CN203052808U - Hybrid-energy remote-intelligent-control heating system - Google Patents

Hybrid-energy remote-intelligent-control heating system Download PDF

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Publication number
CN203052808U
CN203052808U CN2012207283648U CN201220728364U CN203052808U CN 203052808 U CN203052808 U CN 203052808U CN 2012207283648 U CN2012207283648 U CN 2012207283648U CN 201220728364 U CN201220728364 U CN 201220728364U CN 203052808 U CN203052808 U CN 203052808U
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China
Prior art keywords
assembly
heat
control
solar
gas wall
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Expired - Fee Related
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CN2012207283648U
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Chinese (zh)
Inventor
陈建亮
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Fuzhou Aquapower Electric Water Heater Co Ltd
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Fuzhou Aquapower Electric Water Heater Co Ltd
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Priority to CN2012207283648U priority Critical patent/CN203052808U/en
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    • 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
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/20Solar thermal
    • 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
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/70Hybrid systems, e.g. uninterruptible or back-up power supplies integrating renewable energies
    • 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]

Abstract

The utility model discloses a hybrid-energy remote-intelligent-control heating system. The hybrid-energy remote-intelligent-control heating system comprises a heat-preservation water tank assembly, a solar-panel assembly, a heating loop assembly, a gas wall-mounted stove assembly, a controller assembly and a control terminal; the heat-preservation water tank assembly comprises a water-tank inner container, and a solar coil, a heating coil and a gas wall-mounted stove coil are successively installed inside the water-tank inner container from top to bottom, wherein the solar coil is connected with the solar-panel assembly, the heating coil is connected with the heating loop assembly, and the gas wall-mounted stove coil is connected with the gas wall-mounted stove assembly; temperature sensors are installed on the solar-panel assembly, the upper portion of a heat-preservation water tank and the lower portion of the heat-preservation water tank; the solar-panel assembly, the heating loop assembly, the gas wall-mounted stove assembly and the temperature sensors are all in electric connection with the controller assembly; and the control terminal is connected with the controller assembly through a wireless network. According to the hybrid-energy remote-intelligent-control heating system, hybrid energy of solar energy and a gas wall-mounted stove is used in a mutually-complemented mode, the energy utilization rate is improved, wireless intelligent control is realized, and using is more convenient.

Description

Energy mix long-distance intelligent control heat supply heating system
Technical field
The utility model relates to the heat supply heating system, relates in particular to a kind of energy mix long-distance intelligent control heat supply heating system.
Background technology
Traditional storage-type hot water apparatus is generally all by the single source heat supply, as: electric energy, combustion gas, solar energy, air source, water source, geothermal source etc.Owing to be subjected to the restriction of single source, following defective can occur: 1, when device breaks down, often the heat supply heating will be interrupted, and can't guarantee normal instructions for use; 2, be subjected to the restriction of service condition easily, as: electric heater is subjected to the restriction of electric wire capacity, the use safety problem of combustion gas, and solar energy is in overcast and rainy use etc.; The capital produces certain restriction to the use of hot water apparatus; 3, do not satisfy many-sided heating heat supply requirement, as the place of needs heating simultaneously, heating and heat supply water; 4, single source heating heat supply does not meet the environmental protection and energy saving requirement that country advocates; 5, the control mode of at present traditional unit employing all is unit band line control machine, can only satisfy user's operation face to face like this, though timing function is arranged, can not solve well as the user and be in when outside, the requirement of wanting to allow unit heat in advance and the house being heated.
The utility model content
For solving the problems of the technologies described above, the utility model provides a kind of energy mix long-distance intelligent control heat supply heating system.
The technical solution adopted in the utility model is: a kind of energy mix long-distance intelligent control heat supply heating system is provided, comprises attemperater assembly, solar heat-collection plate assembly, heating loop assembly, burnt gas wall hanging furnace assembly, control assembly, control terminal; Described attemperater assembly comprises inner water tank, and the inner water tank bottom is provided with water inlet pipe, and top is provided with outlet pipe, and inner water tank inside is disposed with solar energy coil pipe, heating coil and burnt gas wall hanging furnace coil pipe from top to bottom between outlet pipe and water inlet pipe; Described solar energy coil pipe connects described solar heat-collection plate assembly, and described heating coil connects described heating loop assembly, and described burnt gas wall hanging furnace coil pipe connects the burnt gas wall hanging furnace assembly; Described solar heat-collection plate assembly is provided with first temperature sensor, and described attemperater assembly upper and lower is respectively equipped with second temperature sensor and three-temperature sensor; Described solar heat-collection plate assembly, heating loop assembly, burnt gas wall hanging furnace assembly and first all are electrically connected described control assembly to three-temperature sensor; Described control terminal is connected by wireless network with described control assembly.
Wherein, described control assembly comprises controller housing, is positioned at controller mainboard and the wireless communication module of controller housing; The 3G module that described wireless communication module comprises 3G communication module MCU, connect 3G communication communication module MCU respectively and 485 communicating circuits, the antenna and the SIM that are connected with the 3G module respectively; Described 485 communicating circuits connect described controller mainboard.
Wherein, described solar heat-collection plate assembly comprises solar thermal collector and first circulating pump; Be provided with the working medium circulation line that flows for heat-transfer working medium in the described solar thermal collector, described working medium circulation line is connected by pipeline with solar energy coil pipe in the described attemperater assembly, and described first circulating pump is set on connecting line; Described first circulating pump is electrically connected described control assembly.
Wherein, described solar heat-collection plate assembly also comprises expansion drum, and described expansion drum is connected with described solar thermal collector.
Wherein, the heat-transfer working medium in the described working medium circulation line is freezing liquid.
Wherein, described heating loop assembly comprise second circulating pump, floor heating coil pipe or radiator, for detection of the 4th temperature sensor of indoor temperature; Described floor heating coil pipe or radiator are connected by pipeline with heating coil in the described attemperater assembly, and described second circulating pump is set on connecting line; Described second circulating pump and described the 4th temperature sensor are electrically connected described control assembly.
Wherein, described burnt gas wall hanging furnace assembly comprises burnt gas wall hanging furnace, second heat-transfer working medium; Described burnt gas wall hanging furnace comprises combustion chamber, heat exchanger, water pump and electrical control module; Described heat exchanger is positioned at described combustion chamber, and the burnt gas wall hanging furnace coil pipe in heat exchanger and the described attemperater assembly connects and composes the closed circuit that flows for described second heat-transfer working medium by pipeline, and described water pump is arranged on this closed circuit; Described water pump is electrically connected described electrical control module, and the electrical control module is electrically connected described control assembly.
Wherein, described electrical control module comprise the blast switch that starts described water pump for the blower fan of giving described exhaust combustion chamber, when being used in the combustion chamber for negative pressure state, be used for gas ratio valve that behind starting mode of pump control enters gas quantity in the combustion chamber, for detection of flue gas and under abnormal conditions control cut off the flue gas inductive switch of gas ratio valve; Described blast switch is electrically connected described water pump and gas ratio valve, and described flue gas inductive switch is electrically connected described gas ratio valve.
Wherein, described inner water tank is enamel or stainless steel; Inner water tank is socketed with tank shell outward, is filled with insulation bubble material between tank shell and the inner water tank.
Wherein, described water inlet pipe place is equipped with safety valve.
The beneficial effects of the utility model are: in heat supply heating system of the present utility model, be provided with solar source and the burnt gas wall hanging furnace thermal source heats the water in the water tank, control assembly also is wirelessly connected with control terminal in addition, adopt this system to have following advantage at least: 1, when one group of thermal source unit breaks down, can not influence normal heating heat demand; 2, this Hybrid Heating system is complementary uses, and can effectively reduce the consumption of gas energy, can improve rate of energy; 3, meet the energy-conserving and environment-protective requirement that country advocates, use the high unit combination of energy utilization rate as far as possible; 4, can realize the remote intelligent of this heat supply heating system is controlled feasible more convenient operation and hommization to this system.
Description of drawings
Fig. 1 is the structural representation of the utility model one embodiment;
Fig. 2 is the structural representation of attemperater assembly in the utility model;
Fig. 3 is the structural representation of solar thermal collector in the utility model;
Fig. 4 is the structural representation of burnt gas wall hanging furnace assembly in the utility model;
Fig. 5 is the structural representation of wireless communication module in the utility model.
Label declaration:
1, attemperater assembly; 11, water inlet tube head; 12, burnt gas wall hanging furnace coil pipe; 13, three-temperature sensor; 14, heating coil; 15, second temperature sensor; 16, water outlet tube head; 17, tank upper cover; 18, inner water tank; 19, solar energy coil pipe; 101, insulation bubble material; 102, magnesium rod; 103, tank shell; 104, water tank lower cover; 105, water tank footing;
2, solar heat-collection plate assembly; 21, solar thermal collector; 22, expansion drum; 23, air bleeding valve; 24, circulating pump; 25, first temperature sensor; 210/214, collection distributive pipe; 211, aluminum alloy frame; 212, absorber; 213, frame and base plate heat-preservation cotton; 215, zinc-plated base plate; 216, safety glass; 217, working medium circulation line;
3, heating loop assembly; 31, floor heating coil pipe; 32, circulating pump; 33, pipeline; 34, the 4th temperature sensor;
4, burnt gas wall hanging furnace assembly; 401, water inlet; 403, shell structure; 404, heat exchanger; 405, blast switch; 406, blower fan; 407, exhaust outlet; 408, combustion chamber; 409, expansion drum; 410, water pump; 411, gas ratio valve; 412, delivery port; 413, air inlet;
5, control assembly; 51, wireless communication module; 510,3G module; 512,3G communication module MCU; 513, antenna; 514,485 communicating circuits; 515, SIM; 516, power module;
6, inlet pipeline; 7, water end; 8, control terminal; 9, wireless network.
The specific embodiment
By describing technology contents of the present utility model, structural feature in detail, realized purpose and effect, give explanation below in conjunction with embodiment and conjunction with figs. are detailed.
See also Fig. 1, in the present embodiment, described energy mix long-distance intelligent control heat supply heating system mainly comprises attemperater assembly 1, solar heat-collection plate assembly 2, heating loop assembly 3, burnt gas wall hanging furnace assembly 4, control assembly 5, inlet pipeline 6 and water end 7, control terminal 8, wireless network 9.
As shown in Figure 2, attemperater assembly 1 comprises the housing that is made of inner water tank 18, tank shell 103, tank upper cover 17, water tank lower cover 104 and water tank footing 105, wherein tank shell 103 is socketed on outside the inner water tank 18, and is filled with insulation bubble material 101 between the two with 18 insulations of feed-tank inner bag.Inner water tank 18 is enamel or stainless steel, can high pressure resistant and corrosion.In order to prevent incrustation scale corrosion inner water tank 18, also be set with magnesium rod 102 on the inner water tank 18, magnesium rod 102 stretches to inner water tank 18 inside, prevents the inner water tank corrosion by principle of cathodic protection, reaches to prolong the water tank effect in service life.Inner water tank 18 bottoms are provided with into water tube head 11, and top is provided with water outlet tube head 16, and water outlet tube head 16 connects water ends 7, and water end 7 comprises that gondola water faucet, the fire hose are first-class, and water inlet tube head 11 connects inlet pipelines 6.Because attemperater is press-bearing water tank, at inlet pipeline 6 safety valve is installed, and plays the pressure release effect, prevents hypertonia in the water tank heating process.
Inner water tank 18 inside are disposed with solar energy coil pipe 19, heating coil 14 and burnt gas wall hanging furnace coil pipe 12 from top to bottom between water outlet tube head 16 and water inlet tube head 11.Wherein, solar energy coil pipe 19 connects solar heat-collection plate assembly 2 and constitutes the peripheral passage, by the water in the heat cyclic heating water tank inner bag 18 of solar energy.Heating coil 14 connects heating loop assembly 3, provides heat to be the room heating to heating loop assembly 3 by the water in the inner water tank 18.Burnt gas wall hanging furnace coil pipe 12 connects burnt gas wall hanging furnace assembly 4 and constitutes the peripheral passage, utilizes the heat of fuel gas buring generation to be the water heating of inner water tank 18.According to the layering rule of water temperature in the inner water tank 18, required for heating, heating coil 14 is positioned over inner water tank 18 middle parts, the temperature of this regional water is about 45 degree, just meets the requirement of heating.And because 2 of solar heat-collection plate assemblies can provide the working medium temperature of circulation higher, the upper strata that solar energy coil pipe 19 is arranged on inner water tank 18 is conducive to ensure the total leaving water temperature of water tank.Wherein solar energy coil pipe 19, heating coil 14 and burnt gas wall hanging furnace coil pipe 12 materials can be stainless steel tube or fin steel pipe.
Solar heat-collection plate assembly 2 is provided with first temperature sensor 25, and attemperater assembly 1 upper and lower is respectively equipped with second temperature sensor 15 and the three-temperature sensor 13.Solar heat-collection plate assembly 2, heating loop assembly 3, burnt gas wall hanging furnace assembly 4 and each temperature sensor 25,15,13 all are electrically connected control assembly 5.During work each temperature sensor to control assembly 5 provide collection temperature value in case 5 pairs of solar heat-collection plate assemblies 2 of control assembly, heating loop assembly 3, burnt gas wall hanging furnace assembly 4 control.
Control terminal 8 is connected by wireless network 9 with control assembly 5.Wherein, control assembly 5 comprises controller housing, is positioned at controller mainboard and the wireless communication module of controller housing; Consult Fig. 5, wireless communication module 51 comprises 3G communication module MCU512, connects the 3G module 510 and 485 communicating circuits 514, the antenna 513 that is connected with 3G module 510 respectively and SIM 515 of 3G communication communication module MCU512 respectively; 485 communicating circuits 514 are the communicating circuit that adopts the RS485/232 communications protocol, and it connects the controller mainboard; In addition, power module 516 is 3G communication module MCU512 and 510 power supplies of 3G module.This wireless communication module 51 can use wireless networks such as GPRS, 3G, 4G 9 and control terminal 8 to communicate.Wireless communication module 51 generates corresponding instruction through decoding chip decoding back after receiving information from control terminal 8, communicates with corresponding unit by the controller mainboard then, makes its automatically controlled plate carry out corresponding control action.Control terminal 8 can be that the equipment that can connect wireless network such as 3G mobile, panel computer, the PC that radio transmission-receiving function is arranged or other can connect the control device of wireless network.
From user's angle, control assembly 5 has been realized following function: 1, can be by the mode of manual direct control button, and the start and stop of control machine; 2, can use control terminal, the function software by installing in login WEB browser or the mobile device carries out Long-distance Control to this heat supply heating system.
This system combined operation principle is: in the time of solar light irradiation, can directly adopt the solar heat-collection plate assembly that the water in the water tank is heated, the burnt gas wall hanging furnace assembly then carries out preheating to the water in the water tank, and this moment, the burnt gas wall hanging furnace assembly was done auxiliary heating use.Utilize control assembly respectively solar heat-collection plate assembly and burnt gas wall hanging furnace assembly to be controlled.When the user went out, the user can realize the equipment of function of surfing the Net by mobile phone or other, and login WEB browser or be installed in function software in the equipment for surfing the net carries out Long-distance Control to this heat supply heating system.For example: when shining upon, can start the burnt gas wall hanging furnace assembly in advance heats the water in the water tank, at this moment temperature can arrange lower, because can also utilize the solar heat-collection plate assembly that the water of water tank is heated, if run into overcast and rainy or evening the time, can directly utilize the burnt gas wall hanging furnace assembly that the water in the water tank is heated; If desired the room is heated simultaneously, can adopt the mode of Long-distance Control that it is carried out operated from a distance, embodied the hommization requirement of product systems designs.
In heat supply heating system of the present utility model, be provided with solar source and the burnt gas wall hanging furnace thermal source heats the water in the water tank, control assembly also is wirelessly connected with control terminal in addition, adopt this system to have following advantage at least: 1, when one group of thermal source unit breaks down, can not influence normal heating heat demand; 2, this Hybrid Heating system is complementary uses, and can effectively reduce the consumption of gas energy, can improve rate of energy; 3, meet the energy-conserving and environment-protective requirement that country advocates, use the high unit combination of energy utilization rate as far as possible; 4, can realize the remote intelligent of this heat supply heating system is controlled feasible more convenient operation and hommization to this system.
Introduce the structure of each thermal source and heating loop assembly more one by one below in conjunction with accompanying drawing.
At first consult Fig. 3, and please be simultaneously in conjunction with Fig. 1, solar heat-collection plate assembly 2 comprises solar thermal collector 21, expansion drum 22, circulating pump 24 and air bleeding valve 23; Expansion drum 22 all is connected solar thermal collector 21 with air bleeding valve 23.Solar thermal collector 21 comprises aluminum alloy frame 211, zinc-plated base plate 215, safety glass 216, frame and base plate heat-preservation cotton 213, absorber 212, collection distributive pipe 210/214, working medium circulation line 217 etc., working medium circulation line 217 is communicated with solar energy coil pipe 19 in the attemperater assembly 1 by collection distributive pipe 210/214, and wherein circulating pump 24 is arranged at wherein one and collects on distributive pipe and the pipeline that solar energy coil pipe 19 is connected.Solar heat-collection plate assembly 2 operation principles are: sunshine sees through safety glass 216, the absorber 212 that is coated with the high selectivity absorbed layer absorbs solar radiation and is converted into heat energy, its temperature is raise gradually the heating of the heat-transfer working medium in the working medium circulation line 217 in the solar thermal collector 21.When solar thermal collector 21 top working medium temperature T 1(are gathered by first temperature sensor 25) gathered by three-temperature sensor 13 with water tank bottom water temperature T 2() the temperature difference when reaching certain value (generally being set at 3 ℃-5 ℃), control assembly 5 control circulating pumps 24 start automatically, and heat-transfer working medium is circulated to the solar energy coil pipe 19 of attemperater assembly 1 and the water in the heating water tank inner bag 18.When water tank upper water temperature T 3(is gathered by second temperature sensor 15) when reaching setting value (being generally 50 ℃-60 ℃), forced circulation pump 24 quits work automatically.Wherein, heat-transfer working medium is freezing liquid, to solve antifreeze problem in winter.
Still consult Fig. 1, heating loop assembly 3 comprises that floor heating coil pipe 31(also can be radiator), circulating pump 32, the 4th temperature sensor 34, pipeline 33 etc.; Floor heating coil pipe 31 connects and composes the peripheral passage by pipeline 33 and heating coil 14, and circulating pump 32 is arranged on the connecting line.The 4th temperature sensor 34 and circulating pump 32 are electrically connected control assembly 5, the 4th temperature sensor 34 is gathered indoor temperature, when when control assembly 5 arranges heating mode, circulating pump 32 is according to the temperature difference of actual indoor temperature with the temperature that sets, select to start and close, thereby the house is heated.
Described burnt gas wall hanging furnace assembly 4 comprises burnt gas wall hanging furnace and heat-transfer working medium; Consult Fig. 4, burnt gas wall hanging furnace comprises shell structure 403, be provided with combustion chamber 408 in the shell structure 403, be provided with heat exchanger 404 in the combustion chamber 408, be provided with water inlet 401 and delivery port 412 communicatively with this heat exchanger 404 on the shell structure 403, wherein the pipeline that is connected with heat exchanger 404 of delivery port 412 is provided with water pump 410, water inlet 401 and delivery port 412 is used for being connected the burnt gas wall hanging furnace coil pipe 12 of attemperater assembly 1, thereby make heat exchanger 404 and burnt gas wall hanging furnace coil pipe 12 constitute the closed circuit that flows for heat-transfer working medium, the power that water pump 410 then provides heat-transfer working medium to flow.During work, combustion gas enters combustion chamber 408 burning through air inlet 413 and produces heats, and the heat-transfer working medium in the reheat heat exchanger 404, water pump 410 make heat-transfer working medium cycle through burnt gas wall hanging furnace coil pipe 12 and water in the heating water tank inner bag 18.Heat-transfer working medium can be freezing liquid or water.
Water pump 410 is started by the electrical control module controls of burnt gas wall hanging furnace, wherein electrical control module comprises the blast switch 405 that starts described water pump 410 for the blower fan 406 of giving combustion chamber 408 exhausts, when being used in combustion chamber 408 for negative pressure state, be arranged at air inlet 413 places be used for starting gas ratio valve 411 that back control enters gas quantity combustion chamber 408 at water pump 410, for detection of flue gas and under abnormal conditions, control the flue gas inductive switch (not shown) of cut-out gas ratio valve 411; Blast switch 405 is electrically connected water pump 410 and gas ratio valve 411, and the flue gas inductive switch is electrically connected gas ratio valve 411.Operation principle is: when the burnt gas wall hanging furnace ignition switch enters duty, blower fan 406 starts earlier makes formation Negative Pressure Difference in the combustion chamber 408, blast switch 405 is issued water pump 410 to instruction, after water pump 410 starts, water flow switch on the water pump 410 is issued electrion device (be used for igniting and make fuel gas buring) to instruction, it starts the back instruction and issues gas ratio valve 411, and gas ratio valve 411 begins to start.Gas ratio valve 411 and blast switch 405 and flue gas inductive switch are chain control, there is certain negative pressure combustion chamber 408, gas ratio valve 411 just can be worked, when continuing for some time (as 5 seconds), the flue gas inductive switch detects when having waste gas to discharge less than exhaust outlet 407, just cut off gas ratio valve 411 and stop air feed, thereby guarantee the safe handling combustion gas.
Because variations in temperature is bigger in the burnt gas wall hanging furnace, for compensatory pressure changes, also be provided with expansion drum 409 in the shell structure 403 of burnt gas wall hanging furnace, expansion drum 409 is positioned at outside the combustion chamber 408.
The above only is embodiment of the present utility model; be not so limit claim of the present utility model; every equivalent structure or equivalent flow process conversion that utilizes the utility model specification and accompanying drawing content to do; or directly or indirectly be used in other relevant technical fields, all in like manner be included in the scope of patent protection of the present utility model.

Claims (10)

1. an energy mix long-distance intelligent control heat supply heating system is characterized in that, comprises attemperater assembly, solar heat-collection plate assembly, heating loop assembly, burnt gas wall hanging furnace assembly, control assembly, control terminal;
Described attemperater assembly comprises inner water tank, and the inner water tank bottom is provided with water inlet pipe, and top is provided with outlet pipe, and inner water tank inside is disposed with solar energy coil pipe, heating coil and burnt gas wall hanging furnace coil pipe from top to bottom between outlet pipe and water inlet pipe; Described solar energy coil pipe connects described solar heat-collection plate assembly, and described heating coil connects described heating loop assembly, and described burnt gas wall hanging furnace coil pipe connects the burnt gas wall hanging furnace assembly;
Described solar heat-collection plate assembly is provided with first temperature sensor, and described attemperater assembly upper and lower is respectively equipped with second temperature sensor and three-temperature sensor;
Described solar heat-collection plate assembly, heating loop assembly, burnt gas wall hanging furnace assembly and first all are electrically connected described control assembly to three-temperature sensor; Described control terminal is connected by wireless network with described control assembly.
2. energy mix long-distance intelligent according to claim 1 is controlled the heat supply heating system, and it is characterized in that: described control assembly comprises controller housing, is positioned at controller mainboard and the wireless communication module of controller housing; The 3G module that described wireless communication module comprises 3G communication module MCU, connect 3G communication communication module MCU respectively and 485 communicating circuits, the antenna and the SIM that are connected with the 3G module respectively; Described 485 communicating circuits connect described controller mainboard.
3. energy mix long-distance intelligent according to claim 1 is controlled the heat supply heating system, and it is characterized in that: described solar heat-collection plate assembly comprises solar thermal collector and first circulating pump; Be provided with the working medium circulation line that flows for heat-transfer working medium in the described solar thermal collector, described working medium circulation line is connected by pipeline with solar energy coil pipe in the described attemperater assembly, and described first circulating pump is set on connecting line; Described first circulating pump is electrically connected described control assembly.
4. energy mix long-distance intelligent according to claim 3 is controlled the heat supply heating system, and it is characterized in that: described solar heat-collection plate assembly also comprises expansion drum, and described expansion drum is connected with described solar thermal collector.
5. energy mix long-distance intelligent according to claim 3 is controlled the heat supply heating system, and it is characterized in that: the heat-transfer working medium in the described working medium circulation line is freezing liquid.
6. energy mix long-distance intelligent according to claim 1 control heat supply heating system is characterized in that: described heating loop assembly comprises second circulating pump, floor heating coil pipe or radiator, for detection of the 4th temperature sensor of indoor temperature; Described floor heating coil pipe or radiator are connected by pipeline with heating coil in the described attemperater assembly, and described second circulating pump is set on connecting line; Described second circulating pump and described the 4th temperature sensor are electrically connected described control assembly.
7. energy mix long-distance intelligent according to claim 1 is controlled the heat supply heating system, and it is characterized in that: described burnt gas wall hanging furnace assembly comprises burnt gas wall hanging furnace, second heat-transfer working medium; Described burnt gas wall hanging furnace comprises combustion chamber, heat exchanger, water pump and electrical control module; Described heat exchanger is positioned at described combustion chamber, and the burnt gas wall hanging furnace coil pipe in heat exchanger and the described attemperater assembly connects and composes the closed circuit that flows for described second heat-transfer working medium by pipeline, and described water pump is arranged on this closed circuit; Described water pump is electrically connected described electrical control module, and the electrical control module is electrically connected described control assembly.
8. energy mix long-distance intelligent according to claim 7 control heat supply heating system is characterized in that: described electrical control module comprises the blast switch that starts described water pump for the blower fan of giving described exhaust combustion chamber, when being used in the combustion chamber for negative pressure state, be used for gas ratio valve that behind starting mode of pump control enters gas quantity in the combustion chamber, for detection of flue gas and under abnormal conditions control cut off the flue gas inductive switch of gas ratio valve; Described blast switch is electrically connected described water pump and gas ratio valve, and described flue gas inductive switch is electrically connected described gas ratio valve.
9. according to each described energy mix long-distance intelligent control heat supply heating system of claim 1-8, it is characterized in that: described inner water tank is enamel or stainless steel; Inner water tank is socketed with tank shell outward, is filled with insulation bubble material between tank shell and the inner water tank.
10. according to each described energy mix long-distance intelligent control heat supply heating system of claim 1-8, it is characterized in that: described water inlet pipe place is equipped with safety valve.
CN2012207283648U 2012-12-25 2012-12-25 Hybrid-energy remote-intelligent-control heating system Expired - Fee Related CN203052808U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2012207283648U CN203052808U (en) 2012-12-25 2012-12-25 Hybrid-energy remote-intelligent-control heating system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN2012207283648U CN203052808U (en) 2012-12-25 2012-12-25 Hybrid-energy remote-intelligent-control heating system

Publications (1)

Publication Number Publication Date
CN203052808U true CN203052808U (en) 2013-07-10

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CN2012207283648U Expired - Fee Related CN203052808U (en) 2012-12-25 2012-12-25 Hybrid-energy remote-intelligent-control heating system

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105605794A (en) * 2016-02-22 2016-05-25 广东超人节能厨卫电器有限公司 Sequential control method for rapidly starting forced-exhausting gas water heater

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105605794A (en) * 2016-02-22 2016-05-25 广东超人节能厨卫电器有限公司 Sequential control method for rapidly starting forced-exhausting gas water heater
CN105605794B (en) * 2016-02-22 2018-07-06 广东超人节能厨卫电器有限公司 The sequential control method that a kind of strong suction gas water heater quickly starts

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