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CN103256752A - Composite machine set of steam compression type refrigeration device and heating device, and use thereof - Google Patents

Composite machine set of steam compression type refrigeration device and heating device, and use thereof Download PDF

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Publication number
CN103256752A
CN103256752A CN201210038812.6A CN201210038812A CN103256752A CN 103256752 A CN103256752 A CN 103256752A CN 201210038812 A CN201210038812 A CN 201210038812A CN 103256752 A CN103256752 A CN 103256752A
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interface
seal
threeway
water
pipe
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罗鸣
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Abstract

The invention discloses a composite machine set of a steam compression type refrigeration device and a heating device. The purpose of the composite machine set is to create multiple refrigeration and heating cyclic economies. For example, a composite machine of an air conditioner and an air energy heat-pump water heater is in a steam compression type refrigeration system of the air conditioner; a water-cooling type condenser and a wind-cooling type condenser are connected in parallel through three pairs of tees and left and right bidirectional electromagnetic valves; an air energy evaporator is connected in parallel with a water source evaporator; a thermostatic expansion valve is connected in parallel with a capillary tube, and a control system is internally provided with a temperature difference controller and a defrosting temperature controller, so that the composite machine set heats in winter without using auxiliary electric heating, adjusts air in summer and can obtain hot water at 40 DEG C to 60 DEG C without enabling a compressor to be too hot, and the temperature and enthalpy of the colorant can be increased in winter due to the technical innovation mentioned above; the drop between the condensing temperature and the evaporating temperature of the colorant in summer is reduced; and hot water at 60 DEG C can be obtained in the whole year, so that a digital scroll compressor is unnecessary to be purchased. The composite machine set of the steam compression type refrigeration device and the heating device has the advantages of: (1) saving one host; and (2) saving energy and reducing discharge.

Description

Steam compression type refrigerating equipment and the compound unit of heating equipment and uses thereof
Technical field
The present invention is under the jurisdiction of steam compression type refrigerating equipment and the affiliated technical field of steam compression type heating equipment.
Background technology
Existing air-conditioner refrigeration air-conditioner in summer is to use cold-producing medium principle of sweat cooling in evaporimeter to manufacture and design both at home and abroad, and the condensation hot type that refrigerant vapour discharges in air cooled condenser is given atmosphere, is not utilized; It is to use refrigerant vapour condensation in water cooled condenser that existing air energy heat pump water heater is produced hot water, discharge condensation heat and cold water is heated at 45~60 ℃ hot water, for winter heating, annual bathing is used, and liquid refrigerant is not utilized in the refrigerating capacity that air energy evaporator evaporation produces, at all times particularly modern age global warming, countries in the world are advocated energy-saving and emission-reduction energetically, recycling economy, once constantly there was the people that the direct grafting of air-conditioner and air energy heat pump water heater is become compound unit, thirsting for refrigeration heats simultaneously, construct recycling economy, all do not have successfully, the inventor is at forefathers' failure cause, once in patent 200820118551.8 application documents, heat pump was produced hot water, directly be heated into 60 ℃ of hot water by disposable, change heating at twice into, when the indoor set refrigeration air-conditioner, produce 40 ℃ of low-temperature water heatings in the water cooled condenser earlier, to guarantee that the indoor set refrigeration does not reduce, the compound unit of recycling self heat pump is heated into 60 ℃ of hot water when treating without air-conditioner, hit half, but winter heating with produce hot water and still do not reach requirement, the present invention is repetition test on its basis, analysis and research are innovation again, has solved this technical barrier of all times finally.
Summary of the invention
Innovative point of the present invention is: (1) is clearly in parallel with an air energy evaporimeter with a water source evaporimeter by a pair of threeway in vapor compression refrigeration system, and is clearly that a water cooled condenser is in parallel with a typhoon cold type condenser to threeway by another; (2) particularly again by a pair of threeway with heating power expansion valve and capillary paralleling; (3) vertical center line in its three interface tube cross sections of each threeway of refrigerant conveying is parallel to each other in steam compression type refrigerating heats hybrid system.
Task of the present invention is: air conditioner be become the multi-function peripheral group with the air energy heat pump water heater grafting, not only summer the indoor set refrigeration air-conditioner, simultaneously can pass through water cooled condenser, first generation product is produced 40 ℃ of low-temperature water heatings earlier, is heated into 60 ℃ of bathing hot water for the second time by self heat pump again when treating without air-conditioning; Not only summer can refrigeration air-conditioner for second generation product; And can become 55 °~60 ℃ bathing hot water by the direct one-time heating of water cooled condenser simultaneously, and refrigeration and Energy Efficiency Ratio are still in the GB claimed range; Winter heating's heating, indoor set air port temperature reaches 35 °~45 ℃, and without the auxiliary electrical heating, also can move winter, can be used as air energy heat pump water heater the whole year, produce 55 °~60 ℃ bathing hot water, and can be without the more expensive digital scroll compressor of price, this is because above-mentioned innovative point has been realized first generic task of the present invention, and can also make other three major types cooling and warming energy-conserving product of aftermentioned, construct recycling economy, realize energy-saving and emission-reduction.
The present invention is achieved in that shown in figure (2): in its vapor compression type refrigerating system of family expenses air-conditioner, between the left interface of the left interface of four-way electromagnetic reversing valve and device for drying and filtering, by a pair of threeway and about two pairs of bidirectional electromagnetic valves a water cooled condenser is in parallel with a typhoon cold type condenser, again by the right interface of four-way electromagnetic reversing valve by another to threeway and about two pairs of bidirectional electromagnetic valves a water source evaporimeter is in parallel with an air energy evaporimeter, again by the right interface of device for drying and filtering again by a pair of threeway with heating power expansion valve and capillary paralleling, and heating power expansion valve is connected with seal for pipe joints with water source evaporimeter its vertical direction interface tube of below threeway with air energy evaporimeter and coupling with its vertical direction interface tube of right side threeway with capillary paralleling, thereby constitute domestic air conditioner and air energy heat pump water heater and steam compression type refrigerating thereof and heat hybrid system, in described system, charge an amount of cold-producing medium, fluorine Lyons F22 for example, because the winter air temperature is below 0 ℃, and the running water temperature is more than 0 ℃, thereby it is higher by the liquid refrigerant temperature of exporting in the air cooled condenser by the liquid refrigerant temperature ratio of water cooled condenser output, cold-producing medium evaporating temperature because of the capillary section discharge orifice of flowing through is-10 ℃ again, and the cold-producing medium evaporating temperature of the heating power expansion valve throttle orifice of flowing through is by little increase, for example by-10 ℃ increase to gradually+20 °, depend on that throttle orifice opens greatly gradually, the cold-producing medium throttling and evaporation temperature-averaging maximum t after importing threeway simultaneously and converge by capillary and heating power expansion valve Max÷ 2=5 ℃ of=[+20 °+(10 °)]; it is than capillary-compensated evaporating temperature-10 ℃; 15 ℃ have been promoted; [Δ t=[5 ℃-(10 °)]=15 ℃]; the refrigerant vapour that converges winter is inhaled into compressor and constantly compresses; help to heat up and increase enthalpy; so winter heating's heating can be heated without auxiliary electrical; producing 60 ℃ of bathings again winter can digital scroll compressor with hot water; if the off-premises station of air-conditioner is used as the main frame of heat pump; produce 60 ° of hot water; then condensation temperature is 60 ℃; evaporating temperature is-10 ℃; both temperature falls are big; Δ t=60 ℃-(10 ℃)=70 ℃; the easy overheated shutdown of compressor; and capillary is with after heating power expansion valve is in parallel; the mix refrigerant evaporating temperature is 5 ℃; t=60 ℃-5 ℃=55 ℃ of both temperature fall Δs; thereby the whole year is when producing 60 ℃ of hot water; compressor can be not overheated yet; when indoor set while refrigeration air-conditioner; Energy Efficiency Ratio is still in the GB claimed range; this prototype test confirms one by one, and adopts the vertical center line threeway parallel to each other in three interface tube cross sections, shown in enlarged drawing among the figure (9); be intended to guarantee that the refrigerant vapor forced direction is parallel to each other, do not produce acting in opposition pressure flow of refrigerant is obstructed.
Advantage of the present invention is: it compares (1) with the air energy heat pump water heater of the air-conditioner of domestic and international simple function and simple function and has saved a main frame, can reduce manufacturing cost for enterprise, is national resource-saving, for the user reduces expenses; (2) use a electric power, cooling and warming obtains two parts of incomes simultaneously, can make energy-conserving product, constructs recycling economy, energy-saving and emission-reduction, and mitigation of global climate warms.
Description of drawings:
Figure (1) is that first kind of steam compression type refrigerating equipment and its steam compression type refrigerating of the compound unit of heating equipment that solar water heating system is housed heat hybrid system A1 principle schematic.
Figure (2) is that the first ' kind steam compression type refrigerating equipment and its steam compression type refrigerating of the compound unit of heating equipment of not adorning solar water heating system heat hybrid system A1 ' principle schematic.
Figure (3) is that second kind of steam compression type refrigerating equipment and its steam compression type refrigerating of the compound unit of heating equipment of being connected with attemperater heat hybrid system A2 principle schematic.
Figure (4) is that the second ' kind vapor compression refrigeration equipment and its steam compression type refrigerating of the compound unit of heating equipment of not connecting attemperater and solar thermal collector thereof heat hybrid system A2 ' principle schematic.
To be the third steam compression type refrigerating equipment that solar water heating system is housed establish its steam compression type refrigerating of compound unit and heat hybrid system A3 principle schematic with heating figure (5).
Figure (6) be do not adorn solar water heating system the 3rd ' plant steam compression type refrigerating equipment and its steam compression type refrigerating of the compound unit of heating equipment heats hybrid system A3 ' principle schematic.
Figure (7) is that the 4th kind of compression refrigeration equipment and its steam compression type refrigerating of the compound unit of heating equipment heat hybrid system A4 principle schematic.
Figure (8) is that the 5th kind of steam compression type refrigerating equipment and its steam compression type refrigerating of the compound unit of heating equipment heat hybrid system A5 principle schematic.
Figure (9) is the 5th ' plant be parallel with in steam compression type refrigerating equipment and the compound unit of heating equipment an air can evaporimeter and a typhoon cold type condenser the 5th ' the kind steam compression type refrigerating heats hybrid system A5 ' principle schematic.
Figure (10) is that the 6th kind of steam compression type refrigerating equipment and its steam compression type refrigerating of the compound unit of heating equipment heat hybrid system A6 principle schematic.
Figure (11) is that the 7th kind of steam compression type refrigerating equipment and its steam compression type refrigerating of the compound unit of heating equipment heat hybrid system A7 principle schematic.
Figure (12) is that the 8th kind of steam compression type refrigerating equipment and its steam compression type refrigerating of the compound unit of heating equipment heat hybrid system A8 principle schematic.
Figure (13) heats its control system of hybrid system A1 ' C circuit theory diagrams corresponding to the first ' kind steam compression type refrigerating equipment and its steam compression type of the compound unit of heating equipment that solar water heating system is not housed of scheming (2).
The specification remarks
Related equipment, parts and device comprises existing conventional products and up-to-date innovative product on the market in specification of the present invention and claims, suited measures to local conditions to select for use by the designer to customize or choose.
(1) solar water heating system: comprise water tank and heat collector separated type solar water heater, integral type solar energy heat hydrophone, solar heating engineering system, solar vacuum-tube water system or water heater, heat pipe solar energy water system or water heater, plate tube-sheet type solar water heating system or water heater or three anti-solar vacuum-tube water systems or water heater etc.
(2) heat-exchange system: comprise the floor heating heat-exchange system, the fan coil heat-exchange system of leaking water, cold and hot air channel heat-exchange system, the heat-exchange system of walking cold-producing medium of ceiling mounting type indoor set, wall indoor unit or vertical cabinet-type air conditioner etc. be housed.
(3) water cooled condenser: comprise big displacement type water cooled condenser, little displacement type water cooled condenser, be that the heat-exchangers of the plate type of refrigerant is as water cooled condenser with water, or be that the heat-exchangers of the plate type of refrigerant is as the liquid-cooled condenser with anti-icing fluid, the garden cartridge type water cooled condenser that spiral metal tube and garden tube are formed, the water cooled condenser that snakelike metal tube and box describe device are formed, the shell pipe type water cooled condenser, the water-cooled tube-in-tube condenser, coiled pipe template water cooled condenser etc.
(4) water source evaporimeter: spiral tube evaporator, shell and tube evaporator, bushing type evaporimeter, upright tubular evaparator, pipe-coil type evaporator, tube-sheet type evaporimeter, plate-type evaporator, coiled evaporimeter etc.
(5) air cooled condenser: comprise finned coil formula condenser, calandria evaporator, interchanger as evaporimeter.
(6) air energy evaporimeter: comprise the described version of above-mentioned air cooled condenser.
(7) compressor: comprise the used compressor of air-conditioner, Reciprocting piston compressor, rotary piston compressor, screw compressor, scroll compressor, constant speed compressor, frequency-changeable compressor, centrifugal compressor, turbocompressor etc.
(8) choke valve: comprise a capillary, one group of parallel capillary, heating power expansion valve, electric expansion valve.
(9) main frame: comprise air-conditioner main frame (off-premises station), air energy heat pump water heater main frame, the used compressor of central air-conditioning, central heat pump water-heating machine dedicated compressor.
(10) water source: comprise water source, river source, lake water source, water source, pond, well water source, running water source, earth surface water source, underground water source from the beginning, change into the water source by soil heat source.
Case study on implementation (one)
Existing its vapor compression type refrigerating system of air-conditioner A0; be by compressor 1; interface 2C is to left interface 2a on the centre of four-way electromagnetic reversing valve 2; air cooled condenser 5A; device for drying and filtering 9; choke valve 10; air energy evaporimeter 6A; the right interface 2b of four-way electromagnetic reversing valve 2 is to middle lower interface 2d and gas-liquid separator 11; be tightly connected into vapor compression type refrigerating system A0 successively with pipeline; the invention process case (one) is that first kind of steam compression type refrigerating of steam compression type refrigerating equipment and the compound unit of heating equipment heats hybrid system A1; shown in figure (1); its architectural feature is: in the vapor compression type refrigerating system A0 of existing air-conditioner; between the left interface of the left interface 2a of four-way electromagnetic reversing valve 2 and device for drying and filtering 9; by number one threeway 3A and No. second threeway 3B that water cooled condenser 5B is in parallel with air cooled condenser 5A; that is in the left interface of number one threeway 3A and the air cooled condenser 5A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints; in its connecting pipe bidirectional electromagnetic valve 4C is housed or is not adorned No. three; in the right interface of number one threeway 3A and the water cooled condenser 5B on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints; in its connecting pipe bidirectional electromagnetic valve 4D is housed or is not adorned No. four; the last interface of number one threeway 3A is connected with seal for pipe joints with the left interface 2a of four-way electromagnetic reversing valve 2; the left interface of No. second threeway 3B is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser 5A; in its connecting pipe number one bidirectional electromagnetic valve 4A is housed; the right interface of No. second threeway 3B is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of water cooled condenser 5B; in its connecting pipe bidirectional electromagnetic valve 4B is housed No. second; the lower interface of No. second threeway 3B is connected with seal for pipe joints with the left interface of device for drying and filtering 9; particularly by No. five threeway 3E and No. six threeway 3F that heating power expansion valve 10B is in parallel with capillary 10A; that is No. five threeway 3E vertical direction interface tube is connected with seal for pipe joints with the right interface of device for drying and filtering 9; the last interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of capillary 10A; in its connecting pipe bidirectional electromagnetic valve 4J is housed No. ten; the lower interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of heating power expansion valve 10B; in its connecting pipe bidirectional electromagnetic valve 4I is housed No. nine, and the last interface of No. six threeway 3F is connected with seal for pipe joints with the right interface of capillary 10A, and the lower interface of No. six threeway 3F is connected with seal for pipe joints with the right interface of heating power expansion valve 10B; by No. three threeway 3C and No. four threeway 3D that water source evaporimeter 6B is in parallel with air energy evaporimeter 6A again; that is the right interface 2b of four-way electromagnetic reversing valve 2 is connected with seal for pipe joints with the last interface of No. three threeway 3C, and interface is connected with seal for pipe joints on the spiral metal tube of No. three threeway 3C left side interface and the interior refrigerant conveying of water source evaporimeter 6B, in its connecting pipe bidirectional electromagnetic valve 4H is housed or does not adorn No. eight; the right interface of No. three threeway 3C and air can evaporimeter 6A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints; in its connecting pipe bidirectional electromagnetic valve 4G is housed or does not adorn No. seven, the right interface of No. four threeway 3D is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter 6A, in its connecting pipe bidirectional electromagnetic valve 4E is housed No. five; No. four threeway 3D left side interface is connected with seal for pipe joints with the lower interface of the spiral metal tube of the interior refrigerant conveying of water source evaporimeter 6B; in its connecting pipe bidirectional electromagnetic valve 4F is housed No. six, the lower interface of No. four threeway 3D is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway 3F, thereby constitutes closed system; in described system, charge an amount of cold-producing medium; for example: fluorine Lyons F22, or F134a, water cooled condenser 5B and water source its water container of evaporimeter 6B are connected with; the lower communicating tube road; and at last connecting pipe No. seven unidirectional electrical magnet valve 15G is housed No. five water pump 14E and No. seven unidirectional electrical magnet valve 15G are housed in the lower communicating tube road; but the number one differential temperature controller 7A of design temperature is housed on the water cooled condenser 5B, and its water container of water cooled condenser 5B does not connect or is connected with number one attemperater 12A and first group of solar thermal collector 13A thereof, that is the outlet pipe interface of its water container of water cooled condenser 5B is connected with seal for pipe joints with the water inlet pipe interface of number one attemperater 12A; in its connecting pipe number one water pump 14A is housed; the water inlet pipe interface of its water container of water cooled condenser 5B is connected with seal for pipe joints with the outlet pipe interface of number one attemperater 12A, in its connecting pipe unidirectional electrical magnet valve 15B is housed No. second, and the opposite side water inlet pipe and water outlet pipe interface of number one attemperater 12A is connected with first group of solar thermal collector 13A; at number one attemperater 12A outlet conduit number one unidirectional electrical magnet valve 15A is housed; the inlet channel of number one attemperater 12A is equipped with water pump 14C No. three, below water cooled condenser 5B water container interface tube and number one from the beginning water source 16A be connected with seal for pipe joints, in its connecting pipe unidirectional electrical magnet valve 15E is housed No. five; the outlet pipe interface is housed above the opposite side of water cooled condenser 5B water container; connect usefulness for watering equipment, and unidirectional electrical magnet valve 15C is housed No. three, water cooled condenser 5B water container below is provided with drain interface; and unidirectional electrical magnet valve 15D is housed No. four; its top is provided with overfall, but evaporimeter 6B in water source is equipped with No. second differential temperature controller 7B of design temperature again, and interface tube is connected with seal for pipe joints with No. second water source 16B below water source evaporimeter 6B water container; at its pipeline unidirectional electrical magnet valve 15L is housed the ten No. two; water inlet pipe and water outlet pipe interface at water source evaporimeter 6B water container opposite side is connected with seal for pipe joints with the indoor fan coil 18 water inlet pipe and water outlet pipe interfaces of leaking water, and in its connecting pipe No. six water pump 14F and ride on Bus No. 11 unidirectional electrical magnet valve 15K is housed, and water source evaporimeter 6B is provided with an outlet pipe interface; and unidirectional electrical magnet valve 15M is housed the ten No. three; connect usefulness for watering equipment, heat hybrid system A1 thereby formation refrigeration plant and heating equipment compounding machine are assembled with first kind of steam compression type refrigerating of solar water heating system, shown in figure (1); or constitute the first ' the kind steam compression type refrigerating that refrigeration plant and heating equipment do not adorn solar water heating system and heat hybrid system A1 '; shown in figure (2), and its steam compression type refrigerating of the compound unit of refrigeration plant and heating equipment heats hybrid system control system C is housed, and it is by compressor electric motor 1a; air cooled condenser fan electromotor 5Aa; air energy evaporimeter fan electromotor 6Aa; pump motor 14a; four-way electromagnetic reversing valve coil 2a '; bi-directional electromagnetic valve coil 4a; unidirectional electromagnetic valve coil 15a; starting relay 20; capacitor 1C; overload protective device 22; temperature controller 23; but the differential temperature controller 7a of design temperature; defrosting temperature controller 27; selector switch 24; battery main switch 28; attaching plug 25; the above main electrical equipment of supply socket is according to refrigeration plant and the compound unit structural principle of heating equipment and purposes apolegamy combination; be electrically connected and form; for example figure (13) is figure (2), and the compound unit the first ' of refrigeration plant and heating equipment is planted steam compression type refrigerating and heated its control system of hybrid system A1 ' C circuit theory diagrams, and 1a is compressor electric motor among the figure; 5Aa is the air cooled condenser fan electromotor; 6Aa is air energy evaporator fan motor; 14Ea is No. five pump motor; 14Fa is No. six pump motor; 2a is the four-way electromagnetic reversing valve coil; 4a is number one bi-directional electromagnetic valve coil; 4b is No. second bi-directional electromagnetic valve coil; 4C is No. three bi-directional electromagnetic valve coil; 4d is No. four bi-directional electromagnetic valve coil; 4e is No. five bi-directional electromagnetic valve coil; 4f is No. six bi-directional electromagnetic valve coil; 4g is No. seven bi-directional electromagnetic valve coil; 4h is No. eight bi-directional electromagnetic valve coil; 4i is No. nine bi-directional electromagnetic valve coil; 4J is No. ten bi-directional electromagnetic valve coil; 15C is No. three unidirectional electromagnetic valve coil; 15e is No. five unidirectional electromagnetic valve coil; 15g is No. seven unidirectional electromagnetic valve coil; 15k is the unidirectional electromagnetic valve coil of ride on Bus No. 11; 1C is the compressor electric motor capacitor; 5Ac is air cooled condenser fan electromotor capacitor; 6Ac is air energy evaporator fan motor capacitor; 14Ec is No. five pump motor capacitor; 14Fc is No. six pump motor capacitor; 23 are the compressor temperature controller; 27 are the defrosting temperature controller; 27 are the defrosting temperature controller; 7a is water cooled condenser number one differential temperature controller; 7b for the water source evaporimeter with No. second differential temperature controller; 22 is overload protective device; 24 is selector switch; 25 is attaching plug; 28 is battery main switch.
Case study on implementation (two) is that second kind of refrigeration plant and its steam compression type refrigerating of the compound unit of heating equipment heat hybrid system A2, shown in figure (3), its architectural feature is: heat in the hybrid system A1 at first kind of steam compression type refrigerating, between the left interface of the left interface 2a of four-way electromagnetic reversing valve 2 and device for drying and filtering 9, in parallel with air cooled condenser 5A by number one threeway 3A and No. second threeway 3B little displacement type water cooled condenser 5B that will be rapidly heated, that is interface is connected with seal for pipe joints on the coil pipe of number one threeway 3A left side interface and the interior refrigerant conveying of air cooled condenser 5A, in its connecting pipe bidirectional electromagnetic valve 4C is housed or is not adorned No. three, interface is connected with seal for pipe joints on the spiral metal tube of the right interface of number one threeway 3A and the refrigerant conveying in the little displacement type water cooled condenser 5B of being rapidly heated, in its connecting pipe bidirectional electromagnetic valve 4D is housed or is not adorned No. four, the last interface of number one threeway 3A is connected with seal for pipe joints with the left interface 2a of four-way electromagnetic reversing valve 2, the left interface of No. second threeway 3B is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser 5A, in its connecting pipe number one bidirectional electromagnetic valve 4A is housed, the right interface of No. second threeway 3B is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of little displacement type water cooled condenser 5B that is rapidly heated, in its connecting pipe bidirectional electromagnetic valve 4B is housed No. second, the lower interface of No. second threeway 3B is connected with seal for pipe joints with the left interface of device for drying and filtering 9, the right interface of device for drying and filtering 9 is connected with seal for pipe joints with No. five threeway 3E vertical direction interface tube, the last interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of capillary 10A, in its connecting pipe bidirectional electromagnetic valve 4J is housed No. ten, the lower interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of heating power expansion valve 10B, adorn bidirectional electromagnetic valve 4I No. nine in its connecting pipe, and the last interface of No. six threeway 3F is connected with seal for pipe joints with the right interface of capillary 10A, the lower interface of No. six threeway 3F is connected with seal for pipe joints with the right interface of heating power expansion valve 10B, by No. three threeway 3C and No. four threeway 3D that air energy evaporimeter 6A is in parallel with the little displacement type of fast cooling water source evaporimeter 6B again, that is the right interface 2b of four-way electromagnetic reversing valve 2 is connected with seal for pipe joints with the last interface of No. three threeway 3C, in the left interface of No. three threeway 3C and the little displacement type of the fast cooling water source evaporimeter 6B on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints, in its connecting pipe bidirectional electromagnetic valve 4H is housed or is not adorned No. eight, the right interface of No. three threeway 3C and air can evaporimeter 6A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints, in its connecting pipe bidirectional electromagnetic valve 4G is housed or is not adorned No. seven, the right interface of No. four threeway 3D is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter 6A, in its connecting pipe bidirectional electromagnetic valve 4E is housed No. five, the left interface of No. four threeway 3D is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of the little displacement type of fast cooling water source evaporimeter 6B, in its connecting pipe the 6th bidirectional electromagnetic valve 4F is housed, the lower interface of No. four threeway 3D is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway 3F, thereby the formation closed system, irritating in described system has an amount of cold-producing medium, as fluorine Lyons F22 or F134a, but the number one differential temperature controller 7A of design temperature is housed at the little displacement type water cooled condenser 5B that is rapidly heated, the water inlet pipe and water outlet pipe interface of little its water container of displacement type water cooled condenser 5B of being rapidly heated is connected with or does not connect number one attemperater 12A, does not connect or is connected with first group of solar thermal collector 13A, and the water inlet pipe interface of number one attemperater 12A is connected with seal for pipe joints with the outlet pipe interface of the little displacement type water cooled condenser 5B water container that is rapidly heated, number one water pump 14A is housed on its connecting pipe, the water inlet pipe interface of little its water container of displacement type water cooled condenser 5B of being rapidly heated is connected with seal for pipe joints with the outlet pipe interface of number one attemperater 12A, in its connecting pipe unidirectional electrical magnet valve 15B is housed No. second, and the below interface tube of number one attemperater and number one water source 16A from the beginning are connected with seal for pipe joints, in its connecting pipe unidirectional electrical magnet valve 15E is housed No. five, number one attemperater 12A leaves an outlet pipe interface, and No. four unidirectional electrical magnet valve 15D is housed connects usefulness for watering equipment, but the little displacement type of fast cooling water source evaporimeter 6A also is equipped with No. second differential temperature controller 7B of design temperature again, its water container outlet pipe interface of the little displacement type of fast cooling water source evaporimeter 6A is connected with seal for pipe joints with the water inlet pipe interface of No. second attemperater 12B, in its connecting pipe water pump 14C is housed No. three, the water inlet pipe interface of the little displacement type of fast cooling water source its water container of evaporimeter 6A is connected with seal for pipe joints with the outlet pipe interface of No. second attemperater 12B, in its connecting pipe unidirectional electrical magnet valve 15I is housed No. nine, the below interface tube of No. second attemperater 12B is connected with seal for pipe joints with No. second water source 16B, at its pipeline unidirectional electrical magnet valve 15L is housed the ten No. two, the little displacement type of fast cooling water source evaporimeter 6A, the water inlet pipe and water outlet pipe interface of its water container opposite side is connected with seal for pipe joints with the indoor fan coil 18 water inlet pipe and water outlet pipe interfaces of leaking water, in its connecting pipe No. six water pump 14F and ride on Bus No. 11 unidirectional electrical magnet valve 15K are housed, between number one attemperater 12A and No. second attemperater 12B Inlet and outlet water tube connector up and down is housed, last tube connector is equipped with unidirectional electrical magnet valve 15G No. seven, and following tube connector is equipped with water pump 14E No. five, with the 7th ' number unidirectional electrical magnet valve 15G ', leave a titting water outlet at the second attemperater 12B, and the 13 unidirectional electrical magnet valve 15M is housed, connect for watering equipment and use, thereby constitute refrigeration plant and second kind of steam compression type refrigerating of the compound unit of heating equipment and heat hybrid system A2, shown in figure (3), or constitute refrigeration plant and do not plant steam compression type refrigerating with the second ' of attemperater and solar thermal collector thereof with the compound unit of heating equipment and do not heat hybrid system A2 ', as scheming shown in (4).
Case study on implementation (three) is that the compound unit steam compression type refrigerating of the third refrigeration plant and heating equipment heats hybrid system A3, shown in figure (5), its architectural feature is: heat in the hybrid system A1 at first kind of steam compression type refrigerating, between the left interface of the left interface 2a of four-way electromagnetic reversing valve 2 and device for drying and filtering 9, by number one threeway 3A and No. second threeway 3B that air cooled condenser 5A is in parallel with the big displacement type water cooled condenser 5B that heats up at a slow speed, that is in the left interface of number one threeway 3A and the air cooled condenser 5A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints, in its connecting pipe bidirectional electromagnetic valve 4C is housed or is not adorned No. three, interface is connected with seal for pipe joints on the spiral metal tube of the right interface of number one threeway 3A and the refrigerant conveying in the big displacement type water cooled condenser 5B of heating up at a slow speed, in its connecting pipe bidirectional electromagnetic valve 4D is housed or is not adorned No. four, the last interface of number one threeway 3A is connected with seal for pipe joints with the left interface 2a of four-way electromagnetic reversing valve 2, the left interface of No. second threeway 3B is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser 5A, in its connecting pipe number one bidirectional electromagnetic valve 4A is housed, the right interface of No. second threeway 3B is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of big displacement type water cooled condenser 5B that heats up at a slow speed, in its connecting pipe bidirectional electromagnetic valve 4B is housed No. second, the lower interface of No. second threeway 3B is connected with seal for pipe joints with the left interface of device for drying and filtering 9, the right interface of device for drying and filtering 9 is connected with seal for pipe joints with No. five threeway 3E vertical direction interface tube, No. five threeway 3E goes up interface and is connected with seal for pipe joints with the left interface of capillary 10A, in its connecting pipe bidirectional electromagnetic valve 4J is housed No. ten, the lower interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of heating power expansion valve 10B, in its connecting pipe bidirectional electromagnetic valve 4I is housed No. nine, and the last interface of No. six threeway 3F is connected with seal for pipe joints with the right interface of capillary 10A, the lower interface of No. six threeway 3F is connected with seal for pipe joints with the right interface of heating power expansion valve 10B, again by No. three threeway 3C and No. four threeway 3D with the little displacement type of fast cooling with water be heat transfer medium pass through air that number one fan coil 18A absorbs the room air heat can evaporimeter 6A evaporimeter 6B is in parallel with the big displacement type water source that lowers the temperature at a slow speed, that is the right interface 2b of four-way electromagnetic reversing valve 2 is connected with seal for pipe joints with the last interface of No. three threeway 3C, interface is connected with seal for pipe joints on the spiral metal tube of the right interface of No. three threeway 3C and the refrigerant conveying in the big displacement type water source evaporimeter 6B of lowering the temperature at a slow speed, in its connecting pipe bidirectional electromagnetic valve 4G is housed or is not adorned No. seven, the little displacement type air of the left interface of No. three threeway 3C and fast cooling can evaporimeter 6A on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints, in its connecting pipe bidirectional electromagnetic valve 4H is housed or is not adorned No. eight, the left interface of No. four threeway 3D is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of the little displacement type air energy of fast cooling evaporimeter 6A, in its connecting pipe bidirectional electromagnetic valve 4F is housed No. six, the right interface of No. four threeway 3D is connected with seal for pipe joints with the lower interface of the spiral metal tube of the interior refrigerant conveying of big displacement type water source evaporimeter 6B of lowering the temperature at a slow speed, in its connecting pipe bidirectional electromagnetic valve 4E is housed No. five, the lower interface of No. four threeway 3D is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway 3F, thereby the formation closed system in described system, charges an amount of cold-producing medium, as fluorine Lyons R22 or R134a, but the number one differential temperature controller 7A of design temperature is housed on the water cooled condenser 5B, below water cooled condenser 5B interface tube and number one from the beginning water source 16A be connected with seal for pipe joints, in its connecting pipe unidirectional electrical magnet valve 15C is housed No. three, water cooled condenser 5B leaves an outlet pipe interface, and unidirectional electrical magnet valve 15D is housed No. four, and connecting usefulness for watering equipment, the little displacement type air of fast cooling can be connected with water source 16B No. second by evaporimeter 6A water container below water inlet pipe interface, and the 12 unidirectional electrical magnet valve 15L is housed, the little displacement type air of fast cooling can leave drain interface by its water container of evaporimeter 6A, and unidirectional electrical magnet valve 15N is housed the ten No. four, and the little displacement type air evaporator of fast cooling 6A walks water receptacle opposite side water inlet pipe and water outlet pipe interface and is connected with the indoor number one fan coil 18A that leakes water, number one water pump 14A is housed on the connecting pipe thereon, its down connecting pipe unidirectional electrical magnet valve 15H is housed No. eight, the little displacement type air of fast cooling can evaporimeter 6A again, but No. second temperature controller 7B of design temperature also is housed, water source evaporimeter 6B is connected with or does not connect attemperater 12B No. second, the outlet pipe interface of water source its water container of evaporimeter 6B is connected with seal for pipe joints with the water inlet pipe interface of No. second attemperater 12B, in its connecting pipe water pump 14C is housed No. three, and the water inlet pipe interface of water source its water container of evaporimeter 6B is connected with seal for pipe joints with the outlet pipe interface of the second insulation water 12B, in its connecting pipe unidirectional electrical magnet valve 15E is arranged No. five, interface tube is connected with seal for pipe joints with No. second water source 16B below water source evaporimeter 6B water container, at its pipeline unidirectional electrical magnet valve 15F is housed No. six, is connected with seal for pipe joints with the indoor No. second fan coil 18B water inlet pipe and water outlet pipe interface of leaking water at the water inlet pipe and water outlet pipe interface of water source evaporimeter 6B water container opposite side, water pump 14B is housed on the connecting pipe No. second thereon, its down connecting pipe unidirectional electrical magnet valve 15I is housed No. nine, the opposite side water inlet pipe and water outlet pipe interface of No. second attemperater 12B is connected with pipeline or does not connect second group of solar thermal collector 13B, at the inlet channel of No. second attemperater 12B water pump 14D is housed No. four, outlet conduit at No. second attemperater 12B is equipped with unidirectional electrical magnet valve 15H No. eight, the little displacement type air of the water container of water cooled condenser 5B and fast cooling can be provided with between the water container of evaporimeter 6A, unidirectional electrical magnet valve 15G is adorned in lower communicating tube road, last pipeline No. seven, and following pipeline is equipped with water pump 14E No. five, with the 7th ' number unidirectional electrical magnet valve 15G ' thus constitute refrigeration plant and the third steam compression type refrigerating of the compound unit of heating equipment heats hybrid system A3, shown in figure (5), or constitute refrigeration plant and heating equipment do not adorn solar water heating system the 3rd ' plant steam compression type refrigerating and heat hybrid system A3 ', as scheming shown in (6).
Case study on implementation (four) is that the 4th kind of refrigeration plant and the compound unit steam compression type refrigerating of heating equipment heat hybrid system A4, shown in figure (7), its architectural feature is: heat in the hybrid system A1 at first kind of steam compression type refrigerating, the left interface 2a of four-way electromagnetic reversing valve 2 only with air cooled condenser 5A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints, the coil pipe lower interface of refrigerant conveying is connected with seal for pipe joints with the left interface of device for drying and filtering 9 in the air cooled condenser 5A, the right interface of device for drying and filtering 9 is connected with seal for pipe joints with the vertical direction interface tube of No. five threeway 3E, the last interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of capillary 10A, in its connecting pipe bidirectional electromagnetic valve 4J is housed No. ten, and the right interface of capillary 10A is connected with seal for pipe joints with the last interface of No. six threeway 3F, the lower interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of heating power expansion valve 10B, in its connecting pipe bidirectional electromagnetic valve 4I is housed No. nine, and the right interface of heating power expansion valve 10B is connected with seal for pipe joints with the lower interface of No. six threeway 3F, by No. three threeway 3C and No. four threeway 3D that water source evaporimeter 6B is in parallel with air energy evaporimeter 6A again, that is the left interface of No. three threeway 3C and air can evaporimeter 6A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints, in its connecting pipe bidirectional electromagnetic valve 4G is housed or is not adorned No. seven, in the right interface of No. three threeway 3C and the water source evaporimeter 6B on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints, in its connecting pipe bidirectional electromagnetic valve 4H is housed or is not adorned No. eight, the last interface of No. three threeway 3C is connected with seal for pipe joints with the right interface 2b of four-way electromagnetic reversing valve 2, the left interface of No. four threeway 3D is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter 6A, in its connecting pipe bidirectional electromagnetic valve 4E is housed No. five, the right interface of No. four threeway 3D is connected with seal for pipe joints with the lower interface of the spiral metal tube of the interior refrigerant conveying of water source evaporimeter 6B, in its connecting pipe bidirectional electromagnetic valve 4F is housed No. six, the lower interface of No. four threeway 3D is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway 3F, thereby formation closed system, in described system, charge an amount of cold-producing medium, for example fluorine Lyons F22 or F134a, water source evaporimeter 6B is provided with the relevant device supporting with it selectively, device, parts and part, thereby constitute refrigeration plant and the 4th kind of steam compression type refrigerating of the compound unit of heating equipment and heat hybrid system A4, shown in figure (7), or constituting refrigeration plant and the compound unit the 4th of heating equipment ' the kind steam compression type refrigerating of not adorning solar water heating system heats hybrid system A4 '.
Case study on implementation (five) is that the 5th kind of refrigeration plant and the compound unit steam compression type refrigerating of heating equipment heat hybrid system A5, shown in figure (8), its architectural feature is: heat in the hybrid system A1 at first kind of steam compression type refrigerating, the left interface 2a of four-way electromagnetic reversing valve 2 only with water cooled condenser 5B on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints, the spiral metal tube lower interface of refrigerant conveying is connected with seal for pipe joints with the left interface of device for drying and filtering 9 in the water cooled condenser 5B, and the right interface of device for drying and filtering 9 is connected with seal for pipe joints with the interface tube of No. five threeway 3E vertical direction, the last interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of capillary 10A, in its connecting pipe bidirectional electromagnetic valve 4J is housed No. ten, the lower interface of No. five threeway 3E is connected with seal for pipe joints with heating power expansion valve 10B left side interface, in its connecting pipe bidirectional electromagnetic valve 4I is housed No. nine, the right interface of capillary 10A is connected with seal for pipe joints with the last interface of the 6th threeway 3F, and the right interface of thermal expansion 10B is connected with seal for pipe joints with No. six threeway 3F lower interface, by No. three threeway 3C and No. four threeway 3D that the first ' number air energy evaporimeter 6A ' is in parallel with air energy evaporimeter 6A again, or it is water source evaporimeter 6B is in parallel with air energy evaporimeter 6A, that is the left interface of No. three threeway 3C and air can evaporimeter 6A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints, in its connecting pipe bidirectional electromagnetic valve 4G is housed or is not adorned No. seven, the right interface of No. three threeway 3C and the first ' number air can the coil pipe of the interior refrigerant conveying of evaporimeter 6A ' on interface be connected with seal for pipe joints, or in the right interface of No. three threeway 3C and the water source evaporimeter 6B on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints, in its connecting pipe bidirectional electromagnetic valve 4H is housed or is not adorned No. eight, the last interface of No. three threeway 3C is connected with seal for pipe joints with the right interface 2b of four-way electromagnetic reversing valve 2, the left interface of No. four threeway 3D is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter 6A, in its connecting pipe bidirectional electromagnetic valve 4E is housed No. five, the right interface of No. four threeway 3D is connected with seal for pipe joints with the coil pipe lower interface of the first ' number interior refrigerant conveying of air energy evaporimeter 6A ', or the right interface of No. four threeway 3D is connected with seal for pipe joints with the lower interface of the spiral metal tube of the interior refrigerant conveying of water source evaporimeter 6B, in its connecting pipe bidirectional electromagnetic valve 4F is housed No. six, the lower interface of No. four threeway 3D is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway 3F, thereby formation closed system, in described system, charge an amount of cold-producing medium, for example fluorine Lyons F22 or F134a, water cooled condenser 5B is provided with relative corollary equipment selectively, device, parts and part; Water source evaporimeter 6B also is provided with relative corollary equipment selectively, device, parts and part, be provided with between the water container of the water container of water cooled condenser 5B and water source evaporimeter 6B, the lower communicating tube road, last connecting pipe is equipped with unidirectional electrical magnet valve 15G No. seven, the lower communicating tube road is equipped with water pump 14E No. five, with the 7th ' number unidirectional electrical magnet valve 15G ', thereby constitute refrigeration plant and the 5th kind of steam compression type refrigerating of the compound unit of heating equipment and heat hybrid system A5, shown in figure (8), constitute be parallel with in refrigeration plant and the heating equipment two air can evaporimeter 5A or be parallel with an air can evaporimeter 5A with a typhoon cold type condenser 6A the 5th ' the kind steam compression type refrigerating heats hybrid system A5 ', as scheming shown in (9).
Case study on implementation (six) is that the 6th kind of refrigeration plant and the compound unit steam compression type refrigerating of heating equipment heat hybrid system A6, shown in figure (10), its architectural feature is: heat in the hybrid system A1 at first kind of steam compression type refrigerating, the left interface 2a of four-way electromagnetic reversing valve 2 only with air cooled condenser 5A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints, the coil pipe lower interface of refrigerant conveying is connected with seal for pipe joints with the left interface of device for drying and filtering 9 in the air cooled condenser 5A, the right interface of device for drying and filtering 9 is connected with seal for pipe joints with the interface tube of No. five threeway 3E vertical direction, the last interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of capillary 10A, in its connecting pipe bidirectional electromagnetic valve 4J is housed No. ten, and the right interface of capillary 10A is connected with seal for pipe joints with the last interface of the 6th threeway 3F, the lower interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of thermal expansion 10B, in its connecting pipe bidirectional electromagnetic valve 4I is housed No. nine, and the right interface of thermal expansion 10B is connected with seal for pipe joints with No. six threeway 3F lower interface, again the right interface 2b of four-way electromagnetic reversing valve 2 and air can evaporimeter 6A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints, the coil pipe lower interface of refrigerant conveying is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway 3F in the air energy evaporimeter 6A, thereby constitute refrigeration plant and the 6th kind of hot hybrid system A6 of steam compression type refrigerating of the compound unit of heating equipment, shown in figure (10), in described system A6, charge an amount of cold-producing medium, for example fluorine Lyons F22 or F134a.
Case study on implementation (seven) is that the 7th kind of refrigeration plant and the compound unit steam compression type refrigerating of heating equipment heat hybrid system A7, shown in figure (11), its architectural feature is: heat in the hybrid system A1 at first kind of steam compression type refrigerating, the left interface 2a of four-way electromagnetic reversing valve 2 only with air cooled condenser 5A on the coil pipe of refrigerant conveying interface be connected with seal for pipe joints, the coil pipe lower interface of refrigerant conveying is connected with seal for pipe joints with the left interface of device for drying and filtering 9 in the air cooled condenser 5A, the right interface of device for drying and filtering 9 is connected with seal for pipe joints with the vertical direction interface tube of No. five threeway 3E, the last interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of capillary 10A, in its connecting pipe bidirectional electromagnetic valve 4J is housed No. ten, and the right interface of capillary 10A is connected with seal for pipe joints with the last interface of No. six threeway 3F, the lower interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of heating power expansion valve 10B, in its connecting pipe bidirectional electromagnetic valve 4I is housed No. nine, and the right interface of heating power expansion valve 10B is connected with seal for pipe joints with the lower interface of No. six threeway 3F, again the right interface 2b of four-way electromagnetic reversing valve 2 only with water source evaporimeter 6B on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints, the lower interface of the spiral metal tube of refrigerant conveying is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway 3F in the water source evaporimeter 6B, thereby formation closed system, in described system, charge an amount of cold-producing medium, for example fluorine Lyons F22 or F134a, water source evaporimeter 6B is provided with the corollary equipment relevant with it selectively, device, parts and part, thereby constitute refrigeration plant and the 7th kind of steam compression type refrigerating of the compound unit of heating equipment and heat hybrid system A7, shown in figure (11), or constitute not with solar water heating system the 7th ' plant steam compression type refrigerating and heat hybrid system A7 '.
Case study on implementation (eight) is that the 8th kind of refrigeration plant and the compound unit steam compression type refrigerating of heating equipment heat hybrid system A8, shown in figure (12), its architectural feature is: heat in the hybrid system A1 at first kind of steam compression type refrigerating, the left interface 2a of four-way electromagnetic reversing valve 2 only with water cooled condenser 5B on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints, the spiral metal tube lower interface of refrigerant conveying is connected with seal for pipe joints with the left interface of device for drying and filtering 9 in the water cooled condenser 5B, and the right interface of device for drying and filtering 9 is connected with seal for pipe joints with the interface tube of No. five threeway 3E vertical direction, the last interface of No. five threeway 3E is connected with seal for pipe joints with the left interface of capillary 0A, in its connecting pipe bidirectional electromagnetic valve 4J is housed No. ten, the lower interface of No. five threeway 3E is connected with seal for pipe joints with heating power expansion valve 10B left side interface, in its connecting pipe bidirectional electromagnetic valve 4I is housed No. nine, the right interface of capillary 10A is connected with seal for pipe joints with the last interface of the 6th threeway 3F, and the right interface of thermal expansion 10B is connected with seal for pipe joints with No. six threeway 3F lower interface, again the right interface 2b of four-way electromagnetic reversing valve 2 only with water source evaporimeter 6B on the spiral metal tube of refrigerant conveying interface be connected with seal for pipe joints, the lower interface of the spiral metal tube of refrigerant conveying is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway 3F in the water source evaporimeter 6B, thereby formation closed system, in described system, charge an amount of cold-producing medium, as fluorine Lyons F22 or F134a, be equipped with between water cooled condenser 5B and water source its water container of evaporimeter 6B, the lower communicating tube road, last connecting pipe is equipped with unidirectional electrical magnet valve 15G No. seven, unidirectional electrical magnet valve 15G ' is housed on the lower communicating tube road No. five water pump 14E and the 7th ' number, each is provided with relevant supporting equipment with it selectively water cooled condenser 5B and water source evaporimeter 6B, device, parts and part, thereby constitute refrigeration plant and the 8th kind of steam compression type refrigerating of the compound unit of heating equipment and heat hybrid system A8, shown in figure (12), or constitute not with solar water heating system the 8th ' plant steam compression type refrigerating and heat hybrid system A8 '.
Above case study on implementation (one), (two), (three), (four), (five), (six), (seven) or (eight) described refrigeration plant and the compound unit of heating equipment, its architectural feature is that its steam compression type refrigerating heats in the hybrid system, the threeway 3 of used refrigerant conveying three interface tube cross section perpendicular center lines separately are parallel to each other, and the steam pressure action direction is parallel to each other when guaranteeing that cold-producing medium converges or separates in threeway 3.
Above case study on implementation (one), (two), (three), (four), (five), (six), (seven) or (eight) described refrigeration plant and its steam compression type refrigerating of the compound unit of heating equipment heat its purposes of hybrid system and are: can be used for manufacturing and designing following four big class cooling and warming multifunctional series energy-conserving products:
(1) can be used to manufacture and design domestic air conditioner and air energy heat pump water heater multi-function peripheral group, make family's cooling and warming recycling economy energy-saving and emission-reduction low-carbon (LC) life, heat in the hybrid system at above case study on implementation (), (two), (three), (four), (five), (six), (seven) or (eight) described heating equipment and its steam compression type refrigerating of refrigeration plant, its air can all can be used as air conditioner room unit by evaporimeter 6A, summer refrigeration air-conditioner, winter heating's heating; Or year round cooling is as refrigerator, refrigerator-freezer, ice machine, refrigeration, freezing, ice making, and water source evaporimeter 6B produces 7 ℃ of low-temperature cold waters summer; Produce 45 ℃ of hot water winter; By the floor heat-exchange system or by the indoor fan coil refrigeration air-conditioner in summer of leaking water, Winter heat supply heating, and water cooled condenser 5B produces 40 ℃ of low-temperature water heatings simultaneously earlier when room conditioning, utilize self heat pump to be heated into 60 ℃ of bathing hot water for the second time during without air-conditioning, or utilize solar energy to be heated into 60 ℃ of hot water again, the annual heat pump that can be used as during without air-conditioning, or one-time heating becomes 60 ℃ to have a bath and use hot water, air cooled condenser 5A produces hot blast again, can be used as baker, drying clothes or as dehumidifier, suiting measures to local conditions selectively, the synthetic air-conditioner of design team and air energy heat pump water heater are main multi-function peripheral group;
(2) can be used to manufacture and design the central heat pump water-heating machine multi-function peripheral group of commercial or home central air-conditioning and air energy, make cooling and warming and follow bad economical; At above case study on implementation (), (2), (3), (4), (5), (6), (7) or (eight) described heating equipment and its steam compression type refrigerating of refrigeration plant heat in the hybrid system, its air can freeze by evaporimeter (6A) interior summer, winter heating, cold to indoor conveying by the air channel heat-exchange system, hot blast, summer air-conditioning, winter heating, and in the water source evaporimeter 6B summer produce 7 ℃ of low-temperature cold waters, produce 45 ℃ of hot water winter, carry 7 ℃ of low-temperature cold waters or 45 ℃ of hot water by floor heat-exchange system or the fan coil of leaking water to other room, with the room air heat exchange, summer refrigeration air-conditioner, winter heating's heating, and 40 ℃ of low-temperature water heatings are produced in the condensation of water cooled condenser 5B refrigerant vapour earlier, utilize self heat pump to be heated into 60 ℃ of life hot water such as have a bath for the second time when treating without air-conditioning, or utilize solar energy to be heated into 60 ℃ of hot water again, air cooled condenser 5A refrigerant vapour condensation again, heat release, produce hot blast, by the air channel heat-exchange system to the baking room heat air delivery, in order to dry crops or clothing, the synthetic commercial or home central air-conditioning of the design team that suits measures to local conditions selectively be main multi-function peripheral group with the central heat pump water-heating machine of air energy;
(3) can be used to manufacture and design freezer refrigeration machine and heating plant heat supply air source heat pump water heater multi-function peripheral group, make the cooling and warming recycling economy, above case study on implementation (one), (2), (3), (4), (5), (6), (7) or (eight) described heating equipment and its steam compression type refrigerating of refrigeration plant heat in the hybrid system, air source evaporimeter 6A inner refrigerant sweat cooling, by the air channel heat-exchange system, to freezer transporting low temperature cold wind refrigerating, to use saline solution instead be heat exchange medium to water source evaporimeter 6B again, cold-producing medium is by the evaporation of evaporation comb, absorb freezer by the heat of solidifiable substance, refrigeration, freezing, and 60 ℃ of hot water are produced in the condensation of water cooled condenser 5B refrigerant vapour, for heating plant provides lives such as bathing and heating hot water to the user, can replace and burn the coal heating, eliminate the city chimney, and air cooled condenser 5A refrigerant vapour condensation heat release, produce hot blast, by the air channel heat-exchange system to the baking room heat air delivery, in order to dry crops or clothing, suiting measures to local conditions selectively, the synthetic freezer of design team is main multi-function peripheral group with refrigeration machine and heating plant air-source heat pump hot water;
(4) can be used to manufacture and design freezer uses with refrigeration machine and drying shed drying or the big grid heat temperature raising of overcast and rainy vegetables in winter air energy heat pump air-heater multi-function peripheral group, make the cooling and warming recycling economy, above case study on implementation (one), (2), (3), (4), (5), (6), (7) or (eight) described steam compression type refrigerating heat in the hybrid system, its air can pass through evaporation comb or air-cooler by evaporimeter 6A, the cold-producing medium evaporation absorbs freezer and is cooled, the heat of frozen food, and refrigerating, to use saline solution instead be heat exchange medium to water source evaporimeter 6B again, cold-producing medium is by evaporation comb sweat cooling, refrigeration, freezing, ice making, and air cooled condenser carry to the big grid of vegetables by the air channel heat-exchange system in the required environment temperature of low temperature hot blast simulation growing vegetables, hot blast is produced in air cooled condenser 5A inner refrigerant steam condensation heat release, by the air channel heat-exchange system to the baking room heat air delivery, in order to dry crops or clothing, and water source condenser 5B inner refrigerant steam condensation, produce 40 ℃ of hot water earlier, again by self heat pump or to utilize the solar energy post bake to become 60 ℃ of hot water be that heating plant is supplied the whole year to the user and had a bath, winter heating, hot water is used in life, and it is main multi-function peripheral group with refrigeration machine and drying shed air energy heat pump air-heater that the design team that suits measures to local conditions selectively synthesizes into freezer.

Claims (10)

1. an air-conditioner vapor compression type refrigerating system (A0); it is by compressor (1); interface (2C) is to left interface (2a) on the centre of four-way electromagnetic reversing valve (2); air cooled condenser (5A); device for drying and filtering (9); choke valve (10); air energy evaporimeter (6A); the right interface (2b) of four-way electromagnetic reversing valve (2) is to middle lower interface (2d) and gas-liquid separator (11); be tightly connected into vapor compression type refrigerating system (A0) successively with pipeline; particularly a kind of improved refrigeration plant and the compound unit of heating equipment; it is characterized in that: in the vapor compression type refrigerating system (A0) of air-conditioner; between the left interface of the left interface (2a) of four-way electromagnetic reversing valve (2) and device for drying and filtering (9); by number one threeway (3A) and No. second threeway (3B) that water cooled condenser (5B) is in parallel with air cooled condenser (5A); that is interface is connected with seal for pipe joints on the coil pipe of the left interface of number one threeway (3A) and the interior refrigerant conveying of air cooled condenser (5A); No. three bidirectional electromagnetic valve (4C) be equipped with or do not adorn in its connecting pipe; interface is connected with seal for pipe joints on the spiral metal tube of the right interface of number one threeway (3A) and the interior refrigerant conveying of water cooled condenser (5B); No. four bidirectional electromagnetic valve (4D) be equipped with or do not adorn in its connecting pipe; the last interface of number one threeway (3A) is connected with seal for pipe joints with the left interface (2a) of four-way electromagnetic reversing valve (2); the left interface of No. second threeway (3B) is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser (5A); in its connecting pipe number one bidirectional electromagnetic valve (4A) is housed; the right interface of No. second threeway (3B) is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of water cooled condenser (5B); in its connecting pipe No. second bidirectional electromagnetic valve (4B) is housed; the lower interface of No. second threeway (3B) is connected with seal for pipe joints with the left interface of device for drying and filtering (9); particularly by No. five threeway (3E) and No. six threeway (3F) that heating power expansion valve (10B) is in parallel with capillary (10A); that is No. five threeway (3E) vertical direction interface tube is connected with seal for pipe joints with the right interface of device for drying and filtering (9); the last interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of capillary (10A); in its connecting pipe No. ten bidirectional electromagnetic valve (4J) is housed; the lower interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of heating power expansion valve (10B); in its connecting pipe No. nine bidirectional electromagnetic valve (4I) is housed; and the last interface of No. six threeway (3F) is connected with seal for pipe joints with the right interface of capillary (10A); and the lower interface of No. six threeway (3F) is connected with seal for pipe joints with the right interface of heating power expansion valve (10B); by No. three threeway (3C) and No. four threeway (3D) that water source evaporimeter (6B) is in parallel with air energy evaporimeter (6A) again; that is the right interface (2b) of four-way electromagnetic reversing valve (2) is connected with seal for pipe joints with the last interface of No. three threeway (3C); interface is connected with seal for pipe joints on the spiral metal tube of the left interface of No. three threeway (3C) and the interior refrigerant conveying of water source evaporimeter (6B); No. eight bidirectional electromagnetic valve (4H) be equipped with or do not adorn in its connecting pipe; the right interface of No. three threeway (3C) and air can the coil pipe of the interior refrigerant conveying of evaporimeter (6A) on interface be connected with seal for pipe joints; No. seven bidirectional electromagnetic valve (4G) be equipped with or do not adorn in its connecting pipe; the right interface of No. four threeway (3D) is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter (6A), in its connecting pipe No. five bidirectional electromagnetic valve (4E) is housed, and the left interface of No. four threeway (3D) is connected with seal for pipe joints with the lower interface of the spiral metal tube of the interior refrigerant conveying of water source evaporimeter (6B); in its connecting pipe No. six bidirectional electromagnetic valve (4F) is housed; the lower interface of No. four threeway (3D) is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway (3F), thereby constitutes closed system, charges an amount of cold-producing medium in described system; water cooled condenser (5B) is connected with its water container of water source evaporimeter (6B); the lower communicating tube road; and at last connecting pipe No. seven unidirectional electrical magnet valve (15G) is housed, No. five water pump (14E) is housed in the lower communicating tube road, at water cooled condenser (5B) but the number one differential temperature controller (7A) of design temperature is housed; its water container of water cooled condenser (5B) does not connect or is connected with number one attemperater (12A) and first group of solar thermal collector (13A) thereof; that is the outlet pipe interface of its water container of water cooled condenser (5B) is connected with seal for pipe joints with the water inlet pipe interface of number one attemperater (12A), in its connecting pipe number one water pump (14A) is housed, and the water inlet pipe interface of its water container of water cooled condenser (5B) is connected with seal for pipe joints with the outlet pipe interface of number one attemperater (12A); in its connecting pipe No. second unidirectional electrical magnet valve (15B) is housed; the opposite side water inlet pipe and water outlet pipe interface of number one attemperater (12A) is connected with first group of solar thermal collector (13A), at number one attemperater (12A) outlet conduit number one unidirectional electrical magnet valve (15A) is housed, and the inlet channel of number one attemperater (12A) is equipped with No. three water pump (14C); the below interface tube of water cooled condenser (5B) water container and number one from the beginning water source (16A) be connected with seal for pipe joints; in its connecting pipe No. five unidirectional electrical magnet valve (15E) is housed, in the opposite side top of water cooled condenser (5B) water container the outlet pipe interface is housed, connect for watering equipment and use; and No. three unidirectional electrical magnet valve (15C) be housed; water cooled condenser (5B) water container below is provided with drain interface, and No. four unidirectional electrical magnet valve (15D) is housed, and its top is provided with overfall; again water source evaporimeter (6B) but No. second differential temperature controller (7B) of design temperature is housed; be connected with seal for pipe joints with No. second water source (16B) at water source evaporimeter (6B) water container below interface tube, at its pipeline the ten No. two unidirectional electrical magnet valve (15L) be housed, be connected with seal for pipe joints with the indoor fan coil of leaking water (18) water inlet pipe and water outlet pipe interface at the water inlet pipe and water outlet pipe interface of water source evaporimeter (6B) water container opposite side; in its connecting pipe No. six water pump (14F) and ride on Bus No. 11 unidirectional electrical magnet valve (15K) are housed; water source evaporimeter (6B) is provided with an outlet pipe interface, and the ten No. three unidirectional electrical magnet valve (15M) is housed, and connects for watering equipment and uses; thereby constituting first kind of steam compression type refrigerating that refrigeration plant and heating equipment compounding machine be assembled with solar water heating system heats hybrid system (A1) or formation refrigeration plant and heating equipment and does not adorn first kind of steam compression type refrigerating of solar water heating system and heat hybrid system (A1 '); and its steam compression type refrigerating of the compound unit of each refrigeration plant and heating equipment heats hybrid system control system (C) is housed, it is by compressor electric motor (1a); air cooled condenser fan electromotor (5Aa); air energy evaporimeter fan electromotor (6Aa); pump motor (14Aa); the four-way electromagnetic reversing valve coil (2a '); bi-directional electromagnetic valve coil (4a); unidirectional electromagnetic valve coil (15a); starting relay (20); capacitor (21); overload protective device (22); temperature controller (23); but the differential temperature controller of design temperature (7a); time controller (8Aa); defrosting temperature controller (27); selector switch (24); attaching plug (25); refrigeration plant and the compound unit structural principle of heating equipment and the purposes apolegamy combination separately of the above main electrical equipment basis of supply socket (26) is electrically connected and forms.
2. the compound unit of refrigeration plant according to claim 1 and heating equipment, it is characterized in that: in first kind of steam compression type refrigerating heats hybrid system (A1), between the left interface of the left interface (2a) of four-way electromagnetic reversing valve (2) and device for drying and filtering (9), in parallel with air cooled condenser (5A) by number one threeway (3A) and No. second threeway (3B) the little displacement type water cooled condenser (5B) that will be rapidly heated, that is interface is connected with seal for pipe joints on the coil pipe of the left interface of number one threeway (3A) and the interior refrigerant conveying of air cooled condenser (5A), No. three bidirectional electromagnetic valve (4C) be equipped with or do not adorn in its connecting pipe, interface is connected with seal for pipe joints on the spiral metal tube of the right interface of number one threeway (3A) and the interior refrigerant conveying of little displacement type water cooled condenser (5B) that is rapidly heated, No. four bidirectional electromagnetic valve (4D) be equipped with or do not adorn in its connecting pipe, the last interface of number one threeway (3A) is connected with seal for pipe joints with the left interface (2a) of four-way electromagnetic reversing valve (2), the left interface of No. second threeway (3B) is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser (5A), in its connecting pipe number one bidirectional electromagnetic valve (4A) is housed, the right interface of No. second threeway (3B) is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of little displacement type water cooled condenser (5B) that is rapidly heated, in its connecting pipe No. second bidirectional electromagnetic valve (4B) is housed, the lower interface of No. second threeway (3B) is connected with seal for pipe joints with the left interface of device for drying and filtering (9), the right interface of device for drying and filtering (9) is connected with seal for pipe joints with No. five threeway (3E) vertical direction interface tube, the last interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of capillary (10A), in its connecting pipe No. ten bidirectional electromagnetic valve (4J) is housed, the lower interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of heating power expansion valve (10B), adorn No. nine bidirectional electromagnetic valve (4I) in its connecting pipe, and the last interface of No. six threeway (3F) is connected with seal for pipe joints with the right interface of capillary (10A), the lower interface of No. six threeway (3F) is connected with seal for pipe joints with the right interface of heating power expansion valve (10B), by No. three threeway (3C) and No. four threeway (3D) that air energy evaporimeter (6A) is in parallel with the little displacement type of fast cooling water source evaporimeter (6B) again, that is the right interface (2b) of four-way electromagnetic reversing valve (2) is connected with seal for pipe joints with the last interface of No. three threeway (3C), interface is connected with seal for pipe joints on the spiral metal tube of the left interface of No. three threeway (3C) and the interior refrigerant conveying of the little displacement type of fast cooling water source evaporimeter (6B), No. eight bidirectional electromagnetic valve (4H) be equipped with or do not adorn in its connecting pipe, the right interface of No. three threeway (3C) and air can the coil pipe of the interior refrigerant conveying of evaporimeter (6A) on interface be connected with seal for pipe joints, No. seven bidirectional electromagnetic valve (4G) be equipped with or do not adorn in its connecting pipe, the right interface of No. four threeway (3D) is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter (6A), in its connecting pipe No. five bidirectional electromagnetic valve (4E) is housed, the left interface of No. four threeway (3D) is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of the little displacement type of fast cooling water source evaporimeter (6B), in its connecting pipe the 6th bidirectional electromagnetic valve (4F) is housed, the lower interface of No. four threeway (3D) is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway (3F), thereby formation closed system, in described system, irritate an amount of cold-producing medium is arranged, be rapidly heated little displacement type water cooled condenser (5B) but the number one differential temperature controller (7A) of design temperature is housed, the water inlet pipe and water outlet pipe interface of its water container of little displacement type water cooled condenser (5B) of being rapidly heated is connected with or does not connect number one attemperater (12A), do not connect or be connected with first group of solar thermal collector (13A), and the water inlet pipe interface of number one attemperater (12A) is connected with seal for pipe joints with the outlet pipe interface of little displacement type water cooled condenser (5B) water container that is rapidly heated, number one water pump (14A) is housed on its connecting pipe, and the water inlet pipe interface of its water container of little displacement type water cooled condenser (5B) that is rapidly heated is connected with seal for pipe joints with the outlet pipe interface of number one attemperater (12A), in its connecting pipe No. second unidirectional electrical magnet valve (15B) is housed, the below interface tube of number one attemperater and number one water source (16A) from the beginning are connected with seal for pipe joints, in its connecting pipe No. five unidirectional electrical magnet valve (15E) is housed, number one attemperater (12A) leaves an outlet pipe interface, and No. four unidirectional electrical magnet valve (15D) is housed for watering equipment connection usefulness, again the little displacement type of fast cooling water source evaporimeter (6A) but No. second differential temperature controller (7B) of design temperature also is housed, its water container outlet pipe interface of the little displacement type of fast cooling water source evaporimeter (6A) is connected with seal for pipe joints with the water inlet pipe interface of No. second attemperater (12B), in its connecting pipe No. three water pump (14C) is housed, and the water inlet pipe interface of its water container of the little displacement type of fast cooling water source evaporimeter (6A) is connected with seal for pipe joints with the outlet pipe interface of No. second attemperater (12B), in its connecting pipe No. nine unidirectional electrical magnet valve (15I) is housed, the below interface tube of No. second attemperater (12B) is connected with seal for pipe joints with No. second water source (16B), at its pipeline the ten No. two unidirectional electrical magnet valve (15L) is housed, the little displacement type of fast cooling water source evaporimeter (6A), the water inlet pipe and water outlet pipe interface of its water container opposite side is connected with seal for pipe joints with the indoor fan coil of leaking water (18) water inlet pipe and water outlet pipe interface, in its connecting pipe No. six water pump (14F) and ride on Bus No. 11 unidirectional electrical magnet valve (15K) are housed, Inlet and outlet water tube connector up and down is housed between number one attemperater (12A) and No. second attemperater (12B), last tube connector is equipped with No. seven unidirectional electrical magnet valve (15G), following tube connector is equipped with No. five water pump (14E), (12B) leaves a titting water outlet at second attemperater, and the 13 unidirectional electrical magnet valve (15M) is housed, and connects for watering equipment and uses, heat hybrid system (A2) thereby constitute refrigeration plant with second kind of steam compression type refrigerating of the compound unit of heating equipment, or constitute refrigeration plant and the compound unit of heating equipment and do not heat hybrid system (A2 ') with the second ' kind steam compression type refrigerating of attemperater and solar thermal collector thereof.
3. the compound unit of refrigeration plant according to claim 1 and heating equipment, it is characterized in that: in first kind of steam compression type refrigerating heats hybrid system (A1), between the left interface of the left interface (2a) of four-way electromagnetic reversing valve (2) and device for drying and filtering (9), by number one threeway (3A) and No. second threeway (3B) that air cooled condenser (5A) is in parallel with the big displacement type water cooled condenser (5B) that heats up at a slow speed, that is interface is connected with seal for pipe joints on the coil pipe of the left interface of number one threeway (3A) and the interior refrigerant conveying of air cooled condenser (5A), No. three bidirectional electromagnetic valve (4C) be equipped with or do not adorn in its connecting pipe, interface is connected with seal for pipe joints on the spiral metal tube of the right interface of number one threeway (3A) and the interior refrigerant conveying of big displacement type water cooled condenser (5B) that heats up at a slow speed, No. four bidirectional electromagnetic valve (4D) be equipped with or do not adorn in its connecting pipe, the last interface of number one threeway (3A) is connected with seal for pipe joints with the left interface (2a) of four-way electromagnetic reversing valve (2), the left interface of No. second threeway (3B) is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser (5A), in its connecting pipe number one bidirectional electromagnetic valve (4A) is housed, the right interface of No. second threeway (3B) is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of big displacement type water cooled condenser (5B) that heats up at a slow speed, in its connecting pipe No. second bidirectional electromagnetic valve (4B) is housed, the lower interface of No. second threeway (3B) is connected with seal for pipe joints with the left interface of device for drying and filtering (9), the right interface of device for drying and filtering (9) is connected with seal for pipe joints with No. five threeway (3E) vertical direction interface tube, No. five threeway (3E) gone up interface and is connected with seal for pipe joints with the left interface of capillary (10A), in its connecting pipe No. ten bidirectional electromagnetic valve (4J) is housed, the lower interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of heating power expansion valve (10B), in its connecting pipe No. nine bidirectional electromagnetic valve (4I) is housed, and the last interface of No. six threeway (3F) is connected with seal for pipe joints with the right interface of capillary (10A), the lower interface of No. six threeway (3F) is connected with seal for pipe joints with the right interface of heating power expansion valve (10B), it is can evaporimeter (6A) in parallel with the big displacement type water source evaporimeter (6B) of lowering the temperature at a slow speed by No. three threeway (3C) and No. four threeway (3D) the little displacement type of fast cooling with water to be that heat transfer medium passes through the air that number one fan coil (18A) absorbs the room air heat again, that is the right interface (2b) of four-way electromagnetic reversing valve (2) is connected with seal for pipe joints with the last interface of No. three threeway (3C), interface is connected with seal for pipe joints on the spiral metal tube of the right interface of No. three threeway (3C) and the interior refrigerant conveying of big displacement type water source evaporimeter (6B) of lowering the temperature at a slow speed, No. seven bidirectional electromagnetic valve (4G) be equipped with or do not adorn in its connecting pipe, the little displacement type air of the left interface of No. three threeway (3C) and fast cooling can the spiral metal tube of the interior refrigerant conveying of evaporimeter (6A) on interface be connected with seal for pipe joints, No. eight bidirectional electromagnetic valve (4H) be equipped with or do not adorn in its connecting pipe, the left interface of No. four threeway (3D) is connected with seal for pipe joints with the spiral metal tube lower interface of the interior refrigerant conveying of the little displacement type air energy evaporimeter (6A) of fast cooling, in its connecting pipe No. six bidirectional electromagnetic valve (4F) is housed, the right interface of No. four threeway (3D) is connected with seal for pipe joints with the lower interface of the spiral metal tube of the interior refrigerant conveying of big displacement type water source evaporimeter (6B) of lowering the temperature at a slow speed, in its connecting pipe No. five bidirectional electromagnetic valve (4E) is housed, the lower interface of No. four threeway (3D) is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway (3F), thereby formation closed system, in described system, charge an amount of cold-producing medium, water cooled condenser (5B) but on the number one differential temperature controller (7A) of design temperature is housed, the below interface tube of water cooled condenser (5B) and number one from the beginning water source (16A) be connected with seal for pipe joints, in its connecting pipe No. three unidirectional electrical magnet valve (15C) is housed, water cooled condenser (5B) leaves an outlet pipe interface, and No. four unidirectional electrical magnet valve (15D) is housed, connect usefulness for watering equipment, the little displacement type air of fast cooling can be connected with No. second water source (16B) by evaporimeter (6A) water container below water inlet pipe interface, and the 12 unidirectional electrical magnet valve (15L) is housed, and the little displacement type air of fast cooling can leave drain interface by its water container of evaporimeter (6A), and No. 14 unidirectional electrical magnet valve (15N) be housed, the little displacement type air evaporator of fast cooling (6A) is walked water receptacle opposite side water inlet pipe and water outlet pipe interface and is connected with the indoor number one fan coil (18A) of leaking water, and number one water pump (14A) is housed on the connecting pipe thereon, its down connecting pipe No. eight unidirectional electrical magnet valve (15H) is housed, the little displacement type air of fast cooling can evaporimeter (6A) again, but No. second temperature controller (7B) of design temperature also is housed, and water source evaporimeter (6B) is connected with or does not connect No. second attemperater (12B), and the outlet pipe interface of its water container of water source evaporimeter (6B) is connected with seal for pipe joints with the water inlet pipe interface of No. second attemperater (12B), in its connecting pipe No. three water pump (14C) is housed, the water inlet pipe interface of its water container of water source evaporimeter (6B) is connected with seal for pipe joints with the outlet pipe interface of second attemperater (12B), in its connecting pipe No. five unidirectional electrical magnet valve (15E) is arranged, and is connected with seal for pipe joints with No. second water source (16B) at the below interface tube of water source evaporimeter (6B) water container, at its pipeline No. six unidirectional electrical magnet valve (15F) is housed, water inlet pipe and water outlet pipe interface at water source evaporimeter (6B) water container opposite side is connected with seal for pipe joints with indoor No. second fan coil of leaking water (18B) water inlet pipe and water outlet pipe interface, and No. second water pump (14B) is housed on the connecting pipe thereon, and connecting pipe is equipped with No. nine unidirectional electrical magnet valve (15I) under it, the opposite side water inlet pipe and water outlet pipe interface of No. second attemperater (12B) is connected with pipeline or does not connect second group of solar thermal collector (13B), inlet channel at No. second attemperater (12B) is equipped with No. four water pump (14D), at the outlet conduit of No. second attemperater (12B) No. eight unidirectional electrical magnet valve (15H) is housed, and the little displacement type air of the water container of water cooled condenser (5B) and fast cooling can be provided with between the water container of evaporimeter (6A), the lower communicating tube road, last pipeline is adorned No. seven unidirectional electrical magnet valve (15G), following pipeline is equipped with No. five water pump (14E), heats hybrid system (A3) thereby constitute refrigeration plant with the third steam compression type refrigerating of the compound unit of heating equipment, or constitutes the 3rd ' the kind steam compression type refrigerating heat hybrid system (A3 ' that refrigeration plant and heating equipment are not adorned solar water heating system).
4. the compound unit of refrigeration plant according to claim 1 and heating equipment, it is characterized in that: in first kind of steam compression type refrigerating heats hybrid system (A1), the left interface (2a) of four-way electromagnetic reversing valve (2) only with the coil pipe of the interior refrigerant conveying of air cooled condenser (5A) on interface be connected with seal for pipe joints, the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser (5A) is connected with seal for pipe joints with the left interface of device for drying and filtering (9), the right interface of device for drying and filtering (9) is connected with seal for pipe joints with the vertical direction interface tube of No. five threeway (3E), the last interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of capillary (10A), in its connecting pipe No. ten bidirectional electromagnetic valve (4J) is housed, and the right interface of capillary (10A) is connected with seal for pipe joints with the last interface of No. six threeway (3F), the lower interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of heating power expansion valve (10B), in its connecting pipe No. nine bidirectional electromagnetic valve (4I) is housed, and the right interface of heating power expansion valve (10B) is connected with seal for pipe joints with the lower interface of No. six threeway (3F), by No. three threeway (3C) and No. four threeway (3D) that water source evaporimeter (6B) is in parallel with air energy evaporimeter (6A) again, that is the left interface of No. three threeway (3C) and air can the coil pipe of the interior refrigerant conveying of evaporimeter (6A) on interface be connected with seal for pipe joints, No. seven bidirectional electromagnetic valve (4G) be equipped with or do not adorn in its connecting pipe, interface is connected with seal for pipe joints on the spiral metal tube of the right interface of No. three threeway (3C) and the interior refrigerant conveying of water source evaporimeter (6B), No. eight bidirectional electromagnetic valve (4H) be equipped with or do not adorn in its connecting pipe, the last interface of No. three threeway (3C) is connected with seal for pipe joints with the right interface (2b) of four-way electromagnetic reversing valve (2), the left interface of No. four threeway (3D) is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter (6A), in its connecting pipe No. five bidirectional electromagnetic valve (4E) is housed, the right interface of No. four threeway (3D) is connected with seal for pipe joints with the lower interface of the spiral metal tube of the interior refrigerant conveying of water source evaporimeter (6B), in its connecting pipe No. six bidirectional electromagnetic valve (4F) is housed, the lower interface of No. four threeway (3D) is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway (3F), thereby formation closed system, in described system, charge an amount of cold-producing medium, and water source evaporimeter (6B) is provided with the relevant device supporting with it selectively, device, parts and part, heat hybrid system (A4) thereby constitute refrigeration plant with the 4th kind of steam compression type refrigerating of the compound unit of heating equipment, or constitute refrigeration plant and the compound unit the 4th of heating equipment ' the kind steam compression type refrigerating of not adorning solar water heating system heat hybrid system (A4 ').
5. the compound unit of refrigeration plant according to claim 1 and heating equipment, it is characterized in that: in first kind of steam compression type refrigerating heats hybrid system (A1), the left interface (2a) of four-way electromagnetic reversing valve (2) only with the spiral metal tube of the interior refrigerant conveying of water cooled condenser (5B) on interface be connected with seal for pipe joints, the spiral metal tube lower interface of the interior refrigerant conveying of water cooled condenser (5B) is connected with seal for pipe joints with the left interface of device for drying and filtering (9), and the right interface of device for drying and filtering (9) is connected with seal for pipe joints with the interface tube of No. five threeway (3E) vertical direction, the last interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of capillary (10A), in its connecting pipe No. ten bidirectional electromagnetic valve (4J) is housed, the lower interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of heating power expansion valve (10B), in its connecting pipe No. nine bidirectional electromagnetic valve (4I) is housed, the right interface of capillary (10A) is connected with seal for pipe joints with the last interface of the 6th threeway (3F), and the right interface of thermal expansion (10B) is connected with seal for pipe joints with No. six threeway (3F) lower interface, again by No. three threeway (3C) and No. four threeway (3D) with the first ' number air can evaporimeter (6A ') in parallel with air energy evaporimeter (6A), or it is water source evaporimeter (6B) is in parallel with air energy evaporimeter (6A), that is the left interface of No. three threeway (3C) and air can the coil pipe of the interior refrigerant conveying of evaporimeter (6A) on interface be connected with seal for pipe joints, No. seven bidirectional electromagnetic valve (4G) be equipped with or do not adorn in its connecting pipe, interface is connected with seal for pipe joints on the coil pipe of the right interface of No. three threeway (3C) and the first ' number air can evaporimeters (6A ') interior refrigerant conveying, or interface is connected with seal for pipe joints on the spiral metal tube of the right interface of No. three threeway (3C) and the interior refrigerant conveying of water source evaporimeter (6B), No. eight bidirectional electromagnetic valve (4H) be equipped with or do not adorn in its connecting pipe, the last interface of No. three threeway (3C) is connected with seal for pipe joints with the right interface (2b) of four-way electromagnetic reversing valve (2), the left interface of No. four threeway (3D) is connected with seal for pipe joints with the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter (6A), in its connecting pipe No. five bidirectional electromagnetic valve (4E) is housed, the coil pipe lower interface of the right interface of No. four threeway (3D) and the first ' number air can evaporimeters (6A ') interior refrigerant conveying is connected with seal for pipe joints, or the right interface of No. four threeway (3D) is connected with seal for pipe joints with the lower interface of the spiral metal tube of the interior refrigerant conveying of water source evaporimeter (6B), in its connecting pipe No. six bidirectional electromagnetic valve (4F) is housed, the lower interface of No. four threeway (3D) is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway (3F), thereby formation closed system, charge an amount of cold-producing medium in described system, water cooled condenser (5B) is provided with relative corollary equipment selectively, device, parts and part; Water source evaporimeter (6B) also is provided with relative corollary equipment selectively, device, parts and part, be provided with between the water container of the water container of water cooled condenser (5B) and water source evaporimeter (6B), the lower communicating tube road, last connecting pipe is equipped with No. seven unidirectional electrical magnet valve (15G), the lower communicating tube road is equipped with No. five water pump (14E), heat hybrid system (A5) thereby constitute refrigeration plant with the 5th kind of steam compression type refrigerating of the compound unit of heating equipment, or constitute be parallel with in refrigeration plant and the heating equipment two air can evaporimeters (5A) or the 6th kind of steam compression type refrigerating being parallel with an air energy evaporimeter (5A) and a typhoon cold type condenser (6 ' A) heat hybrid system (A5 ').
6. the compound unit of refrigeration plant according to claim 1 and heating equipment, it is characterized in that: in first kind of steam compression type refrigerating heats hybrid system (A1), the left interface (2a) of four-way electromagnetic reversing valve (2) only with the coil pipe of the interior refrigerant conveying of air cooled condenser (5A) on interface be connected with seal for pipe joints, the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser (5A) is connected with seal for pipe joints with the left interface of device for drying and filtering (9), the right interface of device for drying and filtering (9) is connected with seal for pipe joints with the interface tube of No. five threeway (3E) vertical direction, the last interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of capillary (10A), in its connecting pipe No. ten bidirectional electromagnetic valve (4J) is housed, and the right interface of capillary (10A) is connected with seal for pipe joints with the last interface of the 6th threeway (3F), the lower interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of thermal expansion (10B), in its connecting pipe No. nine bidirectional electromagnetic valve (4I) is housed, and the right interface of thermal expansion (10B) is connected with seal for pipe joints with No. six threeway (3F) lower interface, again the right interface (2b) of four-way electromagnetic reversing valve (2) and air can the coil pipe of the interior refrigerant conveying of evaporimeter (6A) on interface be connected with seal for pipe joints, the coil pipe lower interface of the interior refrigerant conveying of air energy evaporimeter (6A) is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway (3F), thereby constitute refrigeration plant and the 6th kind of hot hybrid system of steam compression type refrigerating of the compound unit of heating equipment (A6), in described system (A6), charge an amount of cold-producing medium.
7. the compound unit of refrigeration plant according to claim 1 and heating equipment, it is characterized in that: in first kind of steam compression type refrigerating heats hybrid system (A1), the left interface (2a) of four-way electromagnetic reversing valve (2) only with the coil pipe of the interior refrigerant conveying of air cooled condenser (5A) on interface be connected with seal for pipe joints, the coil pipe lower interface of the interior refrigerant conveying of air cooled condenser (5A) is connected with seal for pipe joints with the left interface of device for drying and filtering (9), the right interface of device for drying and filtering (9) is connected with seal for pipe joints with the vertical direction interface tube of No. five threeway (3E), the last interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of capillary (10A), in its connecting pipe No. ten bidirectional electromagnetic valve (4J) is housed, and the right interface of capillary (10A) is connected with seal for pipe joints with the last interface of No. six threeway (3F), the lower interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of heating power expansion valve (10B), in its connecting pipe No. nine bidirectional electromagnetic valve (4I) is housed, and the right interface of heating power expansion valve (10B) is connected with seal for pipe joints with the lower interface of No. six threeway (3F), interface is connected with seal for pipe joints on the spiral metal tube of the right interface (2b) of four-way electromagnetic reversing valve (2) and the interior refrigerant conveying of water source evaporimeter (6B) again, the lower interface of the spiral metal tube of the interior refrigerant conveying of water source evaporimeter (6B) is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway (3F), thereby formation closed system, in described system, charge an amount of cold-producing medium, water source evaporimeter (6B) is provided with the corollary equipment relevant with it selectively, device, parts and part, heat hybrid system (A7) thereby constitute refrigeration plant with the 7th kind of steam compression type refrigerating of the compound unit of heating equipment, constitute not the 7th ' kind steam compression type refrigerating heat hybrid system (A7 ' with solar water heating system).
8. the compound unit of refrigeration plant according to claim 1 and heating equipment, it is characterized in that: in first kind of steam compression type refrigerating heats hybrid system (A1), the left interface (2a) of four-way electromagnetic reversing valve (2) only with the spiral metal tube of the interior refrigerant conveying of water cooled condenser (5B) on interface be connected with seal for pipe joints, the spiral metal tube lower interface of the interior refrigerant conveying of water cooled condenser (5B) is connected with seal for pipe joints with the left interface of device for drying and filtering (9), and the right interface of device for drying and filtering (9) is connected with seal for pipe joints with the interface tube of No. five threeway (3E) vertical direction, the last interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of capillary (10A), in its connecting pipe No. ten bidirectional electromagnetic valve (4J) is housed, the lower interface of No. five threeway (3E) is connected with seal for pipe joints with the left interface of heating power expansion valve (10B), in its connecting pipe No. nine bidirectional electromagnetic valve (4I) is housed, the right interface of capillary (10A) is connected with seal for pipe joints with the last interface of the 6th threeway (3F), and the right interface of thermal expansion (10B) is connected with seal for pipe joints with No. six threeway (3F) lower interface, again the right interface (2b) of four-way electromagnetic reversing valve (2) only with the spiral metal tube of the interior refrigerant conveying of water source evaporimeter (6B) on interface be connected with seal for pipe joints, the lower interface of the spiral metal tube of the interior refrigerant conveying of water source evaporimeter (6B) is connected with seal for pipe joints with the vertical direction interface tube of No. six threeway (3F), thereby formation closed system, in described system, charge an amount of cold-producing medium, be equipped with between water cooled condenser (5B) and its water container of water source evaporimeter (6B), the lower communicating tube road, last connecting pipe is equipped with No. seven unidirectional electrical magnet valve (15G), No. five water pump (14E) is housed on the lower communicating tube road, each is provided with relevant supporting equipment with it selectively water cooled condenser (5B) and water source evaporimeter (6B), device, parts and part, heat hybrid system (A8) thereby constitute refrigeration plant with the 8th kind of steam compression type refrigerating of the compound unit of heating equipment, or constitute not the 8th ' kind steam compression type refrigerating heat hybrid system (A8 ' with solar water heating system).
9. according to claim 1,2,3,4,5,6,7 or 8 described refrigeration plants and the compound unit of heating equipment, it is characterized in that its steam compression type refrigerating heats in the hybrid system, the threeway of used refrigerant conveying (3) three interface tube vertical center lines separately are parallel to each other, and the steam pressure action direction is parallel to each other when guaranteeing that cold-producing medium converges or separates in threeway (3).
10. heating the hybrid system purposes according to claim 1,2,3,4,5,6,7 or 8 described refrigeration plants and the compound unit of heating equipment and steam compression type refrigerating thereof is: can be used for manufacturing and designing following four big class cooling and warming multifunctional series energy-conserving products:
(1) can be used to manufacture and design domestic air conditioner and air energy heat pump water heater multi-function peripheral group, make family's cooling and warming recycling economy energy-saving and emission-reduction low-carbon (LC) life, heat in the hybrid system at above claim 1,2,3,4,5,6,7 or 8 described steam compression type refrigeratings, its air can all can be used as air conditioner room unit refrigeration air-conditioner in summer, winter heating's heating by evaporimeter (6A); Or year round cooling is as refrigerator, refrigerator-freezer, water-making machine, refrigeration, freezing, ice making, and water source evaporimeter (6B) is produced 7 ℃ of low-temperature cold waters summer; Produce 45 ℃ of hot water winter; By the floor heat-exchange system or by the indoor fan coil refrigeration air-conditioner in summer of leaking water, Winter heat supply heating, and water cooled condenser (5B) is produced 40 ℃ of low-temperature water heatings simultaneously earlier when room conditioning, utilize self heat pump to be heated into 60 ℃ of bathing hot water for the second time during without air-conditioning, or utilize solar energy to be heated into 60 ℃ of hot water again, the annual heat pump that can be used as during without air-conditioning, or one-time heating becomes 60 ℃ to have a bath and use hot water, air cooled condenser (5A) is produced hot blast again, can be used as baker, drying clothes or as dehumidifier;
(2) can be used to manufacture and design the central heat pump water-heating machine multi-function peripheral group of commercial or home central air-conditioning and air energy, make the cooling and warming recycling economy; In above claim 1,2,3,4,5,6,7 or 8 described steam compression type refrigeratings heat in the hybrid system, its air can freeze by evaporimeter (6A) interior summer, winter heating, by the air channel heat-exchange system to the cold and hot wind of indoor conveying, summer air-conditioning, winter heating, and water source evaporimeter (6B) is produced 7 ℃ of low-temperature cold waters interior summer, produce 45 ℃ of hot water winter, carry 7 ℃ of low-temperature cold waters or 45 ℃ of hot water by floor heat-exchange system or the fan coil of leaking water to other room, with the room air heat exchange, summer refrigeration air-conditioner, winter heating heating, and 40 ℃ of low-temperature water heatings are produced in the condensation of water cooled condenser (5B) refrigerant vapour earlier, utilize self heat pump to be heated into 60 ℃ of life hot water such as have a bath for the second time when treating without air-conditioning, or utilize solar energy to be heated into 60 ℃ of hot water again, air cooled condenser (5A) refrigerant vapour condensation again, hot blast is produced in heat release, by the air channel heat-exchange system to the baking room heat air delivery, in order to dry crops or clothing;
(3) can be used to manufacture and design freezer refrigeration machine and heating plant heat supply air source heat pump water heater multi-function peripheral group, make the cooling and warming recycling economy, in above claim 1,2,3,4,5,6,7 or 8 described steam compression type refrigeratings heat in the hybrid system, air source evaporimeter (6A) inner refrigerant sweat cooling, by the air channel heat-exchange system, to freezer transporting low temperature cold wind refrigerating, to use saline solution instead be heat exchange medium to water source evaporimeter (6B) again, cold-producing medium is by the evaporation of evaporation comb, absorb freezer by the heat of solidifiable substance, refrigeration, freezing, and 60 ℃ of hot water are produced in the condensation of water cooled condenser (5B) refrigerant vapour, for heating plant provides lives such as bathing and heating hot water to the user, can replace and burn the coal heating, eliminate the city chimney, and air cooled condenser (5A) refrigerant vapour condensation heat release, produce hot blast, by the air channel heat-exchange system to the baking room heat air delivery, in order to dry crops or clothing, thereby form freezer refrigeration machine and heating plant air-source heat pump hot water multi-function peripheral group;
(4) can be used to manufacture and design freezer uses with refrigeration machine and drying shed drying or the big grid heat temperature raising of overcast and rainy vegetables in winter air energy heat pump air-heater multi-function peripheral group, make the cooling and warming recycling economy, in above claim 1,2,3,4,5,6,7 or 8 described steam compression type refrigeratings heat in the hybrid system, all air can pass through evaporation comb or air-cooler by evaporimeter (6A), the cold-producing medium evaporation absorbs freezer and is cooled, the heat of frozen food, and refrigerating, to use saline solution instead be heat exchange medium to water source evaporimeter (6B) again, cold-producing medium is by evaporation comb sweat cooling, refrigeration, freezing, ice making, and air cooled condenser carry to the big grid of vegetables by the air channel heat-exchange system in the required environment temperature of low temperature hot blast simulation growing vegetables, hot blast is produced in air cooled condenser (5A) inner refrigerant steam condensation heat release, by the air channel heat-exchange system to the baking room heat air delivery, in order to dry crops or clothing, and the condensation of water source condenser (5B) inner refrigerant steam, produce 40 ℃ of hot water earlier, again by self heat pump or to utilize the solar energy post bake to become 60 ℃ of hot water be that heating plant is supplied the whole year to the user and had a bath, winter heating, life hot water, thus freezer refrigeration machine and drying shed air energy heat pump air-heater multi-function peripheral group formed.
CN201210038812.6A 2012-02-21 2012-02-21 Composite machine set of steam compression type refrigeration device and heating device, and use thereof Pending CN103256752A (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103574989A (en) * 2013-10-25 2014-02-12 中仪睿科(天津)教学实验设备有限公司 Novel multifunctional heat pump and water heater experiment table and experimental method thereof
CN103604246A (en) * 2013-10-25 2014-02-26 四川长虹电器股份有限公司 Temperature regulation device
CN103625242A (en) * 2013-11-18 2014-03-12 华南理工大学 Thermal management system of electric automobile
JP2019100693A (en) * 2017-12-05 2019-06-24 山東栄安電子科技有限公司Shandong Rongan Electronic Science And Technology Co., Ltd. Movable type indoor temperature decreasing and cooling facility
CN111486574A (en) * 2020-04-29 2020-08-04 广东美的暖通设备有限公司 Air conditioning system, anti-condensation control method and device thereof, and storage medium
CN111795503A (en) * 2020-07-14 2020-10-20 葛时欢 Heat energy shunting and recovering device for large bathing place

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103574989A (en) * 2013-10-25 2014-02-12 中仪睿科(天津)教学实验设备有限公司 Novel multifunctional heat pump and water heater experiment table and experimental method thereof
CN103604246A (en) * 2013-10-25 2014-02-26 四川长虹电器股份有限公司 Temperature regulation device
CN103574989B (en) * 2013-10-25 2015-09-23 中仪睿科(天津)教学实验设备有限公司 Novel multifunctional heat pump, water heater experimental bench and experimental technique thereof
CN103604246B (en) * 2013-10-25 2017-01-04 四川长虹电器股份有限公司 A kind of temperature control equipment
CN103625242A (en) * 2013-11-18 2014-03-12 华南理工大学 Thermal management system of electric automobile
JP2019100693A (en) * 2017-12-05 2019-06-24 山東栄安電子科技有限公司Shandong Rongan Electronic Science And Technology Co., Ltd. Movable type indoor temperature decreasing and cooling facility
CN111486574A (en) * 2020-04-29 2020-08-04 广东美的暖通设备有限公司 Air conditioning system, anti-condensation control method and device thereof, and storage medium
CN111795503A (en) * 2020-07-14 2020-10-20 葛时欢 Heat energy shunting and recovering device for large bathing place
CN111795503B (en) * 2020-07-14 2022-05-17 高燕妮 Heat energy shunting and recovering device for large-scale bathing place

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