Building 5G comfort system
Technical Field
The utility model belongs to the technical field of the house, concretely relates to is building 5G comfort system.
Background
With the development of communication technology and network technology and the popularization of 5G networks, the home system gradually realizes intelligent operation. The house comfort system honors the living idea of health, comfort, ecology and energy conservation, and creates five constant health spaces with constant temperature, humidity, oxygen, cleanness, constancy, satisfaction of the psychological needs of people, optimization of the life style of people and enhancement of the safety of home life. At present, a comfortable home system appears, but the energy source utilized by the system is also the traditional external energy source, the energy consumption is larger, meanwhile, the control aspect is also more traditional, and the mode is more single.
SUMMERY OF THE UTILITY MODEL
The to-be-solved technical problem of the utility model is: overcome prior art's not enough, provide a comfortable system of building 5G, the utility model discloses utilize soil energy storage mode, through the cooperation that solar energy and cold source pile, heat source pile, adjust the building indoor temperature throughout the year.
The utility model provides a technical scheme that the problem that prior art exists adopted is:
the building 5G comfort system is characterized in that indoor pipelines are arranged inside the building, a solar energy utilization device is arranged at the top of the building, an energy storage device is buried in underground soil outside the building, and a control device is arranged inside a basement of the building.
The solar energy utilization device is respectively communicated with the solar liquid outlet pipe and the solar liquid inlet pipe.
The solar liquid outlet pipe is respectively communicated with the first heat-conducting liquid inlet of the heat exchanger and the heat-conducting liquid outlet of the energy storage device through a three-way valve, and the solar liquid inlet pipe is respectively communicated with the first heat-conducting liquid outlet of the heat exchanger and the heat-conducting liquid inlet of the energy storage device through a three-way valve.
The water inlet and outlet of the indoor pipeline are respectively communicated with the second heat-conducting liquid inlet and outlet of the heat exchanger through pipelines.
Pipeline pumps are arranged on pipelines between the heat-conducting liquid outlet of the energy storage device and the three-way valve, on pipelines at the water inlet or the water outlet of the indoor pipeline, and on the solar liquid outlet pipe or the solar liquid inlet pipe.
The three-way valve and the pipeline pump are electrically connected with the control device.
Preferably, the energy storage device comprises a cold source stack and a heat source stack which are arranged at intervals.
Preferably, the cold source pile and the heat source pile have the same structure and respectively comprise a plurality of spiral coil pipes buried underground, and a main water inlet pipe and a main water outlet pipe which are respectively communicated with the water inlet and the water outlet of the spiral coil pipes.
Preferably, the heat exchanger comprises a first heat exchanger for cooling the building and a second heat exchanger for heating the building.
Preferably, the solar liquid outlet pipe is respectively communicated with the cold source stacking liquid inlet main pipe and the heat source stacking liquid inlet main pipe through valves, and the solar liquid inlet pipe is respectively communicated with the cold source stacking liquid outlet main pipe and the heat source stacking liquid outlet main pipe through valves.
Cold source pile liquid main pipe is through three-way valve and cold source pile feed liquor pipe and first heat exchanger drain pipe through connection, and cold source pile feed liquor main pipe is through three-way valve and cold source pile drain pipe and first heat exchanger feed liquor pipe through connection, and first heat exchanger feed liquor pipe, first heat exchanger drain pipe are respectively with first heat-conducting liquid business turn over pipe through connection of first heat exchanger.
The cold source pile liquid inlet pipe and the cold source pile liquid outlet pipe are respectively communicated with the cold source pile liquid inlet and outlet.
The heat source pile liquid inlet main pipe is respectively communicated with the second heat exchanger liquid outlet pipe and the heat source pile liquid outlet pipe through a three-way valve, the heat source pile liquid outlet main pipe is respectively communicated with the heat source pile liquid inlet pipe and the second heat exchanger liquid inlet pipe through a three-way valve, and the heat source pile liquid inlet pipe and the heat source pile liquid outlet pipe are respectively communicated with the heat source pile liquid inlet and outlet.
The liquid outlet pipe of the second heat exchanger and the liquid inlet pipe of the second heat exchanger are respectively communicated with the first heat-conducting liquid inlet and the first heat-conducting liquid outlet of the second heat exchanger.
The indoor pipeline liquid inlet and outlet are respectively communicated with the first heat exchanger and the second heat-conducting liquid inlet and outlet of the second heat exchanger through pipelines and a three-way valve.
And a pipeline pump is arranged on the corresponding pipeline.
Preferably, the cold source stack liquid outlet pipe is communicated with the cold source stack liquid outlet main pipe through a first bypass pipeline with a stop valve.
The heat source pile liquid outlet pipe is communicated with the heat source pile liquid outlet main pipe through a second bypass pipeline with a stop valve.
And the first heat exchanger liquid outlet pipe and the second heat exchanger liquid inlet pipe are respectively provided with a temperature sensor which is electrically connected with the control device.
Preferably, the indoor pipeline comprises a water separator and a plurality of water pipes, and each water pipe is laid under the floor or the bottom plate and inside the wall.
The valves of the water separator adopt electric control valves which are electrically connected with a control device.
Preferably, a fresh air system is arranged in the building.
Preferably, the building inside be equipped with humidity transducer, the new trend system has humidification and dehumidification unit, humidity transducer and new trend system respectively with controlling means electric connection.
Preferably, the solar energy utilization device comprises a solar heat absorption plate and a solar power generation plate, and an inlet and an outlet of the solar heat absorption plate are communicated with the solar liquid outlet pipe and the solar liquid inlet pipe.
The solar energy starting board is electrically connected with a power supply system arranged inside a building or a basement.
Compared with the prior art, the utility model discloses beneficial effect who has:
(1) the soil is utilized to store energy, cold energy in winter can be used in summer, and heat energy in summer can be used in winter.
(2) The indoor temperature is adjusted through the cold source stack and the heat source stack.
(3) The solar energy utilization device can respectively utilize the heat energy and the light energy of the solar energy.
(4) The energy storage piles of the cold source pile and the heat source pile are both in a spiral pipe form, and the spiral pipe is similar to a screw and can conveniently move up and down in soil. Meanwhile, the spiral pipe is in closer contact with soil, and the contact area is larger.
(5) The humidification and dehumidification functions of the indoor humidity sensor and the fresh air system are matched, the indoor air humidity is adjusted, and the comfort level of indoor personnel is improved.
Drawings
The present invention will be further explained with reference to the drawings and examples.
Fig. 1 is a schematic diagram of a 5G comfort system of the present invention.
In the figure: 01-building, 02-solar energy utilization device, 021-solar energy liquid outlet pipe, 022-solar energy liquid inlet pipe, 03-cold source stack, 031-cold source stack liquid inlet pipe, 032-cold source stack liquid outlet pipe, 033-first bypass pipeline, 04-heat source stack, 041-heat source stack liquid inlet pipe, 042-heat source stack liquid outlet pipe, 043-second bypass pipeline, 05-first heat exchanger, 051-first heat exchanger liquid inlet pipe, 052-first heat exchanger liquid outlet pipe, 06-second heat exchanger, 061-second heat exchanger liquid outlet pipe, 062-second heat exchanger liquid inlet pipe, 07-water heater, 071-heat source water outlet pipe, 072-water heater liquid inlet pipe, 081-cold source stack liquid outlet manifold, 082-cold source stack liquid inlet manifold, 083-heat source stacking liquid inlet main pipe, 084-heat source stacking liquid outlet main pipe, 091-stop valve, 092-three-way valve, 093-four-way valve, 010-pipeline pump, 011-indoor pipeline and 012-temperature sensor.
Detailed Description
The accompanying drawings illustrate a preferred embodiment of the building 5G comfort system, and the present invention will be described in further detail with reference to the accompanying drawings.
A building 5G comfort system is shown in figure 1, and indoor pipelines 011 are laid below the floor or the floor and the wall of the inner wall of a building 01. The indoor pipeline 011 is composed of a water separator and a plurality of pipelines, each pipeline is respectively communicated with the water separator, and valves on the water separator are all electric control valves.
The top of the building 01 is provided with a solar energy utilization device 02, and a cold source pile 03 and a heat source pile 04 are respectively embedded in underground soil outside the building 01. The cold source stack 03 and the heat source stack 04 may be spaced apart by a distance and disposed at opposite sides of the building, respectively.
The cold source pile 03 and the heat source pile 04 have the same structure and respectively comprise a plurality of spiral coil pipes buried underground, and a main water inlet pipe and a main water outlet pipe which are respectively communicated with the water inlet and the water outlet of the spiral coil pipes.
The solar energy utilization device 02 is respectively communicated with a solar energy liquid outlet pipe 021 and a solar energy liquid inlet pipe 022, and the solar energy liquid outlet pipe 021 is respectively communicated with a cold source stacking liquid inlet header pipe 082 and a heat source stacking liquid inlet header pipe 083 through valves; the solar liquid inlet pipe 022 is respectively communicated with the cold source stacking liquid main pipe 081 and the heat source stacking liquid main pipe 084 through valves.
In order to supply hot water to daily-use water such as showering and washing, a water heater 07 using solar energy is installed inside the building. The solar liquid outlet pipe 021 is respectively communicated and linked with a heat source liquid inlet pipe 072, a cold source stacking liquid inlet header pipe 082 and a heat source stacking liquid inlet header pipe 083 of the water heater through a four-way valve 093; the solar liquid inlet pipe 022 is respectively communicated with a heat source liquid outlet pipe 071, a cold source stacking liquid outlet header pipe 081 and a heat source stacking liquid outlet header pipe 084 of the water heater through a four-way valve 093.
The tap water pipe inside the building 01 supplies water to the water heater 07, and then flows into the hot water pipe inside the building 01 after being heated, so as to be used for showering, washing vegetables and the like.
Cold source stack liquid main 081 passes through three-way valve 092 and cold source stack feed liquor pipe 031 and first heat exchanger drain pipe 052 through connection, cold source stack feed liquor main 082 passes through three-way valve 092 and cold source stack drain pipe 032 and first heat exchanger feed liquor pipe 051 through connection, cold source stack drain pipe 032 and cold source stack liquid main 081 pass through first bypass pipeline 033 through connection who has the stop valve, cold source stack feed liquor pipe 031 and cold source stack drain pipe 032 pile 03 business turn over liquid mouth through connection with the cold source respectively.
The first heat exchanger liquid outlet pipe 052 and the first heat exchanger liquid inlet pipe 051 are respectively communicated with the liquid outlet and the liquid inlet of the first heat exchanger 05.
The heat source heap liquid inlet main pipe 083 is respectively communicated with the second heat exchanger liquid outlet pipe 061 and the heat source heap liquid outlet pipe 042 through a three-way valve, the heat source heap liquid outlet main pipe 084 is respectively communicated with the heat source heap liquid inlet pipe 041 and the second heat exchanger liquid inlet pipe 062 through a three-way valve, the heat source heap liquid outlet pipe 042 is communicated with the heat source heap liquid outlet main pipe 084 through a second bypass pipeline 043 with a stop valve, and the heat source heap liquid inlet pipe 041 and the heat source heap liquid outlet pipe 042 are respectively communicated with a heat source heap 04 liquid inlet and outlet.
The second heat exchanger liquid outlet pipe 061 and the second heat exchanger liquid inlet pipe 062 are respectively communicated with the liquid outlet and the liquid inlet of the second heat exchanger 06.
The liquid inlet and outlet of the indoor pipeline 11 are respectively communicated with the first heat exchanger 05 and the second heat exchanger 06 through pipelines and a three-way valve. The first heat exchanger 05 and the second heat exchanger 06 are plate heat exchangers or tube heat exchangers, each of the first heat exchanger 05 and the second heat exchanger includes two flow paths, i.e., a first heat transfer fluid and a second heat transfer fluid flow path, the solar energy utilization device 02, the cold source stack 03 and the heat source stack 04 flow upward the corresponding pipes with the first heat transfer fluid, and the indoor pipeline 011 flows inward the second heat transfer fluid.
Temperature sensors 012 are arranged on the first heat exchanger liquid outlet pipe 052 and the second heat exchanger liquid inlet pipe 062, and pipeline pumps 010 are arranged on corresponding pipelines. At least one of the liquid inlet and outlet pipelines of the solar energy utilization device 02, the cold source pile 03, the heat source pile 04, the first heat exchanger 05, the second heat exchanger 06 and the water heater 07 is provided with a pipeline pump 010.
In summer: sunlight is sufficient in daytime, and the heat-conducting liquid inside the solar energy utilization device 02 is heated and then flows into the water heater 07 to heat the water inside the water heater 07. When the temperature reaches the threshold value, the high-temperature heat-conducting liquid reserved by the solar energy utilization device 02 flows into the heat source pile for storage by adjusting the corresponding valve. At night, the outdoor temperature is reduced, the temperature of the heat conducting liquid in the solar energy utilization device 02 is reduced, and when the temperature of the heat conducting liquid in the solar energy utilization device is not enough to heat water in the water heater 07, the heat conducting liquid pipeline of the heat source stack 04 is communicated with the water heater 07 through adjusting the corresponding valve, and the heat source stack 04 releases heat to heat hot water in the water heater 07. Because the water heater 07 is used relatively infrequently, the heat absorbed by the heat source stack 04 is greater than the heat released, and the heat is surplus, so that the water heater is convenient to use in winter.
The temperature of cold source heap 03 is less than the inside temperature of building 01, through adjusting corresponding valve, make the cold source heap 03's heat conduction liquid pipeline link up with first heat exchanger 05, indoor pipeline 011 equally with first heat exchanger 05 through connection, the heat conduction liquid that the cold source heap 03 flows out and the heat conduction liquid that indoor pipeline 011 flows out carry out the heat transfer in first heat exchanger 05 is inside, make the inside heat conduction liquid temperature of indoor pipeline 011 flow back to inside of building 01 after reducing, reduce the inside temperature of building 01, play cryogenic effect.
And (3) in winter: in the daytime, the heat transfer fluid inside the solar energy utilization device 02 is heated, and the heated heat transfer fluid heats the heat source stack 04 and the water heater 07. At night, the temperature of the heat conducting liquid inside the solar energy utilization device 02 is reduced, the heat conducting liquid flows into the cold source pile 03 at the moment, the temperature of the cold source pile 03 is reduced, and the solar energy utilization device is convenient to use in summer.
Meanwhile, a heat-conducting liquid pipeline of the heat source stack 04 is in through connection with the second heat exchanger 06, the indoor pipeline 011 is also in through connection with the second heat exchanger 06, and heat-conducting liquid flowing out of the heat source stack 04 heats heat-conducting liquid inside the indoor pipeline 011, so that the temperature inside the building is increased, and the building 01 is heated.
The solar energy utilization device 02 comprises a solar heat absorption plate and a solar power generation plate, wherein an inlet and an outlet of the solar heat absorption plate are in through connection with a solar liquid outlet pipe 021 and a solar liquid inlet pipe 022.
The solar energy starting board is electrically connected with a power supply system arranged inside a building or a basement. The power supply system comprises a storage battery, a charging module and a discharging module, which are all in the prior art.
Building 01 inside be equipped with new trend system and a plurality of humidity transducer, humidity transducer and new trend system respectively with controlling means electric connection.
The fresh air system is provided with a humidifying unit and a dehumidifying unit which are in the prior art, and the air humidity inside the building can be adjusted, so that people feel more comfortable.
Meanwhile, the wall board in the building 01 adopts a biomass rock board, and negative oxygen ions can be released. The control device in the basement is electrically connected or wirelessly connected with all electrical parts of the system, and 5G signals are adopted for wireless connection in order to improve the stability and the signal transmission speed of the wireless connection. The connection relation, structure and control program of the control device all adopt the prior art.
Simultaneously, controlling means can also be connected with cell-phone APP through 5G signal network, through each inside electric spare part of cell-phone APP control building.
The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made without departing from the gist of the present invention within the knowledge of those skilled in the art.