, the Two four-way valves 113 respectively with second compressor 111, the second liquid storage device 112, coupled heat exchanger 211 and the second heat exchanging part 114 one end connection, second heat exchanging part 114 are connected to 104 one end of the first heat exchanging part by control valve 115, and described first The heat exchanging part other end is connected to 116A mouthfuls of third triple valve, and 116B mouthfuls of the third triple valve is connected to the second heat exchanging part 114 The other end, 114 other end of the second heat exchanging part are connected to coupled heat exchanger 211 by second throttling device 215;The coupling Heat exchanger 211 is connected to the first triple valve 213 by water pump 212, and the first triple valve 213 connects after capillary network radiating system It is connected to the second triple valve 214, second triple valve 214 is connected to coupled heat exchanger 211.
On the whole, this system includes but is not limited to following operational mode: quickly exchange heat mode, and individually exchange heat mode, protects Warm dehumidification mode and heat preservation defrosting mode.Now it is described as follows with heat transfer unit (HTU) using the scheme of coupled heat exchanger:
Quickly exchange heat mode: a first compressor and a second compressor starts work, the first heat exchanging part and the second heat exchanging part Between connecting line truncation, the second compressor is that coupled heat exchanger provides refrigerant, and the first compressor is indoor set heat exchanger Refrigerant is provided, the heat transfer unit (HTU) and indoor set heat exchanger of indoor radiation are room air heat exchange simultaneously.
Individually exchange heat mode: the work of the second compressor start, the connecting line between the first heat exchanging part and the second heat exchanging part It connects, yellow pipeline is connected, and the second compressor provides refrigerant for coupled heat exchanger, and the heat transfer unit (HTU) of indoor radiation is Interior Space Air lift exchanges heat for duration.
Keep the temperature dehumidification mode: a first compressor and a second compressor starts work, the first heat exchanging part and the second heat exchanging part Between connecting line truncation, the second compressor is that coupled heat exchanger provides refrigerant, and the first compressor is indoor set heat exchanger Refrigerant is provided, setting indoor set heat exchanger evaporating temperature is lower than room air dew-point temperature, be arranged the evaporation of coupled heat exchanger/ Condensation temperature provides duration heat exchange for room air, keeps room temperature constant.
Keep the temperature defrosting mode: when system starts heat preservation defrosting mode, a first compressor and a second compressor starts work Make, the truncation of connecting line between the first heat exchanging part and the second heat exchanging part, the second compressor and coupled heat exchanger heating operation the One setting time, the second heat exchanging part absorb heat, while the first compressor and indoor heat exchanger defrosting the first setting time of operating, First heat exchanging part discharges heat;Then the second compressor and coupled heat exchanger defrosting the second setting time of operating, the second heat exchanging part Heat, while the second setting time of the first compressor and indoor heat exchanger heating operation are discharged, the first heat exchanging part absorbs heat.The One setting time and the second setting time cycle operation to heat preservation defrosting mode terminate.First setting time and the second setting Heating and Defrost operation in time are controlled by control unit.
This heat preservation defrosting mode is using two compressors alternately heating-defrosting circulation.The meaning of circulation be so that For maintaining indoor heating, another defrosts heat exchanging part one of outdoor heat exchanger for outdoor heat exchanger, for remaining outdoor The heat exchanging part of heating is due to the internal lower meeting of refrigerant temperature so that heat exchanging part frosting, the heat exchange for outdoor heat exchanger defrosting Portion can discharge heat and corresponding heat exchanging part surface frost layer is melted, and after cycle operation, two heat exchanging part alternately discharge heat With absorb heat, while alternately maintaining indoor heating and outdoor defrosting, realize and indoor there is heating and outdoor uninterrupted always The technical effect of defrosting makes room temperature keep stablizing, ensure that the comfort of user.
Particularly, the displacement of second compressor is greater than the displacement of the first compressor, described First setting time can be greater than the second setting time.Specifically, first setting time is usually more than 5 minutes, and second Setting time is usually more than 2 minutes;Preferably, first setting time can be set to 1 minute, the second setting time can It is set as 30 seconds.Since the usual heat transfer area of heat transfer unit (HTU) is very big, the heat exchange amount needed is big, by the cylinder for increasing the second compressor Swept volume can provide bigger capacity to guarantee heat transfer unit (HTU) working efficiency and stability;Again due to the second compressor air-discharging Amount is bigger, and faster, in the second setting time, the second compressor, coupled heat exchanger and the second heat exchanging part are defrosting operating for heat exchange, Coupled heat exchanger needs atmospheric heat in absorption chamber at this time, and since capacity is big, heat exchange area is big, heat exchange efficiency meeting It is very high, so can quickly play the role of defrosting;In this case, allow the second setting time is relatively shorter can reduce The room air heat sponged will not be substantially reduced to keep indoor temperature during defrosting more stable.
Further, in the second setting time, the evaporating temperature of coupled heat exchanger is not less than the dew point temperature of room air Degree.In view of coupled heat exchanger and heat transfer element exchange heat, and heat transfer element is often laid on indoor wall or ground, once evaporation temperature Degree is lower than the dew-point temperature of room air, and wall or ground can be made to condense, influence user experience.By by coupled heat exchanger Evaporating temperature maintains the degree not less than room air dew-point temperature, can ensure the comfortable experience of user.
When heat transfer unit (HTU) uses capillary network radiating system, pump rotary speed is suitably reduced, water flow in capillary network is slowed down Speed.When heat preservation defrosting mode operates in the second setting time, heat transfer unit (HTU) is defrosting operating, and heat transfer unit (HTU) can absorb at this time Indoor energy, so that interior is turned cold influences user experience, can slow down capillary by way of suitably reducing pump rotary speed at this time Water velocity in net, and then slow down the heat exchange efficiency of water at low temperature, the fluctuation of room temperature can be reduced to a certain degree in this way, protected Hinder the comfortable experience of user.
The displacement of second compressor is greater than the displacement of the first compressor.Second compression Machine is substantially heat transfer unit (HTU) service, and since heat transfer unit (HTU) is laid with indoors, heat transfer area is big, and the heat exchange amount needed is bigger, So the larger to reach bigger capacity of the swept volume setting of the second compressor can be better ensured that heat transfer The efficiency and stability of device work.
Above description is merely a prefered embodiment of the utility model, on the protection scope of the utility model is not limited in Embodiment is stated, all technical solutions for belonging to the utility model principle belong to the protection scope of the utility model.For this For the technical staff in field, several improvement carried out under the premise of not departing from the principles of the present invention, these improvement It should be regarded as the protection scope of the utility model.

Claims (4)

1. based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU), it is characterised in that: including outdoor unit, Indoor unit and heat transfer unit (HTU), the outdoor unit include the first compressor, the first liquid storage device, the first four-way valve, second Compressor, the second liquid storage device, the second four-way valve and outdoor heat exchanger, the outdoor heat exchanger include that the first heat exchanging part and second is changed Hot portion, the indoor unit include indoor heat exchanger, the first compressor of the indoor unit and outdoor unit, first Liquid storage device, the first four-way valve, the first heat exchanging part connect to form refrigerant flow cycle one, the heat transfer unit (HTU) and outdoor unit The second compressor, the second liquid storage device, the second four-way valve, the second heat exchanging part connect to form refrigerant flow cycle two, the system Cryogen flow cycle one and refrigerant flow cycle two respectively use one group of throttling set.
2. according to claim 1 based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU), feature It is: is equipped with connecting line between first heat exchanging part and the second heat exchanging part, the connecting pipeline is equipped with control first and changes The control valve for being connected to and separating between hot portion and the second heat exchanging part;On pipeline between first heat exchanging part and the first four-way valve Equipped with third triple valve, the branch C of the third triple valve is connected on the export pipeline of the second heat exchanging part, and branch A is connected to First heat exchanging part, branch B are connected to the first four-way valve;When the connecting line between the first heat exchanging part and the second heat exchanging part is connected When, the branch A of the third triple valve is connected with C, branch B partition;Connection between the first heat exchanging part and the second heat exchanging part When pipeline separates, the branch A of the third triple valve is connected with B, branch C partition.
3. described in any item based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU) according to claim 1~2 System, it is characterised in that: the heat transfer unit (HTU) includes capillary network radiating system and coupled heat exchanger, heat-transfer pipe and heat pipe coupling One of which in device, heat-transfer pipe.
4. described in any item based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU) according to claim 1~2 System, it is characterised in that: the displacement of second compressor is greater than the displacement of the first compressor.
CN201821985631.3U 2018-11-29 2018-11-29 Based on the air-conditioning of double-compressor indoor temperature control system in parallel with heat transfer unit (HTU) Active CN209101601U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN110657604A (en) * 2019-09-23 2020-01-07 珠海格力电器股份有限公司 Heat pump system and control method

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN110657604A (en) * 2019-09-23 2020-01-07 珠海格力电器股份有限公司 Heat pump system and control method

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