KR20170044673A - Heat pump system, combo washer-dryer, and dryer - Google Patents

Abstract

The present invention provides a heat pump system, a laundry dryer, and a clothes dryer. The heat pump system includes an evaporator 3, a compressor 4, a condenser 2 and a coolant control subsystem 1, and is connected to the evaporator 3, the compressor 4, the condenser 2, The coolant control subsystem 1 forms a coolant circulation path by sequentially connecting the coolant control subsystem 1 and the coolant control subsystem 1. The coolant control subsystem 1 includes a first branch passage 11 connected in parallel between the evaporator 3 and the condenser 2, Comprises a two-branch passageway (12); The first branch passage 11 has a first throttling device 111 whose outlet is connected to the piping inlet of the evaporator 3 and a second throttling device 111 which is connected to the first throttling device 111 and the liquid storage device 114); A second throttling device 121 is connected in series to the second branch passage 12. When the temperature is high, the liquid storage device 114 increases the space in which the coolant can be accommodated, prevents the pressure load from rising quickly, and when the temperature is low, the space for accommodating the coolant becomes small, The load of the motor 4 increases relatively quickly.

Description

HEAT PUMP SYSTEM, COMBO WASHER-DRYER, AND DRYER}

The present invention belongs to the field of dehumidification through heating of a heat pump, and more specifically to a heat pump system, a washing and drying machine, and a clothes dryer.

Prior art clothes dryers include direct exhaust clothes dryers and condensable clothes dryers. Direct exhaust clothes dryer and condensate clothes dryer both connect the air inlet passage and the air outlet passage to the drum in the tank body. The direct exhaust clothes dryer and the condensable clothes dryer differ from each other in that a heater for heating the air introduced into the washing tub is seated in the air inlet passage of the direct exhaust clothes dryer; The air inlet passage and the air outlet passage of the condensable clothes dryer are communicated with each other to form an air passage. In the air passage, a heating device for heating the air introduced into the washing tub and a blower And a condensing device for cooling the high-temperature gas flowing out from the inside of the washing tub is also seated. Likewise, the drying system of the conventional washing and drying machine is the same as that of the clothes dryer.

In the prior art, a large direct-exhausted clothes dryer or a laundry dryer uses a heat pump drying method in a drying process, and a heat pump system in a laundry dryer or a clothes dryer using a heat pump drying method uses air Dehumidification and heating are performed. The heat pump system includes an evaporator, a compressor, a condenser, and a throttling device, the evaporator, the compressor, the condenser, and the throttling device being sequentially communicated through piping to form a refrigerant circuit. The evaporator of the heat pump system is installed at the air inlet of the air passage, and when the coolant in the heat pump system enters the evaporator, the evaporator evaporates the liquid coolant to be gaseous coolant. In this process, And is used to condense the air passing through the air passage by the condenser in the air passage. The condenser of the heat pump system is located in the air passage between the blower and the evaporator, and when the coolant in the heat pump system enters the evaporator, the condenser converts the gaseous coolant of high temperature and high pressure into gaseous coolant of low temperature and high pressure, The condenser radiates heat to the outside and heats the air passing through the air passage by the heating device in the air passage.

However, in the drum type laundry drier or clothes dryer used in the conventional art, since the water temperature for rinsing clothes may be slightly higher than 0 ° C in a low temperature environment, for example, at 0 ° C, The temperature of the air coming out of the washing / drying tub approaches 0 ° C. In this case, the saturation temperature is much lower than 0 ° C under the saturated pressure of the coolant in the evaporator of the heat pump system, the load on the compressor system is low, and the input power is low. Since the amount of heat of the drying air is obtained from the power input of the compressor system, the temperature rise in the washing / drying tub is extremely gentle and is not advantageous for efficiency of drying the clothes. Also, in a long-term low-temperature environment where the evaporation temperature is 0 ° C or lower, when the evaporator comes into contact with humid air from the drum, a large amount of frost condenses on the fin surface of the evaporator, The refrigerant in the compressor system can not be completely vaporized in the evaporator, so that the coolant in the liquid state is generated and flows into the compressor along the intake pipe of the compressor, Can be broken.

Conventional solutions include: 1. An auxiliary heating line (line) is further provided on the back of the condenser, and the air heated by the condenser is continuously heated again through a heating tube (line) , But correspondingly the energy consumption level is increased; 2. By using inverter compressors, if it is necessary to shorten the low temperature or the drying time, it is possible to operate at a higher operating frequency, but the correspondingly increased cost is relatively large; 3. Large capacity compressors can be used, but the energy consumption of large displacement compressors at room temperature is relatively high; 4. A multi-exhaust seal compressor can be used, but the operating cost still increases.

Based on the above description, there is a need for a new heat pump system for solving the problem that the clothes drying efficiency existing in the prior art is low and the compressor is easily broken down.

SUMMARY OF THE INVENTION In view of the foregoing, it is an object of the present invention to provide a heat pump system capable of increasing a load rising speed of a compressor in a low temperature environment.

Another object of the present invention is to provide a washing and drying machine, in which the heat pump system is installed to improve the drying efficiency of the clothes.

Yet another object of the present invention is to provide a clothes dryer, wherein the heat pump system is installed in the clothes dryer, thereby improving the clothes drying efficiency.

CLAIMS 1. A heat pump system comprising: an evaporator, a compressor, a condenser and a coolant regulating subsystem, said cooler regulating passage being formed by sequentially connecting the evaporator, the compressor, the condenser and the coolant regulating subsystem via a pipe, The system includes a first branch passage and a second branch passage connected in parallel between the evaporator and the condenser;

The first branch passageway includes a first throttling device having an outlet connected to the evaporator pipe inlet and a liquid storage device positioned between the first throttling device and the condenser;

And a second throttling device is connected in series to the second branch passage.

Preferably, the second branch passage and the first branch passage are connected to the piping outlet of the condenser through a direction switching valve.

Preferably, the first branch passage between the condenser and the liquid storage device and the second branch passage between the second throttling device and the condenser are provided with solenoid valves, respectively.

Preferably, the first throttling device is a first capillary, the second throttling device is a second capillary, and the length of the first capillary is shorter than the length of the second capillary.

Preferably, the first throttling device and the second throttling device are the same electronic expansion valve, and the opening degree of the electronic expansion valve can be adjusted.

Preferably, the first throttling device and the second throttling device are both electronic expansion valves, and the opening degree of the electronic expansion valve can be adjusted.

Preferably, a check valve is provided in each of a first branch passage between the liquid storage device and the first throttling device and a second branch passage between the second throttling device and the solenoid valve.

The washing and drying machine includes an outer cylinder, an air cylinder, and an inner cylinder installed in the outer cylinder. The air inlet and the air outlet of the air cylinder are respectively connected to a rear portion and a front portion of the outer cylinder, The evaporator of the heat pump system is installed in the air inlet of the air passage, and the evaporator of the heat pump system is installed in the air passage, And the condenser of the heat pump system is located in the air passage between the blower and the evaporator and acts to heat air passing through the air passage.

A clothes dryer comprising a tank body, an air passage, and a drying cylinder seated in the tank body, wherein an air inlet port and an air outlet port of the air passage are respectively connected to a rear portion and a front portion of the drying cylinder, The evaporator of the heat pump system is installed in the air inlet of the air passage, and the evaporator of the heat pump system is installed in the air inlet of the air passage, The condenser of the heat pump system is located in the air passage between the blower and the evaporator and acts to heat air passing through the air passage.

Preferably, an auxiliary electric heating device is provided in the air passage between the blower and the air outlet of the air passage.

The technical solution provided in the embodiment of the present invention has the following advantageous technical effects:

(1) the coolant control subsystem of the heat pump system includes a first branch passage and a second branch passage connected in parallel between the evaporator and the condenser; The first branch passageway includes a throttling device having an outlet connected to the pipeline inlet of the evaporator and a liquid storage device positioned between the first throttling device and the condenser; And a second throttling device is connected in series to the second branch passage. When the ambient temperature is high, the flow direction of the coolant is: a compressor, a condenser, a first branch passage (liquid storage device, a first throttling device), an evaporator, and a compressor. When the ambient temperature is low, the flow direction of the coolant is: a compressor, a condenser, a second branch passage (second throttling device), an evaporator, and a compressor. Therefore, when the temperature is high, the liquid storage device enlarges the space for accommodating the coolant, and prevents the pressure load from rising quickly. On the other hand, when the temperature is low, the coolant enters the evaporator through only the second throttling device in the condenser. Since the space for accommodating the coolant becomes small, the load of the compressor rapidly increases, .

(2) The length of the first capillary is shorter than the length of the second capillary, and the length of the second capillary is relatively long. In order to make the capillary relatively long in a low temperature state, it is necessary to match the superheat degree of the evaporator in this environment There is no problem that the refrigerant entering the evaporator is excessive and the evaporation is incomplete and the refrigerant in the liquid state enters the compressor along the intake pipe of the compressor to cause a failure of the compressor.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other aspects of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which: It is an embodiment, and other drawings can be obtained through the contents and drawings of the embodiment of the present invention even under the assumption that creativity labor is not given in the conventional device of the present invention.
1 is a schematic diagram of a heat pump system structure provided in an apparatus embodiment of the present invention.
2 is a schematic diagram of a clothes dryer structure provided in an apparatus embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. An embodiment is merely some embodiments of the invention and is not a complete embodiment. In the embodiment of the present invention, all the other embodiments obtained under the premise that the artisan of ordinary skill in the art does not give creative labor are all within the scope of the present invention.

The present invention solves the problem that arises due to the compressor load at low temperatures present in the prior art at a new angle. 1 is a schematic diagram of a heat pump system structure provided in an apparatus embodiment of the present invention. 1, the heat pump system includes an evaporator 3, a compressor 4, a condenser 2 and a coolant control subsystem 1, and the evaporator 3, the compressor 4, The condenser (2) and the coolant control subsystem (1) are in turn communicated through piping to form a coolant circulation circuit. The coolant control subsystem 1 comprises a first branch passage 11 and a second branch passage 12 connected in parallel between the evaporator 3 and the condenser 2.

The first branch passage 11 has a first throttling device 111 whose outlet is connected to the piping inlet of the evaporator 3 and a second throttling device 111 which is connected to the first throttling device 111 and the liquid storage device 114).

A second throttling device 121 is connected in series to the second branch passage 12.

In the preferred embodiment of the present embodiment, the second branch passage 12 and the first branch passage 11 are connected to the piping outlet of the condenser 2 through a direction switching valve. The directional control valve and the controller are connected to each other. The directional control valve controls the flow direction of the coolant flowing out from the condenser 2 according to the signal sent from the received controller, so that the coolant flows through the first branch passage 11 or the second branch To pass through the passage (12). The purpose of using a directional valve is therefore to control the switching of coolant between the two flow directions.

In another preferred embodiment, the first solenoid valve 116 may be installed in the first branch passage 11 between the condenser 2 and the liquid storage device 114, A second solenoid valve 122 may be installed in the second branch passage 12 between the second throttling device 121 and the piping outlet of the condenser 2. The first solenoid valve 116 and the second solenoid valve 122 are both connected to the controller and the controller controls on / off of the first solenoid valve 116 or the second solenoid valve 122 to control the operation of the condenser 2 so that the coolant passes through the first branch passage (11) or the second branch passage (12) by controlling the flow direction of the coolant flowing out from the second branch passage (2). The purpose of using a solenoid valve is therefore to control the coolant to switch between the two flow directions.

The following describes the operation of the heat pump system:

When the ambient temperature is high, the direction of flow of the coolant is as follows: The gaseous coolant flowing out of the compressor 4 at high temperature and high pressure passes through the condenser 2, is condensed by the condenser 2, And the liquid refrigerant enters the liquid storage device 114 via the direction switching valve and the liquid storage device 114 stores the refrigerant in the liquid storage device 114 for a short period of time And the coolant then enters the evaporator 3 via the first throttling device 111 from the liquid storage device 114 and the evaporator 3 evaporates the coolant in the liquid state and transforms it into a gaseous coolant In this process, the evaporator 3 absorbs the surrounding heat, and the gaseous coolant enters the compressor 4 along the pipe.

When the ambient temperature is low, the flow direction of the coolant is as follows: The gaseous coolant flowing out of the compressor 4 at a high temperature and high pressure passes through the condenser 2, passes through the condenser 2, The coolant in the liquid state enters the second branch passage 12 via the direction switching valve and flows into the second branch passage 12 along the second branch passage 12. In this case, And the evaporator 3 evaporates the liquid coolant into the gaseous coolant. In this process, the evaporator 3 absorbs the amount of heat in the vicinity of the evaporator 3, And the gaseous coolant enters the compressor (4) along the pipe.

Therefore, in the case of a high temperature, the pressure load of the coolant does not rise quickly due to the receiving space of the liquid storage device 114. On the other hand, when the temperature is low, the compressor 4 is operated, first turning off the directional control valve, and returning the coolant in the liquid storage device 114 to the cooling system through the action of the compressor. The next directional valve is communicated to the second branch passage 12 to allow the coolant to progress through the drying process cycle and the branch passage to be filled with the coolant is relatively small so that the load on the compressor 4 rises quickly do.

In a preferred embodiment of the present embodiment, the first throttling device 111 is a first capillary, and the second throttling device 121 is a second capillary.

In a preferred embodiment of the present invention, the length of the first capillary is shorter than the length of the second capillary. The relatively long installation of the second capillary tube is intended to match the superheat degree of the evaporator 3 at low temperature. The refrigerant entering the evaporator 3 is excessive due to the relatively high pressure rise, so that evaporation is not incomplete.

The selection of the first throttling device 111 and the second throttling device 121 is not limited to the above description and the first throttling device 111 and the second throttling device 121 are connected to the electronic expansion valve And the electronic expansion valves of the two branch passages are respectively connected to the controller, and the electronic expansion valve adjusts its opening degree according to the command signal sent from the controller. The degree of opening when the electronic expansion valve of the first branch passage is normally operated is larger than the degree of opening when the electronic expansion valve of the second branch passage 12 is normally operated.

The first throttling device 111 and the second throttling device 121 may use the same electronic expansion valve and the electronic expansion valve may be connected to the controller and the electronic expansion valve may control the self- Adjust the opening degree. When the system uses another branch passage, the opening degree of the electronic expansion valve is different, and the opening degree of the electronic expansion valve when the first branch passage 11 is normally operated is the same as the case where the second branch passage 12 operates normally Is larger than the opening degree of the electronic expansion valve.

In the preferred embodiment of the present invention, the first check valve 112 is installed in the first branch passage 11 between the liquid storage device 114 and the first throttling device 111. The action of the first check valve 112 is to prevent reflux into the liquid reservoir 114 when the coolant is operated in the low temperature mode.

When the distance between the second solenoid valve 122 and the second capillary in the second branch passage 12 is relatively large, the distance between the second throttling device 121 and the second solenoid valve 122 It is possible to prevent the coolant or the lubricant from being concentrated in the piping in a high environmental temperature state by providing the second check valve in the second branch passage 112 of the pipe.

In a preferred embodiment of the present embodiment, the liquid storage device 114 is a liquid storage tank and, of course, it is not limited thereto, and other liquid storage devices may be selected.

The present invention can also provide a clothes dryer. 2, the clothes dryer includes a tank body 6, an air passage 5, and a drying cylinder 7 that is seated inside the tank body 6, and the air passage 5 The air inlet port 51 and the air outlet port 52 are respectively connected to the rear portion and the front portion of the drying cylinder 7 and the air passage 5 and the drying cylinder 7 form one closed circuit, A blower 54 is provided in the air passage 5. The evaporator 3 of the heat pump system is installed in the air inlet 51 of the air passage and is used as a condenser in the air passage 5 to supply air to the air passage 5); < / RTI > The condenser 2 of the heat pump system is located in the air passage 5 between the blower 54 and the evaporator 3 and as a heating device in the air passage 5, It acts to heat the air.

In the preferred embodiment of the present embodiment, the auxiliary electric heater 53 is provided in the air passage 5 between the blower 54 and the air outlet 52 of the air passage 5, (5). ≪ / RTI >

In the preferred embodiment of the present invention, the air inlet port 51 of the air passage 5 is provided with a filtering net 55. The filtering net 55 is disposed in the air passage 5 from the drying bin 7, It is possible to prevent foreign substances such as hair follicles from entering the air passage 5 and to ensure a clean sanitary environment in the air passage 5. [

The drying process of the clothes dryer is as follows: the blower 54 causes air to circulate in the air passage 5 and the drying barrel 7 while at the same time the condenser 2 of the heat pump system passes through The air containing water vapor passes through the evaporator 3 of the heat pump system and the evaporator 3 evaporates the moisture in the garment 3 by heating the air so that hot air enters the drying cylinder 7, So as to cool the surrounding air, so that the water vapor in the hot air is cooled to be condensed into liquid water so that it is discharged to the outside together with tap water. The dry air from which steam has been removed is reheated by the condenser 2 of the heat pump system and enters the drying cistern 7 again to dry the clothes. This process continues until the clothes are dry.

The present invention also provides a washer-dryer. The washing and drying machine includes an outer cylinder, an air cylinder, and an inner cylinder installed in the outer cylinder. The air inlet and the air outlet of the air cylinder are respectively connected to a rear portion and a front portion of the outer cylinder. Forms a closed circuit, and a blower is installed in the air passage. The evaporator (3) of the heat pump system is installed in an air intake port of the air passage, and as the condensing device in the air passage, the washing and drying machine includes an air passage Lt; / RTI > The condenser 2 of the heat pump system is located in the air passage 5 between the blower 54 and the evaporator 3 and serves as a heating device in the air passage for heating the air passing through the air passage do.

In the preferred embodiment of the present invention, an auxiliary electric heater is provided in the air passage between the blower and the air outlet of the air passage to further heat the air passing through the air passage.

The drying process of the washing and drying machine is similar to the drying process of the clothes dryer, and will not be described here again.

It should be noted that the foregoing is a comparative preferred embodiment of the present invention and the technical principles in which it operates. It will be understood by those skilled in the art that the present invention is not limited to the specific embodiments described above and that various obvious changes, reconditions, and substitutions may be made without departing from the scope of the present invention. Although the present invention has been described in detail with reference to the above embodiments, it is to be understood that the present invention is not limited to the above-described embodiments, and many other equivalent embodiments are included in the scope of the present invention. And the scope of the present invention is determined by the appended claims.

1. coolant control subsystem; 2. Condenser; 3. an evaporator; 4. Compressor; 5. Air pathways; 6. Tank body; 7. Drying trough; 11. First branch passage; 12. Second branch passage; 111. First throttling device; 112. A first check valve; 114. Liquid storage device; 116. A system comprising: a first solenoid valve; 121. 2nd throttling device; 122. A solenoid-operated valve comprising: 51. Air inlet; 52. Air outlet; Auxiliary electric heating devices; 54. Blowers; 55. Filter.

Claims (10)

A heat pump system comprising an evaporator, a compressor, a condenser and a coolant control subsystem, said coolant circulation path being formed by sequentially connecting the evaporator, the compressor, the condenser and the coolant control subsystem through piping,
The coolant control subsystem includes a first branch passage and a second branch passage connected in parallel between the evaporator and the condenser;
The first branch passageway includes a first throttling device having an outlet connected to the pipeline inlet of the evaporator and a liquid storage device positioned between the first throttling device and the condenser;
And a second throttling device is connected in series to the second branch passage. The method according to claim 1,
Wherein the second branch passage and the first branch passage are connected to the piping outlet of the condenser through a directional valve. The method according to claim 1,
Wherein a first branch passage between the condenser and the liquid storage device and a second branch passage between the second throttling device and the condenser are provided with solenoid valves, respectively. The method according to claim 1,
Wherein the first throttling device is a first capillary and the second throttling device is a second capillary wherein the length of the first capillary is shorter than the length of the second capillary. The method according to claim 1,
Wherein the first throttling device and the second throttling device are the same electronic expansion valve and the opening degree of the electronic expansion valve is adjustable. The method according to claim 1,
Wherein the first throttling device and the second throttling device are both electronic expansion valves, and the degree of opening of the electronic expansion valve is adjustable. The method of claim 3,
Wherein a check valve is provided in each of a first branch passage between the liquid storage device and the first throttling device and a second branch passage between the second throttling device and the solenoid valve. Wherein the air inlet and the air outlet of the air passage are connected to a rear portion and a front portion of the outer cylinder, respectively, and the air passage and the outer cylinder are connected to each other through one And a blower is installed in the air passage, the washing and drying machine comprising:
The heat pump system according to any one of claims 1 to 7, wherein the evaporator of the heat pump system is installed at an air inlet of the air passage to condense air passing through the air passage, Wherein the condenser of the pump system is located in the air passage between the blower and the evaporator and acts to heat air passing through the air passage. The air inlet and the air outlet of the air passage are connected to a rear portion and a front portion of the drying cylinder, respectively, and the air passage and the drying cylinder are connected to each other through a single A closed circuit is formed, and a blower is installed in the air passage,
The heat pump system according to any one of claims 1 to 7, wherein the evaporator of the heat pump system is installed at an air inlet of the air passage to condense air passing through the air passage, Wherein the condenser of the pump system is located in the air passage between the blower and the evaporator and acts to heat air passing through the air passage. 10. The method of claim 9,
Wherein an auxiliary electrical heating device is provided in the air passage between the blower and the air outlet of the air passage.

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