CN1731041B - Compression type refrigerating, heating apparatus and heat pump water heater combined set - Google Patents

Compression type refrigerating, heating apparatus and heat pump water heater combined set Download PDF

Info

Publication number
CN1731041B
CN1731041B CN 200410055574 CN200410055574A CN1731041B CN 1731041 B CN1731041 B CN 1731041B CN 200410055574 CN200410055574 CN 200410055574 CN 200410055574 A CN200410055574 A CN 200410055574A CN 1731041 B CN1731041 B CN 1731041B
Authority
CN
China
Prior art keywords
threeway
water
tightly connected
heat
evaporimeter
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Fee Related
Application number
CN 200410055574
Other languages
Chinese (zh)
Other versions
CN1731041A (en
Inventor
罗响
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Priority to CN 200410055574 priority Critical patent/CN1731041B/en
Publication of CN1731041A publication Critical patent/CN1731041A/en
Application granted granted Critical
Publication of CN1731041B publication Critical patent/CN1731041B/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

Links

Images

Classifications

    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]
    • Y02B30/12Hot water central heating systems using heat pumps

Landscapes

  • Other Air-Conditioning Systems (AREA)

Abstract

The composite machine of compressing cooling and heating sets and heat pump water heater consists of different compressing cooling and heating sets, hot water supply system, and their control system, and has temperature controller with set temperature and mounted on the water cooled condenser. The present invention is suitable for cooling air conditioning, heating and providing hot water for washing and other uses in various kinds of building. It has high efficiency, power consumption 70 % lower than common electric water heater, high apparatus utilization, low cost and high safety and reliability.

Description

The compound unit of compression-type refrigeration heating equipment and Teat pump boiler
Technical field that the present invention belongs to: the present invention is under the jurisdiction of heating-cooling equipment
Range of application: be suitable for having a bath and live washing with hot water or boiler preheating, industrial or agricultural hot water for the heating of its user's refrigeration air-conditioner in summer of residential housing, villa, office building, industrial or agricultural building and commercial building, winter heating, annual supply.
Technical background: existing air-conditioner of selling on the domestic and international market and central air-conditioning refrigeration air-conditioner in summer, and refrigerant vapour condensation in condenser institute liberated heat is scattered and disappeared by absorption of air, be not utilized, winter heating's heating, the evaporation and cold-producing medium absorbs heat in evaporimeter, the refrigerating capacity that is produced is taken away and is lost by air, be not utilized yet, existing positive displacement electric heater power consumption is bigger, and the Teat pump boiler power consumption of selling on the domestic and international market is little, only account for 1/3rd of electric heater power consumption, also be not utilized but cold-producing medium evaporates the refrigerating capacity that is produced in evaporimeter.
Goal of the invention: the present invention will provide cluster compression-type refrigeration heating equipment and the compound unit of Teat pump boiler, not only summer can refrigeration air-conditioner, winter heating's heating, and can supply the user whole year and have a bath and live washing with hot water or industrial or agricultural hot water, than electric heater economize on electricity 70%.
Invention advantage: one, energy-efficient: it is than electric heater economize on electricity 70%; Two, conserve space and cost: the compression-type refrigeration heating equipment identical with the compound unit of Teat pump boiler with function two single household electrical appliance---air-conditioner is compared with Teat pump boiler, a shared compressor and an evaporimeter, thus save installing space and reduced manufacturing cost; Three, utilization rate of equipment and installations height: equipment is all in running throughout the year; Four, reliable, no potential safety hazard.
Summary of the invention: the present invention is by the compression-type refrigeration heating, hot-water supply system and control system three parts are formed, as figure (20), it is the compound unit of air-conditioner and Teat pump boiler, its compression-type refrigeration heating is by compressor, four-way electromagnetic reversing valve, the condenser that combines with the air-conditioner outdoor unit group, device for drying and filtering, capillary, the evaporimeter that combines with the air conditioner room unit group, be tightly connected into closed system successively with pipeline, and by four magnetic valves and two threeways, with a pipeline and an air-conditioner outdoor unit group sealing water cooled condenser in parallel, the metallic coil of cold-producing medium is housed away in condenser, between condenser inner bag and metallic coil outer wall, water is housed, but the temperature controller and the temperature-sensing element thereof of design temperature are housed on condenser, the hot-water supply system is made up of condenser and heat storage water tank, its titting water outlet of condenser is tightly connected with pipeline and its end admitting pipe joint of heat storage water tank through magnetic valve, its admitting pipe joint of condenser is tightly connected through magnetic valve and its end titting water outlet of heat storage water tank, heat storage water tank its underpart admitting pipe joint passes through gate valve, three general pipelines are tightly connected with water source from the beginning, its underpart titting water outlet passes through gate valve, three general pipelines are sealedly connected with tap and shower shower nozzle respectively, the water temperature nixie display is housed on heat storage water tank, its inner bag of condenser and heat storage water tank all is equipped with heat-insulation layer and shell, and its control system is by compressor electric motor, fan electromotor, starting relay, capacitor, temperature controller, its coil of four-way electromagnetic reversing valve, but the temperature controller of design temperature, magnetic valve, the water temperature nixie display, selector switch and attaching plug are electrically connected to be formed.But and during the heating of the temperature controller refrigeration air-conditioner in summer of design temperature and winter heating, its design temperature is in≤35 ℃~〉=25 ℃ scopes, to guarantee the big and power saving of original coefficient of refrigerating performance of air-conditioner and heating efficiency, utilize again simultaneously cold-producing medium in water cooled condenser institute's liberated heat all to the heat storage water tank preheating, to improve its water inlet initial temperature, treat air-conditioner refrigeration or heat when up to standard or household's working when not needing air-conditioning, then compound unit is used as Teat pump boiler, its design temperature is transferred to 〉=45 ℃~≤ 60 ℃ scopes in, spring and autumn is then round-the-clock as Teat pump boiler, its design temperature 〉=45 ℃~≤ 60 ℃.
Description of drawings: the present invention is further described below in conjunction with accompanying drawing.Figure (1)~(32) are same sequence number and alphabetical same parts and the different installation positions represented thereof wherein, and figure (1)~(32) are sequence number and letter representative identical electrical equipment and different installation positions wherein.
Figure (1) is refrigerator or refrigerator-freezer or ice making case and the compound unit structural representation of Teat pump boiler.
Figure (2) is its control system circuit diagram of compound unit of corresponding diagram (1).
Figure (3) is that freezer is excellent with refrigerator and the compound unit structural representation of Teat pump boiler with refrigerator or ice making.
Figure (4) is its control system circuit diagram of compound unit of corresponding diagram (3).
Figure (5) is the compound unit structural representation of central air-conditioning and air source hot pump water heater.
Figure (6) is its control system circuit diagram of compound unit of corresponding diagram (5).
Figure (7) is that heat pump type air conditioner and water resource heat pump hot water play compound unit structural representation.
Figure (8) is its control system circuit diagram of compound unit of corresponding diagram (7).
Figure (9) is the compound unit structural representation of heat pump type air conditioner and air source hot pump water heater.
Figure (10) is its control system circuit diagram of compound unit of corresponding diagram (9).
Figure (11) is air-conditioner and refrigerator-freezer and the compound unit structural representation of Teat pump boiler.
Figure (12) is its control system circuit diagram of compound unit of corresponding diagram (11).
Figure (13) air-conditioner and the compound unit structural representation of earth source heat pump water heater.
Figure (14) is its control system circuit diagram of compound unit of corresponding diagram (13).
Figure (15) is heat pump type air conditioner and the compound unit structural representation of air source hot pump water heater that replaces four-way electromagnetic reversing valve with magnetic valve.
Figure (15A) is its control system circuit diagram of compound unit of figure (15), and reference diagram (14) is analogized and design, Therefore, omited.
Figure (16) is to be the central air-conditioning and the compound unit structural representation of air source hot pump water heater of heat transferring medium with water.
Figure (17) is its control system circuit diagram of compound unit of corresponding diagram (16).
Figure (18) is refrigerator-freezer and air-conditioner and the compound unit structural representation of air source hot pump water heater.
Figure (19) is its control system circuit diagram of compound unit of corresponding diagram (18).
Figure (20) is the compound unit structural representation of heat pump type air conditioner and air source hot pump water heater.
Figure (21) is its control system circuit diagram of compound unit of corresponding diagram (20).
Figure (22) is the compound unit structural representation of air-conditioner and Teat pump boiler.
Figure (22A) is its control system circuit diagram of compound unit of figure (22), and reference diagram (21) is analogized and design, Therefore, omited.
Figure (23) is two stages of compression, one-level throttling, the middle not exclusively refrigeration plant and the Teat pump boiler structural representation of cool cycles.
Figure (23A) is its control system circuit diagram of compound unit of figure (23), and reference diagram (4) is analogized and design, Therefore, omited.
Figure (24) covers folded its refrigeration plant of formula kind of refrigeration cycle and Teat pump boiler structural representation.
Figure (24A) is its control system circuit diagram of compound unit of figure (24), and reference diagram (4) is analogized and design, Therefore, omited.
Figure (25) is family's central air-conditioning and bedroom, separate room air-conditioner and the compound unit structural representation of Teat pump boiler in parallel.
Figure (25A) is its control system circuit diagram of compound unit of figure (25), and analogize and design, Therefore, omited reference diagram (6) and (21).
Figure (26) is central air-conditioning and night shift room air-conditioner and the compound unit structural representation of Teat pump boiler in parallel.
Figure (26A) is its control system circuit diagram of compound unit of figure (26), and analogize and design, Therefore, omited reference diagram (6) and (21).
Figure (27) is air-conditioner and refrigerator and the compound unit structural representation of Teat pump boiler in parallel.
Figure (28) is its control system circuit diagram of compound unit of corresponding diagram (27).
Figure (29) is heat pump type air conditioner and air source and the compound unit structural representation of water source double heat source heat pump water heater.
Figure (30) is its control system circuit diagram of compound unit of corresponding diagram (29).
Figure (31) is heat pump type air conditioner and air source and the compound unit structural representation of ground source double heat source heat pump water heater.
Figure (31A) is its control system circuit diagram of compound unit of figure (31), and reference diagram (8) is analogized and design, Therefore, omited.
Figure (32) is air-conditioner and water source and the compound unit structural representation of ground source double heat source heat pump water heater.
Figure (32A) is its control system circuit diagram of compound unit of figure (32), and reference diagram (8) is analogized and design, Therefore, omited.
All same sequence number and additional letter or identical electrical equipment of symbology and different parts or dissimilar among figure (1)~figure (32).
6-temperature nixie display.
But the temperature controller of 7-design temperature, 7A-temperature-sensing element, 32-compressor electric motor temperature controller, 32 1-two grades of temperature controllers
9X-compressor electric motor, 9X 1The compressor electric motor of-band built-in type protective relay.
Its capacitor of 9Y-compressor electric motor, 9Y 1-compressor electric motor starter relay.
Its protective relay of 9Z-compressor electric motor, 9Z-mistake heats up and over-current protection relay.
13J 1, 13J 2, 13J 3-be respectively air conditioner room unit group fan electromotor.
13J 1Y, 13J 2Y-be respectively its capacitor of air conditioner room unit group fan electromotor.
13J, 13JY, 13JZ-air-conditioner outdoor unit group fan electromotor and capacitor and protective relay.
13A 0-water-cooled air conditioner indoor units.
23X, 23Y, 23Z-be respectively circulation-water pump electric machine and capacitor and protective relay.
24X, 24Y, 24Z-be respectively recycle liquid pump motor and capacitor and protective relay.
25X, 25Y, 25Z-be respectively circulating hot water pump motor and capacitor and protective relay.
14A 1, 14A 2, 14A 3, 14B 1, 14B 2, 14B 3, 14C 1, 14C 2, 14C 3, 14D 1, 14D 2, 14D 3, 14E 1, 14E 2, 14E 3, 14X, 14Y, 14Q, 14K 1, 14K 2, 14K 3, 14K 4One is installed in the magnetic valve of different parts.
Its coil of 19A-four-way electromagnetic reversing valve, 31-selector switch, 33-attaching plug.
45-superthermal protection fuse, 47-defrost temperature controller, 48-frost removal timer, M T-frost removal timer motor.
49-draining heater, 50-defrosting heater, 52,52 1, 52 11One refrigerating-chamber door switch.
53-refrigerating chamber door switch, 54X-refrigerator internal fan motor, 55-illuminating lamp, 56-defrosting temperature controller.
57A, 57B, 57C-press button.
The relevant electrical equipment electric connection point of cold-temperature controller design temperature air conditioner room unit group refrigeration air-conditioner in 〉=45 ℃~≤ 35 ℃ scopes.
Cold-temperature controller design temperature is the relevant electrical equipment electric connection point of air conditioner room unit group refrigeration in 〉=25 ℃~≤ 35 ℃ scopes.
Figure S04155574520041210D000043
Heat-temperature controller design temperature air conditioner room unit group in 〉=45 ℃~≤ 60 ℃ scopes heats the relevant electrical equipment electric connection point of heating air-conditioner.
Warm-temperature controller design temperature air conditioner room unit group in 〉=25 ℃~≤ 35 ℃ scopes heats warm its relevant electrical equipment electric connection point.
Figure S04155574520041210D000045
Hot water-temperature controller design temperature is refrigeration air-conditioner in summer relevant electrical equipment electric connection point during hot-water supply simultaneously in 〉=45 ℃~≤ 35 ℃ scopes.
Figure S04155574520041210D000046
Hot water-temperature controller design temperature wouldn't heat winter in 〉=45 ℃~≤ 35 ℃ scopes, relevant electrical equipment electric connection point during by the Teat pump boiler hot-water supply.
-temperature controller design temperature wouldn't heat winter in 〉=45 ℃~≤ 60 ℃ scopes, relevant electrical equipment electric connection point during by earth source heat pump water heater hot-water supply.
Freezing
Figure S04155574520041210D0000410
Refrigeration-temperature controller design temperature in 〉=25 ℃~≤ 60 ℃ scopes freezing with refrigeration relevant electrical equipment electric connection point.
Figure S04155574520041210D0000411
Freezing
Figure S04155574520041210D0000412
Refrigeration-temperature controller design temperature in 〉=45 ℃~≤ 60 ℃ scopes freezing with refrigeration relevant electrical equipment electric connection point.
All electrical equipment disconnect during pass-shutdown.
Relevant electrical equipment electric connection point during wind-ventilation.
Invention embodiment: the present invention is that existing any compression-type refrigeration heating equipment (comprises air-conditioner both at home and abroad, central air-conditioning, refrigerator-freezer, refrigerator, following schemes such as refrigerator or freezer freezing equipment are identical,) and the compound unit of Teat pump boiler, it is characterized in that it is by compression-type refrigeration heating (A), the washing of having a bath and live is used or industrial or agricultural is formed with hot-water supply system (B) and control system (C), and compression-type refrigeration heating (A) is by compressor (9), (comprise fully closed compressor (9A), non-enclosed compressor (9B) or rotor compressor (9C), below each scheme identical,) do not adorn or be equipped with four-way electromagnetic reversing valve (19), with water is the condenser (8A) of heat transferring medium, device for drying and filtering (16), choke valve (15), (bag comprises heating power expansion valve (15A), capillary (15B), or electric expansion valve (15C), below each scheme identical,) evaporimeter (11), containing with the air is the evaporimeter (11A) of heat transferring medium, or be the evaporimeter (11B) of heat transferring medium with water or liquid, below each scheme identical,) gas-liquid separator parts such as (10) are equipped with or do not adorn, be tightly connected into the circulatory system successively with pipeline, in its system, charge an amount of cold-producing medium, fluorine Lyons R22 for example, R134a, R12, ammonia R717 etc., its filling weight is determined with reference to conventional refrigeration plant test.And hot-water supply system (B) is made up of the condenser (8A) and the heat storage water tank (5) that with water are heat transferring medium, and condenser (8A) is by inner bag (8Q), heat-insulation layer (8M) and shell (8N) are formed, and be equipped with away cold-producing medium metallic coil (8H) but and temperature controller of design temperature (7) and temperature temperature-sensing element (7A) thereof, for example household electrical appliances are with mechanical electric contact formula temperature controller, electric contact thermometer, or bimetal strip thermostat, its titting water outlet of condenser (8A) (8E) is tightly connected with connecting pipe by magnetic valve (14X) with its end admitting pipe joint (5F) of heat storage water tank (5), its admitting pipe joint of condenser (8A) (8F) passes through magnetic valve (14Y) or circulating hot-water pump (25) with its end titting water outlet (5E) of heat storage water tank (5), be tightly connected with connecting pipe, heat storage water tank (5) its underpart admitting pipe joint (5G) is sealedly connected with water source (1A) from the beginning by gate valve (2A) and threeway (18X) with connecting pipe, the upper end of heat storage water tank (5) its underpart titting water outlet (5H) is sealedly connected with one section water pipe (5D), the lower end of its titting water outlet (5H) is tightly connected in the hole on it with connecting pipe and threeway (18Y) by gate valve (2B), its right hole of threeway (18X) is by gate valve (2C), threeway (18Y) and (18Z) be connected with tap (3) with seal for pipe joints, threeway (18Z) shower that the hole is sealedly connected with belt switch (4A) with connecting pipe on it is with shower nozzle (4), heat storage water tank (5) is by inner bag (5C), heat-insulation layer (5B) and shell (5A) are formed, and at heat storage water tank (5) water temperature nixie display (6) are housed.Shown in figure (1), when compression-type refrigeration heating (A) during as refrigeration, freezing or ice making equipment, the evaporimeter (11A) that then with the air is heat transferring medium is combined into one with refrigerator (13B), or be combined into one with refrigerator-freezer (13C), or be combined into one with ice making case (13D), its evaporimeter (11A) is made up of inner bag (11Q), heat-insulation layer (11M) and shell (11N), in inner bag (11Q) lining metal hose (11H is housed 0).Shown in figure (16), in compression-type refrigeration heating (A) is used as its inner bag of evaporimeter (11B) (11Q) that water-cooled air conditioner then is heat transferring medium with water, metallic coil (11H) is housed, between inner bag (11Q) and metallic coil (11H) outer wall water or antifreezing liquid are housed, for example salt solution or motor vehicle antifreeze fluid, its liquid outlet joint of evaporimeter (11B) (11E) by magnetic valve (14Q) with pipeline and water-cooled air conditioner indoor units (13A 0) its liquid outlet joint (13F) is tightly connected, its feed tube joint (11F) of evaporimeter (11B) by recycle liquid pump (24) with pipeline and water-cooled air conditioner indoor units (13A 0) its liquid outlet joint (13E) is tightly connected water-cooled air conditioner indoor units (13A 0) in the metal coil pipe (13I) of antifreezing liquid is housed away, at metal coil pipe (13I) fan (13H) and fan electromotor (13J) thereof, water-cooled air conditioner indoor units (13A are housed behind 0) its shell (13L) front has shutter.Shown in figure (3), when compression-type refrigeration heating (A) then is the evaporimeter (11B) and freezer freezing equipment or its ice making case (13G) binding of refrigerator of heat transferring medium with the antifreezing liquid as large cold storage freezing equipment or middle-size and small-size ice machine, its feed tube joint (13F) of its liquid outlet joint of evaporimeter (11B) (11E) and ice making case (13G) is connected with seal for pipe joints by magnetic valve (14Q), and its feed tube joint (13F) of evaporimeter (11B) is tightly connected by recycle liquid pump (24) with its liquid outlet joint of ice making case (13G) (13E).And its control system of the compound unit of compression-type refrigeration heating equipment and heat pump is usually by compressor electric motor, fan electromotor, the recycle liquid pump motor, circulation-water pump electric machine, starting relay, capacitor, temperature controller, but the temperature controller of design temperature, the defrosting warmer, its coil of four-way electromagnetic reversing valve, magnetic valve, the water temperature nixie display, selector switch, devices such as attaching plug are electrically connected to be formed, different purposes at the compression-type refrigeration heating equipment, dissimilar, different structure, with reference to refrigerator, refrigerator-freezer, refrigeration case, the routine techniques of household electrical appliance such as air-conditioner or freezer equipment and its control system of refrigerator, be designed to several series circuits respectively, the head end of its series circuit is electrically connected respectively with several groups of tie points of selector switch, the end of its series circuit all is electrically connected with the terminal lead of attaching plug, and the head end lead of attaching plug is electrically connected with first group of tie point of selector switch.Figure (2) is refrigerator (13B) shown in the figure (1) and its control system circuit diagram of the compound unit of Teat pump boiler, freezer freezing equipment or refrigerator and its control system circuit diagram of the compound unit of Teat pump boiler shown in the figure (4).
This compound unit, it is characterized in that in compression-type refrigeration heating (A), between being that condenser (8A) and the evaporimeter (11) of heat transferring medium is between the two by a plurality of threeways (18) with water, be parallel with many heat exchangers (20) more than or with the connecting pipe sealing, (comprising with the air is the heat exchanger (20A) of heat transferring medium, or be the heat exchanger (20B) of heat transferring medium with liquid, below each scheme identical,) shown in figure (5) and figure (9), its compression-type refrigeration heating (A) is by compressor (9), four-way electromagnetic reversing valve (19), with water is the condenser (8A) of heat transferring medium, device for drying and filtering (16), choke valve (15), evaporimeter parts such as (11) are tightly connected into closed system successively with pipeline, and seal by a plurality of threeways (18) and connecting pipe between the two at condenser (8A) and evaporimeter (11) and to be parallel with many heat exchangers (20) more than or, as figure (5), and its left hole of four-way electromagnetic reversing valve (19) connecting pipe and threeway (18A 1) hole is tightly connected on it, the input pipe interface of its cold-producing medium of condenser (8A) is through magnetic valve (14A 1), with connecting pipe and threeway (18A 1) its left hole is tightly connected heat exchanger (20 1) the top carrier pipe interface of its cold-producing medium is through threeway (18B 1) and magnetic valve (14B 1) usefulness connecting pipe and threeway (18A 1) its right hole is tightly connected the left part carrier pipe interface and the threeway (18A of its cold-producing medium of device for drying and filtering (16) 2) it connects in the hole efferent duct interface process magnetic valve (14A of its cold-producing medium of condenser (8A) down with seal for pipe joints 2) usefulness connecting pipe and threeway (18A 2) its left hole is tightly connected heat exchanger (20 1) the bottom carrier pipe interface of its cold-producing medium is through choke valve (15), threeway (18B 2) and magnetic valve (14B 2) usefulness connecting pipe and threeway (18A 2) its right hole is tightly connected, its right hole of four-way electromagnetic reversing valve (19) is with connecting pipe and threeway (18D 1) hole is tightly connected on it, the top carrier pipe interface of its cold-producing medium of evaporimeter (11) is through magnetic valve (14E 1) usefulness connecting pipe and threeway (18D 1) its right hole is tightly connected heat exchanger (20 2) the top carrier pipe interface of its cold-producing medium is through threeway (18C 1) and magnetic valve (14D 1) usefulness connecting pipe and threeway (18D 1) its left hole is tightly connected, the right part carrier pipe interface of its cold-producing medium of device for drying and filtering (16) is with connecting pipe and threeway (18D 2) it is tightly connected in the hole input pipe interface process choke valve (15) and the magnetic valve (14E of its cold-producing medium of evaporimeter (11) down 2) usefulness connecting pipe and threeway (18D 2) its right hole is tightly connected heat exchanger (20 2) the bottom carrier pipe interface of its cold-producing medium is through choke valve (15), threeway (18C 2) and magnetic valve (14D 2) usefulness connecting pipe and threeway (18D 2) its left hole is tightly connected threeway (18B 1) and (18C 1) through magnetic valve (14C 1) be tightly connected threeway (18B with connecting pipe 2) and (18C 2) through magnetic valve (14C 2) be tightly connected with connecting pipe.Figure (6) is central air-conditioning shown in the figure (5) and its control system circuit diagram of the compound unit of air source hot pump water heater, figure (10) is air-conditioner and its control system circuit diagram of the compound unit of air source hot pump water heater of new design or repacking, figure (5) heat exchanger (20) wherein and air conditioner room unit group (13A n) be combined into one, the metal coil pipe (13H) and the fan electromotor (13J) thereof of cold-producing medium are housed away in the unit, evaporimeter (11A) is combined into one with air-conditioner outdoor unit group (13A), the metal coil pipe (13I) of cold-producing medium is housed away, fan (13H) and fan electromotor (13J) thereof in the unit.
This compound unit, it is characterized in that in the compression-type refrigeration heating (A), be equipped with and replace many magnetic valves (14) and the control system (C) thereof that four-way electromagnetic reversing valve (19) can make compound unit refrigeration in summer and winter heating's switching usefulness, shown in figure (7) and figure (11), the compression-type refrigeration heating (A) of its compound unit is by compressor (9), with water is the condenser (8A) of heat transferring medium, device for drying and filtering (16), choke valve (15), evaporimeter (11) has or does not adorn gas-liquid separator (10), connect into closed system with seal for pipe joints, and be parallel with many heat exchangers (20) more than or with seal for pipe joints by a plurality of threeways (18) between the two at condenser (8A) and evaporimeter (11), and the escape pipe interface of compressor (9) and threeway (18A 1) last hole connect with seal for pipe joints, the input pipe interface of its cold-producing medium of condenser (8A) is by magnetic valve (14A 1) and threeway (18A 1) its right hole is tightly connected heat exchanger (20 1) the carrier pipe interface of its top cold-producing medium is by threeway (18B 1) and magnetic valve (14B 1) and threeway (18A 1) its left hole connects with seal for pipe joints, the right-hand member carrier pipe interface of its cold-producing medium of device for drying and filtering (16) is with pipeline and threeway (18A 2) following hole be tightly connected, the efferent duct interface of its cold-producing medium of condenser (8A) is by magnetic valve (14A 2) and threeway (18A 2) its right hole connects heat exchanger (20 with seal for pipe joints 1) the carrier pipe interface of its underpart cold-producing medium is by choke valve (15), threeway (18B 2) and magnetic valve (14B 2) usefulness pipeline and threeway (18A 2) its left hole is tightly connected its air inlet pipe interface of gas-liquid separator (10) and threeway (18D 1) last hole connect with seal for pipe joints, the efferent duct interface of its cold-producing medium of evaporimeter (11) is by magnetic valve (14E 1) usefulness pipeline and threeway (18D 1) its left hole is tightly connected heat exchanger (20 2) its cold-producing medium top carrier pipe interface is by threeway (18C 1) and magnetic valve (14D 1) usefulness pipeline and threeway (18D 1) its right hole is tightly connected, the carrier pipe interface of its left end cold-producing medium of device for drying and filtering (16) is with pipeline and threeway (18D 2) it is tightly connected in hole down, the input pipe interface of its cold-producing medium of evaporimeter (11) is by choke valve (15) and magnetic valve (14E 2) usefulness pipeline and threeway (18D 2) its left hole is tightly connected heat exchanger (20 2) the carrier pipe interface of its underpart cold-producing medium is by choke valve (15), threeway (18C 2) and magnetic valve (14D 2) usefulness pipeline and threeway (18D 2) its right hole is tightly connected threeway (18B 1) by magnetic valve (14C 1) usefulness pipeline and threeway (18C 1) be tightly connected threeway (18B 2) by magnetic valve (14C 2) usefulness pipeline and threeway (18C 2) be tightly connected, figure (8) is air-conditioner shown in the figure (7) and its control system circuit diagram of the compound unit of water source heat pump water heater, figure (12) is central air-conditioning shown in the figure (11) and refrigerator-freezer and its control system circuit diagram of the compound unit of Teat pump boiler.
This compound unit, it is characterized in that in compression-type refrigeration heating (A), between being to be parallel with a heat exchanger (20) by many threeways (18) and connecting pipe sealing between the condenser (8A) of heat transferring medium and the evaporimeter (11) with water, be parallel with the heat exchanger (20 of one group of parallel connection as figure (15) or sealing n), shown in figure (13), in the trunk line top three of its refrigerant conveying, whenever be sealedly connected with unicom pipeline (27A), (27B) and (27C) respectively by threeway (18) between the two, and magnetic valve (14A is housed respectively on unicom pipeline 3), (14B 3) and (14C 3), make UNICOM or disconnection between the two whenever among the trunk line three, as scheming its escape pipe interface of (13) compressor (9) by threeway (18A 1) usefulness connecting pipe and threeway (18A 2) hole is tightly connected on it, its air inlet of compressor (9) is by threeway (18B 1) and magnetic valve (14E 3) usefulness connecting pipe and threeway (18B 2) hole is tightly connected on it, the input pipe interface of its cold-producing medium of condenser (8A) that with water is heat transferring medium is by magnetic valve (14A 1) usefulness pipeline and threeway (18A 2) it is tightly connected in hole down, the efferent duct interface of its cold-producing medium of condenser (8A) is by magnetic valve (14A 2) and threeway (18A 3) its left hole is tightly connected, its left part interface tube of device for drying and filtering (16) is with pipeline and threeway (18A 3) it is tightly connected in hole down, the efferent duct interface of its cold-producing medium of evaporimeter (1) is by magnetic valve (14B 1) usefulness pipeline and threeway (18B 2) it is tightly connected in hole down, the input pipe interface of its cold-producing medium of evaporimeter (11) is by choke valve (15), magnetic valve (14B 2) usefulness pipeline and threeway (18B 3) its right hole is tightly connected, its right part interface tube of device for drying and filtering (16) is with pipeline and threeway (18B 3) it is tightly connected the heat exchanger (20 of one group of parallel connection in the hole down n) top of its cold-producing medium carries the conveying trunk line (27D) and threeway (18C after the lateral parallel connection 1) it is tightly connected in hole down, as the top carrier pipe interface of figure (8A) or its cold-producing medium of single heat exchanger (20) with connecting pipe and threeway (18C 1) it is tightly connected the heat exchanger (20 of one group of parallel connection in the hole down n) bottom of its cold-producing medium carries the conveying trunk line (27E) and threeway (18C after the lateral parallel connection 2) hole is tightly connected on it; Or the bottom carrier pipe interface of its cold-producing medium of single heat exchanger (20) is by choke valve (15) magnetic valve (14C 2) usefulness pipeline and threeway (18C 2) hole is tightly connected threeway (18A on it 3) its right hole and threeway (18C 2) its left hole is by magnetic valve (14E 1) connect threeway (18B with seal for pipe joints 3) its left hole and threeway (18C 2) its right hole is by magnetic valve (14E 2) connect with seal for pipe joints, figure (14) is central air-conditioning shown in the figure (13) and its control system circuit diagram of the compound unit of ground source heat hydrophone, air-conditioner and its control system circuit diagram of the compound unit of air source hot pump water heater shown in the figure (15A), reference diagram (14) is analogized, design and fabrication, the Therefore, omited.
This compound unit, it is characterized in that in the compression-type refrigeration heating (A), with water the condenser (8A) of heat transferring medium and be the evaporimeter (11B) of heat transferring medium with water or anti-icing fluid, be parallel with a heat exchanger (20) between the two, comprise with the air and be the heat exchanger (20A) of heat transferring medium or be the heat exchanger (20B) of heat transferring medium with water, as figure (16), its liquid outlet joint of evaporimeter (11B) (11E) that with water or anti-icing fluid is heat transferring medium is tightly connected with pipeline and threeway (18F) and feed liquor trunk line (21C) through magnetic valve (14Q), its feed tube joint (11F) of evaporimeter (11B) is tightly connected with fluid trunk line (22C) with pipeline and threeway (18E) through recycle liquid pump (24), sealing plug screw (30) all is equipped with at feed liquor trunk line (21C) and its two ends of fluid trunk line (22C), and central air-conditioning indoor units (13A 0) it is leaked water or its feed tube interface (13F) of metal coil pipe (13I) of anti-icing fluid is tightly connected with pipeline and feed liquor trunk line (21C) through threeway (18H), its drain pipe interface (13E) is tightly connected with pipeline and fluid trunk line (22C) through threeway (18I), composition is the central air-conditioning and the compound unit of Teat pump boiler of heat transferring medium with water or antifreezing liquid, or its liquid outlet joint of evaporimeter (11B) (11E) through magnetic valve (14Q) with pipeline directly with leak water or the air conditioner room unit group (13A of anti-icing fluid 0) it is leaked water or the feed tube interface (13F) of the metal coil pipe (13I) of anti-icing fluid is tightly connected, its feed tube joint (11F) of evaporation (11B) through recycle liquid pump (24) with pipeline directly and its liquid outlet joint of metal coil pipe (13I) (11E) be tightly connected, the metallic coil (11H) of cold-producing medium is housed away in its inner bag of evaporimeter (11B) (11Q), inner bag (11Q) outer wall is equipped with heat-insulation layer (11M) and shell (11N), be equipped with in water-cooled central air-conditioning or its indoor units of water-cooled air conditioner (13A0) and leak water or the metal coil pipe (13I) of antifreezing liquid, at its back side of metal coil pipe (13I) fan (13H) and fan electromotor (13J) thereof are housed, and on shell, having the shutter of band blinds, figure (17) is to be central air-conditioning and its control system circuit diagram of the compound unit of air source water heater of heat transferring medium with water shown in the figure (16).
This compound unit is characterized in that in the compression-type refrigeration heating (A), is that the condenser (8A) and the evaporimeter (11) of heat transferring medium respectively is parallel with many heat exchangers (20) more than or with water, as figure (18); Or only there is condenser (8A) to be parallel with many heat exchangers (20) more than or, as figure (20), or have only evaporimeter (11) to be parallel with many heat exchangers (20) more than or, as figure (22), its compression-type refrigeration heating (A) is by compressor (9), four-way electromagnetic reversing valve (19), with water is the condenser (8A) of heat transferring medium, device for drying and filtering (16), choke valve (15), choke valve (15), evaporimeter (11) connects into closed system with seal for pipe joints, and condenser (8A) and evaporimeter (11) respectively are parallel with many heat exchangers (20 more than or n), and its right hole of four-way electromagnetic reversing valve (19) is by connecting pipe and threeway (18A 1) last hole be tightly connected, the input pipe interface of its cold-producing medium of condenser (8A) that with water is heat transferring medium is by magnetic valve (14A 1) usefulness pipeline and threeway (18A 1) its right hole is tightly connected heat exchanger (20 1) the upper tube interface of its cold-producing medium is by magnetic valve (14B 1) usefulness pipeline and threeway (18A 1) its left hole is tightly connected, its cold-producing medium efferent duct interface of condenser (8A) is by magnetic valve (14A 2) usefulness pipeline and threeway (18A 2) its right hole is tightly connected heat exchanger (20 1) the bottom carrier pipe interface of its cold-producing medium is by choke valve (15) and magnetic valve (14B 2) usefulness pipeline and threeway (18A 2) its left hole is tightly connected, the right-hand member carrier pipe joint of its cold-producing medium of device for drying and filtering (16) is by pipeline and threeway (18A 2) it is tightly connected in hole down, its left hole of four-way electromagnetic reversing valve (19) is by pipeline and threeway (18B 1) hole is tightly connected on it, the top carrier pipe interface of its cold-producing medium of evaporimeter (11) is by magnetic valve (14D 1) usefulness pipeline and threeway (18B 1) its left hole is tightly connected heat exchanger (20 2) the top carrier pipe interface of its cold-producing medium is by magnetic valve (14C 1) usefulness pipeline and threeway (18B 1) right hole be tightly connected, the bottom carrier pipe interface of its cold-producing medium of evaporimeter (11) is by choke valve (15) and magnetic valve (14D 2) usefulness pipeline and threeway (18B 2) its left hole is tightly connected heat exchanger (20 2) the bottom carrier pipe interface of its cold-producing medium is by choke valve (15) and magnetic valve (14C 2) usefulness pipeline and threeway (18B 2) its right hole is tightly connected, the left end carrier pipe joint of its cold-producing medium of device for drying and filtering (16) is by pipeline and threeway (18B 2) it is tightly connected in the hole heat exchanger (20 among the figure (18) down 1) with (20 2) its into and out of pipe joint with upper and lower two pipeline UNICOMs, figure (19) is air-conditioner shown in the figure (18) and refrigerator-freezer and its control system circuit diagram of the compound unit of Teat pump boiler, figure (21) is air-conditioner shown in the figure (20) and its control system circuit diagram of the compound unit of Teat pump boiler, air-conditioner and its control system circuit diagram of the compound unit of Teat pump boiler shown in the figure (22), reference diagram (14) is analogized, design and fabrication, the Therefore, omited.
This compound unit, it is characterized in that compression-type refrigeration heating (A) is a two stages of compression formula refrigerating and heating systems, and be that two-stage is steam compressed, the one-level throttling, the middle not exclusively circulatory system of cooling, as figure (23), its steam compression type refrigerating heating (A) is by stage compressor (9N), hiigh pressure stage compressor (9M), with water is the condenser (8A) of heat transferring medium, intercooler (8X) and choke valve (15X) thereof, choke valve (15), evaporimeter parts such as (11) connect into the circulatory system with seal for pipe joints, charge an amount of cold-producing medium in its system, it with the cooling fluid metallic coil (11H) that its inner bag of evaporimeter (11B) (11Q) of heat transferring medium is equipped with away cold-producing medium, between inner bag (11Q) and metallic coil (11H) outer wall saline solution is housed, its feed tube joint (11F) is connected with seal for pipe joints with freezer ice making case (13G) feed tube joint (13E), recycle liquid pump (24) is housed on its pipeline, its feed tube joint (13F) of its liquid outlet joint of evaporimeter (11B) (11E) and ice making case (13G) is connected with seal for pipe joints, two stages of compression formula freezer freezing equipment and its control system circuit diagram of the compound unit of Teat pump boiler shown in the figure (23), reference diagram (4) is analogized, design and making, the Therefore, omited.
This compound unit is characterized in that compression-type refrigeration heating (A) is to cover folded formula two-stage or steam compression type refrigerating heating recycle system independently more than the two-stage, is the low temperature circulatory system (A as figure (24) its one-level 1), another level is the (A of high temperature circulation system 2), its low temperature circulatory system (A 1) be to be tightly connected into the low temperature circulatory system (A successively with pipeline by cryogenic compressor (9N), shared evaporator-condenser (8A-11B), device for drying and filtering (16A), choke valve (15), evaporimeter (11), gas-liquid separator parts such as (10) 1), at the low temperature circulatory system (A 1) in charge an amount of low-temperature refrigerant, R13 for example, the and (A of high temperature circulation system 1) be to be that condenser (8A), device for drying and filtering (16B), choke valve (15), shared evaporator-condenser (8A-11B), the gas-liquid separator parts such as (10) of heat transferring medium are tightly connected into (the A of high temperature circulation system successively with pipeline by high temperature compressed machine (9M), with water 2), at (the A of high temperature circulation system 2) in charge an amount of middle temperature cold-producing medium, R12 for example, it with the cooling liquid metallic coil (11H) that its inner bag of evaporimeter (11B) (11Q) of heat transferring medium is equipped with away cold-producing medium, between inner bag (11Q) and metallic coil (11H) outer wall saline solution is housed, inner bag (11Q) outer wall has heat-insulation layer (11M) and shell (11N), its feed tube joint (11F) is connected with seal for pipe joints with its feed tube joint (13E) of ice making case (13G) with freezer, recycle liquid pump (24) is housed on its pipeline, its liquid outlet joint of evaporimeter (11B) (13E) is tightly connected with its feed tube joint (13F) of ice making case (13G), cover folded formula two-stage steam compression type freezer freezing equipment and its control system circuit diagram of the compound unit of Teat pump boiler shown in the figure (24), reference diagram (4) is analogized, design and making, the Therefore, omited.
This compound unit is characterized in that two independently steam compression type refrigerating heating (A 1) and (A 2) its water cooled condenser (8A 1) and (8A 2) parallel connection, as figure (25), its titting water outlet (8E 1) and (8E 2) through magnetic valve (14X 1) and (14X 2) be tightly connected with pipeline and threeway (18V), and the last hole of threeway (18V) is tightly connected with connecting pipe and its admitting pipe joint of heat storage water tank (5) (5F), two water cooled condenser (8A 1) and (8A 2) its admitting pipe joint (8F 1) and (8F 2) be tightly connected with connecting pipe and threeway (18W), and the last hole of threeway (18W) is tightly connected with connecting pipe and its titting water outlet of heat storage water tank (5) (5E), two water cooled condenser (8A 1) and (8A 2) but the temperature controller (7 of design temperature is housed respectively 1) with (7 2), or two steam compression type refrigerating heating (A independently 1) and (A 2) its water cooled condenser (8A 1) and (8A 2) in parallel with heat storage water tank (5) three, as figure (26), its titting water outlet (8E 1) and (8E 2) respectively by magnetic valve (14X 1) and (14X 2) and its admitting pipe joint of heat storage water tank (5) (5F 1) and (5F 2) be tightly connected respectively, and condenser (8A 1) and (8A 2) its admitting pipe joint (8F 1) and (8F 2) respectively by magnetic valve (14Y 1) and (14Y 2) heat storage water tank and (5) its titting water outlet (5E 1) and (5E 2) be tightly connected two water cooled condenser (8A respectively 1) and (8A 2) but the temperature controller (7 of design temperature is housed respectively 1) with (7 2), or two steam compression type refrigerating heating (A independently 1) and (A 2) its water cooled condenser (8A) is combined into one, both walk the metallic coil (8H of cold-producing medium 1) and (8H 2) be installed in its inner bag of same condenser (8A), as figure (27), its titting water outlet of condenser (8A) (8E) is tightly connected with pipeline and its admitting pipe joint of heat storage water tank (5) (5F) through magnetic valve (14X), its water inlet pipe interface (8F) of condenser (8A) is tightly connected with pipeline and its titting water outlet of heat storage water tank (5) (5E) through magnetic valve (14Y), figure (25) and figure (26) are that unit uses or home-use central air-conditioning and night shift room or bedroom, separate room wall hanging or air-conditioner and the compound unit structural representation of Teat pump boiler, both are identical for its control system circuit diagram, all design and produce into two autonomous control systems, its refrigerating and heating systems of central air-conditioning (A 1) design, make its control system of wall-hanging air conditioner (A with its control system reference diagram (6) of the compound unit of Teat pump boiler 2) design, make the Therefore, omited by figure (21) with its control system circuit diagram of the compound unit of Teat pump boiler.Figure (28) is air-conditioner shown in the figure (27) and the compound unit of Teat pump boiler and refrigerator its control system circuit diagram in parallel with the compound unit of Teat pump boiler.
This compound unit, it is characterized in that it is domestic and international existing compression-type refrigeration heating equipment and the compound unit of air source hot pump water heater (26A), or it is domestic and international existing compression-type refrigeration heating equipment and the compound unit of water source heat pump water heater (26B), or it is domestic and international existing compression-type refrigeration heating equipment and the ground compound unit of seedbed pump water heater (26C), or it is domestic and international existing compression-type refrigeration heating equipment and the compound unit of being made up of air source and water source of double heat source heat pump water heater (26AB), or it is domestic and international existing compression-type refrigeration heating equipment and the compound unit of being made up of air source and source, ground of double heat source heat pump water heater (26AC), or it is domestic and international existing compression-type refrigeration heating equipment and the compound unit of being made up of water source and source, ground of double heat source heat pump water heater (26BC), and the compound unit of compression-type refrigeration heating equipment and air source hot pump water heater (26A) is as figure (5), be characterized in that with the heat energy of containing in the air be thermal source, by in the compression-type refrigeration heating (A) being that to absorb the heat energy of containing in the air source (28A) be thermal source for cold-producing medium evaporation in its metal coil pipe (11I) of evaporation (11A) of heat transferring medium with the air, fan (13H) and fan electromotor (13J) thereof have the band grid on evaporator shell (13L) ventilation window is housed at the back side of its metal coil pipe (13I) of evaporimeter (11A), and the compound unit of compression-type refrigeration heating equipment and water source heat pump water heater (26B) is as figure (7), be characterized in that with the heat energy of containing in the water source be thermal source, by in the compression-type refrigeration heating (A) being that to absorb the heat energy of containing in the water source (28B) be thermal source for cold-producing medium evaporation in its metallic coil of evaporimeter (11B) (11H) of heat transferring medium with water, the metallic coil (11H) of cold-producing medium is housed away in evaporimeter (11B), and the water as heat transferring medium is housed in the evaporimeter (11B), its titting water outlet of evaporimeter (11B) (11E) is tightly connected through the inlet channel (21) of magnetic valve (14K) with water source (28B), its admitting pipe joint of evaporimeter (11B) (11F) is tightly connected through the water circulating pump (23) and the outlet conduit (22) at water source (28B), or as the titting water outlet (8E) of figure (22) its condenser (8A) by threeway (18K 2) and water circulating pump (23) and its outlet conduit of water source (28B) be tightly connected, its admitting pipe joint (8F) is by threeway (18K 1) and magnetic valve (14K) and its inlet channel of water source (28B) be tightly connected; And compression-type refrigeration heating equipment and the compound unit of earth source heat pump water heater (26C), as figure (13), be characterized in that with the heat energy of containing in the earth's crust be thermal source, by being that to absorb the heat energy of containing in the earth's crust (28C) be thermal source for cold-producing medium evaporation in its metallic coil of evaporimeter (11B) (11H) of heat transferring medium in the compression-type refrigeration heating (A) with water or antifreezing liquid, and water or antifreezing liquid as heat transferring medium are housed in the evaporimeter (11B) and between metallic coil (11H) outer wall, its admitting pipe joint of evaporimeter (11B) (11F) is through being tightly connected through recycle liquid pump (24) and buried its outlet conduit of U-shaped pipe (22) of fin (29) of being with in the earth's crust (28C), the titting water outlet (11E) of evaporimeter (11B) is tightly connected by the inlet channel (21) of magnetic valve (14K) with the U-shaped pipe, and compression-type refrigeration heating equipment and the compound unit of forming by air source (28A) and water source (28B) of double heat source heat pump water heater (26AB), as figure (29), be characterized in the heat energy contained in the air and be two thermals source with the heat energy of containing in the water source, by the interior evaporimeter that with water is the evaporimeter (11B) of heat transferring medium as water resource heat pump of compression-type refrigeration heating (A), and by one in parallel with evaporimeter (11B) be the evaporimeter of the heat exchanger (20A) of heat transferring medium with the air as air source heat pump, figure (30) is its control system circuit diagram of compound unit shown in the figure (29); And compression-type refrigeration heating equipment and the compound unit of forming by air source and source, ground of double heat source heat pump water heater (26AC), as figure (31), its characteristics are two thermals source with the heat energy contained in the air with the heat energy of containing in the earth's crust, by the interior evaporimeter that with water is the evaporimeter (11B) of heat transferring medium as earth source heat pump of compression-type refrigeration heating (A), and be the evaporimeter of the heat exchanger (20A) of heat transferring medium as air source heat pump by one in parallel with evaporimeter (11B) with the air, its control system circuit diagram reference diagram (8) of compound unit shown in the figure (31A) is analogized and is designed and produced, and compression-type refrigeration heating equipment and the compound unit of forming by water source and source, ground of double heat source heat pump water heater (26BC), shown in figure (32), its characteristics are two thermals source with the heat energy contained in the water source with the heat energy of containing in the earth's crust, by in the compression-type refrigeration heating (A) be with water the evaporimeter (11B) of heat transferring medium as the evaporimeter of water resource heat pump again as the evaporimeter of earth source heat pump, its admitting pipe joint of evaporimeter (11B) (11F) is through threeway (18K 2) and the outlet conduit (22A) at water circulating pump (23A) and water source (28B) be tightly connected, its admitting pipe joint (11F) is through threeway (18K again 2) and its outlet pipe of U-shaped pipe (22B) of water circulating pump (23B) and buried band fin (29) in the earth's crust be tightly connected, its titting water outlet of evaporimeter (11B) (11E) is through threeway (18K 1), elbow (25A 1) and magnetic valve (14K 1) be tightly connected with the inlet channel (21A) at water source (28B), its titting water outlet (11E) is through threeway (18K again 1) and magnetic valve (14K 2) be tightly connected with its water inlet pipe of U-shaped pipe (21B), its titting water outlet of evaporimeter (11B) (11F) is through threeway (18K 2), elbow (25A 2) and water circulating pump (23A) and its outlet conduit of water source (28B) (22A) be tightly connected, its admitting pipe joint (11F) is through threeway (18K again 2) and water circulating pump (23B) and its outlet conduit of U-shaped pipe (22B) be tightly connected, its control system circuit diagram reference diagram (8) of compound unit shown in the figure (32) is analogized and is designed and produced, so the figure summary.

Claims (7)

1. compression-type refrigeration heating equipment and the compound unit of Teat pump boiler, it is characterized in that it is by compression-type refrigeration heating (A), the life washing is used or industrial or agricultural is formed with hot-water supply system (B) and control system (C), and compression-type refrigeration heating (A) is by compressor (9), four-way electromagnetic reversing valve (19), with water is the condenser (8A) of heat transferring medium, device for drying and filtering (16), choke valve (15), evaporimeter (11), gas-liquid separator (10), be tightly connected into the circulatory system successively with pipeline, and in system, charge an amount of cold-producing medium, and hot-water supply system (B) is made up of the described condenser (8A) and the heat storage water tank (5) that with water are heat transferring medium, and described condenser (8A) is by inner bag (8Q), heat-insulation layer (8M) and shell (8N) are formed, and be equipped with away cold-producing medium metallic coil (8H) but and temperature controller of design temperature (7) and temperature-sensing element (7A), the titting water outlet (8E) of described condenser (8A) is tightly connected with connecting pipe by the 11 magnetic valve (14X) with heat storage water tank (5) end admitting pipe joint (5F), the admitting pipe joint (8F) of described condenser (8A) is tightly connected with connecting pipe by the 12 magnetic valve (14Y) or circulating hot-water pump (25) with heat storage water tank (5) end titting water outlet (5E), heat storage water tank (5) bottom admitting pipe joint (5G) is sealedly connected with water source (1A) from the beginning by first gate valve (2A) and the 11 threeway (18X) with connecting pipe, the upper end of heat storage water tank (5) bottom titting water outlet (5H) is sealedly connected with one section water pipe (5D), the lower end of bottom titting water outlet (5H) is gone up the hole by second gate valve (2B) with connecting pipe and the 12 threeway (18Y) and is tightly connected, the right hole of the 11 threeway (18X) is connected with seal for pipe joints with the left interface of the 12 threeway (18Y) by the 3rd gate valve (2C), the right interface of the 12 threeway (18Y) is connected with seal for pipe joints with the left interface of the 13 threeway (18Z), the right interface of the 13 threeway (18Z) is connected with tap (3) with seal for pipe joints, the hole is sealedly connected with belt switch (4A) with connecting pipe shower shower nozzle (4) is gone up in the 13 threeway (18Z), heat storage water tank (5) is by inner bag (5C), heat-insulation layer (5B) and shell (5A) are formed, and water temperature nixie display (6) is housed on heat storage water tank (5); When the compression-type refrigeration heating is used as refrigerator or refrigerator-freezer, the evaporimeter (11A) that then with the air is heat transferring medium is combined into one with refrigerator (13B), or be combined into one with refrigerator-freezer (13C), the evaporimeter (11A) that with the air is heat transferring medium is made up of inner bag (11Q), heat-insulation layer (11M) and shell (11N), in inner bag (11Q) lining metal hose (11H is housed 0); In the compression-type refrigeration heating as water-cooled air conditioner then with water is the inner bag (11Q) of evaporimeter (11B) of heat transferring medium, metallic coil (11H) is housed, between inner bag (11Q) and metallic coil (11H) outer wall water is housed, with water be heat transferring medium evaporimeter (11B) titting water outlet (11E) by the 15 magnetic valve (14Q) directly and water-cooled air conditioner indoor units (13A with pipeline 0) admitting pipe joint (13F) is tightly connected water-cooled air conditioner indoor units (13A 0) in the metal coil pipe (13I) of leaking water is housed, at metal coil pipe (13I) fan (13H) and fan electromotor (13J), water-cooled air conditioner indoor units (13A are housed behind 0) shell (13L) front have shutter; When the compression-type refrigeration heating then is that the evaporimeter (11B) of heat transferring medium and the ice making case (13G) of freezer freezing equipment or middle-size and small-size ice machine are combined into one with the antifreezing liquid as large cold storage freezing equipment or middle-size and small-size ice machine, the liquid outlet joint (11E) that with the antifreezing liquid is the evaporimeter (11B) of heat transferring medium is connected with seal for pipe joints by the 15 magnetic valve (14Q) with the feed tube joint (13F) of ice making case (13G), is that the feed tube joint (11F) of the evaporimeter (11B) of heat transferring medium is tightly connected by recycle liquid pump (24) with ice making case (13G) liquid outlet joint (13E) with the antifreezing liquid; And the control system of compression-type refrigeration heating equipment and the compound unit of Teat pump boiler is by compressor electric motor, fan electromotor, the recycle liquid pump motor, circulation-water pump electric machine, starting relay, capacitor, temperature controller, but the temperature controller of design temperature, the defrosting warmer, the four-way electromagnetic reversing valve coil, magnetic valve, the water temperature nixie display, selector switch, attaching plug is electrically connected to be formed, different purposes at the compression-type refrigeration heating, dissimilar, different structure, refrigerator, refrigerator-freezer, the ice making case, air-conditioner, the control system of freezer equipment or ice machine, be designed to several series circuits respectively, the head end of series circuit is electrically connected respectively with several groups of tie points of selector switch, the end of series circuit all is electrically connected with the terminal lead of attaching plug, and the head end lead of attaching plug is electrically connected with first group of tie point of selector switch.
2. compound unit according to claim 1, it is characterized in that in compression-type refrigeration heating (A), between being that condenser (8A) and the evaporimeter (11) of heat transferring medium is between the two by a plurality of threeways (18) and magnetic valve (14) with water, be parallel with a heat exchanger (20) or many heat exchangers (20n) with the connecting pipe sealing, the left hole of four-way electromagnetic reversing valve (19) connecting pipe and the first threeway (18A 1) go up the hole and be tightly connected, the input pipe interface of cold-producing medium of condenser (8A) that with water is heat transferring medium is through the first magnetic valve (14A 1), with the connecting pipe and the first threeway (18A 1) left hole is tightly connected first heat exchanger (20 of separate unit heat exchanger (20) or many heat exchangers (20n) 1) the top carrier pipe interface of cold-producing medium through the 3rd threeway (18B 1) and the 3rd magnetic valve (14B 1) the usefulness connecting pipe and the first threeway (18A 1) right hole is tightly connected the left part carrier pipe interface of the cold-producing medium of device for drying and filtering (16) and the second threeway (18A 2) down the hole connect with seal for pipe joints, the efferent duct interface of cold-producing medium of condenser (8A) that with water is heat transferring medium is through the second magnetic valve (14A 2) the usefulness connecting pipe and the second threeway (18A 2) left hole is tightly connected first heat exchanger (20 in separate unit heat exchanger (20) or many heat exchangers (20n) 1) the bottom carrier pipe interface of cold-producing medium through the 3rd choke valve (15B 3), the 4th threeway (18B 2) and the 4th magnetic valve (14B 2) the usefulness connecting pipe and the second threeway (18A 2) right hole is tightly connected, the right hole of four-way electromagnetic reversing valve (19) is with connecting pipe and the 7th threeway (18D 1) last hole be tightly connected, the top carrier pipe interface of the cold-producing medium of evaporimeter (11) is through the 9th magnetic valve (14E 1) usefulness connecting pipe and the 7th threeway (18D 1) right hole is tightly connected second heat exchanger (20 in many heat exchangers (20n) 2) the top carrier pipe interface of cold-producing medium through the 5th threeway (18C 1) and the 7th magnetic valve (14D 1) usefulness connecting pipe and the 7th threeway (18D 1) left hole is tightly connected, the right part carrier pipe interface of the cold-producing medium of device for drying and filtering (16) is with connecting pipe and the 8th threeway (18D 2) descend the hole to be tightly connected, the input pipe interface of the cold-producing medium of evaporimeter (11) is through first throttle valve (15B 1) and the tenth magnetic valve (14E 2) usefulness connecting pipe and the 8th threeway (18D 2) right hole is tightly connected described second heat exchanger (20 2) the bottom carrier pipe interface of cold-producing medium through the second choke valve (15B 2), the 6th threeway (18C 2) and the 8th magnetic valve (14D 2) usefulness connecting pipe and the 8th threeway (18D 2) left hole is tightly connected the 3rd threeway (18B 1) and the 5th threeway (18C 1) through the 5th magnetic valve (14C 1) be tightly connected the 4th threeway (18B with connecting pipe 2) and the 6th threeway (18C 2) through the 6th magnetic valve (14C 2) be tightly connected with connecting pipe.
3. according to the described compound unit of claim 1, it is characterized in that in compression-type refrigeration heating (A), be equipped with and replace four-way electromagnetic reversing valve (19), make compound unit refrigeration in summer and winter heating switch many magnetic valves (14) of usefulness, compression-type refrigeration heating (A) is by compressor (9), with water is the condenser (8A) of heat transferring medium, device for drying and filtering (16), choke valve (15), evaporimeter (11), gas-liquid separator (10) and described many magnetic valves connect into closed system with seal for pipe joints, and be parallel with separate unit heat exchanger (20) or many heat exchangers (20n) by a plurality of threeways (18) and described magnetic valve (14) with seal for pipe joints between the two at the condenser (8A) and the evaporimeter (11) that with water are heat transferring medium, and the escape pipe interface of compressor (9) and the first threeway (18A 1) last hole connect with seal for pipe joints, the input pipe interface of cold-producing medium of condenser (8A) that with water is heat transferring medium is by the first magnetic valve (14A 1) and the first threeway (18A 1) right hole is tightly connected second heat exchanger (20 in many heat exchangers (20n) 2) the carrier pipe interface of top cold-producing medium is by the 3rd threeway (18B 1) and the 3rd magnetic valve (14B 1) and the first threeway (18A 1) left hole connects with seal for pipe joints, the right-hand member carrier pipe interface of the cold-producing medium of device for drying and filtering (16) is with the pipeline and the second threeway (18A 2) following hole be tightly connected, the efferent duct interface of cold-producing medium of condenser (8A) that with water is heat transferring medium is by the second magnetic valve (14A 2) and the second threeway (18A 2) right hole connects described second heat exchanger (20 with seal for pipe joints 2) the carrier pipe interface of bottom cold-producing medium is by the 3rd choke valve (15B 3), the 4th threeway (18B 2) and the 4th magnetic valve (14B 2) the usefulness pipeline and the second threeway (18A 2) left hole is tightly connected gas-liquid separator (10) air inlet pipe interface and the 7th threeway (18D 1) last hole connect with seal for pipe joints, the efferent duct interface of the cold-producing medium of evaporimeter (11) is by the 9th magnetic valve (14E 1) usefulness pipeline and the 7th threeway (18D 1) left hole is tightly connected first heat exchanger (20 in separate unit heat exchanger or many heat exchangers (20n) 1) cold-producing medium top carrier pipe interface by the 5th threeway (18C 1) and the 7th magnetic valve (14D 1) usefulness pipeline and the 7th threeway (18D 1) right hole is tightly connected, the carrier pipe interface of device for drying and filtering (16) left end cold-producing medium is with pipeline and the 8th threeway (18D 2) descend the hole to be tightly connected, the input pipe interface of the cold-producing medium of evaporimeter (11) is by first throttle valve (15B 1) and the tenth magnetic valve (14E 2) usefulness pipeline and the 8th threeway (18D 2) left hole is tightly connected first heat exchanger (20 in separate unit heat exchanger or many heat exchangers (20n) 1) the carrier pipe interface of bottom cold-producing medium is by the second choke valve (15B 2), the 6th threeway (18C 2) and the 8th magnetic valve (14D 2) usefulness pipeline and the 8th threeway (18D 2) right hole is tightly connected the 3rd threeway (18B 1) left hole is by the 5th magnetic valve (14C 1) usefulness pipeline and the 5th threeway (18C 1) right hole is tightly connected the 4th threeway (18B 2) left hole is by the 6th magnetic valve (14C 2) usefulness pipeline and the 6th threeway (18C 2) right hole is tightly connected.
4. compound unit according to claim 1, it is characterized in that in compression-type refrigeration heating (A), between the condenser (8A) and the evaporimeter (11) that with water are heat transferring medium by many threeways (18) with magnetic valve (14) is connected in parallel to separate unit heat exchanger (20) with the connecting pipe sealing or sealing is connected in parallel to one group of heat exchanger in parallel (20n), at the condenser (8A) that with water is heat transferring medium, whenever be sealedly connected with first unicom pipeline (27A) respectively by threeway (18) between the two among the trunk line top three of the refrigerant conveying of evaporimeter (11) and described one group of heat exchanger (20n) or described separate unit heat exchanger (20), second unicom pipeline (27B) and the 3rd unicom pipeline (27C), and at first unicom pipeline, on second unicom pipeline and the 3rd unicom pipeline the 21 magnetic valve (14A is housed respectively 3), the 22 magnetic valve (14B 3) and the 23 magnetic valve (14C 3), so that UNICOM or disconnection between the two whenever among the trunk line three, compressor (9) escape pipe interface is by the first threeway (18A 1) usefulness connecting pipe and the 21 threeway (18A 3) go up the hole and be tightly connected, compressor (9) air inlet pipe interface is by the 5th threeway (18C 1) and the 25 magnetic valve (14E 3) usefulness connecting pipe and the 22 threeway (18B 3) go up the hole and be tightly connected, the input pipe interface of cold-producing medium of condenser (8A) that with water is heat transferring medium is by the first magnetic valve (14A 1) usefulness pipeline and the 21 threeway (18A 3) down the hole be tightly connected, the efferent duct interface of cold-producing medium of condenser (8A) that with water is heat transferring medium is by the second magnetic valve (14A 2) and the second threeway (18A 2) left hole is tightly connected, device for drying and filtering (16) left part interface tube is with the pipeline and the second threeway (18A 2) descend the hole to be tightly connected, the efferent duct interface of the cold-producing medium of evaporimeter (11) is by the 7th magnetic valve (14D 1) usefulness pipeline and the 22 threeway (18B 3) descend the hole to be tightly connected, the input pipe interface of the cold-producing medium of evaporimeter (11) is by first throttle valve (15B 1), the 8th magnetic valve (14D 2) usefulness pipeline and the 6th threeway (18C 2) right hole is tightly connected, device for drying and filtering (16) right part interface tube is with pipeline and the 6th threeway (18C 2) descend the hole to be tightly connected, the top of the cold-producing medium of the heat exchanger (20n) that described-group is in parallel carries conveying the 4th trunk line (27D) after the lateral parallel connection to be tightly connected in the hole down with the 3rd threeway (18B1), or the top carrier pipe interface of the cold-producing medium of described separate unit heat exchanger (20) is with connecting pipe and the 3rd threeway (18B 1) following hole is tightly connected, and conveying the 5th trunk line (27E) and the 4th threeway (18B after the parallel connection of the bottom of the cold-producing medium of the heat exchanger of described one group of parallel connection (20n) conveying lateral 2) last hole is tightly connected, or the bottom carrier pipe interface of the cold-producing medium of described separate unit heat exchanger (20) is by the second choke valve (15B 2) and the 4th magnetic valve (14B 2) usefulness pipeline and the 4th threeway (18B 2) go up the hole and be tightly connected the second threeway (18A 2) right Kong Yudi four threeway (18B 2) left hole is by the 9th magnetic valve (14E 1) connect the 6th threeway (18C with seal for pipe joints 2) left Kong Yudi four threeway (18B 2) right hole is by the tenth magnetic valve (14E 2) connect with seal for pipe joints.
5. compound unit according to claim 2, it is characterized in that in compression-type refrigeration heating (A), with water the condenser (8A) of heat transferring medium and be the evaporimeter (11B) of heat transferring medium with water, be parallel with a heat exchanger (20) between the two, the titting water outlet (11E) that with water is the evaporimeter (11B) of heat transferring medium is tightly connected with pipeline and water inlet trunk line (21C) through the 15 magnetic valve (14Q) and the 31 threeway (18M), the admitting pipe joint (11F) that with water is the evaporimeter (11B) of heat transferring medium is tightly connected with pipeline and water outlet trunk line (22C) through water circulating pump (24) and the 32 threeway (18N), sealing plug screw (30) all is equipped with at water inlet trunk line (21C) and water outlet trunk line (22C) two ends, when the compression-type refrigeration heating is used as water-cooled air conditioner, each indoor units of water-cooled air conditioner (13A 0) metal coil pipe (13I) the water inlet pipe interface (13F) of leaking water through the 33 threeway (18H) with pipeline with the water inlet trunk line (21C) be tightly connected, its outlet pipe interface (13E) is tightly connected with pipeline and water outlet trunk line (22C) through the 34 threeway (18I); Or with water be heat transferring medium evaporimeter (11B) titting water outlet (11E) through the 15 magnetic valve (14Q) with pipeline directly with the separate unit water-cooled indoor apparatus of air conditioner group (13A that leakes water 0) the water inlet pipe interface (13F) of the metal coil pipe (13I) of leaking water be tightly connected, with water be heat transferring medium evaporimeter (11B) admitting pipe joint (11F) through water circulating pump (24) with pipeline directly and metal coil pipe (13I) titting water outlet (13E) be tightly connected, be the metallic coil (11H) that cold-producing medium is housed away in the inner bag (11Q) of evaporimeter (11B) of heat transferring medium with water, inner bag (11Q) outer wall is equipped with heat-insulation layer (11M) and shell (11N).
6. compound unit according to claim 1 is characterized in that in compression-type refrigeration heating (A), is that the condenser (8A) and the evaporimeter (11) of heat transferring medium respectively is parallel with a heat exchanger 20 or many heat exchangers (20 with water n); Or only there is described condenser (8A) to be parallel with one or more heat exchanger (20 separately n); Or have only evaporimeter (11) to be parallel with a heat exchanger (20) or many heat exchangers (20) separately, and the right hole of four-way electromagnetic reversing valve (19) is by the connecting pipe and the first threeway (18A 1) last hole be tightly connected, the input pipe interface of cold-producing medium of condenser (8A) that with water is heat transferring medium is by the first magnetic valve (14A 1) the usefulness pipeline and the first threeway (18A 1) right hole is tightly connected, first heat exchanger (20 in described separate unit heat exchanger or many heat exchangers 1) the upper tube interface of cold-producing medium by the 3rd magnetic valve (14B 1) the usefulness pipeline and the first threeway (18A 1) left hole is tightly connected, and is that the cold-producing medium efferent duct interface of the condenser (8A) of heat transferring medium passes through the second magnetic valve (14A with water 2) the usefulness pipeline and the second threeway (18A 2) right hole is tightly connected, first heat exchanger (20 in described separate unit heat exchanger or many heat exchangers 1) the bottom carrier pipe interface of cold-producing medium by the 3rd choke valve (15B 3) and the 4th magnetic valve (14B 2) the usefulness pipeline and the second threeway (18A 2) left hole is tightly connected, the right-hand member carrier pipe joint of the cold-producing medium of device for drying and filtering (16) is by the pipeline and the second threeway (18A 2) descend the hole to be tightly connected, the left hole of four-way electromagnetic reversing valve (19) is by pipeline and the 3rd threeway (18B 1) go up the hole and be tightly connected, the top carrier pipe interface of the cold-producing medium of evaporimeter (11) is by the 7th magnetic valve (14D 1) usefulness pipeline and the 3rd threeway (18B 1) left hole is tightly connected second heat exchanger (20 in described many heat exchangers 2) the top carrier pipe interface of cold-producing medium by the 5th magnetic valve (14C 1) usefulness pipeline and the 3rd threeway (18B 1) right hole be tightly connected, the bottom carrier pipe interface of evaporimeter (11) cold-producing medium is by first throttle valve (15B 1) and the 8th magnetic valve (14D 2) usefulness pipeline and the 4th threeway (18B 2) left hole is tightly connected described second heat exchanger (20 2) the bottom carrier pipe interface of cold-producing medium by the second choke valve (15B 2) and the 6th magnetic valve (14C 2) usefulness pipeline and the 4th threeway (18B 2) right hole is tightly connected, the left end carrier pipe joint of the cold-producing medium of device for drying and filtering (16) is by pipeline and the 4th threeway (18B 2) descend the hole to be tightly connected.
7. compound unit according to claim 1, it is characterized in that compression-type refrigeration heating (A) is a two stages of compression formula refrigerating and heating systems, and be that two-stage is steam compressed, the one-level throttling, the middle not exclusively circulatory system of cooling, compression-type refrigeration heating (A) is by low-pressure stage compressor (9N), hiigh pressure stage compressor (9M), with water is the condenser (8A) of heat transferring medium, choke valve (15), intercooler (8X) and choke valve (15X) thereof, evaporimeter (11) connects into the circulatory system with seal for pipe joints, charge an amount of cold-producing medium in the system, and with the saline solution metallic coil (11H) that the inner bag (11Q) of the described evaporimeter (11B) of heat transferring medium is equipped with away cold-producing medium, between inner bag (11Q) and metallic coil (11H) outer wall saline solution is housed, when as large cold storage freezing equipment or middle-size and small-size ice machine, the feed tube joint (11F) of described evaporimeter is connected with seal for pipe joints with ice making case (13G) liquid outlet joint (13E), recycle liquid pump (24) is housed on this pipeline, is that its feed tube joint (13F) of liquid outlet joint (11E) and ice making case (13G) of the described evaporimeter (11B) of heat transferring medium is connected with seal for pipe joints with the saline solution.
8. compound unit according to claim 1, it is characterized in that compression-type refrigeration heating (A) is to cover folded formula two-stage or compression-type refrigeration heating recycle system independently more than the two-stage, its one-level is the low temperature circulatory system (A1), another level is high temperature circulation system (A2), the low temperature circulatory system (A1) is by cryogenic compressor (9N), and shared evaporation one condenser (8A one 11B), first device for drying and filtering (16A), first throttle valve (15 '), evaporimeter (11), first gas-liquid separator (10A) are tightly connected into the low temperature circulatory system (A successively with pipeline 1), at the low temperature circulatory system (A 1) in charge an amount of low-temperature refrigerant, the and (A of high temperature circulation system 2) be by high temperature compressed machine (9M), be condenser (8A), second device for drying and filtering (16B), second choke valve (15 "), described shared evaporation one condenser (8A-11B), second gas-liquid separator (10B) of heat transferring medium is tightly connected into (the A of high temperature circulation system successively with pipeline with water 2), at (the A of high temperature circulation system 2) in charge an amount of middle temperature cold-producing medium, when as large cold storage freezing equipment or middle-size and small-size ice machine, it with the antifreezing liquid metallic coil (11H) that the inner bag (11Q) of the described evaporimeter (11B) of heat transferring medium is equipped with away cold-producing medium, between inner bag (11Q) and metallic coil (11H) outer wall antifreezing liquid is housed, inner bag (11Q) outer wall has heat-insulation layer (11M) and shell (11N), the feed tube joint (11F) of described evaporimeter is connected with seal for pipe joints with ice making case (13G) liquid outlet joint (13E), recycle liquid pump (24) is housed on described pipeline, is that the liquid outlet joint (11E) of the described evaporimeter (11B) of heat transferring medium is connected with seal for pipe joints with the feed tube joint (13F) of ice making case (13G) with the antifreezing liquid.
9. according to claim 1,2,3,4,5,6,7 or 8 described compound units, it is characterized in that it is compression-type refrigeration heating equipment and the compound unit of air source hot pump water heater (26A); Or it is compression-type refrigeration heating equipment and the compound unit of water source heat pump water heater (26B); Or it is compression-type refrigeration heating equipment and the compound unit of earth source heat pump water heater (26C); Or it is compression-type refrigeration heating equipment and the compound unit of being made up of air source and water source of double heat source heat pump water heater (26AB); Or it is compression-type refrigeration heating equipment and the compound unit of being made up of air source and source, ground of double heat source heat pump water heater (26AC); Or it is compression-type refrigeration heating equipment and the compound unit of being made up of water source and source, ground of double heat source heat pump water heater (26BC), for compression-type refrigeration heating equipment and the compound unit of air source hot pump water heater (26A), be characterized in that with the heat energy of containing in the air be thermal source, by in the compression-type refrigeration heating (A) being that to absorb the heat energy of containing in the air source (28A) be thermal source for cold-producing medium evaporation in the metal coil pipe (13I) of evaporimeter (11A) of heat transferring medium with the air, fan (13H) and fan electromotor (13J) are equipped with in the back side at the metal coil pipe (13I) of described evaporimeter (11A), have the ventilation window of band grid on evaporator shell (13L); For compression-type refrigeration heating equipment and the compound unit of water source heat pump water heater (26B), be characterized in that with the heat energy of containing in the water source be thermal source, by in the compression-type refrigeration heating (A) being that to absorb the heat energy of containing in the water source (28B) be thermal source for cold-producing medium evaporation in the metallic coil (11H) of evaporimeter (11B) of heat transferring medium with water, the metallic coil (11H) of cold-producing medium is housed away in described evaporimeter (11B), water as heat transferring medium is housed in the described evaporimeter (11B), and the titting water outlet (11E) of described evaporimeter (11B) is through the 14 magnetic valve (14K 1) be tightly connected with the inlet channel (21) at water source (28B), the admitting pipe joint (11F) of described evaporimeter (11B) is tightly connected through the outlet conduit (22) of water circulating pump (23) with water source (28B); For compression-type refrigeration heating equipment and the compound unit of earth source heat pump water heater (26C), be characterized in that with the heat energy of containing in the earth's crust be thermal source, by in the compression-type refrigeration heating (A) being that to absorb the heat energy of containing in the earth's crust (28C) be thermal source for cold-producing medium evaporation in the metallic coil (11H) of evaporimeter (11C) of heat transferring medium with the antifreezing liquid, and antifreezing liquid as heat transferring medium is housed in the described evaporimeter (11C) and between metallic coil (11H) outer wall, with the antifreezing liquid be heat transferring medium described evaporimeter (11C) feed tube joint (11F) through recycle liquid pump (24) with buried in the earth's crust (28C) the fluid pipeline (22) of the U-shaped pipe in pipe of band fin (29) be tightly connected, be that the liquid outlet joint (11E) of the described evaporimeter (11C) of heat transferring medium is passed through the 15 magnetic valve (14K with the antifreezing liquid 2) be tightly connected with U-shaped pipe in pipe input duct (21); For compression-type refrigeration heating equipment and the compound unit of forming by air source (28A) and water source (28B) of double heat source heat pump water heater (26AB), be characterized in the heat energy contained in the air and be two thermals source with the heat energy of containing in the water source, in compression-type refrigeration heating (A), by a pair of threeway (18) and two pairs of magnetic valves (14) will be that the evaporimeter (11A) of heat transferring medium is tightly connected with pipeline is in parallel with the evaporimeter (11B) that is heat transferring medium with the air with water, described is the water inlet pipe and water outlet pipe interface of evaporimeter (11B) and the advancing of water source (28B) of heat transferring medium with water, outlet conduit is tightly connected, and water circulating pump (23) and the 14 magnetic valve (14K are housed respectively on pipeline 1) the formation closed circuit; Form the compound unit of double heat source heat pump water heater (26AC) for the compression-type refrigeration heating equipment and by air source and source, ground, its characteristics are two thermals source with the heat energy contained in the air with the heat energy of containing in the earth's crust, in compression-type refrigeration heating (A), by a pair of threeway (18) and two pairs of magnetic valves (14) will be that the evaporimeter (11A) of heat transferring medium is tightly connected with pipeline is in parallel with the evaporimeter (11C) that is heat transferring medium with the air with the antifreezing liquid, described is the advancing of evaporimeter (11C) of heat transferring medium with the antifreezing liquid, go out the advancing of buried U-shaped pipe in pipe in the earth's crust (28C) of interface tube and used for geothermal heat pump, go out interface tube and be tightly connected, and recycle liquid pump (24) and the 15 magnetic valve (14K are housed 2) the formation closed circuit; For compression-type refrigeration heating equipment and the compound unit of forming by water source and source, ground of double heat source heat pump water heater (26BC), its characteristics are two thermals source with the heat energy contained in the water source with the heat energy of containing in the earth's crust, in compression-type refrigeration heating (A) by a pair of threeway (18) and two pairs of magnetic valves (14), the evaporimeter (11B) that will be heat transferring medium with water is tightly connected with pipeline is in parallel with the evaporimeter (11C) that with the antifreezing liquid is heat transferring medium, described is the advancing of evaporimeter (11B) of heat transferring medium with water, (28B) advances for outlet pipe interface and water source, the outlet conduit correspondence is tightly connected, and respectively water circulating pump is housed (23) and the 14 magnetic valve (14K 1), form closed circuit; Described is corresponding being tightly connected of liquid in-out pipeline of liquid inlet and outlet interface tube and buried U-shaped pipe in pipe in the earth's crust (28C) of the evaporimeter (11C) of heat transferring medium with the antifreezing liquid, and recycle liquid pump (24) and the 15 magnetic valve (14K are housed respectively 2), constitute closed circuit.
CN 200410055574 2004-08-05 2004-08-05 Compression type refrigerating, heating apparatus and heat pump water heater combined set Expired - Fee Related CN1731041B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN 200410055574 CN1731041B (en) 2004-08-05 2004-08-05 Compression type refrigerating, heating apparatus and heat pump water heater combined set

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN 200410055574 CN1731041B (en) 2004-08-05 2004-08-05 Compression type refrigerating, heating apparatus and heat pump water heater combined set

Publications (2)

Publication Number Publication Date
CN1731041A CN1731041A (en) 2006-02-08
CN1731041B true CN1731041B (en) 2010-07-28

Family

ID=35963439

Family Applications (1)

Application Number Title Priority Date Filing Date
CN 200410055574 Expired - Fee Related CN1731041B (en) 2004-08-05 2004-08-05 Compression type refrigerating, heating apparatus and heat pump water heater combined set

Country Status (1)

Country Link
CN (1) CN1731041B (en)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2488797A (en) * 2011-03-08 2012-09-12 Greenfield Master Ipco Ltd Thermal Energy System and Method of Operation
US9360236B2 (en) 2008-06-16 2016-06-07 Greenfield Master Ipco Limited Thermal energy system and method of operation
US9556856B2 (en) 2007-07-06 2017-01-31 Greenfield Master Ipco Limited Geothermal energy system and method of operation
US9915247B2 (en) 2007-07-06 2018-03-13 Erda Master Ipco Limited Geothermal energy system and method of operation

Families Citing this family (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2009006794A1 (en) * 2007-07-06 2009-01-15 Guirong Luo A vapor compression refrigeration system
DE102007040629A1 (en) * 2007-08-27 2009-03-05 Oewa Wasser Und Abwasser Gmbh Safety heat exchanger for the combination of a heat pump with a device of a public drinking water supply system
CN101963416B (en) * 2010-10-28 2012-10-10 江苏天舒电器有限公司 Integrated machine with functions of air conditioner, water heater and floor heating function
CN103363635A (en) * 2012-04-05 2013-10-23 王秀利 Water cooling central air conditioner waste heat recovery device and method
CN105650941A (en) * 2014-03-24 2016-06-08 张明 Independent refrigerating procedure of heat pump and hot water heating combined system
CN107131656A (en) * 2017-06-12 2017-09-05 广东美的暖通设备有限公司 Control method, system, computer equipment and the readable storage medium storing program for executing of water heater
CN109757911B (en) * 2019-01-09 2022-06-28 重庆海尔空调器有限公司 Energy system, method and apparatus for controlling energy system, and storage medium
CN109764513B (en) * 2019-01-09 2022-01-21 青岛海尔空调器有限总公司 Energy system, control method thereof and storage medium
CN110453874A (en) * 2019-07-26 2019-11-15 广东省广弘食品集团有限公司 A kind of cold storage floor winterization system
CN110762791B (en) * 2019-10-18 2021-11-23 Tcl空调器(中山)有限公司 Air conditioner outlet air temperature control method and system and storage medium

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1259644A (en) * 1999-01-04 2000-07-12 童夏民 Heat pump type safety water heater
US6263964B1 (en) * 1999-11-12 2001-07-24 Cheng-Fu Yang Heat exchanging apparatus of refrigeration system
CN2502181Y (en) * 2001-09-30 2002-07-24 郭永劬 Dual-purpose device of air conditioner and heat pump type water heater
CN1472483A (en) * 2003-05-16 2004-02-04 上海交通大学 Energy-saving instant heat hot-pump shower

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1259644A (en) * 1999-01-04 2000-07-12 童夏民 Heat pump type safety water heater
US6263964B1 (en) * 1999-11-12 2001-07-24 Cheng-Fu Yang Heat exchanging apparatus of refrigeration system
CN2502181Y (en) * 2001-09-30 2002-07-24 郭永劬 Dual-purpose device of air conditioner and heat pump type water heater
CN1472483A (en) * 2003-05-16 2004-02-04 上海交通大学 Energy-saving instant heat hot-pump shower

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9556856B2 (en) 2007-07-06 2017-01-31 Greenfield Master Ipco Limited Geothermal energy system and method of operation
US9915247B2 (en) 2007-07-06 2018-03-13 Erda Master Ipco Limited Geothermal energy system and method of operation
US9360236B2 (en) 2008-06-16 2016-06-07 Greenfield Master Ipco Limited Thermal energy system and method of operation
GB2488797A (en) * 2011-03-08 2012-09-12 Greenfield Master Ipco Ltd Thermal Energy System and Method of Operation
US10309693B2 (en) 2011-03-08 2019-06-04 Erda Master Ipco Limited Thermal energy system and method of operation
US10921030B2 (en) 2011-03-08 2021-02-16 Erda Master Ipco Limited Thermal energy system and method of operation

Also Published As

Publication number Publication date
CN1731041A (en) 2006-02-08

Similar Documents

Publication Publication Date Title
CN1731041B (en) Compression type refrigerating, heating apparatus and heat pump water heater combined set
CN101236024B (en) Improved steam compression type refrigeration system and uses thereof
CN109405102B (en) Air Conditioning System
CN102252453A (en) Machine integrating refrigeration, ice-making and heating
CN210118911U (en) Heat pump air conditioning system
CN203824158U (en) Multifunctional ground source heat pump unit
CN108119953A (en) Splitting heat pump air conditioner device
CN105020936B (en) Air-conditioner heat pump hot-water system
CN204084856U (en) A kind of two warm heat pump hot-water system
CN202769825U (en) Air conditioner system
CN104296286A (en) Heat source tower refrigerating and heating energy-saving equipment with ice storage and heat storage functions
CN205300062U (en) Towards white system
CN204987326U (en) Heat pipe air conditioner integral type heat transfer system
CN209726564U (en) A kind of phase-change accumulation energy defrosting Multifunctional cold heating system
CN109724286B (en) Air conditioning system and air conditioner
CN2509490Y (en) Separated vertical cold-hot water air conditioning machine set
CN205641663U (en) Low temperature ice source heat pump set
CN206875636U (en) Energy-saving, compressor-free refrigerating plant
CN201138024Y (en) Air-conditioner water heater
CN204202065U (en) A kind of heat source tower refrigerating and heating energy-saving equipment with ice-reserving heat accumulation function
CN205481504U (en) Ally oneself with domestic air conditioner hot -water heating system more
CN204202063U (en) With the heat source tower heat pump air-conditioner set of ice-reserving function
CN104235984B (en) Heat source tower heat pump air-conditioner set with ice-reserving function
CN216769848U (en) Air source heat pump hot water heat accumulation defrost system based on double-pipe heat exchanger
CN216048352U (en) Low-temperature operation air energy water heater

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C14 Grant of patent or utility model
GR01 Patent grant
C17 Cessation of patent right
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20100728

Termination date: 20130805