CN205119316U - Heat pump system - Google Patents

Abstract

The utility model discloses a heat pump system, including the compressor, the compressor includes induction port and gas vent, evaporation heat exchange assemblies, evaporation heat exchange assemblies have first end and second end, and evaporation heat exchange assemblies's first end links to each other with the induction port, heat shell body is equipped with the baffle in, the baffle becomes first heat transfer chamber and second heat transfer chamber with heat shell body internal partitioning, is formed with the intercommunication mouth on the baffle, is formed with the import on the second heat transfer chamber, and is formed with the export on the first heat transfer chamber, condenser, condenser are established at first heat transfer intracavity, and the condenser is connected between gas vent and evaporation heat exchange assemblies's second end, and the heat exchanger, the heat exchanger is established at second heat transfer intracavity, by after the fluid that enters into second heat transfer intracavity and the heat exchanger heat transfer through the intercommunication mouth enter into first heat transfer intracavity and with the condenser heat transfer after flow from the export. According to the utility model discloses a heat pump system, simple structure, energy -concerving and environment -protective.

Description

Heat pump

Technical field

The utility model relates to heat pump technical field, particularly relates to a kind of heat pump.

Background technology

In correlation technique, domestic air-conditioning system is in process of refrigerastion, and the condenser outwardly Environment release heat of off-premises station, if be directly discharged in environment by this part heat, not only can cause the waste of the energy, and can produce pollution to environment.

Utility model content

The utility model is intended at least to solve one of technical problem existed in prior art.For this reason, an object of the present utility model is to propose a kind of heat pump, and the structure of described heat pump is simple, energy-conserving and environment-protective.

According to the heat pump of the utility model embodiment, comprise compressor, described compressor comprises air entry and exhaust outlet; Evaporation and heat-exchange assembly, described evaporation and heat-exchange assembly has first end and the second end, and the described first end of described evaporation and heat-exchange assembly is connected with described air entry; Heat exchange housing, be provided with dividing plate in described heat exchange housing, described heat exchange enclosure interior is separated into the first heat exchanging chamber and the second heat exchanging chamber by described dividing plate, and described dividing plate is formed with connected entrance, described second heat exchanging chamber is formed with import, and described first heat exchanging chamber is formed with outlet; Condenser, described condenser is located in described first heat exchanging chamber, and described condenser is connected between described exhaust outlet and described second end of described evaporation and heat-exchange assembly; And heat exchanger, described heat exchanger is located in described second heat exchanging chamber; To be entered in described first heat exchanging chamber by described connected entrance after entering into fluid in described second heat exchanging chamber and described heat exchanger heat exchange by described import and with described condenser heat exchange after flow out from described outlet.

According to the heat pump of the utility model embodiment, by arranging dividing plate in heat exchange housing, heat exchange enclosure interior is separated into the first heat exchanging chamber and the second heat exchanging chamber, and condenser and heat exchanger are set respectively in the first heat exchanging chamber and the second heat exchanging chamber, thus twice heating can be carried out to the fluid flowing through heat exchange housing.

According to an embodiment of the present utility model, described heat pump comprises further: heat collector, described heat collector has first end and the second end, and the first end of described heat collector is connected with one end of described heat exchanger, and the second end of described heat collector is connected with the other end of described heat exchanger.

Further, between the described first end of described heat collector and described one end of described heat exchanger or described second end of described heat collector be connected with the described other end of described heat exchanger between be provided with circulating pump.

According to embodiments more of the present utility model, be provided with heat exchange stream in described second heat exchanging chamber, the two ends of described heat exchange stream are connected with described connected entrance with described import respectively, are provided with phase-changing energy storage material part in described second heat exchanging chamber.

Alternatively, described phase-changing energy storage material part comprises multiple phase-change accumulation energy ball.

Particularly, each described phase-change accumulation energy bag is drawn together aluminum spheroid, is filled in paraffin in described aluminum spheroid and copper powders.

Alternatively, the volume ratio of described paraffin and described copper powders is 20:1, and described paraffin and described copper powders account for the 80%-90% of described aluminum ball interior volume.

According to an embodiment of the present utility model, described condenser comprises condenser pipe, heat exchange sleeve is provided with in described first heat exchanging chamber, described Heat exchange jacekt jacket casing is located at outside described condenser pipe, described heat exchange sleeve is formed with the heat exchange entrance be communicated with described connected entrance and exports with the heat exchange of described outlet.

Further, the flow direction of the fluid in described heat exchange sleeve is identical with the flow direction of the cold-producing medium in described condenser pipe.

According to an embodiment of the present utility model, described heat pump comprises further: temperature sensor, and described temperature sensor is located at described exit.

According to an embodiment of the present utility model, described evaporation and heat-exchange assembly comprises evaporimeter, and described evaporimeter is connected between described air entry and described condenser.

According to an embodiment of the present utility model, described heat exchange housing is insulation, and described dividing plate is metalwork.

Additional aspect of the present utility model and advantage will part provide in the following description, and part will become obvious from the following description, or be recognized by practice of the present utility model.

Accompanying drawing explanation

Above-mentioned and/or additional aspect of the present utility model and advantage will become obvious and easy understand from accompanying drawing below combining to the description of embodiment, wherein:

Fig. 1 is the schematic diagram of the heat pump according to the utility model embodiment.

Reference numeral:

Heat pump 100,

Compressor 110, air entry 111, exhaust outlet 112, gas-liquid separator 113,

Evaporation and heat-exchange assembly 120, the first end 121 of evaporation and heat-exchange assembly, the second end 122 of evaporation and heat-exchange assembly,

Heat exchange housing 130, dividing plate 131, the first heat exchanging chamber 132, second heat exchanging chamber 133,

Connected entrance 134, import 135, outlet 136,

Condenser 140, heat exchange sleeve 142, heat exchange entrance 143, heat exchange outlet 144,

Heat exchanger 150, one end 151, the other end 152,

Heat collector 160, first end 161, the second end 162, circulating pump 163,

Heat exchange stream 170, phase-change accumulation energy ball 171,

Temperature sensor 180,

Evaporimeter 190, blower fan 191, throttling arrangement 192.

Detailed description of the invention

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Being exemplary below by the embodiment be described with reference to the drawings, only for explaining the utility model, and can not being interpreted as restriction of the present utility model.

In description of the present utility model, it will be appreciated that, term " on ", D score, "left", "right", " level ", " interior ", the orientation of the instruction such as " outward " or position relationship be based on orientation shown in the drawings or position relationship, only the utility model and simplified characterization for convenience of description, instead of the device of instruction or hint indication or element must have specific orientation, with specific azimuth configuration and operation, therefore can not be interpreted as restriction of the present utility model.In addition, term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance or imply the quantity indicating indicated technical characteristic.Thus, be limited with " first ", the feature of " second " can express or impliedly comprise one or more these features.In description of the present utility model, except as otherwise noted, the implication of " multiple " is two or more.

In description of the present utility model, it should be noted that, unless otherwise clearly defined and limited, term " installation ", " being connected ", " connection " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or connect integratedly; Can be mechanical connection, also can be electrical connection; Can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals.For the ordinary skill in the art, concrete condition the concrete meaning of above-mentioned term in the utility model can be understood.

Below with reference to Fig. 1, the heat pump 100 according to the utility model embodiment is described.

As shown in Figure 1, according to the heat pump 100 of the utility model embodiment, comprise compressor 110, evaporation and heat-exchange assembly 120, heat exchange housing 130, condenser 140 and heat exchanger 150.

Specifically, with reference to Fig. 1, compressor 110 comprises air entry 111 and exhaust outlet 112.Air entry 111 place is provided with gas-liquid separator 113, and cold-producing medium enters in compressor 110 by air entry 111 after gas-liquid separator 113 carries out gas-liquid separation, discharges under the effect of compressor 110 by after above-mentioned refrigerant compression through exhaust outlet 112.Thus, condition can be provided for the further recycling of condensation heat.Evaporation and heat-exchange assembly 120 has first end and the second end, and the first end 121 (right-hand member such as, in Fig. 1) of evaporation and heat-exchange assembly is connected with air entry 111.

Heat exchange housing 130 roughly can be formed as the shape of capsule, but be not limited thereto, be provided with dividing plate 131 in heat exchange housing 130, dividing plate 131 roughly can be positioned at the centre position of heat exchange housing 130, and heat exchange housing 130 interior separation is become the first heat exchanging chamber 132 and the second heat exchanging chamber 133 by dividing plate 131.Such as, as shown in Figure 1, first heat exchanging chamber 132 is positioned at the bottom of heat exchange housing 130, second heat exchanging chamber 133 is positioned at the top of heat exchange housing 130, dividing plate 131 is formed with connected entrance 134, connected entrance 134 can be located at the center-right position of dividing plate 131, but is not limited thereto, second heat exchanging chamber 133 is formed with import 135, and the first heat exchanging chamber 132 is formed with outlet 136.Import 135 on second heat exchanging chamber 133 for carrying fluid such as cold water in heat exchange housing 130, and outlet 136 on the first heat exchanging chamber 132 for the fluid in heat exchange housing 130 outwards after delivery heat transfer such as to user's hot-water supply.

Thus, evaporation and heat-exchange assembly 120 can make full use of the cold-producing medium after condensation intraductal heat exchange and carry out sweat cooling, thus can provide cold for user, achieves recycling of energy, economize energy.

Condenser 140 is located in the first heat exchanging chamber 132, and condenser 140 is connected between exhaust outlet 112 and the second end 122 (left end such as, in Fig. 1) of evaporation and heat-exchange assembly.The cold water entered in the first heat exchanging chamber 132 via connected entrance 134 and heat exchange entrance 143 can carry out heat exchange with condenser 140, such as, condenser 140 comprises condenser pipe, in condenser pipe, there is cold-producing medium, cold-producing medium after cold water heat exchange in the first heat exchanging chamber 132 and in the first heat exchanging chamber 132 can be transported to again evaporation and heat-exchange assembly 120 with further sweat cooling, thus, not only can make full use of condensation heat, in the first heat exchanging chamber 132, preheating be carried out to cold water, and the cold-producing medium after condensation intraductal heat exchange can be utilized to carry out sweat cooling, for user provides cold, achieve recycling of energy, economize energy.

Heat exchanger 150 is located in the second heat exchanging chamber 133.Such as, as shown in Figure 1, heat exchanger 150 is located at the top of heat exchange housing 130, thus, can heat the fluid flowed through in heat exchange stream 170, thus can ensure that heat pump 100 supplies the leaving water temperature of the hot water of user to a certain extent.

To be entered in the first heat exchanging chamber 132 by connected entrance 134 after entering into fluid in the second heat exchanging chamber 133 (comprising liquid such as water etc., gas such as air etc.) and heat exchanger 150 heat exchange via import 135 and with condenser 140 heat exchange after flow out from outlet 136.

According to the heat pump 100 of the utility model embodiment, by arranging dividing plate 131 in heat exchange housing 130, heat exchange housing 130 interior separation is become the first heat exchanging chamber 132 and the second heat exchanging chamber 133, and condenser 140 and heat exchanger 150 are set respectively in the first heat exchanging chamber 132 and the second heat exchanging chamber 133, thus twice heating can be carried out to the fluid flowing through heat exchange housing 130.

According to an embodiment of the present utility model, as shown in Figure 1, heat pump 100 comprises further: heat collector 160, and heat collector 160 can be solar thermal collector, and the heat collection in sunshine can be got up and be passed by the heat of collection by solar thermal collector.Specifically, heat collector 160 has first end 161 (such as, upper end in Fig. 1) and the second end 162 is (such as, lower end in Fig. 1), the first end 161 of heat collector 160 and one end 151 of heat exchanger 150 are (such as, upper end in Fig. 1) be connected, the second end 162 of heat collector 160 is connected with the other end 152 (lower end such as, in Fig. 1) of heat exchanger 150.Thus, the flowing of heat between heat collector 160 and heat exchanger 150 can be ensured, thus the heat collected can be passed to the fluid in the second heat exchanging chamber 133 by heat collector 160, and then the leaving water temperature of fluid such as hot water can be ensured to a certain extent, to meet the demand of user to hot water better.

Further, between the first end 161 of heat collector 160 and one end 151 of heat exchanger 150 or the second end 162 of heat collector 160 be connected with the other end 152 of heat exchanger 150 between be provided with circulating pump 163.Thus, the heat in the sunshine that heat collector 160 is collected can be recycled to heat exchanger 150 under the effect of circulating pump 163, and the fluid such as cold water in heat exchanger 150 and the second heat exchanging chamber 133 carries out heat exchange, thus can ensure leaving water temperature to a certain extent.Wherein, circulating pump 163 can be located between the first end 161 of heat collector 160 and one end 151 of heat exchanger 150, between second end 162 that also can be located at heat collector 160 is connected with the other end 152 of heat exchanger 150, here, concrete restriction is not done to the setting position of circulating pump 163, can accommodation as required in practical application.

Alternatively, heat collector 160 can be flat plate collector.Wherein, the heat absorbing element of flat plate collector can be metal absorber plate (general copper or aluminium), and less scaling, long service life.

According to embodiments more of the present utility model, be provided with heat exchange stream 170 in the second heat exchanging chamber 133, the two ends of heat exchange stream 170 are connected with connected entrance 134 with import 135 respectively, are provided with phase-changing energy storage material part in the second heat exchanging chamber 133.Wherein, the upper end of heat exchange stream 170 (such as, upper end in Fig. 1) be connected with import 135, import 135 is preferably formed in the top of heat exchange housing 130, the lower end of heat exchange stream 170 (such as, lower end in Fig. 1) be connected with connected entrance 134, phase-changing energy storage material part is provided with in second heat exchanging chamber 133, phase-changing energy storage material part can carry out heat exchange with above-mentioned heat exchanger 150, and the storage of heat can be carried out, thus, make the fluid such as cold water flowed in heat exchange stream 170 from import 135 can carry out heat exchange with phase-changing energy storage material part, thus the leaving water temperature of the fluid such as water flowed out from connected entrance 134 can be ensured to a certain extent.

Further, at least part of curve of heat exchange stream 170 extends.Such as, with reference to Fig. 1, heat exchange stream 170 at least partly roughly S-shaped curve extends, thus, be equivalent to extend the stroke of fluid such as cold water in the second heat exchanging chamber 133, thus heat exchange area can be increased to a certain extent, make heat exchange more abundant, and then can leaving water temperature be ensured, to meet the demand of user better.

Alternatively, phase-changing energy storage material part can comprise multiple phase-change accumulation energy ball 171.Multiple phase-change accumulation energy ball 171 is filled in the second heat exchanging chamber 133, and multiple phase-change accumulation energy ball 171 can carry out heat exchange with heat exchanger 150, thus make the fluid in heat exchange stream 170 can carry out heat exchange with multiple phase-change accumulation energy ball 171, multiple phase-change accumulation energy balls 171 after heat exchange continue to carry out heat exchange with heat exchanger 150, heat exchanger 150 carries out heat exchange with heat collector 160 under the effect of circulating pump 163, circulation like this, thus the temperature flowing into the first heat exchanging chamber 132 inner fluid from the second heat exchanging chamber 133 can be ensured to a certain extent, and then can ensure that user's convection current style is as the needs of hot water, to meet the demand of user better.

Wherein, each phase-change accumulation energy ball 171 comprises aluminum spheroid, is filled in paraffin in aluminum spheroid and copper powders.Alternatively, the volume ratio of paraffin and copper powders is 20:1, and paraffin and copper powders account for the 80%-90% of aluminum ball interior volume.Experiment proves, the performance of aluminum spheroid is good, heat-insulation system is high, and the paraffin of filling according to above-mentioned volume ratio in aluminum spheroid and the heat insulation effect of copper powders better, paraffin and copper powders account for the 80%-90% of aluminum ball interior volume, namely the space of 10%-20% is left in phase-change accumulation energy ball 171 inside, above-mentioned space can meet paraffin and the requirement of copper powders after expanded by heating of filling, thus, phase-change accumulation energy ball 171 can fully and heat exchanger 150 carry out heat exchange, thus can leaving water temperature be ensured.It should be noted that, when illumination is sufficient, certain heat can be carried out store in phase-change accumulation energy ball 171, thus, still can ensure the supply of hot water when illumination is not enough, thus the demand of user to hot water can be met better.

According to an embodiment of the present utility model, with reference to Fig. 1, heat exchange sleeve 142 is provided with in first heat exchanging chamber 132, heat exchange sleeve 142 can all roughly become sigmoid curve to extend with condenser pipe in the first heat exchanging chamber 132, and heat exchange sleeve 142 is set in outside condenser pipe, heat exchange sleeve 142 is formed with the heat exchange entrance 143 be communicated with connected entrance 134 and the heat exchange be communicated with outlet 136 exports 144.Thus, the fluid entered by import 135 such as cold water enters in the second heat exchanging chamber 133 and carries out heat exchange with phase-change accumulation energy ball 171, then flow through connected entrance 134 successively, heat exchange entrance 143 enters in heat exchange sleeve 142, the heat exchange sleeve 142 roughly becoming sigmoid curve to extend and condenser pipe are equivalent to extend the stroke of fluid in the first heat exchanging chamber 132, thus heat exchange area can be increased to a certain extent, make heat exchange more abundant, and then can leaving water temperature be ensured, meet the demand of user to hot water further better.

Further, the flow direction of fluid in heat exchange sleeve 142 is identical with the flow direction of the cold-producing medium in condenser pipe.In second heat exchanging chamber, 133 inner fluids such as cold water carries out heat exchange with phase-change accumulation energy ball 171 in 133 in the second heat exchanging chamber, now, the flow direction of the fluid in heat exchange sleeve 142 is identical with the flow direction of the cold-producing medium in condenser pipe can reach reasonable heat transfer effect, can meet the demand of user to hot water.

Alternatively, heat exchange sleeve 142 can be metalwork.The heat conductivility of metalwork is better, and thus, the fluid in heat exchange sleeve 142 can carry out heat exchange with the cold-producing medium in condenser pipe more fully, thus can ensure leaving water temperature further, meets consumers' demand better.

Alternatively, the first heat exchanging chamber 132 can be positioned at the below of the second heat exchanging chamber 133.With reference to Fig. 1, dividing plate 131 can be horizontally disposed.Certainly, when not affecting heat transfer effect, dividing plate 131 also can be arranged (scheming not shown) with suitable angular slope.The concrete arrangement of the utility model to dividing plate 131 is not construed as limiting, can accommodation as required in practical application.

As shown in Figure 1, heat pump 100 comprises further: temperature sensor 180, and temperature sensor 180 is located at outlet 136 place.Thus, the temperature through exporting 136 outflow hot water can be detected, thus the demand of user can be met better.

With reference to Fig. 1, evaporation and heat-exchange assembly 120 comprises evaporimeter 190, and evaporimeter 190 is connected between air entry 111 and condenser 140.Condensation " liquid " body through the low temperature of condenser 140 outflow passes through evaporimeter 190, carries out heat exchange with the air in the external world, and " gas " changes heat absorption, reaches the effect of refrigeration.Further, evaporimeter 190 place is provided with blower fan 191, (throttling arrangement 192 can be electric expansion valve to be provided with throttling arrangement 192 between evaporimeter 190 and condenser 140, electric expansion valve can regulate liquid supply rate according to pre-set programs), thus, can need according to user the supply ensureing cold, and can recovering condensing heat be user's hot-water supply, realize recycling of the energy, energy-conserving and environment-protective.

According to an embodiment of the present utility model, heat exchange housing 130 can be insulation, such as, heat exchange housing 130 can be the fibrous material of light weight, loose, porous, both can be insulation material in above-mentioned fibrous material, and can be also cold insulation material, but be not limited thereto.Thus, by adopting heat-insulating material to make heat exchange housing 130, the heat insulation effect of heat exchange housing 130 can be ensured, reducing and extraneous heat exchange.Thus, can while guarantee heat pump 100 heat exchange and sweat cooling effect, economize energy.Dividing plate 131 can be metalwork.

Dividing plate 131 can be metalwork, the heat conductivility of metalwork is better, thus, in first heat exchanging chamber, 132 and second fluids in heat exchanging chamber in 133 suitably can carry out heat exchange, thus, accommodation can be carried out to leaving water temperature, ensure that leaving water temperature is in proper scope, thus the demand of user can be met better.

The course of work according to the heat pump 100 of the utility model embodiment is described in detail below in conjunction with Fig. 1.Solar energy phase-change heat storage and heat pump cycle two processes are comprised according to the course of work of the heat pump 100 of the utility model embodiment.

Specifically, the exhaust outlet 112 of compressor 110 and the upper end of condenser 140 are (such as, upper end in Fig. 1) connect, condenser 140 is provided with heat exchange sleeve 142, heat exchange sleeve 142 upper end is communicated with import 135, lower end is communicated with outlet 136, the two ends of heat exchange sleeve 142 (such as, top and bottom in Fig. 1) be welded on adiabatic heat exchange housing 130, the export pipeline of condenser 140 is connected with throttling arrangement 192, throttling arrangement 192 is connected with evaporimeter 190, evaporimeter 190 is connected with gas-liquid separator 113, in heat exchange housing 130, fluid enters the heat exchange stream 170 in the second heat exchanging chamber 133 from import 135, heat exchange is carried out with phase-change accumulation energy ball 171, fluid after preheating flows through intercommunicating pore 134 successively and heat exchange entrance 143 enters in the heat exchange sleeve 142 in the first heat exchanging chamber 132, the fluid entered in heat exchange sleeve 142 continues to carry out heat exchange with the cold-producing medium in condenser pipe, fluid after heating flows through heat exchange outlet 144 successively along heat exchange sleeve 142, outlet 136 is flowed out, outlet 136 is provided with temperature sensor 180, temperature sensor 180 can detect that coolant-temperature gage is to control unlatching or the closedown of heat pump 100, control the running status of throttling arrangement 192 and compressor 110 simultaneously, thus can ensure that leaving water temperature is applicable to user and uses.

In solar energy phase-change heat storage process, heat collector 160 (such as, plate solar collector) collect sunshine and sunshine is changed into heat energy, by circulating pump 163, working medium is circulated between heat collector 160 and heat exchanger 150, thus heat exchange can be carried out with phase-change accumulation energy ball 171, by thermal energy storage in phase-change accumulation energy ball 171, fluid enters in the heat exchange stream 170 in the second heat exchanging chamber 133 by import 135, fluid carries out heat exchange with phase-change accumulation energy ball 171 in heat exchange stream 170, the heat that phase-change accumulation energy ball 171 discharges storage makes the temperature of fluid raise, fluid after preheating is successively by intercommunicating pore 134, heat exchange entrance 143 enters in heat exchange sleeve 142.

In heat pump cycle, the heat that cold-producing medium in condenser pipe discharges is by the absorption of fluids in heat exchange sleeve 142, fluid is along the tube runs of heat exchange sleeve 142, export 144 by heat exchange successively after the temperature rising of fluid, export 136 for user, outlet 136 is provided with temperature sensor 180, the temperature of water outlet can be monitored thus.So far, the course of work of the heat pump 100 according to the utility model embodiment is completed.

According to the heat pump 100 of the utility model embodiment other form and operation be all known for those of ordinary skills, be not described in detail here.

Disclosing hereafter provides many different embodiments or example is used for realizing different structure of the present utility model.Of the present utility model open in order to simplify, hereinafter the parts of specific examples and setting are described.Certainly, they are only example, and object does not lie in restriction the utility model.In addition, the utility model can in different example repeat reference numerals and/or letter.This repetition is to simplify and clearly object, itself does not indicate the relation between discussed various embodiment and/or setting.In addition, the various specific technique that the utility model provides and the example of material, but those of ordinary skill in the art can recognize the property of can be applicable to of other techniques and/or the use of other materials.

In addition, fisrt feature described below second feature it " on " structure can comprise the embodiment that the first and second features are formed as directly contact, also can comprise other feature and be formed in embodiment between the first and second features, such first and second features may not be direct contacts.

In the description of this description, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " illustrative examples ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, identical embodiment or example are not necessarily referred to the schematic representation of above-mentioned term.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiment or example.

Although illustrate and described embodiment of the present utility model, those having ordinary skill in the art will appreciate that: can carry out multiple change, amendment, replacement and modification to these embodiments when not departing from principle of the present utility model and aim, scope of the present utility model is by claim and equivalents thereof.

Claims (12)

1. a heat pump, is characterized in that, comprising:

Compressor, described compressor comprises air entry and exhaust outlet;

Evaporation and heat-exchange assembly, described evaporation and heat-exchange assembly has first end and the second end, and the described first end of described evaporation and heat-exchange assembly is connected with described air entry;

Heat exchange housing, be provided with dividing plate in described heat exchange housing, described heat exchange enclosure interior is separated into the first heat exchanging chamber and the second heat exchanging chamber by described dividing plate, and described dividing plate is formed with connected entrance, described second heat exchanging chamber is formed with import, and described first heat exchanging chamber is formed with outlet;

Condenser, described condenser is located in described first heat exchanging chamber, and described condenser is connected between described exhaust outlet and described second end of described evaporation and heat-exchange assembly; And

Heat exchanger, described heat exchanger is located in described second heat exchanging chamber,

To be entered in described first heat exchanging chamber by described connected entrance after entering into fluid in described second heat exchanging chamber and described heat exchanger heat exchange by described import and with described condenser heat exchange after flow out from described outlet.

2. heat pump according to claim 1, is characterized in that, comprises further:

Heat collector, described heat collector has first end and the second end, and described first end is connected with one end of described heat exchanger, and described second end is connected with the other end of described heat exchanger.

3. heat pump according to claim 2, is characterized in that, between the described first end of described heat collector and described one end of described heat exchanger or described second end of described heat collector be connected with the described other end of described heat exchanger between be provided with circulating pump.

4. the heat pump according to any one of claim 1-3, is characterized in that, is provided with heat exchange stream in described second heat exchanging chamber, and the two ends of described heat exchange stream are connected with described connected entrance with described import respectively,

Phase-changing energy storage material part is provided with in described second heat exchanging chamber.

5. heat pump according to claim 4, is characterized in that, described phase-changing energy storage material part comprises multiple phase-change accumulation energy ball.

6. heat pump according to claim 5, is characterized in that, each described phase-change accumulation energy bag draws together aluminum spheroid, be filled in paraffin in described aluminum spheroid and copper powders.

7. heat pump according to claim 6, is characterized in that, the volume ratio of described paraffin and described copper powders is 20:1, and described paraffin and described copper powders account for the 80%-90% of described aluminum ball interior volume.

8. heat pump according to claim 1, is characterized in that, described condenser comprises condenser pipe,

Be provided with heat exchange sleeve in described first heat exchanging chamber, described Heat exchange jacekt jacket casing is located at outside described condenser pipe, described heat exchange sleeve is formed with the heat exchange entrance be communicated with described connected entrance and exports with the heat exchange of described outlet.

9. heat pump according to claim 8, is characterized in that, the flow direction of the fluid in described heat exchange sleeve is identical with the flow direction of the cold-producing medium in described condenser pipe.

10. heat pump according to claim 1, is characterized in that, comprises further:

Temperature sensor, described temperature sensor is located at described exit.

11. heat pumps according to claim 1, is characterized in that, described evaporation and heat-exchange assembly comprises evaporimeter, and described evaporimeter is connected between described air entry and described condenser.

12. heat pumps according to claim 1, is characterized in that, described heat exchange housing is insulation, and described dividing plate is metalwork.