CN2767925Y - Heating cycle system for air energy heat pump - Google Patents

Abstract

The utility model relates to a heating cycle system of an air energy heat pump, which belongs to the technical field of heating and can be used for a water heater and an air conditioner. The heating circulation system comprises a compressor (1), a heat exchanger (2), a throttling device (3), an evaporator (4), a water reservoir (5), a first electromagnetic valve (7), a second electromagnetic valve (8), and an auxiliary evaporator (9) which is arranged between the evaporator (4) and the water reservoir (5). The heating circulation system of the air energy heat pump has the function of frost removal, and needs not to stop the compressor when the frost removal is carried out, so that the damage to a machine and the impact to an electric network due to the compressor is frequently started can be effectively avoided. Simultaneously, the frost removal is carried out by sucking heat from air, which avoids the time of pressure balance and improves the service efficiency of the heating cycle system of the heat pump.

Description

Heating circulation system of air energy heat pump

Technical field

The utility model relates to technical field of heating, relates in particular to a kind of heating circulation system of air energy heat pump, and this heating circulation system of air energy heat pump can be widely used on water heater and the air-conditioning.

Background technology

Heat pump techniques is a new energy technology, receive world experts and scholars' very big concern always, air energy heat pump water heater is the application of heat pump techniques aspect production hot water, and traditional water heater (electric heater, fuel oil, gas heater) has shortcomings such as energy consumption is big, expense is high, seriously polluted; The operation of energy saving and environment friendly solar water heater is subjected to the restriction of meteorological condition again; And the heat supply principle of Teat pump boiler and traditional solar water heater are completely different, with air, water, solar energy etc. is low-temperature heat source, with the electric energy is that power heats domestic water from the low temperature side draw heat, and air energy heat pump water heater is one of state-of-the-art using energy source product in the world today.

As a patent No. is that the Chinese utility model patent " air heat energy water heater " of ZL03272547.7 (notification number is CN2636123Y) has disclosed the structure so a kind of, a kind of air heat energy water heater, comprise switch board and water storage box, in switch board, be provided with the heat exchanger that links to each other successively, compressor, heat dump, flow controller, filter and liquid reservoir, be provided with in a side of heat dump and adopt air-heater, be connected to input pipe and efferent duct on the heat exchanger, described input pipe and efferent duct and storage tank join, on circulation line, be provided with the heat cycles pump, on water storage box, be provided with the water inlet pipe and the hot water outlet pipe of automatic control water level.Because the heat dump (also being evaporimeter) in the above-mentioned air energy heat pump will absorb heats a large amount of in the air, therefore heat dump (evaporimeter) is usually worked under the lower and moist again situation in air themperature, evaporator temperature is lower than zero degree, at this moment the surface that airborne moisture can condense in evaporimeter forms the frost layer, influence the cold-producing medium in the evaporimeter and the heat exchange of air, greatly reduce the efficient of machine.

In order to improve the efficient of air energy heat pump, at this moment just need take the effective method defrosting, so a kind of air energy heat pump water heater occurred on the market with defrost function, have heating circulation system of air energy heat pump, it includes compressor 1, heat exchanger 2, throttling arrangement 3, evaporimeter 4, reservoir 5; Wherein the port of export of compressor 1 is connected by the entrance point of pipeline with heat exchanger 2, the port of export of heat exchanger 2 is connected by the entrance point of pipeline with throttling arrangement 3, the port of export of throttling arrangement 3 is connected by the entrance point of pipeline with evaporimeter 4, the port of export of evaporimeter 4 is connected by the entrance point of pipeline with reservoir 5, and the port of export of reservoir 5 is connected by the entrance point of pipeline with compressor 1; Also be provided with cold water inlet 21 and hot water outlet pipe 22 on the described heat exchanger 2; Described heating circulation system also comprises a defrosting structure, and this defrosting structure is for being provided with a commutation cross valve 11 between the pipeline between the pipeline between reservoir 5 and the evaporimeter 4 and compressor 1 and the heat exchanger 1.The defrost process of this water heater is such: as shown in Figure 2, during defrosting at first compressor 1 quit work, treating that commutation cross valve 11 is started working after the system pressure balance changes the flow direction (refrigerant flow direction is according to shown in the dotted line) of cold-producing medium, compressor 1 restarts, at this moment the gas of HTHP enters the frost generation heat exchange on evaporimeter 4 and evaporimeter 4 surfaces, melt the frost on evaporimeter 4 surfaces, warm highly pressurised liquid was that the liquid of low-temp low-pressure enters into the heat that heat exchanger 2 draws hot water and is converted to gas through throttling arrangement 3 throttlings during himself was cooled to, this gas is sucked compression through commutation cross valve 11 by compressor 1, finish a contrary circulation, so reach the purpose of defrosting repeatedly, after defrosting finishes, compressor 1 quits work, commutation cross valve 11 commutates once more, after treating pressure balance equally, start compressor 1 and restart operate as normal.

There is twice shutdown and the startup of compressor 1 in such Defrost method; also there is pressure balance time simultaneously; frequent starting influences service life of a machine and electrical network is impacted like this; the pressure balance time cisco unity malfunction; needing heat in the hot water in the extract heat interchanger 2 to defrost has simultaneously influenced the efficient of heat pump, and therefore above-mentioned heating circulation system of air energy heat pump can also improve further.

Summary of the invention

Technical problem to be solved in the utility model is to provide a kind of heating circulation system of air energy heat pump with defrost function at above-mentioned prior art present situation, needn't cut off compressor earlier when heating circulation system of air energy heat pump defrosts, it also has service efficiency height, advantage such as rational in infrastructure.

The utility model solves the problems of the technologies described above the technical scheme that is adopted: a kind of heating circulation system of air energy heat pump, and it includes compressor, heat exchanger, throttling arrangement, evaporimeter, reservoir;

Wherein the port of export of compressor is connected with the entrance point of heat exchanger by pipeline, the port of export of heat exchanger is connected with an end of throttling arrangement by pipeline, the other end of throttling arrangement is connected with the entrance point of evaporimeter by pipeline, the port of export of evaporimeter is connected with the entrance point of reservoir by pipeline, and the port of export of reservoir is connected with the entrance point of compressor by pipeline;

Also be provided with cold water inlet and hot water outlet pipe on the described heat exchanger;

Described heating circulation system also comprises a defrosting structure;

It is characterized in that described defrosting structure includes first magnetic valve, second magnetic valve, is arranged on the auxiliary evaporator between evaporimeter and the reservoir; One end of described first magnetic valve is connected with pipeline between compressor and the heat exchanger by pipeline, and the other end is connected with pipeline between throttling arrangement and the evaporimeter by pipeline; The entrance point of described auxiliary evaporator is connected by the port of export of capillary and evaporimeter, and its port of export is connected with the reservoir entrance point by pipeline; One end of described second magnetic valve is connected with the port of export of evaporimeter by pipeline, and the other end communicates with pipeline between reservoir and the auxiliary evaporator by pipeline.

The liquid that produces in the evaporimeter in order to prevent to defrost flows into a large amount of in compressor and to impacting in service life of compressor, we also are provided with the 3rd magnetic valve between evaporimeter and auxiliary evaporator, one end of the 3rd magnetic valve is connected with the port of export of evaporimeter by pipeline, and its other end is connected with the entrance point of auxiliary evaporator by pipeline.Adopted this structure can improve the service life of compressor effectively.

Above-mentioned throttling arrangement is an expansion valve.

Above-mentioned heat exchanger comprises attemperater and heat exchanger, and the two ends of heat exchanger are connected with compressor and throttling arrangement respectively, and described attemperater is sealed, and heat exchanger is arranged on attemperater inside.

For the thermal efficiency that makes heat exchanger can improve further, we become shape in the shape of a spiral with above-mentioned design of heat exchanger.The cold water contact-making surface that adopts spiral helicine heat exchanger can increase in itself and the attemperater increases greatly, therefore can make the cold water heat exchange in heat exchanger and the attemperater more abundant.

Compared with prior art, advantage of the present utility model is: the defrost process of heating circulation system of air energy heat pump is such in the utility model, it is when defrosting, open first magnetic valve, close second magnetic valve, the high-temperature high-pressure refrigerant gas overwhelming majority just directly enters in the evaporimeter through first magnetic valve like this, wherein the sub-fraction higher pressure refrigerant gas also can continue the water in the heat exchanger is heated, certainly improve expansion valve for the refrigerant gas that does not make HTHP, we can also turn off expansion valve, at this moment enter the frost generation heat exchange of the refrigerant gas and the evaporator surface of evaporimeter HTHP, melt the frost of evaporator surface, and the refrigerant gas of HTHP is after warm highly pressurised liquid becomes the liquid of low-temp low-pressure through the capillary-compensated throttling in himself being cooled to, enter in the auxiliary evaporator, draw airborne heat again and finished a circulation by the compressor suction after evaporating, so reach the purpose of defrosting repeatedly, after defrosting finishes, close first magnetic valve, open the 3rd magnetic valve successively, second magnetic valve, the middle temperature highly pressurised liquid of opening the purpose of the 3rd magnetic valve earlier and being for the generation that also do not drain in the device that avoids evaporating directly enters in the compressor by reservoir, thereby influence the service life of compressor, after the 3rd magnetic valve is opened a bit of time, just can close the 3rd magnetic valve, make the whole air energy heat pump circulatory system revert to normal duty.

In whole like this defrost process the inside, the frequent starting that we can effectively avoid compressor is to the injury of machine with to the impact of electrical network, be that draw heat defrosts from air simultaneously, but also avoided the pressure balanced time, improved the service efficiency of heat pump circulating system greatly.

Description of drawings

Fig. 1 is the structural representation of the utility model embodiment;

Fig. 2 is the prior art constructions schematic diagram.

The specific embodiment

Embodiment describes in further detail the utility model below in conjunction with accompanying drawing.

As shown in Figure 1, a kind of heating circulation system of air energy heat pump, it includes compressor 1, heat exchanger 2, throttling arrangement 3, evaporimeter 4, reservoir 5, first magnetic valve 7, second magnetic valve 8, auxiliary evaporator 9, above-mentioned throttling arrangement 3 is an expansion valve, certain above-mentioned throttling arrangement 3 also can be other common choke valve, heat exchanger 2 includes attemperater 23 and heat exchanger 24, attemperater 23 is provided with cold water inlet 21 and hot water outlet pipe 22, heat exchanger 24 is arranged on attemperater 23 inside, above-mentioned heat exchanger 24 is shape in the shape of a spiral, the two ends of heat exchanger 24 are connected with compressor 1 and throttling arrangement 3 respectively by pipeline, and described attemperater 23 is sealed.

The annexation of above-mentioned element is such: the port of export of compressor 1 is connected by the entrance point of pipeline with heat exchanger 2, the port of export of heat exchanger 2 is connected with an end of throttling arrangement 3 by pipeline, the other end of throttling arrangement 3 is connected by the entrance point of pipeline with evaporimeter 4, one end of described first magnetic valve 7 is connected with pipeline between compressor 1 and the heat exchanger 2 by pipeline, the other end is connected with pipeline between throttling arrangement 3 and the evaporimeter 4 by pipeline, the port of export of described evaporimeter 4 is connected by the entrance point of capillary 10 and auxiliary evaporator 9, its port of export is connected with reservoir 5 entrance points by pipeline, one end of described second magnetic valve 8 is connected with the port of export of evaporimeter by pipeline, the other end communicates with pipeline between reservoir 5 and the auxiliary evaporator 9 by pipeline, between evaporimeter and auxiliary evaporator 9, also be provided with the 3rd magnetic valve 6, one end of the 3rd magnetic valve 6 is connected with the port of export of evaporimeter by pipeline, and its other end is connected by the entrance point of pipeline with auxiliary evaporator 9.

The course of work of the utility model embodiment and principle are such:

During operate as normal, first magnetic valve 7 and the 3rd magnetic valve 6 are in closed condition in this course of work, second magnetic valve 8 and expansion valve are open mode, the refrigerant gas of the HTHP of the port of export of compressor 1 discharge at this moment enters heat exchanger 24, and with attemperater 23 in cold water generation heat exchange, cold water is heated into hot water offers the user by the hot water outlet pipe, cold water constantly adds in the attemperater 23 from cold water inlet 21 again continuously simultaneously, and the refrigerant gas of HTHP self will be cooled in the refrigerant liquid of warm high pressure, again through the liquid of throttling arrangement 3 throttlings becoming low-temp low-pressure, flow in the evaporimeter 4 by pipeline, and draw airborne heat in 4 li evaporations of evaporimeter, after becoming the gas of low-temp low-pressure, via second magnetic valve 8 and reservoir 5, sucked again the boil down to high temperature and high pressure gas by compressor 1 at last and finish a circulation, so reach the purpose that adds hot water repeatedly, though evaporimeter 4 and auxiliary evaporator 9 are connected together by capillary 10 all the time, because this capillary 10 is equivalent to the effect of throttling arrangement 3, therefore almost there is not gas to flow in the auxiliary evaporator 9, and the effect of reservoir 5 is equivalent to the effect of device for drying and filtering, purpose is that the small amount of moisture that will reserve from evaporimeter 4 or auxiliary evaporator 9 stops, liquid gas is separated, prevent that liquid from directly entering in the compressor 1.(its gas or liquid in the flow direction in the pipeline shown in solid arrow among Fig. 1)

Because evaporimeter 4 temperature are lower than zero degree, in air themperature under the lower and moist again situation, at this moment the surface that airborne moisture can condense in evaporimeter 4 forms the frost layer, influence the cold-producing medium of 4 li in evaporimeter and the heat exchange of air, greatly reduce the efficient of machine, at this moment just need us to defrost.

Its defrost process is such, during defrosting, open first magnetic valve 7, close second magnetic valve 8, the high-temperature high-pressure refrigerant gas overwhelming majority just directly enters in the evaporimeter 4 through first magnetic valve 7 like this, wherein the sub-fraction higher pressure refrigerant gas also can continue the water in the heat exchanger 2 is heated, certainly improve expansion valve for the refrigerant gas that does not make HTHP, we can also turn off expansion valve, at this moment enter the refrigerant gas of evaporimeter 4 HTHPs and the frost generation heat exchange on evaporimeter 4 surfaces, melt the frost on evaporimeter 4 surfaces, and the refrigerant gas of HTHP himself be cooled in warm highly pressurised liquid behind the liquid of capillary 10 throttlings becoming low-temp low-pressure, enter in the auxiliary evaporator 9, this moment low-temp low-pressure the airborne heat of liquid assimilating and evaporate, the gas that the evaporation back forms is sucked by compressor 1 and finishes a circulation, so just reach the purpose of defrosting repeatedly, after defrosting finishes, close first magnetic valve 7, open the 3rd magnetic valve 6 and second magnetic valve 8 successively, opening the 3rd magnetic valve 6 earlier and be low-temp low-pressure liquid for the generation that will also not drain in the evaporimeter 4 imports in the auxiliary evaporator 9 and evaporates, reach and prevent that liquid from directly entering the purpose that influences the service life of compressor 1 in the compressor 1 by reservoir 5, after the 3rd magnetic valve 6 is opened a bit of time, just can close the 3rd magnetic valve 6, at this moment make the whole air energy heat pump circulatory system revert to normal duty.(its gas or liquid in the flow direction in the pipeline shown in dotted arrow among Fig. 1)

Above-mentioned heating circulation system of air energy heat pump is widely used on electric heater and the air-conditioning.

Claims (5)

1, a kind of heating circulation system of air energy heat pump, it includes compressor (1), heat exchanger (2), throttling arrangement (3), evaporimeter (4), reservoir (5);

Wherein the port of export of compressor (1) is connected by the entrance point of pipeline with heat exchanger (2), the port of export of heat exchanger (2) is connected by the entrance point of pipeline with throttling arrangement (3), one end of throttling arrangement (3) is connected by the entrance point of pipeline with evaporimeter (4), the other end of evaporimeter (4) is connected by the entrance point of pipeline with reservoir (5), and the port of export of reservoir (5) is connected by the entrance point of pipeline with compressor (1);

Also be provided with cold water inlet (21) and hot water outlet pipe (22) on the described heat exchanger (2);

Described heating circulation system also comprises a defrosting structure;

It is characterized in that described defrosting structure includes first magnetic valve (7), second magnetic valve (8), is arranged on the auxiliary evaporator (9) between evaporimeter (4) and the reservoir (5); One end of described first magnetic valve (7) is connected with pipeline between compressor (1) and the heat exchanger (2) by pipeline, and the other end is connected with pipeline between throttling arrangement (3) and the evaporimeter (4) by pipeline; The entrance point of described auxiliary evaporator (9) is connected by the port of export of capillary (10) and evaporimeter (4), and its port of export is connected with reservoir (5) entrance point by pipeline; One end of described second magnetic valve (8) is connected by the port of export of pipeline with evaporimeter (4), and the other end communicates with pipeline between reservoir (5) and the auxiliary evaporator (9) by pipeline.

2, heating circulation system of air energy heat pump according to claim 1, it is characterized in that also being provided with the 3rd magnetic valve (6) between described evaporimeter (4) and the auxiliary evaporator (9), one end of the 3rd magnetic valve (6) is connected by the port of export of pipeline with evaporimeter (4), and its other end is connected by the entrance point of pipeline with auxiliary evaporator (9).

3, heating circulation system of air energy heat pump according to claim 1 is characterized in that described throttling arrangement (3) is an expansion valve.

4, heating circulation system of air energy heat pump according to claim 1, it is characterized in that described heat exchanger (2) comprises attemperater (23) and heat exchanger (24), the two ends of heat exchanger (24) are connected with compressor (1) and throttling arrangement (3) respectively, described attemperater (23) is sealed, and heat exchanger (24) is arranged on attemperater (23) inside.

5, heating circulation system of air energy heat pump according to claim 4 is characterized in that described heat exchanger (24) shape in the shape of a spiral.

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