CN209782815U - Intelligent hot water supply station based on solar photovoltaic power generation - Google Patents

Abstract

The utility model discloses an intelligent hot water supply station based on solar photovoltaic power generation, which comprises a solar heat collecting device, a water tank, a hot water using device, a solar vacuum heat collecting tube and a photovoltaic power generation plate, wherein the left side of the solar heat collecting device is provided with the water tank, the solar heat collecting device comprises a base and a bottom plate, the bottom of the bottom plate is fixedly provided with a support frame, the bottom of the bottom plate is provided with the base, the top of the base is fixedly provided with a support column, a rotary mounting frame is arranged in the support column, the top of the bottom plate is fixedly provided with a support seat, the solar vacuum heat collecting tube is arranged between the support seats, the top of the bottom plate is fixedly provided with the photovoltaic power generation plate, the top of the bottom plate is fixedly provided with a toughened glass cover, the top of the toughened glass cover is fixedly provided with a light sensor, a battery bin is arranged in the base, the, the hot water conversion efficiency is improved.

Description

Intelligent hot water supply station based on solar photovoltaic power generation

Technical Field

The utility model relates to a hot water supply station specifically is an intelligent hot water supply station based on solar photovoltaic power generation.

Background

Solar energy is a durable energy which can be freely utilized, is pollution-free and has low energy density, is the richest energy which can be utilized by human beings, and is the cleanest, cheapest and most promising energy, when the existing hot water supply station based on solar photovoltaic power generation is used for producing hot water, hot water is usually produced only through a solar energy conversion way of photoelectric conversion or photothermal conversion, the illumination angles of the sun in the sky are different in one day, the solar photovoltaic equipment cannot intelligently adjust the angles, the sunlight is directly irradiated at any time, and therefore the utilization rate of the solar energy cannot be maximized as far as possible.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an intelligent hot water supply station based on solar photovoltaic power generation to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

An intelligent hot water supply station based on solar photovoltaic power generation comprises a solar heat collecting device, a water tank, a hot water using device, a light sensor, a solar vacuum heat collecting tube, a photovoltaic power generation plate, a rotating motor and an electric heater, wherein the water tank is arranged on the left side of the solar heat collecting device, the solar heat collecting device comprises a base and a bottom plate, a support is fixedly arranged at the bottom of the bottom plate, a through hole is formed in the support in a front-back penetrating manner, a rotating shaft is fixedly arranged at the bottom of the bottom plate, a base is arranged at the bottom of the bottom plate, a supporting column is fixedly arranged at the top of the base, an arc-shaped groove is formed in the supporting column, a through hole is formed in the support in a front-back penetrating manner, the rotating shaft is rotatably arranged in the through hole, the solar vacuum heat collecting tube comprises a bottom plate, an input shaft, an output shaft, a support column, a driving belt pulley, a belt pulley, a support seat, two support seats, solar vacuum heat collecting tubes, a plurality of solar vacuum heat collecting tubes, an arc connecting tube, two photovoltaic power generation plates, a plurality of solar vacuum heat collecting tubes, a plurality of photovoltaic power generation plates and a plurality of solar vacuum heat collecting tubes, wherein the input shaft and the output shaft of the speed reducer are both fixedly provided with the driving belt pulley, the right side of the support column is fixedly provided with a rotating motor, the driving shaft of the rotating motor is fixedly provided with the driving belt pulley, the belt is sleeved between the driving belt pulley and the driving belt pulley positioned on the input shaft of the speed reducer, the solar vacuum heat collecting tube comprises an outer glass tube and an inner glass tube, wherein the outer glass tube is sleeved on the inner glass tube, the outer glass tube and the inner glass tube are vacuumized, the inner glass tube is covered and sleeved with a light energy absorption film, the outer glass tube is made of a high-light-transmission non-reflective material, a vacuum heat collecting tube interface is fixedly installed outside the solar vacuum heat collecting tube, the heat collecting tube vacuum interface is communicated with the vacuum position in the solar vacuum heat collecting tube, each heat collecting vacuum interface is fixedly connected and communicated with each other through a heat collecting tube connecting tube, a battery bin is arranged in the base, and a storage battery is fixedly installed at the bottom of the inner side of the battery bin, the water storage tank is characterized in that a water pump is fixedly arranged on the left side of the base, the water outlet end of the water pump is communicated with the inner water inlet end of the inner glass tube through a second water inlet tube, a controller is fixedly arranged on the left side of the top of the base, the water tank comprises a water storage tank body, one end of a uniform temperature partition plate is fixedly arranged on the inner wall on the left side of the water storage tank body, the other end of the uniform temperature partition plate is fixedly arranged on the inner wall on the right side of the water storage tank body, the inner space above the uniform temperature partition plate above the water storage tank body is arranged as a water storage cavity, the lower part of the uniform temperature partition plate is arranged in the inner space of the water storage tank body and is arranged as a heating cavity, a water inlet is formed in the top of the water storage tank body, an electric heater is fixedly arranged at, and hot water using equipment is arranged on the left side of the water tank.

As a further aspect of the present invention: the bottom of the water storage tank body is fixedly provided with supporting legs.

As a further aspect of the present invention: the hot water user equipment includes cold water inlet tube and hot water inlet tube, the hot water inlet tube is intake and is held and the inside intercommunication of retaining chamber, and the hot water inlet tube goes out the water outlet end fixed connection and the intercommunication of water outlet end and cold water inlet tube, and has mixed water pipe in the fixed intercommunication in junction bottom, and the inside temperature meter that is provided with of mixed water pipe, fixed mounting has the temperature display on the mixed water pipe, has seted up the delivery port bottom the mixed water pipe, vertically run through and fixed mounting has even temperature board in the mixed water pipe, even temperature inboard seted up even temperature chamber and with the inside intercommunication of mixed water pipe.

As a further aspect of the present invention: the cold water inlet pipe is provided with a cold water throttle valve, and the hot water inlet pipe is provided with a hot water throttle valve.

As a further aspect of the present invention: and the bottom of the bottom plate is fixedly provided with a vacuumizing device, and the vacuumizing device is communicated with the vacuum part in the solar heat collection vacuum pipe through a connecting pipe.

As a further aspect of the present invention: the control input end of the controller is electrically connected with the light sensor, and the control output end of the controller is electrically connected with the rotating motor.

As a further aspect of the present invention: the support both sides all fixed mounting have buffer spring's one end, buffer spring's the other end fixed mounting in the inboard bottom of arc wall.

As a further aspect of the present invention: the cover is established and is installed the torsional spring in the axis of rotation, and the torsional spring has two, and the torsional spring is located between support and the inside front surface of arc wall and the inside rear surface respectively.

Compared with the prior art, the beneficial effects of the utility model are that: the solar energy is converted into electric energy by utilizing photoelectric conversion through the photovoltaic power generation panel and stored in the storage battery as an auxiliary power source for heating hot water of a hot water supply station, the illumination intensity of the surrounding sunlight is detected through the light sensor, the controller controls the rotating motor to work to rotate the bottom plate towards the direction of the light sensor with high illumination intensity, so that the sunlight can be directly irradiated on the bottom plate as far as possible, the photoelectric conversion efficiency and the photothermal conversion efficiency reach the maximum value, the water pump supplies energy through the storage battery, the water in the water tank is pumped into the solar vacuum heat collecting tube to circularly flow, the solar vacuum heat collecting tube is used for converting the solar energy into heat energy to circularly and repeatedly heat water flow, the solar vacuum heat collecting tube cannot effectively absorb the solar energy to heat water through photothermal conversion in rainy days, and then the storage battery filled with electricity is used for supplying energy to the electric, the hot water supply station can supply hot water in rainy days, when indoor people need to use hot water, hot water in the hot water inlet pipe and cold water in the cold water inlet pipe are mixed, and the flow rate of the cold water and the hot water are adjusted through the hot water throttle valve and the cold water throttle valve, so that the temperature of the finally discharged water is controlled, and the requirements of people on the hot water with different temperatures in daily life are met.

Drawings

Fig. 1 is a schematic structural diagram of an intelligent hot water supply station based on solar photovoltaic power generation.

Fig. 2 is a schematic structural diagram of hot water using equipment in an intelligent hot water supply station based on solar photovoltaic power generation.

Fig. 3 is a schematic structural diagram of a solar heat collecting device in an intelligent hot water supply station based on solar photovoltaic power generation.

Fig. 4 is a schematic structural diagram of a water tank in an intelligent hot water supply station based on solar photovoltaic power generation.

Fig. 5 is a top view of a solar vacuum heat collecting tube in an intelligent hot water supply station based on solar photovoltaic power generation.

Fig. 6 is a side view of a photovoltaic panel in an intelligent hot water supply station based on solar photovoltaic power generation.

Fig. 7 is a partial sectional view of a solar vacuum heat collecting tube in an intelligent hot water supply station based on solar photovoltaic power generation.

Fig. 8 is a side view of a solar heat collecting apparatus in an intelligent hot water supply station based on solar photovoltaic power generation.

In the figure: the solar energy heat collecting device comprises a solar energy heat collecting device 1, a water tank 2, a hot water using device 3, a first water inlet pipe 4, a second water inlet pipe 5, a water outlet pipe 6, a cold water throttle valve 7, a mixed water pipe 8, a water temperature meter 9, a water temperature display 10, a water outlet 11, a cold water inlet pipe 12, a hot water inlet pipe 13, a hot water throttle valve 14, a uniform temperature plate 15, a light sensor 16, a toughened glass cover 17, a solar vacuum heat collecting pipe 18, an arc-shaped connecting pipe 19, a heat collecting pipe vacuum interface 20, a heat collecting pipe connecting pipe 21, a photovoltaic power generating plate 22, a vacuumizing device 23, a support 24, a support pillar 25, a rotating motor 26, a base 27, a battery bin 28, a storage battery 29, a driving belt pulley 30, a speed reducer 31, a transmission belt pulley 32, a driven belt pulley 33, an arc-shaped groove 34, a water pump, The water storage tank comprises support legs 43, a water storage tank body 44, a water inlet 45, a water storage cavity 46, a torsion spring 47, a heating cavity 48, a light energy absorption film 49, an inner layer glass tube 50 and an outer layer glass tube 51.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 8, in an embodiment of the present invention, an intelligent hot water supply station based on solar photovoltaic power generation includes a solar heat collecting device 1, a water tank 2, a hot water using device 3, a first water inlet pipe 4, a second water inlet pipe 5, a water outlet pipe 6, a cold water throttle valve 7, a mixed water pipe 8, a water temperature meter 9, a water temperature display 10, a water outlet 11, a cold water inlet pipe 12, a hot water inlet pipe 13, a hot water throttle valve 14, a temperature equalizing plate 15, a light sensor 16, a tempered glass cover 17, a solar vacuum heat collecting pipe 18, an arc connecting pipe 19, a heat collecting pipe vacuum interface 20, a heat collecting pipe connecting pipe 21, a photovoltaic power generating plate 22, a vacuum pumping device 23, a support 24, a support pillar 25, a rotating motor 26, a base 27, a battery compartment 28, a storage battery 29, a driving pulley 30, a speed reducer 31, a, The solar heat collecting device comprises a water pump 35, a controller 36, a rotating shaft 37, a supporting seat 38, a bottom plate 39, a conducting wire 40, an electric heater 41, a temperature-uniforming partition plate 42, supporting legs 43, a water storage tank body 44, a water inlet 45, a water storage cavity 46, a torsion spring 47, a heating cavity 48, a light energy absorption film 49, an inner layer glass tube 50 and an outer layer glass tube 51, wherein the left side of the solar heat collecting device 1 is provided with a water tank 2, the solar heat collecting device comprises a base 27 and the bottom plate 39, the bottom of the bottom plate 39 is fixedly provided with a support 24, the support 24 is internally provided with a through hole in a front-back penetrating manner and fixedly provided with the rotating shaft 37, the bottom of the bottom plate 39 is provided with the base 27, the top of the base 27 is fixedly provided with a supporting column 25, the supporting column 25 is internally provided with an arc-shaped groove 34, the bottom of the support, the front surface of the supporting column 25 is fixedly provided with a speed reducer 31, the input shaft and the output shaft of the speed reducer 31 are fixedly provided with a transmission belt pulley 32, the right side of the supporting column 25 is fixedly provided with a rotating motor 26, the transmission shaft of the rotating motor 26 is fixedly provided with a driving belt pulley 30, a belt is sleeved between the driving belt pulley 30 and the transmission belt pulley positioned on the input shaft of the speed reducer 31, a belt is sleeved between a driven belt pulley 33 and the transmission belt pulley 32 positioned on the output shaft of the speed reducer 31, the top of the bottom plate 39 is fixedly provided with a supporting seat 38, the supporting seat 38 is provided with two, a solar vacuum heat collecting tube 18 is arranged between the supporting seats 38, the solar vacuum heat collecting tubes 18 are provided with a plurality of solar heat collecting tubes, each solar vacuum heat collecting tube 18 is fixedly connected through an arc-, the solar vacuum heat collecting tube 18 comprises three light sensors 16, the three light sensors 16 are uniformly distributed along the top of the toughened glass cover 17, a supporting seat 38, the solar vacuum heat collecting tube 18 and the photovoltaic power generating plate 22 are positioned in the toughened glass cover 17, the solar vacuum heat collecting tube 18 comprises an outer glass tube 51 and an inner glass tube 50, the outer glass tube 51 is sleeved on the inner glass tube 50, a vacuum is pumped between the outer glass tube 51 and the inner glass tube 50, a light energy absorbing film 49 is sleeved outside the inner glass tube 50, the outer glass tube 51 is made of a high-light-transmitting non-reflective material, the vacuum heat collecting tube 20 is fixedly installed outside the solar vacuum heat collecting tube 18, the heat collecting tube vacuum connectors 20 are communicated with the inner vacuum part of the solar vacuum heat collecting tube 18, each heat collecting vacuum connector 20 is fixedly connected and communicated with each other through a heat collecting tube connecting tube 18, a battery bin 28 is arranged in a base 27, a storage battery 29 is fixedly arranged at the bottom of the inner side of the battery bin 28, a water pump 35 is fixedly arranged at the left side of the base 27, the water outlet end of the water pump 35 is communicated with the inner water inlet end of an inner glass tube 50 through a second water inlet tube 5, a controller 36 is fixedly arranged at the left side of the top of the base 27, the water tank 2 comprises a water storage tank body 44, one end of a uniform temperature partition plate 42 is fixedly arranged on the inner wall at the left side of the water storage tank body 44, the other end of the uniform temperature partition plate 42 is fixedly arranged on the inner wall at the right side of the water storage tank body 44, the inner space of the, the water storage tank is characterized in that a water inlet 45 is formed in the top of the water storage tank body 44, an electric heater 41 is fixedly mounted at the top of the inner side of the heating cavity 48, the electric heaters 41 are connected in series through a conducting wire 40, the water inlet end of the water pump 35 is communicated with the interior of the water storage cavity 46 through a first water inlet pipe 4, the water outlet end of the interior of the inner glass tube 50 is communicated with the interior of the water storage cavity 46 through a water outlet pipe 6, hot water using equipment 3 is arranged on the left side of the water tank 2, a supporting leg 43 is fixedly mounted at the bottom of the water storage tank body 44, the hot water using equipment 3 comprises a cold water inlet pipe 12 and a hot water inlet pipe 13, the water inlet end of the hot water inlet pipe 13 is communicated with the interior of the water storage cavity 46, the water outlet end of the hot water inlet pipe 13 is fixedly connected and communicated with the water outlet end, the bottom of the mixed water pipe 8 is provided with a water outlet 11, a uniform temperature plate 15 longitudinally penetrates through and is fixedly installed in the mixed water pipe 8, a uniform temperature cavity is formed in the uniform temperature plate 15 and is communicated with the interior of the mixed water pipe 8, a cold water throttle valve 7 is arranged on a cold water inlet pipe 12, a hot water throttle valve 14 is arranged on a hot water inlet pipe 13, a vacuumizing device 23 is fixedly installed at the bottom of the bottom plate 39, the vacuumizing device 23 is communicated with a vacuum part in a solar heat collecting vacuum pipe 18 through a connecting pipe, a control input end of a controller 36 is electrically connected with a light sensor 16, a control output end of the controller 36 is electrically connected with a rotating motor 26, one end of a buffer spring is fixedly installed at each of two sides of the support 24, the other end of the buffer spring is fixedly installed at the bottom of the inner side of the arc-, and the torsion spring 47 is respectively positioned between the front surface and the rear surface inside the bracket 24 and the arc-shaped groove 34, when the intelligent hot water power supply station based on solar photovoltaic power generation is used, the solar heat collecting device 1 is used for collecting outdoor solar energy, the solar energy irradiated on the photovoltaic power generation plate 22 is converted into electric energy by utilizing photoelectric conversion through the photovoltaic power generation plate 22 and is stored into the storage battery 29, the ambient sunlight illumination intensity is detected through the light sensor 16, the detection result is transmitted into the controller 36, the controller 36 analyzes and judges the illumination intensity of the three light sensors 16 and sorts the illumination intensity from large to small, the controller 36 controls the rotating motor 26 to work to rotate the bottom plate 39 towards the direction of the light sensor 16 with large illumination intensity, so that the sunlight can be directly irradiated on the bottom plate 39 as far as possible, and the photoelectric conversion efficiency and the photothermal conversion efficiency reach the maximum value of the time period, the water pump 35 is powered after the storage battery is charged, the water pump 35 pumps clean water in the water storage cavity 46 into the solar vacuum heat collecting tube 18 for circulating flow, solar energy is converted into heat energy through the solar vacuum heat collecting tube 18 to heat water flow in a circulating and reciprocating mode, water in the water tank 2 is heated, the water is used as an auxiliary power device to supply power to the water pump 35 through solar photoelectric conversion, additional power for water circulation is not needed, energy is further saved, meanwhile, the solar vacuum heat collecting tube 18 cannot effectively absorb solar energy to carry out photothermal conversion to heat water in rainy days, at the moment, the storage battery 29 which is fully charged through photoelectric conversion is used for supplying power to the electric heater 41 in the rainy days to heat water in the water tank 2 in the sunny days, so that hot water can be supplied by the hot water supply station in rainy days, when indoor people need to use hot water, the hot water is led out through the hot water inlet tube 13, cold water flows out from the cold water inlet pipe 12 and is mixed with hot water, the flow and the flow speed of the cold water and the hot water are adjusted by using the hot water throttle valve 14 and the cold water throttle valve 7, so that the temperature of the finally discharged water is controlled, the requirements of people on the hot water with different water temperatures in daily life are met, the water temperature is measured by the water temperature meter 9, the mixed water temperature is displayed by the water temperature display, and the water temperature can be selected and controlled by people more intuitively.

The utility model discloses a theory of operation is: when the intelligent hot water power supply station based on solar photovoltaic power generation is used, the solar heat collecting equipment 1 is used for collecting outdoor solar energy, the solar energy irradiated on the photovoltaic power generation panel 22 is converted into electric energy by utilizing photoelectric conversion through the photovoltaic power generation panel 22 and is stored in the storage battery 29, the ambient sunlight illumination intensity is detected through the light ray sensors 16, the detection result is transmitted into the controller 36, the controller 36 analyzes and judges the illumination intensity of the three light ray sensors 16 and sorts the illumination intensity from large to small, the controller 36 controls the rotating motor 26 to work to rotate the bottom plate 39 towards the direction of the light ray sensor 16 with large illumination intensity, so that the sunlight rays can be directly irradiated on the bottom plate 39 as far as possible, the photoelectric conversion efficiency and the photothermal conversion efficiency reach the maximum value of the time period, the storage battery supplies power to the water pump 35 after being charged, the water pump 35 pumps clean water in the water storage cavity 46 into the solar vacuum heat collecting tube 18 for circulating flow, solar energy is converted into heat energy through the solar vacuum heat collecting tube 18 to circularly and repeatedly heat water flow, so that water in the water tank 2 is heated and is used as an auxiliary power device to supply power for the water pump 35 through solar photoelectric conversion, so that power of water circulation is not required to be additionally provided, energy is further saved, meanwhile, the solar vacuum heat collecting tube 18 can not effectively absorb the solar energy to carry out photothermal conversion to heat water in rainy days, at the moment, the storage battery 29 fully charged by photoelectric conversion is used for supplying energy to the electric heater 41 in sunny days, water in the water tank 2 is heated, so that hot water can be supplied by the hot water supply station in rainy days, when indoor people need to use hot water, the hot water is led out through the hot water inlet tube 13 and is mixed with the hot water through the outflow of cold water in the cold water inlet tube 12, and the flow and flow rate of the cold water and the hot water are adjusted through the hot water throttle valve 14 and the, thereby the temperature of final play water of control satisfies the hot-water demand of people to different temperatures in daily life, measures the temperature through temperature meter 9 and shows the temperature after mixing through the temperature display to can supply people to select and control the temperature more directly perceivedly.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (8)

1. An intelligent hot water supply station based on solar photovoltaic power generation comprises a solar heat collecting device (1), a water tank (2), a hot water using device (3), a light sensor (16), a solar vacuum heat collecting tube (18), a photovoltaic power generation plate (22), a rotating motor (26) and an electric heater (41), and is characterized in that the water tank (2) is arranged on the left side of the solar heat collecting device (1), the solar heat collecting device comprises a base (27) and a bottom plate (39), a bracket (24) is fixedly installed at the bottom of the bottom plate (39), a through hole is formed in the bracket (24) in a front-back penetrating mode, a rotating shaft (37) is fixedly installed in the bracket (24), the base (27) is arranged at the bottom of the bottom plate (39), a supporting column (25) is fixedly installed at the top of the base (27), an arc-shaped groove (34) is formed in the supporting column, run through around in support column (25) and seted up the through-hole, axis of rotation (37) rotate and install in the through-hole on support column (25), the one end fixed mounting that axis of rotation (37) is located support column (25) front surface has driven pulley (33), and fixed surface installs speed reducer (31) before support column (25), and the equal fixed mounting of input shaft and the output shaft of speed reducer (31) has drive pulley (32), and support column (25) right side fixed mounting has rotation motor (26), and the transmission shaft fixed mounting who rotates motor (26) has drive pulley (30), the cover is established between drive pulley (30) and the drive pulley that is located speed reducer (31) input shaft and is installed the belt, the cover is established between driven pulley (33) and drive pulley (32) that are located speed reducer (31) output shaft and is installed the belt, and bottom plate (39) top fixed mounting has supporting, there are two supporting seats (38), there are solar vacuum heat collecting tubes (18) between the supporting seats (38), there are a plurality of solar vacuum heat collecting tubes (18), and pass through arc connecting pipe (19) fixed connection between every solar vacuum heat collecting tube (18), fixed mounting has two photovoltaic power generation boards (22) between every solar vacuum heat collecting tube (18), and symmetric distribution is in thermal-collecting tube vacuum interface (20) both sides, and the top of photovoltaic power generation board (22) is higher than the top of solar vacuum heat collecting tube (18), bottom plate (39) top fixed mounting has toughened glass cover (17), and toughened glass cover (17) top fixed mounting has optical line sensors (16), and optical line sensors (16) have threely, and along toughened glass cover (17) top evenly distributed, supporting seats (38), solar vacuum heat collecting tubes (18) and photovoltaic power generation board (22) are located toughened glass cover (17), the solar vacuum heat collecting tube (18) comprises an outer glass tube (51) and an inner glass tube (50), the outer glass tube (51) is sleeved on the inner glass tube (50), the outer glass tube (51) and the inner glass tube (50) are vacuumized, a light energy absorbing film (49) is covered and sleeved outside the inner glass tube (50), the outer glass tube (51) is made of a high-light-transmission non-reflective material, a vacuum heat collecting tube interface (20) is fixedly installed outside the solar vacuum heat collecting tube (18), the heat collecting tube vacuum interface (20) is communicated with a vacuum part in the solar vacuum heat collecting tube (18), each heat collecting tube vacuum interface (20) is fixedly connected and communicated with each other through a heat collecting tube connecting tube (21), a battery bin (28) is arranged in the base (27), a storage battery (29) is fixedly installed at the bottom of the inner side of the battery bin (28), a water pump (35) is fixedly installed at the left side of the base (27, the water outlet end of the water pump (35) is communicated with the internal water inlet end of the inner glass tube (50) through a second water inlet tube (5), the controller (36) is fixedly arranged on the left side of the top of the base (27), the water tank (2) comprises a water storage tank body (44), one end of a uniform temperature partition plate (42) is fixedly arranged on the inner wall on the left side of the water storage tank body (44), the other end of the uniform temperature partition plate (42) is fixedly arranged on the inner wall on the right side of the water storage tank body (44), the inner space of the water storage tank body (44) above the uniform temperature partition plate (42) is arranged into a water storage cavity (46), the inner space of the water storage tank body (44) below the uniform temperature partition plate (42) is arranged into a heating cavity (48), a water inlet (45) is arranged at the top of the water storage tank body (44), an electric heater (41) is, and are connected in series through a wire (40), the water inlet end of the water pump (35) is communicated with the inside of the water storage cavity (46) through a first water inlet pipe (4), the water outlet end inside the inner glass tube (50) is communicated with the inside of the water storage cavity (46) through a water outlet pipe (6), and hot water using equipment (3) is arranged on the left side of the water tank (2).

2. The intelligent solar photovoltaic power generation-based hot water supply station as claimed in claim 1, wherein a support leg (43) is fixedly installed at the bottom of the water tank body (44).

3. The intelligent solar photovoltaic power generation-based hot water supply station according to claim 1, it is characterized in that the hot water using equipment (3) comprises a cold water inlet pipe (12) and a hot water inlet pipe (13), the water inlet end of the hot water inlet pipe (13) is communicated with the interior of the water storage cavity (46), the water outlet end of the hot water inlet pipe (13) is fixedly connected and communicated with the water outlet end of the cold water inlet pipe (12), a mixed water pipe (8) is fixedly communicated with the bottom of the joint, a water temperature meter (9) is arranged in the mixed water pipe (8), a water temperature display (10) is fixedly arranged on the mixed water pipe (8), a water outlet (11) is arranged at the bottom of the mixed water pipe (8), the mixing water pipe (8) is internally and longitudinally penetrated and fixedly provided with a uniform temperature plate (15), and a uniform temperature cavity is arranged in the uniform temperature plate (15) and is communicated with the inside of the mixing water pipe (8).

4. the intelligent solar photovoltaic power generation-based hot water supply station according to claim 3, wherein a cold water throttle valve (7) is arranged on the cold water inlet pipe (12), and a hot water throttle valve (14) is arranged on the hot water inlet pipe (13).

5. The intelligent solar photovoltaic power generation-based hot water supply station as claimed in claim 1, wherein an evacuating device (23) is fixedly mounted at the bottom of the bottom plate (39), and the evacuating device (23) is communicated with a vacuum part in the solar evacuated collector tube (18) through a connecting tube.

6. The intelligent solar-photovoltaic-power-generation-based hot water supply station as claimed in claim 1, wherein a control input end of the controller (36) is electrically connected with the light sensor (16), and a control output end of the controller (36) is electrically connected with the rotating motor (26).

7. The intelligent solar photovoltaic power generation-based hot water supply station as claimed in claim 1, wherein one end of a buffer spring is fixedly mounted on both sides of the bracket (24), and the other end of the buffer spring is fixedly mounted at the bottom of the inner side of the arc-shaped groove (34).

8. The intelligent solar photovoltaic power generation-based hot water supply station as claimed in claim 1, wherein two torsion springs (47) are sleeved on the rotating shaft (37), and the torsion springs (47) are respectively arranged between the inner front surface and the inner rear surface of the bracket (24) and the arc-shaped groove (34).