CN214841130U - Indoor cloud control solar heating dual-purpose water heater system - Google Patents

Abstract

The utility model relates to a heating field, especially an indoor cloud accuse dual-purpose water heater system of solar heating. The intelligent human body induction controller is arranged on a connecting pipeline between the intelligent heat collector and the indoor hot water terminal, and a heating water return pipe of the heating equipment is communicated with the intelligent heat collector; the intelligent heat collector comprises an intelligent water replenishing heat conduction water storage tank and a vacuum heat collecting pipe, and water is adopted for heat conduction in the intelligent water replenishing heat conduction water storage tank and the vacuum heat collecting pipe; the solar heating network control mechanism is connected with a heating circulating pump of heating equipment. By combining solar energy with auxiliary energy, the problem of heating in winter of single family of buildings and the problem of low-temperature heating in winter of southern areas are solved.

Description

Indoor cloud control solar heating dual-purpose water heater system

Technical Field

The utility model relates to a heating field, especially an indoor cloud accuse dual-purpose water heater system of solar heating.

Background

The weather in winter in northern areas of China is relatively cold, and the central heating mode mainly adopted at present provides heat for residents. Although compared with the original single-household coal-fired heating, the central heating of the central heating has the advantages of safety, environmental protection, economy and energy conservation, along with the higher and higher global requirements on carbon emission and the more and more shortage of renewable energy sources, the defects of the central heating are gradually exposed: firstly, coal is mainly combusted in central heating of the central heating in China at present, and the problem of central pollution is caused while the central heating is carried out by the central heating, so that a large amount of carbon dioxide is still discharged to pollute the air in the central heating process of the central heating in winter; the second, can't do in the heating installation central heating cycle according to the required time quantum heating of single family branch, and no matter need, the heating installation is the supply all weather all the time, however to most residential user, does not need the heat supply at home mostly daytime, only need the heating after getting home, and the heat supply all the day has caused the waste of a large amount of no longer giving birth to the energy. With the change of climate, most of the areas in south China currently get warm in winter by electric appliances, so that the phenomena of switching-off and power limitation are caused, and great pressure is brought to the power industry.

At present, renewable resources for replacing central heating of a heating system are replaced, only solar energy is utilized to the maximum extent, only solar energy is the most feasible for heating of single-family clean energy, solar energy is utilized to collect heat and supply heat in an idle mode in Xinjiang areas at present, but a large amount of land is occupied, so that the problem of heating of single-family, particularly high-rise and super-high-rise single-family by utilizing solar energy in cities is always solved.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the above-mentioned defect that prior art exists, provide an indoor cloud control dual-purpose water heater system of solar heating, combine the auxiliary energy through solar energy, solved the single family winter heating problem of building to and the low temperature heating problem in south area winter.

The technical scheme of the utility model is that: an indoor cloud control solar heating dual-purpose water heater system comprises an intelligent human body induction controller, an intelligent heat collector, auxiliary energy equipment, heating equipment, an indoor hot water terminal and a solar heating network control mechanism, wherein the intelligent heat collector is respectively connected with the heating equipment and the indoor hot water terminal, the intelligent heat collector is connected with the auxiliary energy equipment, the intelligent human body induction controller is arranged on a connecting pipeline of the intelligent heat collector and the indoor hot water terminal, and a heating water return pipe of the heating equipment is communicated with the intelligent heat collector;

the intelligent heat collector comprises an intelligent water replenishing heat conduction water storage tank and a vacuum heat collecting pipe, and water is adopted for heat conduction in the intelligent water replenishing heat conduction water storage tank and the vacuum heat collecting pipe;

the solar heating network control mechanism is connected with a heating circulating pump of heating equipment. In the present application, the indoor hot water terminal may be, but is not limited to, a kitchen hot water terminal and/or a toilet hot water terminal.

The utility model discloses in, intelligence thermal collector can communicate through outlet pipe and auxiliary energy equipment, and auxiliary energy equipment communicates through outlet pipe and heating equipment and indoor hot water terminal respectively this moment auxiliary energy equipment can adopt dual-purpose gas heater, perhaps dual-purpose electric water heater etc. this moment. The auxiliary energy source equipment can also be arranged in the intelligent heat collector, and the auxiliary energy source equipment can adopt an electric auxiliary heater at the moment.

The intelligent heat collector can adopt a single-set heat-conducting-coil double-supply system, a heat-conducting coil I is arranged in the intelligent heat collector at the moment, the water outlet end of the heat-conducting coil I is communicated with the domestic hot water end water inlet of the auxiliary energy equipment through a water outlet pipe I, the water inlet end of the heat-conducting coil I is communicated with a water inlet pipe I, the water outlet end of the intelligent heat collector is communicated with the heating end water inlet of the auxiliary energy equipment through a water outlet pipe II, a tee joint is arranged on the water inlet pipe I, an intelligent water supplementing pipe is connected with the water inlet pipe I in parallel through the tee joint, and the intelligent water supplementing pipe is communicated with the water inlet end of the intelligent heat collector;

and a heating circulating pump is arranged on the water outlet pipe II, a water outlet of the heating end of the auxiliary energy equipment is communicated with the floor heating water separator through a water outlet pipe III, the outlet end of the floor heating water separator is communicated with heating equipment, and a heating water return pipe of the heating equipment is communicated with a water inlet end of the intelligent heat collector.

The intelligent heat collector can adopt a double-set heat-conducting coil double-supply system, a heat-conducting coil II and a heat-conducting coil III are arranged in the intelligent heat collector at the moment, the water inlet end of the heat-conducting coil II is communicated with a water inlet pipe II, the water outlet end of the heat-conducting coil II is communicated with a water outlet pipe I, two tee joints are arranged on the water inlet pipe II, the water inlet pipe III is connected with the water inlet pipe II in parallel through one of the tee joints, the water inlet end of the heat-conducting coil III is communicated with the water inlet pipe III, the water outlet end of the heat-conducting coil III is communicated with the water outlet pipe II, an intelligent water replenishing pipe is connected with the water inlet pipe II in parallel through the second tee joint, and the intelligent water replenishing pipe is communicated with the water inlet end of the intelligent heat collector;

be equipped with three-way valve I on the inlet tube III, heating equipment's heating wet return and I intercommunication of three-way valve, the water that heating equipment mesocycle flows passes through in three-way valve I gets into inlet tube III to flow into heat conduction coil pipe III again, be equipped with the heating circulating pump on the heating wet return, the place ahead that just is located three-way valve I on inlet tube III is equipped with the check valve.

The system further comprises a solar heating network control mechanism, the solar heating network control mechanism is connected with a heating circulating pump and comprises a relay control module, a temperature controller, an intelligent gateway, a router, a network cloud server and a mobile phone, the relay control module is connected with the heating circulating pump, the relay control module and the temperature controller are connected to the intelligent gateway in parallel, the intelligent gateway controls a host computer, the intelligent gateway is connected with the router, the router is connected with the network cloud server, and the network cloud server is connected with the mobile phone. The temperature controller adopts a 485 communication temperature controller, so that the mobile phone control is convenient to realize.

The intelligent heat collector can adopt H-shaped intelligent heat collector, including intelligent moisturizing heat conduction storage water tank and two sets of vacuum heat collection nest of tubes, optional position department along intelligent moisturizing heat conduction storage water tank length direction sets up bellied water tank exchange groove, water tank exchange groove and intelligent moisturizing heat conduction storage water tank intercommunication, water tank exchange groove and intelligent moisturizing heat conduction storage water tank are surrounded by the water tank shell and are formed, the internal surface of water tank shell is equipped with the inner bag, the both sides in water tank exchange groove are equipped with the vacuum heat collection nest of tubes respectively, the open end and the water tank exchange groove intercommunication of vacuum heat collection nest of tubes, the other end and the linking bridge of vacuum heat collection nest of tubes are connected, set up the division board in the water tank exchange groove and be located between the open end of two vacuum heat collection of tubes.

The intelligent heat collector can be a desktop intelligent heat collector or a window type intelligent heat collector, and when the intelligent heat collector is the desktop intelligent heat collector, the intelligent heat collector is arranged at the position of a windowsill at the inner side of a balcony window on the sun surface of a building or at the position of a windowsill at the inner side of other windows; when the intelligent heat collector is a window type intelligent heat collector, the intelligent heat collector is arranged at the position of a fixed window below an opening window on the sun surface of a building, and the intelligent heat collector and the opening window can be of an integrated structure. When indoor heating area is not enough, intelligent heat collector supplies return water system can extend to outdoor position, for example: the vacuum tube heating body is arranged on a preset concrete support table, an outer wall surface arranged on a balcony guardrail and an outer exposed surface of a building, a curtain wall, an air-conditioning grille, a balcony wall hanging and the like.

The shell and the inner container of the intelligent water replenishing and heat conducting water storage tank of the intelligent heat collector are made of glass fiber reinforced plastics or stainless steel materials, so that the intelligent heat collector is corrosion-resistant and ageing-resistant, and the service life of the intelligent heat collector is prolonged.

The intelligent human body induction controller comprises a double-element human body infrared sensor, a relay, a solenoid valve I and a solenoid valve II, wherein the double-element human body infrared sensor is connected with the relay, the solenoid valve I is positioned on a water inlet pipe of a water inlet end of a heat conduction coil connected with an indoor hot water terminal, and the solenoid valve II is positioned on a water outlet pipe of a water outlet end of the heat conduction coil connected with the indoor hot water terminal.

The intelligent heat collector is also provided with an exhaust pipe, and water vapor enters the overflow pipe orifice of the water receiving tray through the exhaust pipe.

The utility model has the advantages that:

(1) the solar energy is mainly utilized, and auxiliary energy is combined when necessary, so that the heating problem of a single household, particularly a single household of a high-rise and super-high-rise building is solved, low-temperature clean heating required in southern areas is met, and the problem of switching off and power limiting for heating in winter in southern areas is solved;

(2) the system is mainly arranged on the sun surface of an indoor building, the solar light source on the sun surface of the building is fully utilized, solar heating is maximally utilized, the light-heat energy efficiency reaches more than 80%, the auxiliary energy is lower than 20%, the system is mainly arranged indoors, when the indoor heat collection area is insufficient, the system can extend outdoors, the single-family heat collection area is met, and the system is very suitable for heating of a single high-rise building;

(3) the system realizes that a heating circulating pump and auxiliary energy equipment are in a stop state and a heating system is in a micro-circulation state when no person is at home, a user can remotely set to a normal temperature or high temperature mode by a mobile phone according to the room temperature required by the user before going home, the heating circulating pump of the heating equipment is started, hot water circulates in the heating equipment and starts to heat the indoor, and the indoor can reach the required comfortable temperature after the user arrives home;

(4) by adopting the intelligent human body induction controller, when a person is at home, the circulating water system at the domestic water end is started, and when no person is at home, the circulating water at the domestic water end is closed, so that water leakage and water waste of an indoor hot water terminal are prevented; meanwhile, the problems of water leakage, water seepage and the like caused by water supply and water return from the building to the building sun from the building interior when nobody is at home are solved, and the indoor circulating water system is not limited to be controlled, and can be controlled to extend to an outdoor circulating water system.

Drawings

Fig. 1 is a schematic view of a connection structure of the water heater system in embodiment 1;

FIG. 2 is a schematic view of the internal structure of the intelligent heat collector in example 1;

FIG. 3 is a schematic view of the external structure of the intelligent heat collector in example 1;

FIG. 4 is a schematic view showing a connection structure of the water heater system in embodiment 2;

FIG. 5 is a schematic diagram of the connections of the solar heating network control;

FIG. 6 is a schematic structural diagram of the intelligent heat collector in the embodiment 3 in the internal top view;

FIG. 7 is a schematic diagram of the internal top view structure of the intelligent heat collector in example 4;

FIG. 8 is a schematic view showing the connection structure of the intelligent heat collector in example 5;

FIG. 9 is a schematic structural view of the intelligent heat collector in example 6;

fig. 10 is a schematic view of the connection structure of the intelligent heat collector in example 7.

In the figure: 1, an intelligent human body induction controller; 2, an intelligent heat collector; 3 dual-purpose gas water heater; 4, heating equipment; 5 kitchen hot water terminals; 6 hot water terminal for toilet; 7 exhausting pipe; 8, a heat conducting coil I; 9, vacuum heat collecting pipe group I; 10 vacuum heat collecting pipe group II; 11, discharging a pipe I; 12, discharging a pipe II; 14, a solenoid valve II; 15 a domestic hot water outlet; 16 a water inlet at the domestic hot water end; 17 a water inlet at the heating end; 18 heating end water outlet; 19 a water outlet pipe III; 20 floor heating water separator; 21, a water inlet pipe II; 22 a one-way valve; 23 heating circulating pump; 24, a water inlet pipe III; 25 heat conducting coil II; 26 a heat conducting coil III; 27 connecting the bracket I; 28 water tank exchange tank; 29 connecting a bracket II; 30 a water tank housing; 31 a partition plate; 32 intelligent water replenishing and heat conducting water storage tank; 38 securing the cover; 39 vacuum tube heat collecting body I; 3901, collecting a hot water tank I; 3902 vacuum heat collecting tube group III; 3903 connecting bracket III; 40 vacuum tube heating element II; 4001 collecting hot water tank II; 4002 vacuum heat collecting tube set IV; 4003 connecting bracket IV; 41 vacuum tube heat collecting body III; 4101 collecting hot water tank III; 4102 vacuum heat collecting tube group V; 4103 connecting bracket V; 42 a water outlet pipe IV; 43 a water inlet pipe IV; 44 water outlet pipe V; 45, a water inlet pipe V; 46 a water outlet pipe VI; 47 a water inlet pipe VI; 48 opening the window; 49 ultra-white toughened glass; 50 vacuum tube heat collecting body IV; 5001 collecting a hot water tank IV; 5002 vacuum heat collecting tube group VI; 5003 connecting with a bracket VI; 53, discharging a water pipe VII; 54 a water inlet pipe VII; 55 a relay control module; 56 temperature controller; 57 an intelligent gateway; 58 a router; 59 a network cloud server; 60 mobile phone; 61 a filter; 62, an electromagnetic valve I; 63, a water inlet pipe I; 64 intelligent water replenishing pipes; 65 a water outlet pipe VII; 66 a three-way valve I; 67 hollow aluminum alloy frame; 68 heating water return pipe; .

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings.

In the following description, specific details are set forth in order to provide a thorough understanding of the present invention. The invention can be implemented in a number of other ways than those described herein, and those skilled in the art will be able to make similar generalizations without departing from the spirit of the invention. The invention is therefore not limited to the specific embodiments disclosed below.

Example 1

As shown in fig. 1, the indoor cloud-control solar heating dual-purpose water heater system comprises an intelligent human body induction controller 1, an intelligent heat collector 2, auxiliary energy equipment, heating equipment 4 and an indoor hot water terminal, wherein the indoor hot water terminal comprises a kitchen hot water terminal 5 and a bathroom hot water terminal 6. The intelligent heat collector 2 is communicated with the dual-purpose gas water heater 3 through a water outlet pipe, the intelligent human body induction controller 1 is connected with the intelligent heat collector 2, the dual-purpose gas water heater 3 is communicated with the heating equipment 4 and an indoor hot water terminal through a water outlet pipe respectively, and a heating water return pipe of the heating equipment 4 is communicated with the intelligent heat collector 2, so that circulation is formed. The auxiliary energy equipment in this embodiment employs a dual-purpose gas water heater 3.

The dual-purpose water heater system of indoor cloud accuse solar heating of this embodiment adopts single set of heat conduction coil pipe dual supply system, is equipped with one set of heat conduction coil pipe I8 in intelligent heat collector 2 promptly.

The dual-purpose gas water heater 3 is provided with a domestic hot water outlet 15, a domestic hot water inlet 16, a heating end water inlet 17 and a heating end water outlet 18, the heating end water inlet 17 of the dual-purpose gas water heater 3 is communicated with the water outlet of the intelligent heat collector 2 through a water outlet pipe II 12, the water outlet pipe II 12 is provided with a heating circulating pump 23, the heating end water outlet 18 of the dual-purpose gas water heater 3 is communicated with the floor heating water separator 20 through a water outlet pipe III 19, the outlet end of the floor heating water separator 20 is communicated with the heating equipment 4, and a heating water return pipe 68 of the heating equipment 4 is communicated with the water inlet of the intelligent heat collector 2. A domestic hot water end water inlet 16 of the dual-purpose gas water heater 3 is communicated with a water outlet end of the heat conducting pipe disc I8 through a water outlet pipe I11, and a domestic hot water end water outlet 15 of the dual-purpose gas water heater 3 is communicated with a domestic water end through a water outlet pipe VII 65. The domestic hot water terminals in this embodiment include a kitchen hot water terminal 5 and a toilet hot water terminal 6.

The intelligent human body induction controller 1 comprises a double-element human body infrared sensor, a relay, an electromagnetic valve I62 and an electromagnetic valve II 14, wherein the double-element human body infrared sensor is arranged in a kitchen and a toilet, and is connected with the relay. The electromagnetic valve I62 is positioned on a water inlet pipe I63 connected with the water inlet end of the heat-conducting coil I8, and the electromagnetic valve II 14 is positioned on a water outlet pipe I11 connected with the water outlet end of the heat-conducting coil I8 and the water inlet 16 of the domestic hot water end. Human infrared sensor of binary is used for responding to whether someone in kitchen and the bathroom, if sense indoor long time nobody through human infrared sensor of binary, the relay can I62 of automatic control solenoid valve and II 14 of solenoid valve close, and the rivers in the heat conduction coil pipe I8 no longer flow this moment. At this moment, even if the water tank in the intelligent heating pipe 2 leaks, only the water in the water tank leaks, and meanwhile, because the bottom of the intelligent heating pipe 2 is provided with the anti-leakage water receiving tray and the overflow pipe opening in the embodiment, the water leaking from the water tank can flow into a nearby floor drain or an outdoor drain pipe of a building through the overflow pipe opening, so that the problems of water leakage, water leakage or overflow of the water tank are effectively solved, and the table board water leakage is prevented. When the double-element human body infrared sensor senses that people exist in a kitchen and a toilet, the relay automatically controls the solenoid valve I62 and the solenoid valve II 14 to be opened, and hot water circularly flows in the heat conduction coil pipe I8 at the moment, so that hot water can be supplied to the kitchen hot water terminal 5 and the toilet hot water terminal 6.

Still be equipped with filter 61 on inlet tube I63, filter 61 is located the front portion of solenoid valve I62 for the running water in the heat conduction coil pipe I8 of flowing in filters, guarantees domestic water's cleanness as far as possible. Still be equipped with the three-way valve on inlet tube I63, the one end of intelligence moisturizing pipe 64 is passed through the three-way valve and is connected in parallel with inlet tube I63, and the other end communicates with the end of intaking of intelligent heat collector 2. According to the water level of the water tank in the intelligent heat collector 2, tap water is injected into the intelligent heat collector 2 through the intelligent water replenishing pipe 64.

As shown in fig. 1 to 3, the intelligent heat collector 2 in the present embodiment is a desktop E-shaped intelligent heat collector, and in this case, the intelligent heat collector 2 is installed at a windowsill position inside a balcony window of a building or at another windowsill position inside a window. Desk-top E shape intelligence heat collector includes intelligent moisturizing heat conduction storage water tank 32, linking bridge and vacuum heat collection nest of tubes, and in this embodiment, the middle part and the bellied water tank exchange groove 28 intercommunication of intelligence moisturizing heat conduction storage water tank 32, and intelligence moisturizing heat conduction storage water tank 32 and water tank exchange groove 28 are surrounded by E shape water tank shell 30 and are formed, and the internal surface of water tank shell 30 is equipped with the inner bag, and the material of water tank shell 30 and inner bag can adopt but not limited to glass steel, stainless steel etc.. Two ends of the front side surface along the length direction of the intelligent water replenishing heat conduction water storage tank 32 are respectively fixed with a connecting support I27 and a connecting support II 29, the water tank exchange tank 28 is positioned between the two connecting supports, the water tank exchange tank and the connecting support I27 are connected through a vacuum heat collection pipe assembly I9, and the water tank exchange tank and the connecting support II 29 are connected through a vacuum heat collection pipe assembly II 10. The vacuum heat-collecting pipe group comprises a plurality of vacuum heat-collecting pipes which are arranged at intervals up and down, the open ends of the vacuum heat-collecting pipes are communicated with the water tank exchange groove 28, and the other ends of the vacuum heat-collecting pipes are connected with the connecting bracket. A partition plate 31 is arranged in the water tank exchange tank 28 and between the open ends of the two vacuum heat collecting pipe groups, and the partition plate 31 can prevent the hot water flowing out of the two vacuum heat collecting pipe groups from influencing each other. In the present application, the position of the water tank exchanging groove 28 is not limited to the middle of the intelligent water replenishing and heat conducting water storage tank 32, and it may be located at any position between the two connecting brackets. The connecting bracket in this embodiment may also be replaced by a boot.

The vacuum heat pipe in this embodiment may be, but is not limited to, a small-bore vacuum heat pipe, and when the vacuum heat pipe works, the circulation of water in the vacuum heat pipe is realized by using a thermosiphon principle. The back of the rear side of the desk type E-shaped intelligent heat collector is provided with a back plate or a transparent window, and the back plate can be an A-level fireproof heat-insulation plate. The transparent window can achieve the lighting effect and is convenient to install and maintain. The top of the intelligent water replenishing heat conducting water storage tank 32 is provided with a fixed tank cover 38.

In the structure of the above-mentioned desk-top E-shaped intelligent thermal collector, the positions of the connecting bracket and the water tank exchange groove 28 can be interchanged, that is, the water tank exchange groove 28 is fixed at each of the two ends of the front side surface of the intelligent water replenishing heat conduction water storage tank 32, the water tank exchange groove 28 is communicated with the intelligent water replenishing heat conduction water storage tank 32, the connecting bracket is fixed at any position along the length direction of the intelligent water replenishing heat conduction water storage tank 32, the open end of the vacuum thermal collection pipe group is connected with the water tank exchange groove 28 at one end, and the other end of the vacuum thermal collection pipe group is connected with the connecting bracket.

Heat-conducting coil I8 is located intelligent moisturizing heat conduction storage water tank 32, and the heat pipe group is adopted in the vacuum utilizes solar light, makes the temperature of the interior water of heat pipe group rise to adopt in the heat pipe group is adopted in the vacuum, and the hot water after the intensification constantly flows to intelligent moisturizing heat conduction storage water tank 32 in to carry out the heat exchange with the flowing water in heat-conducting coil I8, thereby make the flowing water temperature rise in the heat-conducting coil I8.

The lower part of the intelligent heat collector 2 is provided with an anti-seepage water pan, the water pan is provided with an overflow pipe orifice, the overflow pipe orifice is connected with an overflow water pipe, and the overflow water pipe is connected with a nearby floor drain of a building or a drain pipe outside the building. After the intelligent heat collector leaks accidentally, leaked water is received by the water receiving disc and flows into a nearby floor drain or a drain pipe outside a building through the overflow water pipe, so that the problems of water seepage, water leakage or overflow are solved, and the convenience of maintenance and drainage is improved.

As shown in the figures 1 and 2, the water outlet end of a heat conducting coil I8 in the intelligent water replenishing and heat conducting water storage tank 32 is communicated with a domestic hot water end water inlet 16 of the dual-purpose gas water heater 3 through a water outlet pipe I11, and the water inlet end of the heat conducting coil I8 is communicated with a water inlet pipe I63. The water outlet end of the intelligent water replenishing heat conduction water storage tank 32 is communicated with the water inlet 17 of the heating end of the dual-purpose gas water heater 3 through the water outlet pipe II 12, and one water inlet end of the intelligent water replenishing heat conduction water storage tank 32 is communicated with the intelligent water replenishing pipe 64. An exhaust pipe 7 is further arranged on the intelligent water replenishing and heat conducting water storage tank 32, and water vapor enters an overflow pipe opening of the water pan through the exhaust pipe 7 and enters a nearby floor drain through an overflow water pipe to prevent the water vapor from entering a room.

In this embodiment, the working principle of the system is as follows: tap water of a building enters the heat conduction coil I8 through the water inlet pipe I63, hot water in the heat conduction coil I8 reaches the domestic hot water end water inlet 16 of the dual-purpose gas water heater 3 through the water outlet pipe I11 after heat conduction, and when the temperature of water flowing out of the heat conduction coil I8 is higher than the set temperature of the dual-purpose gas water heater 3, the dual-purpose gas water heater 3 does not need to be started to work; when the water temperature is lower than the set temperature of the dual-purpose gas water heater 3, the dual-purpose gas water heater 3 is started immediately to compensate the temperature difference. Hot water enters the water outlet pipe VII 65 through the domestic hot water end outlet 15 and finally enters the domestic water end, namely a kitchen or a toilet. The water in the water outlet pipe I11 can also directly flow into a domestic hot water terminal.

The working principle of heating by using the system is as follows: tap water of a building enters the intelligent water replenishing pipe 64 through the tee joint of the water inlet pipe I63, enters the intelligent water replenishing heat conduction water storage tank 32 through the intelligent water replenishing pipe 64, absorbs hot water heat heated by solar illumination in the vacuum heating pipe group I9 and the vacuum heating pipe group II 10, enters the water outlet pipe II 12, passes through the heating circulating pump 23 and enters the water inlet 17 of the heating end of the dual-purpose gas water heater 3. When the temperature of the inflowing water is higher than the set temperature of the dual-purpose gas water heater 3, the dual-purpose gas water heater 3 does not need to be started to work; when the temperature of the inflowing water is lower than the set temperature of the dual-purpose gas water heater 3, the dual-purpose gas water heater 3 is immediately started to compensate the temperature difference, hot water enters the water outlet pipe III 19 through the water outlet 18 at the heating end, reaches the floor heating water separator 20, enters heating equipment 4 such as a heating plate, a floor heating pipe and the like for circulation, and then enters the intelligent water supplementing heat conduction water storage tank 32 through the heating water return pipe 68. And the water flow is heated by the solar illumination of the vacuum heat collecting pipe group I9 and the vacuum heat collecting pipe group II 10 again, and then circulation heating is carried out.

In this application, auxiliary energy equipment also can set up in intelligent moisturizing heat conduction storage water tank 32 of intelligent heat collector 2, and intelligent heat collector 2 is connected with heating equipment 4 and indoor hot water terminal through the outlet pipe respectively this moment, and human induction controller 1 setting of intelligence is on the connecting pipeline of intelligent heat collector 2 and indoor hot water terminal, and auxiliary energy equipment adopts the electric auxiliary heater.

Example 2

Different from embodiment 1, the dual-purpose water heater system of indoor cloud accuse solar heating of this embodiment adopts two sets of heat conduction coil pipe dual supply systems, is equipped with heat conduction coil pipe II 25 and heat conduction coil pipe III 26 in intelligent heat collector 2 promptly, and heat conduction coil pipe II 25 and heat conduction coil pipe III 26 all set up in intelligent moisturizing heat conduction storage water tank of intelligent heat collector 2.

As shown in FIG. 4, the water inlet end of the heat conducting coil II 25 is communicated with the water inlet pipe II 21, and the water outlet end of the heat conducting coil II 25 is communicated with the water outlet pipe I11. Two tee joints are arranged on the water inlet pipe II 21, the water inlet pipe III 24 is connected with the water inlet pipe II 21 in parallel through one tee joint, the water inlet end of the heat-conducting coil pipe III 26 is communicated with the water inlet pipe III 24, and the water outlet end of the heat-conducting coil pipe III 26 is communicated with the water outlet pipe II 12. The intelligent water replenishing pipe 64 is connected with the water inlet pipe II 21 in parallel through a second tee joint, and the intelligent water replenishing pipe 64 is communicated with the water inlet end of the intelligent water replenishing heat conduction water storage tank of the intelligent heat collector 2.

Be equipped with three-way valve I66 on inlet tube III 24, heating equipment 4's heating wet return 68 is connected with I66 of three-way valve, and the water that the circulation flows in heating equipment 4 passes through I66 of three-way valve and gets into in inlet tube III 24 to heat conduction coil III 26 flows in again, thereby has realized circulation heating. The heating water return pipe is provided with a heating circulating pump 23, and circulation of water in heating equipment is realized through the heating circulating pump 23, so that circulating heating is realized. A check valve 22 is arranged on the water inlet pipe III 24 and in front of the three-way valve I66.

As shown in fig. 5, the system further includes a solar heating network control mechanism, the solar heating network control mechanism includes a relay control module 55, a temperature controller 56, an intelligent gateway 57, a router 58, a network cloud server 59, and a mobile phone 60, the relay control module 55 is connected to the heating circulation pump 23, the relay control module 55 and the temperature controller 56 are connected to the intelligent gateway 57 in parallel, the intelligent gateway 57 controls a host, the intelligent gateway 57 is connected to the router 58, the router 58 is connected to the network cloud server 59, and the network cloud server 59 is connected to the mobile phone 60. In this implementation, the temperature controller adopts the 485 communication temperature controller, is convenient for realize cell-phone control.

In this embodiment, the operation of the system is as follows. Tap water in the heat conduction coil pipe II 25 is conducted heat through hot water in the intelligent water replenishing and heat conducting water storage tank and then enters the domestic hot water end water inlet 16 of the dual-purpose gas water heater 3 through the water outlet pipe I11. When the temperature of the water flowing into the dual-purpose gas water heater 3 is higher than the set temperature of the dual-purpose gas water heater 3, the dual-purpose gas water heater 3 directly flows into the water outlet 15 at the domestic hot water end without heating; when the temperature of the water flowing into the dual-purpose gas water heater 3 is lower than the set temperature of the dual-purpose gas water heater 3, the dual-purpose gas water heater 3 is started immediately to compensate the temperature difference, and the heated hot water enters the water outlet 15 at the domestic hot water end. Finally, the water flows from the domestic hot water outlet 15 to domestic hot water terminals such as a kitchen hot water terminal 5 and a toilet hot water terminal 6 through a water outlet pipe VII 65. The water in the water outlet pipe I11 can also directly flow into a domestic hot water terminal.

Tap water in the heat conduction coil pipe III 26 is conducted heat through hot water in the intelligent water replenishing and heat conducting water storage tank and then enters the water inlet 17 at the heating end of the dual-purpose gas water heater 3 through the water outlet pipe II 12. When the temperature of the inflowing water is higher than the set temperature of the dual-purpose gas water heater 3, the dual-purpose gas water heater 3 does not need to be started to work; when the temperature of the inflowing water is lower than the set temperature of the dual-purpose gas water heater 3, the dual-purpose gas water heater 3 is started immediately to compensate the temperature difference. And then the water outlet 18 of the heating end reaches the ground heating water separator 20 through a water outlet pipe III 19, and then the water from the ground heating water separator 20 to the heating equipment 4, such as a heating plate, a ground heating coil and the like, enters a heating water return pipe, enters a water inlet pipe III 24 through a three-way valve I66, and flows back to a heat conducting coil III 26 from the rear end of a one-way valve 22 for circulation.

The solar heating network control mechanism is provided with a two-dimensional code, the two-dimensional code is scanned by a mobile phone 60, the two-dimensional code is accessed through a 4G or 5G or wireless network cloud server 59, the router 58 enters an intelligent gateway 57 of the solar heating network control mechanism, and the indoor temperature index and the circulation state can be detected on the mobile phone 60 in real time through the intelligent gateway 57. When no one is present at home, the thermostat 56 is set in the energy saving mode; before going home, the temperature controller 56 can be remotely set in a normal temperature mode or a high temperature mode through the mobile phone 60, and the on/off of the heating circulation pump 23 is controlled through the relay control module 55 by utilizing the set temperature mode of the temperature controller 56. After the heating circulating pump 23 is started, the circulating water is continuously heated through the dual-purpose gas water heater 3 and the intelligent heat collector 2. When the indoor temperature reaches the set temperature, the relay control module 55 controls the heating circulation pump 23 to be automatically turned off, and the thermostat 56 is restored to the initial mode or reset.

The rest is the same as example 1.

Example 3

As shown in fig. 6, unlike embodiment 1, the intelligent heat collector in this embodiment is a desktop H-shaped intelligent heat collector. Desk-top H shape intelligence adopts the hot nest of tubes including intelligent moisturizing heat conduction storage water tank 32 and two sets of vacuum, and optional position department along intelligent moisturizing heat conduction storage water tank 32 length direction is equipped with bellied water tank exchange groove 28, and water tank exchange groove 28 and intelligent moisturizing heat conduction storage water tank 32 intercommunication, and intelligent moisturizing heat conduction storage water tank 32 of water tank exchange groove 28 is surrounded by water tank shell 30 and forms. Two sides of the water tank exchange tank 28 are respectively provided with a vacuum heat collection pipe set, namely a vacuum heat collection pipe set I9 and a vacuum heat collection pipe set II 10, the open end of the vacuum heat collection pipe set I9 is communicated with the water tank exchange tank 28, and the other end of the vacuum heat collection pipe set I9 is connected with a connecting support I27; the open end of the vacuum heat collection pipe group II 10 is communicated with the water tank exchange groove 28, and the other end of the vacuum heat collection pipe group II 10 is connected with the connecting support II 29. The connecting bracket I27 and the connecting bracket II 29 are movable single bodies, and are not connected with the intelligent water replenishing heat conduction water storage tank 32. A partition plate 31 is arranged in the water tank exchange tank 28 and between the open ends of the vacuum heat collection pipe group I9 and the vacuum heat collection pipe group II 10.

The intelligent thermal collector in the present application may adopt a desktop intelligent thermal collector with any shape, and is not limited to the desktop E-shaped intelligent thermal collector or the desktop H-shaped intelligent thermal collector described in embodiments 1 and 2. Desktop intelligent heating ware in this application means to set up in the inboard windowsill position of balcony window, the vacuum tube heating body sets up the windowsill position in other windows inboards. And performing anti-seepage water treatment on a concrete table surface at the lower part of the intelligent heat collector at the indoor windowsill position.

The intelligent heat collector in this embodiment may be used in both the single set of heat-conducting coil dual supply system in embodiment 1 and the two set of heat-conducting coil dual supply system in embodiment 2.

When a single set of heat conducting coil is arranged in the H-shaped intelligent heat collector, solar energy is combined with auxiliary energy, and the heat collecting device is suitable for clean heating in winter in the south and north areas of China. The reason is that, firstly, the intelligent water replenishing and heat conducting water storage tank 32 can increase the capacity according to the demand of the hot water; secondly, the water tank exchange tank 28 does not occupy the length and heat collecting area of the vacuum heat collecting pipe, and hot water is concentrated in the middle of the intelligent water replenishing and heat conducting water storage tank 32, so that heat conduction is faster; thirdly, the position of the connecting bracket can be moved, and the vacuum heat collecting pipe can be properly prolonged according to the heat collecting area, so that the heat collecting area is increased; fourthly, heating water directly enters heating equipment without passing through a heat conduction coil, and the heating efficiency is high; fifthly, a set of heat conducting coil pipes is omitted in the intelligent water replenishing and heat conducting water storage tank 32, so that the manufacturing cost is reduced, the occupied volume of the heat conducting coil pipes is reduced, and the water capacity is increased.

Example 4

As shown in fig. 7, different from embodiment 1, the intelligent thermal collector in this embodiment adopts a desktop split type intelligent thermal collector, the intelligent thermal collector includes an intelligent water replenishing and heat conducting water storage tank 32, a connection bracket and a vacuum thermal collection pipe set, the connection bracket and the intelligent water replenishing and heat conducting water storage tank 32 are split, and there is no connection relationship therebetween. In this embodiment, two sets of vacuum heat collection pipe sets, namely a vacuum heat collection pipe set i 9 and a vacuum heat collection pipe set ii 10, are provided, and the intelligent water replenishing heat transfer water storage tank 32 is located between the two vacuum heat collection pipe sets. The opening end of the vacuum heat collection pipe set I9 is communicated with the intelligent water replenishing heat conduction water storage tank 32, and the other end of the vacuum heat collection pipe set I9 is connected with the connecting support I27; the open end of the vacuum heat collection pipe group II 10 is communicated with the intelligent water replenishing heat conduction water storage tank 32, and the other end of the vacuum heat collection pipe group II 10 is connected with the connecting support II 29. The connecting bracket I27 and the connecting bracket II 29 are both movable single bodies. And a partition plate 31 is arranged in the intelligent water replenishing heat conduction water storage tank 32 and between the opening ends of the vacuum heat collection pipe group I9 and the vacuum heat collection pipe group II 10, so that the mutual influence of hot water flowing out of the two vacuum heat collection pipe groups is prevented.

The intelligent water replenishing and heat conducting water storage tank 32 may take any shape, and is not limited to the square shape in the embodiment.

The intelligent heat collector in this embodiment may be used in both the single set of heat-conducting coil dual supply system in embodiment 1 and the two set of heat-conducting coil dual supply system in embodiment 2.

Example 5

Different from the embodiment 1, the intelligent heat collector in the embodiment adopts a desktop series-parallel connection type intelligent heat collector. This intelligent heat collector can utilize above embodiment in desk-top E shape intelligent heat collector, desk-top H shape intelligent heat collector, the original function of the intelligent moisturizing heat conduction storage water tank of desk-top components of a whole that can function independently intelligent heat collector, with the multiunit vacuum tube heating body again on the basis of original function, adopt the series-parallel connection form to pass through inlet tube and outlet pipe intercommunication together, pass through the hot water of multiunit vacuum tube heating body for the time interval, or temperature control mode forced circulation to intelligent moisturizing heat conduction storage water tank in, realize supplying life hot water heat transfer, or heating circulating water.

As shown in fig. 8, the intelligent heat collector includes an intelligent water replenishing heat-conducting water storage tank 32 and a plurality of vacuum tube heat collecting bodies, in this embodiment, three vacuum tube heat collecting bodies are provided, which are a vacuum tube heat collecting body i 39, a vacuum tube heat collecting body ii 40, and a vacuum tube heat collecting body iii 41, wherein after the vacuum tube heat collecting body i 39 and the vacuum tube heat collecting body ii 40 are connected in series, the vacuum tube heat collecting body i 39 and the vacuum tube heat collecting body ii 41 are connected in parallel to the intelligent water replenishing heat-conducting water storage tank 32.

The vacuum tube heat collection body I39 comprises a heat collection water tank I3901, a vacuum heat collection tube group III 3902, a connecting support III 3903, ultra-white toughened glass and a back plate, wherein the vacuum heat collection tube group III 3902 is composed of a plurality of vacuum heat collection tubes arranged at intervals along the horizontal direction, the open end of the vacuum heat collection tube group III 3902 is communicated with the heat collection water tank I3901, and the other end of the vacuum heat collection tube group III 3902 is connected with the connecting support III 3903. The vacuum tube heat collecting body II 40 comprises a heat collecting water tank II 4001, a vacuum heat collecting tube group IV 4002 and a connecting support IV 4003, the vacuum heat collecting tube group IV 4002 is composed of a plurality of vacuum heat collecting tubes arranged at intervals along the horizontal and vertical direction, the open end of the vacuum heat collecting tube group IV 4002 is communicated with the heat collecting water tank II 4001, and the other end of the vacuum heat collecting tube group IV 4002 is connected with the connecting support IV 4003. The vacuum tube heat collection body III 41 comprises a heat collection water tank III 4101, a vacuum heat collection tube group V4102 and a connecting support V4103, wherein the vacuum heat collection tube group V4102 consists of a plurality of vacuum heat collection tubes arranged at intervals along the horizontal and vertical direction, the opening end of the vacuum heat collection tube group V4102 is communicated with the heat collection water tank III 4101, and the other end of the vacuum heat collection tube group V4102 is connected with the connecting support V4103.

The water outlet end of the hot water collecting tank II 4001 is communicated with the second water inlet end of the hot water collecting tank I3901 through a water outlet pipe V44, the water inlet end of the hot water collecting tank II 4001 is communicated with the second water outlet end of the hot water collecting tank I3901 through a water inlet pipe V45, therefore, series connection between the vacuum tube heat collecting body I39 and the vacuum tube heat collecting body II 40 is achieved, and hot water flows in the vacuum tube heat collecting body I39 and the vacuum tube heat collecting body II 40 in a series connection circulating mode.

The first water outlet end of the hot water collecting tank I3901 is communicated with the first water inlet end of the intelligent water replenishing heat-conducting water storage tank 32 through a water outlet pipe IV 42, and the first water inlet end of the hot water collecting tank I3901 is communicated with the first water outlet end of the intelligent water replenishing heat-conducting water storage tank 32 through a water inlet pipe IV 43. The water outlet end of the heat collecting water tank III 4101 is communicated with the second water inlet end of the intelligent water replenishing heat-conducting water storage tank 32 through a water outlet pipe VI 46, and the water inlet end of the heat collecting water tank III 4101 is communicated with the second water outlet end of the intelligent water replenishing heat-conducting water storage tank 32 through a water inlet pipe VI 47, so that the vacuum tube heat collecting body I39 and the vacuum tube heat collecting body II 40 which are connected in series are connected in parallel with the vacuum tube heat collecting body III 41.

The front surfaces of the heat collecting water tank, the vacuum heat collecting pipe group and the connecting support are provided with ultra-white toughened glass, the back surfaces of the heat collecting water tank, the vacuum heat collecting pipe group and the connecting support are provided with a back plate or a transparent window, and the back plate can adopt an A-level fireproof heat-insulating plate. A hollow aluminum alloy frame 67 is adopted to fix the heat collecting water tank, the vacuum heat collecting pipe group, the connecting support, the ultra-white toughened glass and the back plate together to form a vacuum pipe heat collecting body.

The intelligent heat collector can be arranged at the position of a windowsill on the inner side of a balcony window on the sun surface of a building, and the vacuum tube heat collecting body can be arranged at the position of a windowsill or a window on the inner side of other windows. In addition, the intelligent heat collector can adopt various structural forms, such as: the balcony guardrail type is combined with the balcony guardrail into a whole; the wall-mounted type is mounted in parallel with the wall surface by clinging to the wall surface; the curtain wall type replaces glass and is combined with a curtain wall into a whole; the grid type is integrated with the building instead of an air conditioner grid; the balcony wall-mounted type is reserved and installed on the platform and tightly combined with the building.

The intelligent heat collector in this embodiment may be used in both the single set of heat-conducting coil dual supply system in embodiment 1 and the two set of heat-conducting coil dual supply system in embodiment 2.

A single set of heat conducting coil pipe is arranged in the H-shaped intelligent heat collector, and the heat conducting coil pipe can be matched into a set through a series-parallel connection mode, so that hot water for life can be supplied, solar energy and auxiliary energy can be utilized in winter in the south-north area of China, and the problem of heating of buildings and high-rise and super-high-rise single households in winter is solved. The H-type intelligent heat collector is matched with the series-parallel connection type, so that the clean heating of single building families by combining solar energy with auxiliary energy in winter is further improved. The reason for this is, first; the series-parallel connection type is characterized in that a vacuum tube heat collecting body group is respectively arranged at the positions of windowsills at the inner sides of all windows on the sun side of a single-family building of the residence, series-parallel connection among the vacuum tube heat collecting body groups is realized through a water inlet pipe and a water outlet pipe, and the vacuum tube heat collecting body groups are communicated to an intelligent water replenishing and heat conducting water storage tank, so that clean heating is realized by fully utilizing solar energy, thermal energy and the like; secondly, still further, according to the required daylighting area of single family of building, set up a plurality of vacuum tube heating body group on positions such as outdoor precast concrete saddle of building sun face, air conditioner grid, curtain, establish ties or be in parallel together through inlet tube and outlet pipe, get into in the intelligent moisturizing heat conduction water storage tank of intelligent heating ware, and then realized the maximize and utilized solar energy to combine auxiliary energy to carry out clean heating.

Example 6

Different from the embodiment 1, the intelligent heat collector in the embodiment is a window type E-shaped intelligent heat collector. As shown in fig. 9, the intelligent heat collector 2 in this embodiment is installed at a fixed window position below the opening window 48 of the building facade window, and is integrated with the opening window 48. The window type E-shaped intelligent heat collector comprises an intelligent water replenishing and heat conducting water storage tank, a water tank exchange groove, a vacuum heat collecting pipe set and a connecting support, and the connection relation among the parts is the same as that in embodiment 1, so that the details are not repeated. The front side surface of the intelligent heat collector is provided with the ultra-white toughened glass 49, the hollow aluminum alloy frame 67 is used for fixing the ultra-white toughened glass 49, the connecting supports on two sides and the water tank exchange tank together to form a heat collection body, and the hollow aluminum alloy frame 67 and the ultra-white toughened glass are sealed by sealant to prevent water from entering and fogging.

The intelligent heat collector in this embodiment may be used in both the single set of heat-conducting coil dual supply system in embodiment 1 and the two set of heat-conducting coil dual supply system in embodiment 2.

The shape of the window type intelligent heat collector is not limited to the E shape described in the embodiment, and may be any other shape. The window type intelligent heat collector is an intelligent heat collector which is arranged at a fixed window part at the lower part of an opening window of a building sun window and combined with the opening window into a whole.

Example 7

Different from the embodiment 6, the intelligent heat collector in the embodiment adopts a window-type split-type intelligent heat collector. As shown in fig. 10, the window-type split-type intelligent heat collector comprises an intelligent water replenishing heat-conducting water storage tank 32 and a vacuum tube heat collecting body iv 50, wherein the intelligent water replenishing heat-conducting water storage tank 32 and the vacuum tube heat collecting body iv 50 are in a split-type structure, and the vacuum tube heat collecting body iv 50 is located at a fixed window part at the lower part of an opening window and is combined with the opening window into a whole. The intelligent water replenishing heat-conducting water storage tank 32 can be positioned behind the vacuum tube heating body IV 50, and the intelligent water replenishing heat-conducting water storage tank 32 can be cuboid or any other shape.

The vacuum tube heating body IV 50 comprises a heating water tank IV 5001, a vacuum heating tube group VI 5002 and a connecting support VI 5003, wherein the open end of the vacuum heating tube group VI 5002 is communicated with the heating water tank IV 5001, and the other end of the vacuum heating tube group VI 5002 is connected with the connecting support VI 5003. The front side surfaces of the hot water collection tank IV 5001, the vacuum heat collection pipe group VI 5002 and the connecting support VI 5003 are provided with ultra-white toughened glass 49, the back surfaces of the rear sides of the hot water collection tank IV 5001, the vacuum heat collection pipe group VI 5002 and the connecting support VI 5003 are provided with back plates, the back plates can adopt A-level fireproof heat insulation plates, and the back plates can also adopt transparent windows. The ultra-white toughened glass 49, the hot water collecting tank IV 5001, the vacuum heat collecting pipe group VI 5002, the connecting support VI 5003 and the back plate are fixed together by adopting a hollow aluminum alloy frame 67 to form a vacuum pipe heat collecting body IV 50.

The water outlet end of the heat collection water tank IV 5001 is communicated with the water inlet end of the intelligent water replenishing heat-conducting water storage tank 32 through a water outlet pipe VII 53, the water inlet end of the heat collection water tank IV 5001 is communicated with the water outlet end of the intelligent water replenishing heat-conducting water storage tank 32 through a water inlet pipe VII 54, so that water circulates between the vacuum tube heat collection body IV 50 and the intelligent water replenishing heat-conducting water storage tank 32, and time-interval or forced circulation can be set.

The intelligent heat collector in this embodiment may be used in both the single set of heat-conducting coil dual supply system in embodiment 1 and the two set of heat-conducting coil dual supply system in embodiment 2.

It is right above the utility model provides an indoor cloud control dual-purpose water heater system of solar heating has carried out the detailed introduction. The principles and embodiments of the present invention have been explained herein using specific examples, and the above descriptions of the embodiments are only used to help understand the method and its core ideas of the present invention. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims. The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. The utility model provides an indoor cloud accuse solar heating dual-purpose water heater system which characterized in that: the intelligent human body induction controller (1) is arranged on a connecting pipeline between the intelligent heat collector (2) and the indoor hot water terminal, and a heating water return pipe (68) of the heating equipment (4) is communicated with the intelligent heat collector (2);

the intelligent heat collector comprises an intelligent water replenishing heat conduction water storage tank and a vacuum heat collecting pipe, and the intelligent water replenishing heat conduction water storage tank and the vacuum heat collecting pipe conduct heat by using water;

the solar heating network control mechanism is connected with a heating circulating pump of heating equipment.

2. The indoor cloud-controlled dual-purpose solar heating water heater system according to claim 1, wherein: the intelligent heat collector is characterized in that a heat-conducting coil pipe I (8) is arranged in the intelligent heat collector (2), the water outlet end of the heat-conducting coil pipe I (8) is communicated with a domestic hot water end water inlet (16) of auxiliary energy equipment through a water outlet pipe I (11), the water inlet end of the heat-conducting coil pipe I (8) is communicated with a water inlet pipe I (63), the water outlet end of the intelligent heat collector (2) is communicated with a heating end water inlet (17) of the auxiliary energy equipment through a water outlet pipe II (12), a tee joint is arranged on the water inlet pipe I (63), an intelligent water supplementing pipe (64) is connected with the water inlet pipe I (63) in parallel through the tee joint, and the intelligent water supplementing pipe (64) is communicated with the water inlet end of the intelligent heat collector (2);

and a heating circulating pump (23) is arranged on the water outlet pipe II (12), a heating end water outlet (18) of the auxiliary energy equipment is communicated with the floor heating water distributor (20) through a water outlet pipe III (19), the outlet end of the floor heating water distributor (20) is communicated with the heating equipment (4), and a heating water return pipe (68) of the heating equipment (4) is communicated with a water inlet end of the intelligent heat collector (2).

3. The indoor cloud-controlled dual-purpose solar heating water heater system according to claim 1, wherein: a heat-conducting coil II (25) and a heat-conducting coil III (26) are arranged in the intelligent heat collector (2), the water inlet end of the heat-conducting coil II (25) is communicated with a water inlet pipe II (21), the water outlet end of the heat-conducting coil II (25) is communicated with a water outlet pipe I (11), two tee joints are arranged on the water inlet pipe II (21), the water inlet pipe III (24) is connected with the water inlet pipe II (21) in parallel through one of the tee joints, the water inlet end of the heat-conducting coil III (26) is communicated with the water inlet pipe III (24), the water outlet end of the heat-conducting coil III (26) is communicated with a water outlet pipe II (12), an intelligent water supplementing pipe (64) is connected with the water inlet pipe II (21) in parallel through a second tee joint, and the intelligent water supplementing pipe (64) is communicated with the water inlet end of the intelligent heat collector (2);

be equipped with three-way valve I (66) on inlet tube III (24), the heating wet return and the I (66) intercommunication of three-way valve of heating equipment (4), the water that circulation flow passes through in I (66) entering inlet tube III (24) of three-way valve in heating equipment (4), and heat conduction coil pipe III (26) of refluence inflow are equipped with heating circulating pump (23) on the heating wet return, and the place ahead that just is located I (66) of three-way valve on inlet tube III (24) is equipped with check valve (22).

4. The indoor cloud controlled dual-purpose water heater system for solar heating according to claim 2 or 3, wherein: still include solar heating network control mechanism, solar heating network control mechanism is connected with heating circulating pump (23), including relay control module (55), temperature controller (56), intelligent gateway (57), router (58), network cloud server (59) and cell-phone (60), relay control module (55) are connected with heating circulating pump (23), relay control module (55) and temperature controller (56) connect in parallel to intelligent gateway (57), intelligent gateway (57) control host computer, intelligent gateway (57) are connected with router (58), router (58) are connected with network cloud server (59), network cloud server (59) are connected with cell-phone (60).

5. The indoor cloud-controlled dual-purpose solar heating water heater system according to claim 1, wherein: intelligent heat collector (2) adopt H shape intelligence heat collector, including intelligent moisturizing heat conduction storage water tank (32) and two sets of vacuum heat collection nest of tubes, arbitrary position department along intelligent moisturizing heat conduction storage water tank (32) length direction is equipped with bellied water tank exchange groove (28), water tank exchange groove (28) and intelligent moisturizing heat conduction storage water tank (32) intercommunication, water tank exchange groove (28) and intelligent moisturizing heat conduction storage water tank (32) are surrounded by water tank shell (30) and form, the internal surface of water tank shell (30) is equipped with the inner bag, the both sides of water tank exchange groove (28) are equipped with the vacuum heat collection nest of tubes respectively, the open end and water tank exchange groove (28) intercommunication of vacuum heat collection nest of tubes, the other end and the linking bridge connection of vacuum heat collection nest of tubes, just be located in water tank exchange groove (28) and be equipped with division board (31) between the open end of two vacuum heat collection nest of tubes.

6. The indoor cloud-controlled dual-purpose solar heating water heater system according to claim 1, wherein: the intelligent heat collector is arranged at the position of an inner windowsill of a balcony window on the exposed surface of a building, or at the position of an inner windowsill of other windows, or at the position of a fixed window below an opening window on the exposed surface of the building, or extends to the outside.

7. The indoor cloud-controlled dual-purpose solar heating water heater system according to claim 1, wherein: the shell and the inner container of the intelligent water replenishing and heat conducting water storage tank of the intelligent heat collector are made of glass fiber reinforced plastics or stainless steel materials.

8. The indoor cloud-controlled dual-purpose solar heating water heater system according to claim 1, wherein: the intelligent human body induction controller (1) comprises a binary human body infrared sensor, a relay, an electromagnetic valve I (62) and an electromagnetic valve II (14), the binary human body infrared sensor is connected with the relay, the electromagnetic valve I (62) is located on a water inlet pipe of a water inlet end of a heat conduction coil pipe connected with an indoor hot water terminal, and the electromagnetic valve II (14) is located on a water outlet pipe of a water outlet end of the heat conduction coil pipe connected with an indoor hot water terminal.

9. The indoor cloud-controlled dual-purpose solar heating water heater system according to claim 1, wherein: the intelligent heat collector (2) is further provided with an exhaust pipe (7), and water vapor enters the overflow pipe orifice of the water pan through the exhaust pipe (7).

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