CN109764514A - A kind of energy resource system and its control method and storage medium - Google Patents

Abstract

The invention discloses a kind of energy resource system and its control method and storage mediums, belong to energy field.Energy resource system, including one or more first heat regulation equipment；With one or more second heat regulation equipment；First evaporator of one or more first heat regulation equipment is connected in a manner of heat exchange with multiple or a second heat regulation equipment the second evaporator heat exchanger in first；First condenser of one or more first heat regulation equipment is connected in a manner of heat exchange with multiple or a second heat regulation equipment the second condenser heat exchanger in second.Discarded energy between different heat regulation equipment has been carried out planning as a whole to utilize, has reduced energy consumption and waste, realize energy-saving and emission-reduction by the energy resource system of the embodiment of the present invention.Realize that a heat regulation equipment exchanges the heat of multiple heat regulation equipment.

Description

A kind of energy resource system and its control method and storage medium

Technical field

The present invention relates to energy technology field, in particular to a kind of energy resource system and its control method and storage medium.

Background technique

In general home environment, can there are many household electrical appliance, and a plurality of types of household electrical appliance often have it is different Function, and all refer to the conversion of heat.For example, outdoor unit simultaneously can dissipate heat, together when air conditioner room unit freezes Sample, water heater are also required to consumption electric energy or dissipate heat when freezing, and on the other hand, water heater is needed hot water heating, Also electric energy can be consumed；When winter, air-conditioning needs to heat, and can also discharge a part of cooling capacity.Some need heat, some distribute Heat, some need refrigeration, some distribute cooling capacity, therefore, cause great energy waste.

The air conditioner of heating mode, condenser quantity of heat given up is for heating indoor environment, the cooling capacity of evaporator output It is distributed as useless cold by air.And the evaporator output cooling capacity of refrigerator is defeated for freezing or chilled food, the condenser of refrigerator Heat out is distributed as waste heat by air.How to realize the energy allotment between air conditioner and refrigerator, reduces energy consumption And waste, it realizes energy-saving and emission-reduction, is current urgent problem to be solved.

Summary of the invention

The embodiment of the invention provides a kind of energy resource system and its control method and storage mediums.For the implementation to disclosure The some aspects of example have a basic understanding, and simple summary is shown below.The summarized section is not extensive overview, also not It is key/critical component to be determined or the protection scope for describing these embodiments.Its sole purpose is with simple form Some concepts are presented, in this, as the preamble of following detailed description.

According to a first aspect of the embodiments of the present invention, a kind of energy resource system, including one or more first heats are provided Adjustment equipment；With one or more second heat regulation equipment；

The first evaporator and multiple or the second heat tune of one or more first heat regulation equipment Second evaporator of section equipment is connected in a manner of heat exchange heat exchanger in first；

The first condenser and multiple or the second heat tune of one or more first heat regulation equipment Second condenser of section equipment is connected in a manner of heat exchange heat exchanger in second.

In some optional embodiments, heat exchanger is arranged in series in one or more first evaporations in described first On the access of heat exchange between device and multiple or second evaporator；Heat exchanger is arranged in series in described second In the communication paths of heat exchange between one or more first condensers and multiple or second condenser.

In some optional embodiments, heat exchanger in heat exchanger and described second in described first, is denoted as the first Middle heat exchanger, comprising:

Input terminal, for being connected to second condenser or the second evaporator of the second heat regulation equipment； Alternatively, the first evaporator or the first condenser for being connected to the first heat regulation equipment；

Output end, correspondingly, for being connected to the first condenser or the first evaporation of multiple first heat regulation equipment Device；Alternatively, the second evaporator or the second condenser for being connected to multiple second heat regulation equipment；

Be connected valve, be arranged on the connecting pipeline of the input terminal and the connecting pipeline of the output end on.

In some optional embodiments, heat exchanger in heat exchanger and described second in first, is denoted as second of transfer Heat exchanger, further includes:

The both ends of the undirectional thermal conducting are arranged in undirectional thermal conducting, the input terminal and the output end.

In some optional embodiments, the first evaporator of one or more first heat regulation equipment and it is multiple or Series connection accesses in the first in the communication paths of heat exchange between second evaporator of one the second heat regulation equipment Heat exchanger, in the first the first evaporator of heat exchanger and first heat regulation equipment or with one described It is in parallel in the communication paths of second evaporator of two heat regulation equipment to access heat exchanger in second；And/or one or more First condenser of a first heat regulation equipment and multiple or the second heat regulation equipment the second condensations Series connection access heat exchanger in the first in the communication paths of heat exchange between device, heat exchanger and one the in the first First condenser of one heat regulation equipment is logical with the connection of the second condenser of the second heat regulation equipment Heat exchanger in second of road access in parallel.

It in some optional embodiments, further include switching device, heat exchanger is arranged in second in the switching device At the connecting interface being connected in parallel, for switching the communication paths between first evaporator and second evaporator；Institute Switching device is stated to be arranged at the connecting interface that heat exchanger in second is connected in parallel, for switch first condenser with Communication paths between second condenser.

It in some optional embodiments, further include control device；The control device, for according to first heat The temperature of second evaporator of the temperature of the first evaporator of adjustment equipment and the second heat regulation equipment controls described the The aperture of total aperture of multiple conducting valves of heat exchanger and each conducting valve in one；The control device is used for basis The temperature of second condenser of the temperature of the first condenser of the first heat regulation equipment and the second heat regulation equipment Degree controls the aperture of total aperture of multiple conducting valves of heat exchanger and each conducting valve in described second.

According to a second aspect of the embodiments of the present invention, a kind of control method of energy resource system is provided, comprising:

According to the second evaporator of the temperature of the first evaporator of the first heat regulation equipment and the second heat regulation equipment Temperature, control first in heat exchanger multiple conducting valves total aperture and it is each conducting valve aperture.

According to the second condenser of the temperature of the first condenser of the first heat regulation equipment and the second heat regulation equipment Temperature, control second in heat exchanger multiple conducting valves total aperture and it is each conducting valve aperture.

In some optional embodiments, the control method, further includes:

When between the first evaporator and the second evaporator heat exchange can not be carried out by the direction of setting, the first evaporation of switching The communication paths of heat exchange between device and the second evaporator pass through heat exchanger in second；

When between the first condenser and the second condenser heat exchange can not be carried out by the direction of setting, the first condensation of switching The communication paths of heat exchange between device and the second condenser pass through heat exchanger in second.

According to a third aspect of the embodiments of the present invention, a kind of storage medium, is stored thereon with computer program, when the meter Calculation machine program realizes the control method of energy resource system above-mentioned when being executed by processor.

Technical solution provided in an embodiment of the present invention can include the following benefits:

The energy resource system of the embodiment of the present invention has carried out the discarded energy between different heat regulation equipment to plan as a whole benefit With reducing energy consumption and waste, realize energy-saving and emission-reduction.Realize a heat regulation equipment to multiple heat regulation equipment Heat exchange.

It should be understood that above general description and following detailed description be only it is exemplary and explanatory, not It can the limitation present invention.

Detailed description of the invention

The drawings herein are incorporated into the specification and forms part of this specification, and shows and meets implementation of the invention Example, and be used to explain the principle of the present invention together with specification.

Fig. 1 is a kind of structural schematic diagram of energy resource system shown according to an exemplary embodiment；

Fig. 2 is a kind of structural schematic diagram of energy resource system shown according to an exemplary embodiment；

Fig. 3 is a kind of structural schematic diagram of energy resource system shown according to an exemplary embodiment；

Fig. 4 is a kind of structural schematic diagram of middle heat exchanger shown according to an exemplary embodiment；

Fig. 5 is a kind of structural schematic diagram of middle heat exchanger shown according to an exemplary embodiment；

Fig. 6 is a kind of structural schematic diagram of middle heat exchanger shown according to an exemplary embodiment；

Fig. 7 is a kind of structural schematic diagram of middle heat exchanger shown according to an exemplary embodiment；

Fig. 8 is a kind of structural schematic diagram of middle heat exchanger shown according to an exemplary embodiment；

Fig. 9 is a kind of structural schematic diagram of middle heat exchanger shown according to an exemplary embodiment；

Figure 10 is a kind of structural schematic diagram of middle heat exchanger shown according to an exemplary embodiment；

Figure 11 is a kind of structural schematic diagram of middle heat exchanger shown according to an exemplary embodiment；

Figure 12 is a kind of structural schematic diagram of energy resource system shown according to an exemplary embodiment；

Figure 13 is a kind of flow diagram of the control method of energy resource system shown according to an exemplary embodiment；

Figure 14 is a kind of flow diagram of the control method of energy resource system shown according to an exemplary embodiment.

Specific embodiment

The following description and drawings fully show specific embodiments of the present invention, to enable those skilled in the art to Practice them.Other embodiments may include structure, logic, it is electrical, process and other change.Embodiment Only represent possible variation.Unless explicitly requested, otherwise individual components and functionality is optional, and the sequence operated can be with Variation.The part of some embodiments and feature can be included in or replace part and the feature of other embodiments.This hair The range of bright embodiment includes equivalent obtained by the entire scope of claims and all of claims Object.Herein, each embodiment individually or can be indicated generally with term " invention ", and it is convenient that this is used for the purpose of, And if in fact disclosing the invention more than one, the range for being not meant to automatically limit the application is any single invention Or inventive concept.Herein, relational terms such as first and second and the like be used only for by an entity or operation with Another entity or operation distinguish, and without requiring or implying, there are any actual relationships between these entities or operation Or sequence.Moreover, the terms "include", "comprise" or any other variant thereof is intended to cover non-exclusive inclusion, thus So that process, method or equipment including a series of elements not only include those elements, but also including being not explicitly listed Other element, or further include for this process, method or the intrinsic element of equipment.In the feelings not limited more Under condition, the element that is limited by sentence "including a ...", it is not excluded that in process, method or equipment including the element In there is also other identical elements.Each embodiment herein is described in a progressive manner, and each embodiment stresses Be the difference from other embodiments, the same or similar parts in each embodiment may refer to each other.For implementing For method, product etc. disclosed in example, since it is corresponding with method part disclosed in embodiment, so the comparison of description is simple Single, reference may be made to the description of the method.

In conjunction with shown in Fig. 1 to Figure 12, illustrate the embodiment of the present invention in a first aspect, a kind of energy resource system, including one or Multiple first heat regulation equipment 40；With one or more second heat regulation equipment 50；

The first evaporator 41 and multiple (or one) the second heat tune of one (or multiple) the first heat regulation equipment 40 Second evaporator 51 of section equipment 50 is connected in a manner of heat exchange heat exchanger 20 (or 30) in first；

The first condenser 42 and multiple (or one) the second heat tune of one (or multiple) the first heat regulation equipment 40 Second condenser 52 of section equipment 50 is connected in a manner of heat exchange heat exchanger 20 (or 30) in second.

Wherein, in first heat exchanger 20 (or 30) for mutually being passed on from one to another between the first evaporator 41 and the second evaporator 51 Defeated heat, heat exchanger 20 (or 30) is used between the first condenser 42 and the second condenser 52 transmission heat mutually in second Amount.

The energy resource system of the embodiment of the present invention has carried out the discarded energy between different heat regulation equipment to plan as a whole benefit With reducing energy consumption and waste, realize energy-saving and emission-reduction.Specifically, realize a heat regulation equipment to multiple heat tune Save the heat exchange of equipment.

Optionally, as shown in Fig. 1 to Fig. 3 and Figure 12, the first heat regulation equipment 40 is the air conditioner under heating mode, the Two heat regulation equipment 50 are refrigerator.The cooling capacity of the first evaporator 41 output of air conditioner 40 passes through heat exchanger 20 in first (or 30) and the second evaporator 51 of refrigerator 50 exchange heat, for the food stored in refrigerator to be freezed or refrigerated. The heat of the second condenser 52 output of refrigerator 50 passes through the first condensation of heat exchanger 20 (or 30) and air conditioner 40 in second Device 42 exchanges heat, for heating to room air.Wherein, air conditioner can be domestic air conditioner, be also possible to building Central air conditioner system, the entire central air conditioner system of cell or the air conditioner of other forms.Refrigerator can be Refrigerator product is also possible to the food freezing or refrigerating system of freezer or other forms.Certainly, the first heat regulation is set Standby 40 may be refrigerator, the air conditioner under the second heat regulation equipment 50 or heating mode.

In an alternative embodiment, energy resource system, as depicted in figs. 1 and 2, including a first heat regulation equipment 40 and multiple second heat regulation equipment 50.One the first evaporator 41 exchanges heat with multiple second evaporators 51, as shown in Fig. 2, Using heat exchanger 20 (or 30) in turn multichannel all the way first, first evaporator 41 is multiple second evaporator, 51 cooling supply Amount.One the first condenser 42 exchanges heat with multiple second condensers 52, as shown in Figure 1, turning the first transfer all the way using multichannel Heat exchanger 20 (or 30), multiple second condensers 52 are 42 heating load of the first condenser.

In an alternative embodiment, energy resource system, including multiple first heat regulation equipment 40 and one second heat Measure adjustment equipment 50.Multiple first evaporators 41 and second evaporator 51 exchange heat, and with reference to shown in Figure 12, turn one using multichannel Heat exchanger 20 (or 30) in the first of road, multiple first evaporators 41 are 51 semen donors of the second evaporator.Multiple first Condenser 42 and second condenser 52 exchange heat, as shown in figure 3, using heat exchanger 20 in turn multichannel all the way first (or 30), second condenser 52 is multiple first condenser, 42 heating loads.

In the embodiment of the present invention, the middle heat exchanger in energy resource system as shown in Figure 1 to Figure 3 can use the first Middle heat exchanger 20, can also be using heat exchanger 30 in second.

In the embodiment of the present invention, as shown in Figure 1 to Figure 3, heat exchanger (heat exchanger and the second transfer in first in The general designation of heat exchanger) realize the heat exchange (Cooling capacity exchanging) between evaporator and the heat exchange (heat exchange) between condenser.One In kind optional embodiment, heat exchanger 20 (or 30) is arranged in series in the first evaporation of the first heat regulation equipment 40 in first On the access of heat exchange between device 41 and the second evaporator 51 of the second heat regulation equipment 50；Heat exchanger 20 in second (or 30) it is second cold to be arranged in series in the first condenser 42 of the first heat regulation equipment 40 and the second heat regulation equipment 50 In the communication paths of heat exchange between condenser 52.

In an alternative embodiment, with the air conditioner under 40 heating mode of the first heat regulation equipment, the second heat Adjustment equipment 50 be refrigerator for, air conditioner 41 side of the first evaporator be arranged the first cooling capacity heat-exchanger rig, the second of refrigerator The second heat heat-exchanger rig is arranged in 52 side of condenser.The connecting pipeline of the input terminal of heat exchanger and the first cooling capacity exchange heat in first The connecting pipeline of device is connected to, and the connecting pipeline of output end is connected to the second evaporator 51 of refrigerator.At this point, the second of refrigerator steams Hair device 51 can be the evaporator being connected in refrigerator with the compressor of refrigerator, is also possible to additional evaporator and (is arranged in refrigerator Refrigerating chamber room in, can not be communicated with compressor).The second of the connecting pipeline refrigerator side of the input terminal of heat exchanger in second The connecting pipeline of heat heat-exchanger rig is connected to, and the connecting pipeline of output end is connected to the first condenser 42 of air conditioner.At this point, empty It adjusts the first condenser 42 of device to can be the condenser being communicated with compressor in air conditioner, is also possible to additional condenser and (sets It sets in the air duct of air conditioner, can not be communicated with compressor).

Illustrate in the first of the embodiment of the present invention heat exchanger in heat exchanger and second, system below with reference to Fig. 4 to Figure 11 Referred to as middle heat exchanger.The two it is structurally and functionally all the same, be intended merely to distinguish and define in first heat exchanger with Heat exchanger in second.Whether undirectional thermal conducting 31 is set in heat exchanger according in below, middle heat exchanger is divided into the Heat exchanger 30 in a kind of middle heat exchanger 20 and second.

As shown in Fig. 4 to Fig. 9, heat exchanger 20 in the first, including,

Energy input end 201, for being connected to heat storage device or cooling capacity storage device/calorie adjusting device；

Energy output end 202, for being connected to calorie adjusting device/heat storage device or cooling capacity storage device；With

Be connected valve, be arranged on the access at energy input end 201 and the access of energy output end 202 on.

In an alternative embodiment, conducting valve includes that valve 231 is connected in input terminal and valve is connected in output end 232, input terminal conducting valve 231 is arranged in series on the pipeline at energy input end 201, and the output end conducting series connection of valve 232 is set It sets on the pipeline of energy output end 202.The purpose that conducting valve is arranged is control energy input end 201 and energy output end 202 open or close.In specific embodiment, each energy input end 201 (each heat-exchanger rig) inlet tube and go out Input terminal input terminal conducting valve 231 is respectively provided in liquid pipe, in the inlet tube of each energy output end 202 (each heat-exchanger rig) Valve 232 is connected with output end is respectively provided on outlet tube.By the control to each conducting valve, realized respectively to the first transfer The folding control and flow control of each connecting pipeline at the energy input end 201 and energy output end 202 of heat exchanger 20 are adjusted The transmitting of amount of energy saving can control between the first heat regulation equipment 40 and the second heat regulation equipment 50 according to actual conditions Heat exchange.

Energy input end 201, for inputting the cooling capacity (or heat) of first evaporator 41 (or second condenser 52) side.It adopts Specific structure multiplicity, e.g., using liquid mediums as carrier, energy input end 201 is using heat-exchanger rig and the first evaporation For the heat-exchanger rig of device 41 (or second condenser 52) side by pipeline connection, liquid mediums absorb the first evaporator 41 (or second Condenser 52) side cooling capacity (or heat), liquid mediums flow to the energy input end 201, and energy input end 201 and energy are defeated The medium fluid of outlet 202 carries out heat exchange, to converting energy to energy output end 202.

In an alternative embodiment, energy input end 201 specifically uses heat-exchanger rig, e.g., plate heat exchanger, evaporation Device or heat exchange coil etc..Energy output end 202 is specifically using heat-exchanger rig, e.g., plate heat exchanger, condenser, alternatively, heat exchange Coil pipe etc..

In the middle heat exchanger of the embodiment of the present invention, the number at energy input end 201 and energy output end 202, and, energy The setting for measuring the external connecting pipeline group of input terminal 201 and energy output end 202, according to the evaporator and condenser for being connected to side The factors such as number determine.

In an alternative embodiment, the energy input end 201 of heat exchanger 20 is in the first of the embodiment of the present invention The pipeline of one or more, each energy input end 201 is independently arranged.For example, energy input end 201 include one (such as Fig. 4, Shown in Fig. 5 and Fig. 9) or multiple (referring to the energy output end 202 of the middle heat exchanger 20 of Fig. 7) third heat-exchanger rigs, Mei Ge Three heat-exchanger rigs all have inlet tube 211 and outlet tube 212 (that is, one group of connecting pipeline group 21), pass through two pipelines and first Evaporator 41 is connected to, and specifically, can be connected to the first cooling capacity heat-exchanger rig of 41 side of the first evaporator, alternatively, passing through two pipes Road is connected to the second condenser 52, specifically, can be connected to the second heat heat-exchanger rig of 52 side of the second condenser.Utilize fluid Medium is by the heat transfer of 52 side of the cooling capacity of 41 side of the first evaporator or the second condenser to energy input end 201.That is, every A third heat-exchanger rig is independently connected to each first evaporator 41 (or each second condenser 52).For another example, as Fig. 6, Shown in Fig. 8, energy input end 201 is a third heat-exchanger rig, and is connected to multiple feed liquors in the liquid feeding end of third heat-exchanger rig Pipe 211, outlet end are connected to multiple outlet tubes 212.One inlet tube 211 and an outlet tube 222 are used as a connecting pipeline group 21, constitute multiple independent connecting pipeline groups, by multiple independent communication pipeline group respectively with each first evaporator 41 (or Each second condenser 52 of person) connection.

In another alternative embodiment, energy input end 201 is multiple, and the pipeline at multiple energy input ends 201 is mutual Connection.There are many mode interconnected, if realize can multiple energy input ends with the energy at energy stores station 10 discharge 102 connection of end.For example, as shown in fig. 7, multiple energy input ends 201 pass through feed liquor transfer pipeline 221 and out tube in liquid Road 222 is connected to, and the inlet tube 211 at each energy input end 201 is connected to feed liquor transfer pipeline 221, each energy input end 201 outlet tube 212 is connected to liquid transfer pipeline 222 out.Pass through feed liquor transfer pipeline 221 and out liquid transfer pipeline 222 again As one group of connecting pipeline group, it is connected to by two root canal roads with the first evaporator 41 (or each second condenser 52).

Similarly, when energy output end 202 is one or more, the pipeline of each energy output end 202 is independently arranged, setting Mode is identical with energy input end 201 above-mentioned.When energy output end 202 is multiple, the pipeline of multiple energy output ends 202 is mutual It is connected, mode of communicating is identical with energy input end 201 above-mentioned.Details are not described herein.

In the first of the embodiment of the present invention in heat exchanger, according to the pipeline of energy input end 202 and heat-exchange end 202 Set-up mode provides following several specific embodiments.

As shown in figure 4, the first transfer heat exchanger I, energy input end 201 is one, has a connecting pipeline group；Energy Measure output end 202 be it is multiple, the connecting pipeline group of multiple energy output ends 202 is independently arranged.That is, energy input end 201 and energy The pipeline of amount output end 202 is independently arranged.Turn multichannel all the way.

As shown in figure 5, the first transfer heat exchanger II, energy input end 201 is one, has a connecting pipeline group； Energy output end 202 is one, and an energy output end 202 has multiple connecting pipeline groups being independently arranged.That is, energy input The pipeline of end 201 and energy output end 202 is independently arranged.Turn multichannel all the way.

As shown in fig. 6, heat exchanger III in the first, energy input end 201 is one, and an energy input end 201 has There are multiple connecting pipeline groups being independently arranged；Energy output end 202 is one, has a connecting pipeline group.That is, energy input The pipeline of end 201 and energy output end 202 is independently arranged.Multichannel turns all the way.

As shown in fig. 7, heat exchanger V in the first, energy input end 201 is multiple, multiple 201 phases of energy input end It is intercommunicated by one group communicating pipe group be connected to the heat-exchanger rig of energy stores station 10 (or absorption edge temperature equipment 1011) side；Energy Measure output end 202 be it is multiple, the connecting pipeline group of multiple energy output ends 202 is independently arranged.That is, multiple energy input ends 201 Pipeline be interconnected, the pipeline of multiple energy output ends 202 is independently arranged.Turn multichannel all the way.

As shown in figure 8, heat exchanger IV in the first, energy input end 201 is one, and an energy input end 201 has There are multiple connecting pipeline groups being independently arranged；Energy output end 202 is one, and an energy output end 202 has multiple independences The connecting pipeline group of setting.That is, the pipeline of energy input end 201 and energy output end 202 is independently arranged.Multichannel turns multichannel.

As shown in figure 9, heat exchanger VI in the first, energy input end 201 is one, has a connecting pipeline group； Energy output end 202 is one, has a connecting pipeline group.That is, the pipeline at energy input end 201 and energy output end 202 It is independently arranged.Turn all the way all the way.

Certainly, the structure of heat exchanger 20 is not limited to above-mentioned six kinds in the first of the embodiment of the present invention, and wherein energy is defeated The structure for entering end 201 and energy output end 202 can be interchanged, can also be in any combination.In practical application, in selection adaptation The structure of heat exchanger.In addition, in the first heat exchanger 20 energy input end 201 (or energy output end 202) Connecting pipeline group when being multiple groups, number does not limit, the first evaporator 41 (or each second condenser according to required access 52) number determines.

In the first of the embodiment of the present invention in heat exchanger 20, the heat-exchanger rig and energy at energy input end 201 are exported The heat-exchanger rig at end 202 can be separately provided, and e.g., when using plate heat exchanger, the two is oppositely arranged and (can contact or do not contact), Guarantee that heat exchange area maximizes；When using heat exchange coil, the interlaced setting of the coil portions of the two is made (to can contact or not connect Touching), guarantee effectively heat exchange.Alternatively, the heat-exchanger rig at energy input end 201 and the heat-exchanger rig of energy output end 202 are designed as One.Set-up mode does not limit, as long as realizing, the heat-exchanger rig at energy input end 201 and the heat-exchanger rig of energy output end 202 It is able to carry out heat transmitting.It is that energy input end 201 and energy output end 202 are used and do not contacted as shown in Fig. 4 to Fig. 9 The heat-exchanger rig structure of formula being oppositely arranged, heat exchanger is not limited to given by attached drawing in the first of certain embodiment of the present invention Structure.

The energy input end 201 of heat exchanger 20 and energy output end 202, are exchanging heat in the first of the embodiment of the present invention When mode is the same, the structure of the two be it is the same, the two may be used interchangeably, simply facilitate differentiation be defined and ?.

As shown in Figure 10 and Figure 11, heat exchanger 30 in second, comprising:

Energy input end I 301, for being connected to one or more energy stores stations 10；

Energy output end I 302, for being connected to one or more mixed cells 41；With,

Undirectional thermal conducting 31, energy input end I 301 and energy output end I 302 are arranged in the two of undirectional thermal conducting 31 End.

Heat exchanger 30 in second of the embodiment of the present invention, can be in the first evaporation by increasing undirectional thermal conducting 31 When device 41 carries out Cooling capacity exchanging to the second evaporator 51, the target component (e.g., target temperature) according to the second evaporator 51 is to the Two evaporators 51 provide more accurate cooling capacity transmitting.In addition, apply also for when the first evaporator 41 and the second evaporator 51 (or Person, the second condenser 52 and the first condenser 42) between cannot by the direction of setting carry out energy transmission the case where.It is general to carry out When heat transmitting, the low one end of temperature can only be transmitted to from the high one end of temperature, for example, in the second condenser 52 and the first condenser 42 Between heat exchange direction initialization be the second condenser 52 to the first condenser 42 carry out heat exchange, if second condensation The medium temp of 52 side of device itself is lower than the medium temp of 42 side of the first condenser, then can not carry out heat by direction initialization at this time Exchange, will cause the heat losses of 42 side of the first condenser instead, plays opposite effect.Cooling capacity exchanging is carried out between evaporator When, and identical problem can be encountered.Therefore the embodiment of the invention provides heat exchanger 30 in this second, using unidirectionally leading Thermal 31 is adjusted to from the medium temp of heat (cooling capacity) storage sites guide device, can be to the accurate energy of offer Amount transmitting；Alternatively, making cooling capacity transmitting and the first condenser 42 and second between the first evaporator 41 and the second evaporator 51 Heat transfer between condenser 52 can normally carry out energy exchange by direction initialization.

Heat exchanger 30 in second of the embodiment of the present invention is the basis of the heat exchanger 20 in the first above-mentioned On, undirectional thermal conducting 31 is increased between energy input end and energy output end.Therefore, heat exchanger 30 in second The structure setting and role of energy input end I 301 and energy output end I 302 with heat exchanger 20 in the first Energy input end 201 and energy output end 202 it is identical, meanwhile, on energy input end I 301 and energy output end I 302 Input terminal conducting valve and output end conducting valve is respectively set, as heat exchanger 20 in the first.Before specifically referring to Content is stated, details are not described herein.

Therefore, the first the transfer heat exchanger I of foundation as described in Fig. 4 to Fig. 9 VI structure of heat exchanger into the first, Energy input end and energy output can successively be obtained by increasing undirectional thermal conducting 31 between energy input end and energy output end End corresponds to consistent second of transfer heat exchanger I to heat exchanger VI in second.Transition heat in as shown in Figure 10 second Device II 30 is to increase undirectional thermal conducting 31 on the basis of the first transfer heat exchanger II 20 to obtain, as shown in figure 11 Increase undirectional thermal conducting 31 on the basis of heat exchanger VI 30 is heat exchanger VI 20 in the first in second to obtain 's.

Heat exchanger 30 in second of the embodiment of the present invention, undirectional thermal conducting 31 are realized energy input terminal I 301 Heat (pressure) is exchanged to energy output end I 302.Refrigerant heat exchanger or semiconductor temperature adjustor can specifically be used.

In an alternative embodiment, as shown in Figure 10 and Figure 11, refrigerant heat exchanger includes evaporator 311, compressor (not shown), condenser 312 and expansion valve (not shown), four connect and compose heat-exchanging loop.Heat exchanger 30 wraps in second Include the heat absorption chamber 303 and heat release chamber 304 of the setting of two adiabatic heat-insulations；Heat exchanger 30 in evaporator 311 and second Energy input end I 301 is oppositely arranged, and is arranged in heat absorption chamber 303；Heat exchanger 30 in condenser 312 and second Energy output end I 302 is oppositely arranged, and is arranged in heat release chamber 304.

In an alternative embodiment, semiconductor temperature adjustor, including semiconductor chilling plate, setting are in semiconductor The first end heat exchanger of the first end of cooling piece and the second end heat exchanger and power supply unit of second end.Power supply unit is used for Electric energy is provided for semiconductor chilling plate.By controlling the direction of supply current, the first end and second of semiconductor chilling plate can be made It holds and is switched under the cold both of which of heat production and production.For example, first end is cold end under forward current, second end is heat End；Behind switching electric current direction, first end is switched to hot end, and second end is switched to cold end.Heat exchanger 30 includes two in second The heat absorption chamber 303 and heat release chamber 304 of a adiabatic heat-insulation setting；The energy of heat exchanger 30 in first end heat exchanger and second Amount input terminal I 301 is oppositely arranged, and is arranged in heat absorption chamber 303；Heat exchanger 30 in second end heat exchanger and second Energy output end I 302 is oppositely arranged, and is arranged in heat release chamber 304.Determine first end heat exchanger for heat according to actual conditions It holds (either cold end) and second end heat exchanger is cold end (or hot end).

In an alternative embodiment, a kind of energy resource system I, as shown in figure 12, one (or multiple) the first heat tune Save the heat between the first evaporator 41 of equipment 40 and the second evaporator 51 of multiple (or one) the second heat regulation equipment 50 Series connection accesses heat exchanger 20 in the first, heat exchanger and a first heat tune in the first in the communication paths of exchange Save the communication paths of the first evaporator 41 (or second evaporator 51 with a second heat regulation equipment 50) of equipment 40 Heat exchanger 30 in upper second of access in parallel；And/or

The first condenser 42 and multiple (or one) the second heat tune of one (or multiple) the first heat regulation equipment 40 Series connection access heat exchanger 20 in the first is saved in the communication paths of the heat exchange between the second condenser 52 of equipment 50, the A kind of middle heat exchanger and first heat regulation equipment 40 the first condenser 42 (or with the second heat tune Save the second condenser 52 of equipment 50) communication paths on it is second of access in parallel in heat exchanger 30.

As shown in figure 12, it is set with the first evaporator 41 of multiple first heat regulation equipment 40 with second heat regulation For the communication paths of heat exchange between standby 50 the second evaporator 51, illustrate above-mentioned energy resource system I.Multiple first evaporations Device 41 is turned in all the way the first heat exchanger 20 multichannel and is connected in a manner of heat exchange with second evaporator 51.And It is converted in second of the access in parallel on the connecting pipeline of the second evaporator 51 of the interface all the way of heat exchanger 20 in the first Hot device 30.And in the interface of parallel connection access, switching device is set, for switch the first evaporator 41 and the second evaporator 51 it Between the communication paths of heat exchange whether pass through heat exchanger in second.The position in parallel of heat exchanger 30 in certain second It does not limit, as long as can constitute in parallel with heat exchanger 20 in the first.Similarly, the first condenser 42 and the second condenser Heat exchanger 20 is consistent with the access way of heat exchanger 30 in second in the first between 52, repeats no more.

In further alternative embodiment, energy resource system further includes switching device, and the structure of switching device does not limit, only Realize that its switching acts on.Switching device is arranged at the connecting interface that heat exchanger in second is connected in parallel, and is used for Switch the communication paths between the first evaporator 41 and the second evaporator 51；And switching device setting is converted in second At the connecting interface that hot device is connected in parallel, for switching the communication paths between the first condenser 42 and the second condenser 52.The The connection between communication paths and the first condenser 42 and the second condenser 52 between one evaporator 41 and the second evaporator 51 Access is there are two state, and first state is that the two is connected in a manner of heat exchange heat exchanger in the first, the second shape State is that the two is connected in a manner of heat exchange heat exchanger in heat exchanger in the first and second.

Optionally, the switching device is control valve group, including two valves, liquid inlet control valve door 161 and returns hydraulic control Valve 162 processed passes through second of the transfer of the first state of the parallel pipeline 310 of heat exchanger 30 in blocking second and conducting The parallel pipeline 310 of heat exchanger 30 simultaneously blocks in second between second state of the connecting pipeline 320 of heat exchanger parallel connection section Switching the first evaporator 41 of switching and the second evaporator 51 (alternatively, the first condenser 42 and second condenser 52) are realized in conversion Between communication paths.

In an alternative embodiment, energy resource system further includes control device, for being set according to the first heat regulation The temperature of second evaporator 51 of the temperature and the second heat regulation equipment 50 of standby 40 the first evaporator 41, controls the first transfer Total aperture of multiple conducting valves of heat exchanger (heat exchanger 30 in heat exchanger 20 or second in the first) and each The aperture of valve is connected；And for the temperature and the second heat according to the first condenser 42 of the first heat regulation equipment 40 The temperature of second condenser 52 of adjustment equipment 50, heat exchanger (heat exchanger 20 or second in the first in control second Heat exchanger 30 in kind) multiple conducting valves total aperture and it is each conducting valve aperture.

In the present embodiment, with multiple first evaporations of multiple first heat regulation equipment 40 (air conditioner under heating mode) For device and second evaporator of a second heat regulation equipment 50 (refrigerator), illustrate the control process of control device. Total aperture of multiple conducting valves of heat exchanger can control total heat exchange amount, i.e. heat exchange needed for the second evaporator 51 in first Amount.And the aperture of each conducting valve can control the heat exchange amount of corresponding each first evaporator 41.Each first evaporator The summation of 41 heat exchange amount is total heat exchange amount needed for the second evaporator 51.It includes unidirectional for using for heat exchanger in first Heat exchanger in second of heat-transfer device, according to the temperature of the first evaporator 41 of the first heat regulation equipment 40 and the second heat The temperature for measuring the second evaporator 51 of adjustment equipment 50, controls heat exchanger in the thermally conductive parameter and first of undirectional thermal conducting The aperture of valve is connected.Pass through the aperture control of the conducting valve of heat exchanger in the thermally conductive parameter of undirectional thermal conducting and first Heat exchange amount.When undirectional thermal conducting is semiconductor temperature adjustor, thermally conductive parameter includes voltage, the temperature of collecting end of heat, collection cold end Temperature etc..When undirectional thermal conducting is refrigerant heat-exchanger rig, thermally conductive parameter includes compressor frequency, refrigerant temperature etc..Second The determination of the heat exchange amount of middle heat exchanger is ditto stated, and is repeated no more.

In the present embodiment, the aperture of valve is connected according to actual conditions, can be 0 to 1,0 is closing, 1 is standard-sized sheet.

For energy resource system I above-mentioned, control device is also used to, when determining the first evaporator 41 and the second evaporator 51 Between (alternatively, between the first condenser 42 and the second condenser 52) can not by the direction of setting carry out heat exchange when, control is cut It changes by heat exchanger 30 in second between the first evaporator 41 and the second evaporator 51 and heat exchanger 20 connects in the first It is logical.

Specifically, by taking the connection between the first condenser 42 and the second condenser 52 as an example, illustrate control process.Pass through inspection The first medium temp for surveying 42 side of the second medium temp and the first condenser of 52 side of the second condenser, by judging the first medium Whether the relationship of temperature and the second medium temp, determining can be by the side of setting between the first condenser 42 and the second condenser 52 To progress heat exchange.For example, the heat exchange direction set is, from the second condenser 52 to 42 heat supply of the first condenser, realizes that this sets The premise for determining heat exchange direction is that the second medium temp of 52 side of the second condenser is greater than the first medium of 42 side of the first condenser Temperature.Therefore, when the second medium temp is less than the first medium temp, with regard to nothing between the first condenser 42 and the second condenser 52 Method carries out heat exchange by the direction of setting, at this point, control switching device, switches between the first condenser 42 and the second condenser 52 The communication paths of heat exchange be connected to by heat exchanger 30 in second.The rest may be inferred, the first evaporator 41 and the second evaporation The control principle of Cooling capacity exchanging between device 51 is identical, and details are not described herein.

According to a second aspect of the embodiments of the present invention, the control method for providing a kind of energy resource system (can refer to aforementioned control The contents of device part processed), including,

S100, it is steamed according to the temperature of the first evaporator and the second of the second heat regulation equipment of the first heat regulation equipment The temperature of device is sent out, the aperture of total aperture of multiple conducting valves of heat exchanger and each conducting valve in control first.

It is S200, cold according to the second of the temperature of the first condenser of the first heat regulation equipment and the second heat regulation equipment The temperature of condenser controls the aperture of total aperture of multiple conducting valves of heat exchanger and each conducting valve in second.

It is the air conditioner under heating mode, the second heat regulation with the first heat regulation equipment 40 in the embodiment of the present invention Equipment 50 is for refrigerator.First evaporator 41 of air conditioner discharges useless cold in outdoor；First condenser 42 is room indoors Interior heating.Second evaporator 51 of refrigerator is the indoor food refrigeration of refrigerating chamber in the refrigerating chamber room of refrigerator；Second condenser 52 are located at the outside of refrigerator, discharge waste heat.

In the following, being set with a first heat regulation equipment 40 (air conditioner under heating mode) and multiple second heat regulations For standby 50 (refrigerators), illustrate the control method of the embodiment of the present invention.

In step S100, the temperature of the first evaporator 41 include the environment temperature of 41 side of the first evaporator (discharge it is useless cold Temperature), the temperature of the second evaporator 51 includes target temperature and actual temperature.The target temperature of second evaporator 51 is artificial Setting, e.g., -4 DEG C.Actual temperature is the actual temperature in refrigerator.

Optionally, as shown in figure 13, step S100, comprising:

S110, the environment temperature for obtaining 41 side of the first evaporator；The target temperature of each second evaporator 51 and practical temperature Degree, and obtain multiple temperature difference of target temperature and actual temperature；

S120, according to the environment temperature of multiple temperature difference and the first evaporator 41, obtain the input of heat exchanger in first The aperture (i.e. total aperture) of end conducting valve and the aperture of each output end conducting valve.

Wherein, in step S120, the temperature difference of the second evaporator is bigger, the output end conducting valve in corresponding communication paths Aperture is bigger；Conversely, the temperature difference is smaller, aperture is smaller.Guarantee enough heat exchange amounts, makes the practical temperature of each second evaporator, 51 side Degree reaches target temperature.Here heat exchanger can be heat exchanger in the first in first, be also possible to second of transfer Heat exchanger.

In further alternative embodiment, for energy resource system I above-mentioned, control method, comprising:

S110', the environment temperature for obtaining 41 side of the first evaporator；Obtain the target temperature and reality of each second evaporator 51 Border temperature, and obtain multiple temperature difference of target temperature and actual temperature；

The size of the actual temperature of S111, the environment temperature for judging 41 side of the first evaporator and the second evaporator 51；

S112, (nothing between the first evaporator 41 and the second evaporator 51 is determined when environment temperature is greater than actual temperature Method carries out heat exchange by the direction of setting, and direction initialization is the first evaporator 41 to 51 semen donors of the second evaporator), control the The communication paths of heat exchange between one evaporator 41 and the second evaporator 51 pass through heat exchanger in second；And execute step S120'.Switching device is controlled, the parallel pipeline 310 of heat exchanger 30 in second is connected and blocks transition heat in second The connecting pipeline 320 of device parallel connection section makes between the first evaporator 41 and the second evaporator 51 through heat exchanger 20 in the first It is connected to heat exchanger 30 in second with heat exchange method.

When environment temperature is greater than actual temperature, step S120 " is executed.

Heat exchanger unidirectionally leads in S120', the environment temperature of foundation temperature difference and the first evaporator 41 and second The thermally conductive parameter of thermal；The aperture for determining the conducting valve of heat exchanger in second and heat exchanger in the first The aperture (i.e. total aperture) of valve and the aperture of each output end conducting valve is connected in input terminal.

S120 ", the environment temperature according to temperature difference and the first evaporator 41, determine the input terminal of heat exchanger in the first The aperture (i.e. total aperture) of valve and the aperture of each output end conducting valve is connected.

In step S120', the thermally conductive parameter according to undirectional thermal conducting can be determined forces through heat exchanger in second The temperature of the medium of output end after heat exchange (lower than the target temperature of the second evaporator 51).At this point, heat exchanger in second Output end medium temperature it is lower, the aperture of the conducting valve (output end conducting valve) of heat exchanger is in subtracting in second Small trend.It, can be with according to multiple temperature difference in the case that the temperature of the medium of the output end of heat exchanger determines in second Determine the aperture (total aperture) of input terminal conducting valve and opening for each output end conducting valve of heat exchanger in the first Degree.Under normal circumstances, the temperature difference is bigger, and the aperture of corresponding output end conducting valve is bigger；Conversely, the temperature difference is smaller, aperture is smaller. Guarantee enough heat exchange amounts, the actual temperature of each second evaporator, 51 side is made to reach target temperature.

Step S120 " is the same as aforementioned step S120.

In step S200, the temperature of the first condenser 42 includes target temperature and actual temperature, the temperature of the second condenser 52 Degree includes the environment temperature (temperature of the waste heat of discharge) of 52 side of the second condenser,.The target temperature of first condenser 42 is people For setting, e.g., 24 DEG C.Actual temperature is indoor actual temperature.

Optionally, as shown in figure 14, step S200, comprising:

S210, the target temperature and actual temperature for obtaining each first condenser 42, and obtain target temperature and practical temperature Multiple temperature difference of degree；And obtain the environment temperature of 52 side of the second condenser；

S220, according to the environment temperature of 52 side of multiple temperature difference and the second condenser, determine the defeated of heat exchanger in second Enter the aperture (i.e. total aperture) of end conducting valve and the aperture of each output end conducting valve.

Wherein, in step S220, the temperature difference of the first condenser 42 is bigger, and valve is connected in the output end in corresponding communication paths Aperture it is bigger；Conversely, the temperature difference is smaller, aperture is smaller.Guarantee enough heat exchange amounts, makes the reality of each first condenser, 42 side Temperature reaches target temperature.Here heat exchanger can be heat exchanger in the first in second, be also possible in second Heat exchanger.

In further alternative embodiment, for energy resource system I above-mentioned, control method, comprising:

S210', the target temperature and actual temperature for obtaining each first condenser 42, and obtain target temperature and practical temperature Multiple temperature difference of degree；And obtain the environment temperature of 52 side of the second condenser；

The size of the environment temperature of S211, the actual temperature for judging 42 side of the first condenser and the second condenser 52；

S212, (determine that the second condenser 52 can not be by the direction of setting when environment temperature is less than actual temperature Cooling capacity exchanging is carried out to the second condenser 52, direction initialization is the second condenser 52 to 42 heating load of the first condenser), control the The communication paths of heat exchange between one condenser 42 and the second condenser 52 pass through heat exchanger in second；And execute step S220'.I.e. control switching device, conducting second in heat exchanger 30 parallel pipeline and block second in heat exchanger simultaneously The connecting pipeline for joining section makes between the first condenser 42 and the second condenser 52 through heat exchanger 20 in the first and second Middle heat exchanger 30 is connected to heat exchange method.

When environment temperature is greater than actual temperature, step S220 " is executed.

Heat exchanger unidirectionally leads in S220', the environment temperature of foundation temperature difference and the second condenser 52 and second The thermally conductive parameter of thermal；Determine conducting valve (input terminal conducting valve and the input terminal conducting valve of heat exchanger in second Door) aperture and in the first heat exchanger input terminal conducting valve aperture (i.e. total aperture) and each output end The aperture of valve is connected.

S220 ", according to the environment temperature of 52 side of multiple temperature difference and the second condenser, determine heat exchanger in second The aperture (i.e. total aperture) of valve and the aperture of each output end conducting valve is connected in input terminal.

In step S220', the thermally conductive parameter according to undirectional thermal conducting can be determined forces through heat exchanger in second The temperature of the medium of output end after heat exchange (greater than the target temperature of the first condenser 42).At this point, heat exchanger in second Output end medium temperature it is higher, the aperture of the conducting valve (output end conducting valve) of heat exchanger is in subtracting in second Small trend.It, can be with according to multiple temperature difference in the case that the temperature of the medium of the output end of heat exchanger determines in second Determine the aperture (total aperture) of input terminal conducting valve and opening for each output end conducting valve of heat exchanger in the first Degree.Under normal circumstances, the temperature difference is bigger, and the aperture of corresponding output end conducting valve is bigger；Conversely, the temperature difference is smaller, aperture is smaller. Guarantee enough heat exchange amounts, the actual temperature of 42 side of the first condenser is made to reach target temperature.

According to a third aspect of the embodiments of the present invention, a kind of storage medium is provided, computer program is stored thereon with, It is characterized in that, the control method of energy resource system above-mentioned is realized when the computer program is executed by processor.

The invention is not limited to the structures for being described above and being shown in the accompanying drawings, and can not depart from its model It encloses and carry out various modifications and change.The scope of the present invention is limited only by the attached claims.

Claims (10)

1. a kind of energy resource system, which is characterized in that including one or more first heat regulation equipment；With one or more the Two heat regulation equipment；

First evaporator of one or more first heat regulation equipment is set with multiple or second heat regulation The second standby evaporator is connected in a manner of heat exchange heat exchanger in first；

First condenser of one or more first heat regulation equipment is set with multiple or second heat regulation The second standby condenser is connected in a manner of heat exchange heat exchanger in second.

2. a kind of energy resource system according to claim 1, which is characterized in that

Heat exchanger is arranged in series in one or more first evaporators and multiple or one described second in described first On the access of heat exchange between evaporator；

Heat exchanger is arranged in series in one or more first condensers and multiple or one described second in described second In the communication paths of heat exchange between condenser.

3. a kind of energy resource system according to claim 1 or 2, which is characterized in that heat exchanger and described in described first Heat exchanger in second, comprising:

Input terminal, for being connected to second condenser or the second evaporator of the second heat regulation equipment；Alternatively, For being connected to first evaporator or the first condenser of the first heat regulation equipment；

Output end, correspondingly, for being connected to the first condenser or the first evaporator of multiple first heat regulation equipment；Or Person, for being connected to the second evaporator or the second condenser of multiple second heat regulation equipment；

Be connected valve, be arranged on the connecting pipeline of the input terminal and the connecting pipeline of the output end on.

4. a kind of energy resource system according to claim 3, which is characterized in that heat exchanger and second transfer in first Heat exchanger, further includes:

The both ends of the undirectional thermal conducting are arranged in undirectional thermal conducting, the input terminal and the output end.

5. a kind of energy resource system according to claim 1 or 2, which is characterized in that

First evaporator of one or more first heat regulation equipment is set with multiple or second heat regulation Transition heat in series connection access as claimed in claim 3 first in the communication paths of heat exchange between the second standby evaporator Device, in as claimed in claim 3 first first evaporator of heat exchanger and first heat regulation equipment or with Access as claimed in claim 4 first in parallel in the communication paths of second evaporator of one the second heat regulation equipment Middle heat exchanger；And/or

First condenser of one or more first heat regulation equipment is set with multiple or second heat regulation Transition heat in series connection access as claimed in claim 3 second in the communication paths of heat exchange between the second standby condenser Device, in as claimed in claim 3 second first condenser of heat exchanger and first heat regulation equipment or with Access as claimed in claim 4 second in parallel in the communication paths of second condenser of one the second heat regulation equipment Middle heat exchanger.

6. a kind of energy resource system according to claim 5, which is characterized in that it further include switching device, the switching device It is arranged at the connecting interface that heat exchanger is connected in parallel in as claimed in claim 4 first, is steamed for switching described first Send out the communication paths between device and second evaporator；

The switching device is arranged at the connecting interface that heat exchanger is connected in parallel in as claimed in claim 4 second, uses Communication paths between switching first condenser and second condenser.

7. a kind of energy resource system according to claim 1 or 2, which is characterized in that further include control device；

The control device, for according to the first evaporator of the first heat regulation equipment temperature and second heat The temperature of second evaporator of adjustment equipment, total aperture of multiple conducting valves of heat exchanger and each in control described first The aperture of valve is connected；

The control device, for according to the first condenser of the first heat regulation equipment temperature and second heat The temperature of second condenser of adjustment equipment, total aperture of multiple conducting valves of heat exchanger and each in control described second The aperture of valve is connected.

8. a kind of control method of energy resource system as described in any one of claims 1 to 7 characterized by comprising

According to the temperature of the second evaporator of the temperature of the first evaporator of the first heat regulation equipment and the second heat regulation equipment Degree controls the aperture of total aperture of multiple conducting valves of heat exchanger and each conducting valve in first；

According to the temperature of the second condenser of the temperature of the first condenser of the first heat regulation equipment and the second heat regulation equipment Degree controls the aperture of total aperture of multiple conducting valves of heat exchanger and each conducting valve in second.

9. control method according to claim 8, the energy resource system is energy resource system as claimed in claim 5；Its It is characterized in that, the control method, further includes:

When between the first evaporator and the second evaporator can not by the direction of setting carry out heat exchange when, switching the first evaporator and The communication paths of heat exchange between second evaporator pass through heat exchanger in as claimed in claim 4 first；

When between the first condenser and the second condenser can not by the direction of setting carry out heat exchange when, switching the first condenser and The communication paths of heat exchange between second condenser pass through heat exchanger in as claimed in claim 4 second.

10. a kind of storage medium, is stored thereon with computer program, which is characterized in that when the computer program is by processor The control method of the energy resource system as described in claim 8 to 9 any one is realized when execution.