CN102494378A

CN102494378A - Architectural energy-saving system utilizing multiple renewable energy sources

Info

Publication number: CN102494378A
Application number: CN2011103985603A
Authority: CN
Inventors: 张明军; 蒋海洋
Original assignee: ANHUI RIYUAN ENVIRONMENTAL PROTECTION ENERGY TECHNOLOGY Co Ltd
Current assignee: Anhui daily energy saving Polytron Technologies Inc
Priority date: 2011-12-06
Filing date: 2011-12-06
Publication date: 2012-06-13
Anticipated expiration: 2031-12-06
Also published as: CN102494378B

Abstract

The invention discloses an architectural energy-saving system utilizing multiple renewable energy sources. The architectural energy-saving system consists of a water source heat pump unit, an air-conditioning terminal system which is connected with user sides in each building, a billing system, a wind and solar power generation public lighting system, a solar thermal collector, a domestic hot water storage tank, a buried pipe heat exchange system and a water energy storage system. The architectural energy-saving system can meet the requirements of buildings on cooling, heating, hot water supply and public lighting; and an intelligent household metering system is arranged, so that the architectural energy-saving system is energy-saving, convenient and quick, and is widely applied to places such as residences, villas, hotels, schools and the like.

Description

A kind of building energy conservation system that utilizes multiple regenerative resource

Technical field

The present invention relates to relate to building energy conservation system field, specifically is a kind of building energy conservation system that utilizes multiple regenerative resource.

Background technology

Existing building cold and heat supply heat supply water illuminator generally has following deficiency: at first; Traditional refrigeration form such as wind-cooled cold-water unit or water-cooled handpiece Water Chilling Units; The installation site is big, produces tropical island effect simultaneously, and the heating in past and hot water mode generally adopt the boiler mode; Poor stability, and operating cost is higher; The big polydispersion of cooling heat and heat water supplying equipment, investment is big, and operating cost is high; Secondly, building charging problem, north heating is pressed area and is charged unreasonable; The 3rd, cooling heat and heat water supplying system be unable to do without electricity consumption, and most of areas is more and more obvious at home with severe power shortage, must reasonable distribution building electricity consumption and using electricity wisely; The 4th, along with the development of ground source heat pump technology, for example progressively showing, soil moisture decline in winter causes the stability of a system and Energy Efficiency Ratio to reduce, need add problems such as anti-icing fluid.

Summary of the invention

The technical problem that the present invention will solve provides a kind of building energy conservation system that utilizes multiple regenerative resource; It makes full use of ground source heat and is aided with water energy-storage system and builds cooling, heating, preparation hot water; Utilize the solar energy optical-thermal system at non-refrigeration rehabilitating soil in season energy; And can utilize the whole year solar energy to prepare the domestic hot-water, adopt wind light generation that the building public illumination is provided in addition.

Technical scheme of the present invention is:

A kind of building energy conservation system that utilizes multiple regenerative resource; Comprise with each building in the air conditioning terminal system, charge system and the wind light generation public lighting system that are connected of user side, solar thermal collector, domestic hot-water's storage tank, pipe laying heat-exchange system, water energy-storage system, first water source heat pump units and second water source heat pump units; Described first water source heat pump units comprises first compressor, first condenser, first throttle device and first evaporimeter that circulation successively connects, and described second water source heat pump units comprises two compressors, second condenser, second throttling arrangement and second evaporimeter that circulation successively connects;

Described air conditioning terminal system circulates successively with air-conditioner circulating water pump, the 4th control valve, first evaporimeter, the 5th control valve, second control valve and is connected; Described air conditioning terminal system circulates successively with air-conditioner circulating water pump, the 4th control valve, second evaporimeter, the 5th control valve, second control valve and is connected; Described air conditioning terminal system circulates successively and is connected with air-conditioner circulating water pump, the 9th control valve, first condenser, the 11 control valve, second control valve;

Described ground pipe laying heat-exchange system circulates successively with ground source water circulating pump, the tenth control valve, first evaporimeter, the 8th control valve, first control valve and is connected; Described ground pipe laying heat-exchange system circulates successively with ground source water circulating pump, the tenth control valve, second evaporimeter, the 8th control valve, first control valve and is connected; Described ground pipe laying heat-exchange system circulates successively with ground source water circulating pump, the 7th control valve, first condenser, the 6th control valve, first control valve and is connected;

Described domestic hot-water's storage tank circulates successively with hot-water circulating pump, second condenser and is connected; Described domestic hot-water's storage tank circulates successively with first outlet valve, solar energy water circulating pump, solar thermal collector, first water intaking valve and is connected;

Described water energy-storage system circulates successively with the 4th outlet valve, the 3rd control valve, air-conditioner circulating water pump, the 4th control valve, first evaporimeter, the 5th control valve, the 4th water intaking valve and is connected; Described water energy-storage system circulates successively with the 4th outlet valve, the 3rd control valve, air-conditioner circulating water pump, the 4th control valve, second evaporimeter, the 5th control valve, the 4th water intaking valve and is connected; Described water energy-storage system circulates successively and is connected with the 4th outlet valve, the 3rd control valve, air-conditioner circulating water pump, the 9th control valve, first condenser, the 11 control valve, the 4th water intaking valve.

Described domestic hot-water's storage tank is connected with the interior user side of each building through hot water supply water pump.

Described solar thermal collector circulates successively with second water intaking valve, plate type heat exchanger, second outlet valve, solar energy water circulating pump and is connected; Described ground pipe laying heat-exchange system circulates successively with ground source water circulating pump, the 7th control valve, first condenser, the 6th control valve, the 3rd water intaking valve, plate type heat exchanger, the 3rd outlet valve and is connected.

User side all is equipped with individual household metering device in described each building.

The advantage of the utility model:

The present invention makes full use of wind light generation illumination is provided; Utilize geothermal energy, solar energy refrigeration, heating and heat supply water to be provided for user in building; And be aided with solar energy rehabilitating soil energy and water heat storage technology, energy-saving low-carbon, rational cold and hot hot water household charge system; For building provides a cover concentrated, energy-conservation, intelligent feasible program, adaptable across places such as villa, dwelling house, hotel, schools.

Description of drawings

Fig. 1 is a structural representation of the present invention.

Wherein, Wherein, user side, 2-changes in temperature hot water user, 3-individual household metering device, 4-charge system, 5-wind light generation public lighting system, 6-solar thermal collector, 7-domestic hot-water storage tank, 8-first outlet valve, 9-first water intaking valve, 10-second outlet valve, 11-second water intaking valve, 12-the 3rd water intaking valve, 13-the 3rd outlet valve, 14-first control valve, 15-second control valve, 16-the 4th outlet valve, 17-the 4th water intaking valve, 18-solar energy water circulating pump, 19-hot water supply water pump, 20-plate type heat exchanger, 21-hot-water circulating pump, 22-air-conditioner circulating water pump, 23-ground pipe laying heat-exchange system, 24-water energy storage equipment, 25-first water source heat pump units, 26-ground source water circulating pump, 27-the 3rd control valve, 28-second condenser, 29-first evaporimeter, 30-first condenser, 31-the 4th control valve, 32-the 5th control valve, 33-the 6th control valve, 34-the 7th control valve, 35-the 8th control valve, 36-the 9th control valve, 37-the tenth control valve, 38-the 11 control valve, 39-first throttle device, 40-first compressor, 41-second evaporimeter, 42-second throttling arrangement, 43-second water source heat pump units, 44-second compressor in the 1-building.

The specific embodiment

A kind of building energy conservation system that utilizes multiple regenerative resource; Comprise with each building in the air conditioning terminal system 2, individual household metering device 3, charge system 4 and the wind light generation public lighting system 5 that are connected of user side 1, solar thermal collector 6, domestic hot-water's storage tank 7, pipe laying heat-exchange system 23, water energy-storage system 24, first water source heat pump units 25 and second water source heat pump units 43; Two compressors 44 that first compressor 40 that first water source heat pump units 25 comprises successively that circulation connects, first condenser 30, first throttle device 39 and first evaporimeter, 29, the second water source heat pump units 43 comprise that circulation successively connects, second condenser 28, second throttling arrangement 42 and second evaporimeter 41;

Air conditioning terminal system 2 and air-conditioner circulating water pump 22, the 4th control valve 31, first evaporimeter 29, the 5th control valve 32, second control valve 15 circulate successively and are connected; Air conditioning terminal system 2 and air-conditioner circulating water pump 22, the 4th control valve 31, second evaporimeter 41, the 5th control valve 32, second control valve 15 circulate successively and are connected; Air conditioning terminal system 2 and air-conditioner circulating water pump 22, the 9th control valve 36, first condenser the 30, the 11 control valve 38, second control valve 15 circulate successively and are connected;

Ground pipe laying heat-exchange system 23 and ground source water circulating pump 26, the tenth control valve 37, first evaporimeter 29, the 8th control valve 35, first control valve 14 circulate successively and are connected; Ground pipe laying heat-exchange system 23 and ground source water circulating pump 26, the tenth control valve 37, second evaporimeter 41, the 8th control valve 35, first control valve 14 circulate successively and are connected; Ground pipe laying heat-exchange system 23 and ground source water circulating pump 26, the 7th control valve 34, first condenser 30, the 6th control valve 33, first control valve 14 circulate successively and are connected; Ground pipe laying heat-exchange system 23 and ground source water circulating pump 26, the 7th control valve 34, first condenser 30, the 6th control valve 33, the 3rd water intaking valve 12, plate type heat exchanger 20, the 3rd outlet valve 13 circulate successively and are connected;

Domestic hot-water's storage tank 7 circulates successively with hot-water circulating pump 21, second condenser 28 and is connected; Domestic hot-water's storage tank 7 circulates successively and is connected with first outlet valve 8, solar energy water circulating pump 18, solar thermal collector 6, first water intaking valve 9;

Water energy-storage system 24 and the 4th outlet valve 16, the 3rd control valve 27, air-conditioner circulating water pump 22, the 4th control valve 31, first evaporimeter 29, the 5th control valve 32, the 4th water intaking valve 17 circulate successively and are connected; Described water energy-storage system 24 and the 4th outlet valve 16, the 3rd control valve 27, air-conditioner circulating water pump 22, the 4th control valve 31, second evaporimeter 41, the 5th control valve 32, the 4th water intaking valve 17 circulate successively and are connected; Water energy-storage system 24 and the 4th outlet valve 16, the 3rd control valve 27, air-conditioner circulating water pump 22, the 9th control valve 36, first condenser the 30, the 11 control valve 38, the 4th water intaking valve 17 circulate successively and are connected;

Solar thermal collector 6 and second water intaking valve 11, plate type heat exchanger 20, second outlet valve 10, solar energy water circulating pump 18 circulate successively and are connected; Domestic hot-water's storage tank 6 is connected with the interior user side 1 of each building through hot water supply water pump 19.

The present invention utilizes the control method of the building energy conservation system of multiple regenerative resource, may further comprise the steps:

(1), air conditioner refrigerating pattern:

The refrigeration mode of a, first water source heat pump units: the heat that the air conditioning terminal system 2 that is connected with user side 1 in each building absorbs user side passes to first evaporimeter 29 through air-conditioner circulating water pump 22, the 4th control valve 31 successively; Circulate heat transferred first condenser 30 of first evaporimeter 29 through internal refrigeration storage through first water source heat pump units 25 then; Cold after 29 heat exchange of first evaporimeter is passed air conditioning terminal system 2 back through the 5th control valve 32, second control valve 15 more successively; Simultaneously first condenser 30 passes to ground pipe laying heat-exchange system 23 through the 6th control valve 33, first control valve 14 successively with heat, finally is discharged into heat in the soil; The kind of refrigeration cycle of air conditioning terminal system 2 is: 2 → 22 → 31 → 29 → 32 → 15 → 2; The circulation of first water source heat pump units, 25 internal refrigeration storage is: 40 → 30 → 39 → 29 → 40, and the heat exchange circulation of ground pipe laying heat-exchange system 23 is: 23 → 26 → 34 → 30 → 33 → 14 → 23;

The refrigeration mode of b, second water source heat pump units: the heat that the air conditioning terminal system 2 that is connected with user side 1 in each building absorbs user side passes to second evaporimeter 41 through air-conditioner circulating water pump 22, the 4th control valve 31 successively; Circulate heat transferred second condenser 28 of second evaporimeter 41 through internal refrigeration storage through second water source heat pump units 43 then; Cold after 41 heat exchange of second evaporimeter is passed air conditioning terminal system 2 back through the 5th control valve 32, second control valve 15 more successively, and second condenser 28 rejects heat in domestic hot-water's storage tank 7 at last simultaneously; The kind of refrigeration cycle of air conditioning terminal system 2 is: the circulation of 2 → 22 → 31 → 41 → 32 → 15 → 2, second water source heat pump units, 43 internal refrigeration storage is: 44 → 28 → 42 → 41 → 44, and the heat exchange circulation of domestic hot-water's storage tank 7 is: 7 → 21 → 28 → 7.

(2), air conditioning and heating pattern:

Source water circulating pump 26, the tenth control valve 37 pass to first evaporimeter 29 to ground pipe laying heat-exchange system 23 through ground successively with the heat energy in the soil; Then through first water source heat pump units 25 through heat transferred first condenser 30 of internal refrigeration storage circulation with first evaporimeter 29, last first condenser 30 at last with heat successively through the 11 control valve 38, second control valve 15 passes to each building in the air conditioning terminal system 2 that is connected of user side 1; The heat exchange circulation of ground pipe laying heat-exchange system 23 is: the circulation of 23 → 26 → 37 → 29 → 35 → 14 → 23, first water source heat pump units, 25 internal refrigeration storage is: 40 → 30 → 39 → 29 → 40; The heating circulation of air conditioning terminal system 2 is: 2 → 22 → 36 → 30 → 38 → 15 → 2.

(3), heat supply aqueous mode:

A, solar energy prepare hot water: solar thermal collector 6 passes to domestic hot-water's storage tank 7 to the solar heat of heat absorption through first water intaking valve 9, and the heat exchange circulation of solar thermal collector 6 is: 6 → 9 → 7 → 8 → 18 → 6;

B, geothermal source prepare hot water: source water circulating pump 26, the tenth control valve 37 pass to second evaporimeter 41 to ground pipe laying heat-exchange system 23 through ground successively heat energy in the soil; Circulate heat transferred second condenser 28 of second evaporimeter 41 through internal refrigeration storage through second water source heat pump units 43 then; The second last condenser 28 rejects heat in domestic hot-water's storage tank 7 at last, and domestic hot-water's storage tank 6 is supplied water pump 19 with user side 1 in delivery to each building through hot water; The heat exchange circulation of ground pipe laying heat-exchange system 23 is: the circulation of 23 → 26 → 37 → 41 → 35 → 14 → 23, second water source heat pump units, 43 internal refrigeration storage is: 44 → 28 → 42 → 41 → 44, and the heat exchange circulation of domestic hot-water's storage tank 7 is: 7 → 21 → 28 → 7;

The heat energy of c, summer air-conditioning end system 2 prepares hot water: the heat that air conditioning terminal system 2 absorbs passes to second evaporimeter 41 through air-conditioner circulating water pump 22, the 4th control valve 31 successively; Circulate heat transferred second condenser 28 of second evaporimeter 41 through internal refrigeration storage through second water source heat pump units 43 then; The second last condenser 28 rejects heat in domestic hot-water's storage tank 7 at last, and domestic hot-water's storage tank 6 is supplied water pump 19 with user side 1 in delivery to each building through hot water; The heat exchange circulation of air conditioning terminal system 2 is: the circulation of 2 → 22 → 31 → 41 → 32 → 15 → 2, second water source heat pump units, 43 internal refrigeration storage is: 44 → 28 → 42 → 41 → 44, and the heat exchange circulation of domestic hot-water's storage tank 7 is: 7 → 21 → 28 → 7;

(4), solar thermal collector 6 is ground pipe laying heat-exchange system 23 accumulation of energys: solar thermal collector 6 passes to plate type heat exchanger 20 to the solar heat of heat absorption through second water intaking valve; Plate type heat exchanger 20 is delivered to ground heat exchanger system 23 with heat through the 3rd outlet valve 13 again, is discharged in the soil; The heat exchange circulation of solar thermal collector 6 is: 6 → 11 → 20 → 10 → 18 → 6, and the heat exchange circulation of ground heat exchanger system 23 is: 20 → 23 → 26 → 34 → 30 → 33 → 12 → 20 → 13 → 23.

(5), water energy storage equipment accumulation of heat in 24 winter: source water circulating pump 26, the tenth control valve 37 pass to first evaporimeter 29 to source, ground heat-exchange system 23 through ground successively with the heat energy in the soil; Circulate heat transferred first condenser 30 of first evaporimeter 29 through internal refrigeration storage through first water source heat pump units 25 then; Last first condenser 30 transmits feedwater energy storage equipments 24 through the 11 control valve 38, the 4th water intaking valve 17 successively with heat, improves the accumulation of energy water temperature; The heat exchange circulation of source, ground heat-exchange system 23 is: the circulation of 23 → 26 → 37 → 29 → 35 → 14 → 23, first water source heat pump units, 25 internal refrigeration storage is: 40 → 30 → 39 → 29 → 40; The heat exchange circulation of water energy storage equipment 24 is: 24 → 16 → 27 → 22 → 36 → 30 → 38 → 17 → 24.

(6), water energy storage equipment 24 cool-storage in summer:

The cold-storage pattern of a, first water source heat pump units: water energy storage equipment 24 passes to first evaporimeter 29 through the 4th outlet valve 16, the 3rd control valve 27, air-conditioner circulating water pump 22, the 4th control valve 31 successively; First water source heat pump units 25 is through heat transferred first condenser 30 of internal refrigeration storage circulation with first evaporimeter 29 then; Cold after 29 heat exchange of first evaporimeter is passed water energy storage equipment 24 back through the 5th control valve 32, the 4th water intaking valve 17 more successively; Simultaneously first condenser 30 passes to ground pipe laying heat-exchange system 23 through the 6th control valve 33, first control valve 14 successively with heat, finally is discharged into heat in the soil; The kind of refrigeration cycle of water energy storage equipment 24 is: 24 → 16 → 27 → 22 → 31 → 29 → 32 → 17 → 24; The circulation of first water source heat pump units, 25 internal refrigeration storage is: 40 → 30 → 39 → 29 → 40, and the heat exchange circulation of ground pipe laying heat-exchange system 23 is: 23 → 26 → 34 → 30 → 33 → 14 → 23;

The cold-storage pattern of b, second water source heat pump units: water energy storage equipment 24 is given second evaporimeter 41 through the 4th outlet valve 16, the 3rd control valve 27, air-conditioner circulating water pump 22, the 4th control valve 31 with thermal energy transfer successively; Second water source heat pump units 43 is through heat transferred second condenser 28 of internal refrigeration storage circulation with second evaporimeter 41 then; Cold after 41 heat exchange of second evaporimeter is passed water energy storage equipment 24 back through the 5th control valve 32, the 4th water intaking valve 17 more successively, and second condenser 28 rejects heat in domestic hot-water's storage tank 7 at last simultaneously; The kind of refrigeration cycle of water energy storage equipment 24 is: the circulation of 24 → 16 → 27 → 22 → 31 → 41 → 32 → 17 → 24, second water source heat pump units, 43 internal refrigeration storage is: 44 → 28 → 42 → 41 → 44, and the heat exchange circulation of domestic hot-water's storage tank 7 is: 7 → 21 → 28 → 7.

(7), power supply: wind light generation public lighting system 5 utilizes wind-powered electricity generation, photoelectricity, wind light mutual complementing power generation for user side 1 in each building public illumination to be provided.

(8), charge: the delivery of individual household metering device 3 heating of record cooling consumption, hot water output and wind light generation public lighting systems passes in set of signals in the charge system 4 then.

Claims

1. building energy conservation system that utilizes multiple regenerative resource; It is characterized in that: comprise with each building in the air conditioning terminal system, charge system and the wind light generation public lighting system that are connected of user side, solar thermal collector, domestic hot-water's storage tank, pipe laying heat-exchange system, water energy-storage system, first water source heat pump units and second water source heat pump units; Described first water source heat pump units comprises first compressor, first condenser, first throttle device and first evaporimeter that circulation successively connects, and described second water source heat pump units comprises two compressors, second condenser, second throttling arrangement and second evaporimeter that circulation successively connects;

2. a kind of building energy conservation system that utilizes multiple regenerative resource according to claim 1 is characterized in that: described domestic hot-water's storage tank is connected with the interior user side of each building through hot water supply water pump.

3. a kind of building energy conservation system that utilizes multiple regenerative resource according to claim 1 is characterized in that: described solar thermal collector circulates successively with second water intaking valve, plate type heat exchanger, second outlet valve, solar energy water circulating pump and is connected; Described ground pipe laying heat-exchange system circulates successively with ground source water circulating pump, the 7th control valve, first condenser, the 6th control valve, the 3rd water intaking valve, plate type heat exchanger, the 3rd outlet valve and is connected.

4. a kind of building energy conservation system that utilizes multiple regenerative resource according to claim 1 is characterized in that: user side all is equipped with individual household metering device in described each building.