CN114525946A

CN114525946A - Green energy-saving ecological building structure

Info

Publication number: CN114525946A
Application number: CN202210075226.2A
Authority: CN
Inventors: 张玉琼; 毛开平
Original assignee: Sichuan Ruiyun Construction Engineering Co ltd
Current assignee: Sichuan Ruiyun Construction Engineering Co ltd
Priority date: 2022-01-22
Filing date: 2022-01-22
Publication date: 2022-05-24

Abstract

The utility model relates to a green energy-conserving ecological building structure, it includes wall body and storage water tank, the intercommunication has inlet tube and outlet pipe on the storage water tank, the inlet tube is used for communicateing domestic water source, the intercommunication has heating water tank on the outlet pipe, be provided with the heating element who is used for carrying out the heating to heating water tank water-logging on the heating water tank, the intercommunication has first aqueduct on the heating water tank, the embedded heat-conducting plate that is equipped with of wall body, the inside of heat-conducting plate is provided with the water storage chamber, set up the water inlet with water storage chamber intercommunication on the heat-conducting plate, first aqueduct and water inlet intercommunication, the water storage chamber of heat-conducting plate still communicates there is the drain pipe, the roof that the drain pipe is close to the wall body with the heat-conducting plate intercommunication end. The application has the effect of improving the health and safety of people when living.

Description

Green energy-saving ecological building structure

Technical Field

The application relates to the technical field of building construction, in particular to a green energy-saving ecological building structure.

Background

The green building refers to a building capable of achieving energy conservation and emission reduction; the green building emphasizes the ecological and sustainable design concept, the whole building has the minimum influence on the environment in the life cycle through creative structure and use design, and the purpose of saving resources is achieved, so that harmonious symbiosis between people and nature is realized to the maximum extent.

At present, most building walls on the market are built by reinforced concrete and bricks, the heat insulation capability of the walls is poor, and in a cold environment in winter, the reinforced concrete, the cement and the bricks dissipate heat in a room to reduce the indoor temperature; therefore, in winter or in cold days, the room temperature is usually adjusted by an air conditioner, so that people feel more comfortable when living.

However, when the air conditioner is in use, a large amount of bacteria and microorganisms are easily deposited and attached to the air outlet of the air conditioner, and the bacteria and microorganisms are rapidly spread and spread to the whole building through the air conditioner, thereby seriously affecting the health safety of people.

Disclosure of Invention

In order to improve the health and safety of people when living, the application provides a green energy-saving ecological building structure.

The application provides a green energy-conserving ecological building structure adopts following technical scheme:

the utility model provides a green energy-conserving ecological building structure, includes wall body and storage water tank, the intercommunication has inlet tube and outlet pipe on the storage water tank, the inlet tube is used for communicateing domestic water source, the intercommunication has heating water tank on the outlet pipe, the last heating element who is used for heating the heating water tank water that is provided with of heating water tank, the intercommunication has first aqueduct on the heating water tank, the embedded heat-conducting plate that is equipped with of wall body, the inside of heat-conducting plate is provided with the water storage chamber, set up the water inlet with water storage chamber intercommunication on the heat-conducting plate, first aqueduct and water inlet intercommunication, the water storage chamber of heat-conducting plate still communicates there is the drain pipe, the roof that the drain pipe is close to the wall body with the intercommunication end of heat-conducting plate.

By adopting the technical scheme, water is guided into the water storage tank through the water inlet pipe, when heat supply is needed to be carried out indoors, the water in the water storage tank is guided into the heating water tank through the water outlet pipe, the water in the heating water tank is heated by the heating assembly, the heated water is guided into the water storage cavity of the heat conducting plate through the first water guide pipe, the heat is transferred to the wall body through the heat conducting plate, so that heat supply is carried out indoors, and then the water is discharged through the water discharge pipe, so that heat supply is continuously carried out indoors; when people live in the room, the room can be heated without an air conditioner, so that the health and safety of the people during the living are greatly improved.

Optionally, the first water guide pipe is detachably connected with the heat conducting plate, and a first connecting piece used for connecting the first water guide pipe or the drain pipe is arranged at the water inlet.

By adopting the technical scheme, the first water guide pipe is connected with the water inlet on one of the wall bodies through the first connecting piece, and the drain pipe of the wall body is connected with the water inlet of the next-level wall body, so that one heating water tank supplies heat to a plurality of wall bodies simultaneously, the indoor heat supply effect of the wall bodies is greatly improved, and the cost is saved.

Optionally, the first connecting piece includes an installation sleeve, the water inlet is worn to locate by installation sleeve's one end and rotates with the heat-conducting plate to be connected, the installation sleeve is last and has been located the lateral wall in the water inlet outside and seted up the external screw thread, the internal thread with the installation sleeve on external screw thread looks adaptation is all seted up to the inner wall of first aqueduct and drain pipe.

Through adopting above-mentioned technical scheme, when being connected the drain pipe of heat-conducting plate and first aqueduct or last one-level wall body, make the installation sleeve insert in first aqueduct or the drain pipe, rotate the installation sleeve, make the installation sleeve cooperate with the internal thread on first aqueduct or the drain pipe to connect first aqueduct or drain pipe.

Optionally, the water storage tank is further communicated with a second water guide pipe, a second connecting piece for connecting a drain pipe is arranged on the second water guide pipe, and a water suction pump for pumping water in the water storage cavity to the water storage tank is arranged on the second water guide pipe.

Through adopting above-mentioned technical scheme, be connected drain pipe and storage water tank through the second aqueduct, in the exhaust water in the drain pipe was pumped back the storage water tank through the suction pump, realized hydrologic cycle, improved the utilization ratio of water greatly.

Optionally, the heating assembly comprises a heating pipe, a storage battery and a solar panel, the heating pipe is arranged in the heating water tank, the storage battery is connected with the heating pipe, and the solar panel is connected with the storage battery.

Through adopting above-mentioned technical scheme, convert solar energy into the electric energy through solar panel to store in the battery, when needs are to indoor heat supply, with the leading-in heating water tank of water in, the circular telegram of heating pipe through the battery, thereby heat the water in the heating water tank.

Optionally, the inlet tube intercommunication has the shunt tubes, the shunt tubes intercommunication has the cistern, the open-top setting of cistern, be provided with the drainage spare that is used for filtering aquatic impurity in the cistern.

Through adopting above-mentioned technical scheme, collect the rainwater through the cistern, the rainwater that gets into the cistern leads to and filters water spare, later, gets into in the inlet tube through the shunt tubes, carries to the storage water tank in by the inlet tube again, improves the utilization to the water resource.

Optionally, the water filtering piece comprises a water filtering cylinder, a partition plate is fixedly arranged in the reservoir, the water filtering cylinder penetrates through the partition plate, a first clamping plate is fixedly arranged at one end, close to the top wall of the reservoir, of the water filtering cylinder, a second clamping plate is fixedly arranged at one end, close to the bottom wall of the reservoir, of the water filtering cylinder, water filtering holes are formed in the first clamping plate and the second clamping plate, and water filtering cotton is arranged between the first clamping plate and the second clamping plate; the communication end of shunt tubes and the reservoir is positioned on one side of the partition board close to the bottom wall of the reservoir.

By adopting the technical scheme, rainwater entering the reservoir is gathered on the partition plate and then enters the water filtering cylinder through the water filtering holes in the first clamping plate, and the rainwater is filtered through the water filtering cotton in the water filtering cylinder; then, the filtered rainwater enters the lower part of the clapboard through the water filtering holes on the second clamping plate and is guided into the water inlet pipe through the flow dividing pipe.

Optionally, the first clamping plate is detachably connected with the water filtering cylinder, and a fixing piece for fixing the first clamping plate is arranged on the water filtering cylinder.

Through adopting above-mentioned technical scheme, the drainage cotton in the water filtering section of thick bamboo takes place dirty after using a period easily, through loosening the mounting, dismantles first splint from the water filtering section of thick bamboo, and the drainage cotton in the section of thick bamboo that can filter is changed, has improved the practicality greatly.

Optionally, the fixed block that is provided with in the shunt tube, the limbers has been seted up on the fixed block, one side that the cistern was kept away from to the shunt tube and be located the fixed block slides along the direction of being close to or keeping away from the fixed block and is provided with and keeps off the flow board, it is used for the shutoff limbers to keep off the flow board, be provided with on the fixed block and be used for ordering about and keep off the gliding elastic component of flow board to being close to the fixed block direction.

By adopting the technical scheme, rainwater entering the flow dividing plate through the reservoir forms certain pressure on the flow blocking plate and pushes the flow blocking plate to slide in the direction away from the fixed block, so that the water through hole is opened, and then water flows into the water inlet pipe through the gap between the flow blocking plate and the inner wall of the flow dividing plate; when no water flows through the flow dividing pipe, the flow blocking plate slides towards the direction close to the fixed block under the driving of the elasticity of the elastic part, and the water through hole in the fixed block is blocked, so that the water in the water storage tank is prevented from flowing back into the water storage tank to a certain extent.

Optionally, a cavity is formed in the wall body and located on one side, close to the outdoor side, of the water storage cavity, and heat insulation cotton is arranged in the cavity.

By adopting the technical scheme, the temperature on the heat conducting plate is placed to a certain extent through the heat insulation cotton and is transferred to the outdoor, and the heat is exchanged with the outdoor cold air, so that the heat loss is caused.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the water is guided into the water storage tank through the water inlet pipe, when heat supply needs to be carried out indoors, the water in the water storage tank is guided into the heating water tank through the water outlet pipe, the water in the heating water tank is heated through the heating assembly, the heated water is guided into the water storage cavity of the heat conducting plate through the first water guide pipe, the heat is transferred to the wall body through the heat conducting plate, heat supply is carried out indoors, and then the water is discharged through the water discharge pipe, so that heat supply is continuously carried out indoors; when people live in the room, the room can be heated without an air conditioner, so that the health and safety of the people during the live in the room are greatly improved;

2. the first water guide pipe is connected with the water inlet on one wall body through the first connecting piece, and the water discharge pipe of the wall body is connected with the water inlet of the next-stage wall body, so that one heating water tank can supply heat to a plurality of wall bodies simultaneously, the indoor heat supply effect of the wall bodies is greatly improved, and the cost is saved;

3. rainwater is collected through the water storage tank, the rainwater entering the water storage tank is gathered on the partition plate, then enters the water filtering cylinder through the water filtering holes in the first clamping plate, and is filtered through the water filtering cotton in the water filtering cylinder; then, filtered rainwater enters the lower part of the partition plate through the water filtering holes in the second clamping plate, is guided into the water inlet pipe through the flow dividing pipe, and is conveyed into the water storage tank through the water inlet pipe, so that the utilization of water resources is improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present application;

FIG. 2 is a partial schematic structural diagram of an embodiment of the present application, which is mainly used for expressing a connection relationship between a water reservoir and a water storage tank;

FIG. 3 is an enlarged view of portion A of FIG. 2;

fig. 4 is a partial structural schematic diagram of an embodiment of the present application, which is mainly used for expressing the structural schematic diagram of a water filtering cylinder;

FIG. 5 is a partial schematic structural view of an embodiment of the present application, which is mainly used for expressing a schematic structural view of a heating assembly;

fig. 6 is a partial schematic structural diagram of an embodiment of the present application, which is mainly used for expressing a structural diagram of a wall.

Description of reference numerals: 1. a wall body; 11. a frame column; 12. a roof; 121. mounting grooves; 13. a heat conducting plate; 131. a water storage cavity; 132. a water inlet; 133. a drain pipe; 134. installing a sleeve; 14. a cavity; 15. heat preservation cotton; 2. a water storage tank; 21. a water inlet pipe; 211. a shunt tube; 22. a water outlet pipe; 23. a second water conduit; 231. a water pump; 232. connecting a sleeve; 233. a third water conduit; 234. a diverter valve; 3. a reservoir; 31. a partition plate; 4. heating the water tank; 41. a first water conduit; 5. a heating assembly; 51. heating a tube; 52. a storage battery; 53. a solar panel; 6. a fixed block; 61. a water through hole; 62. a flow baffle plate; 621. a connecting rod; 6211. a limiting block; 63. an elastic member; 64. connecting grooves; 65. a limiting groove; 7. a water filtration cartridge; 71. a containing groove; 72. a first splint; 73. a fixing member; 74. a second splint; 75. water filtering holes; 76. and (5) draining the cotton.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses green energy-saving ecological building structure. Referring to fig. 1 and 2, including wall body 1, set up in the frame post 11 of wall body 1 both sides and set up in the roof 12 at wall body 1 and frame post 11 top, fixed storage water tank 2 and the cistern 3 of being provided with on the roof of roof 12, the fixed heating water tank 4 that is provided with on the lateral wall of roof 12, the roof opening setting of cistern 3, be provided with the water filtering piece that is used for filtering aquatic impurity in the cistern 3, storage water tank 2 respectively with cistern 3 and heating water tank 4, be provided with on the heating water tank 4 and be used for carrying out the heating element 5 that heats to heating water tank 4 water.

Referring to fig. 2, on the roof 12 and be located the bottom of cistern 3 and seted up mounting groove 121, the lateral wall intercommunication of storage water tank 2 has inlet tube 21, inlet tube 21 is located mounting groove 121, inlet tube 21 be used for with domestic water source intercommunication, the intercommunication has shunt tubes 211 on the lateral wall of inlet tube 21, shunt tubes 211 and the diapire intercommunication of cistern 3.

Referring to fig. 2 and 3, the dividing tube 211 is internally and fixedly provided with a fixing block 6, the fixing block 6 is provided with a water passage hole 61, a flow blocking plate 62 is arranged in the dividing tube 211 and positioned at one side of the fixing block 6 far away from the water reservoir 3 in a sliding manner along a direction close to or far away from the fixing block 6, the flow blocking plate 62 and the inner wall of the dividing tube 211 are arranged at intervals, the flow blocking plate 62 is used for blocking the water passage hole 61, and the fixing block 6 is provided with an elastic member 63 for driving the flow blocking plate 62 to slide towards the direction close to the fixing block 6.

Referring to fig. 3, a connecting rod 621 is fixedly disposed at one end of the flow blocking plate 62 close to the fixing block 6, a connecting groove 64 is disposed at one end of the fixing block 6 close to the flow blocking plate 62 along a sliding direction of the flow blocking plate 62, the connecting rod 621 is slidably disposed in the connecting groove 64, a limiting block 6211 is fixedly disposed on a side wall of the connecting rod 621, a limiting groove 65 is disposed on a side wall of the connecting groove 64 along the sliding direction of the connecting rod 621, and the limiting block 6211 is slidably disposed in the limiting groove 65; the elastic member 63 includes a tension spring, the tension spring is disposed in the connecting groove 64, one end of the tension spring is fixedly connected to the bottom wall of the connecting groove 64, and the other end of the tension spring is fixedly connected to the connecting rod 621.

Rainwater entering the flow dividing plate through the water storage tank 3 forms certain pressure on the flow blocking plate 62 and pushes the flow blocking plate 62 to slide towards the direction far away from the fixing block 6, so that the water through hole 61 is opened, and then water flows into the water inlet pipe 21 through a gap between the flow blocking plate 62 and the inner wall of the flow dividing pipe 211; when no water flows through the dividing pipe 211, the flow blocking plate 62 is driven by the elasticity of the tension spring to slide towards the direction close to the fixing block 6 and block the water through hole 61 on the fixing block 6, so that the water in the water storage tank 2 is prevented from flowing back into the water storage tank 3 to a certain extent.

Referring to fig. 2 and 4, the water filtering element includes a water filtering cylinder 7, a partition plate 31 is fixedly arranged in the reservoir 3, the partition plate 31 is horizontally arranged, the water filtering cylinder 7 penetrates through the partition plate 31 and is fixedly connected with the partition plate 31, the axial direction of the water filtering cylinder 7 is perpendicular to the partition plate 31, the top end of the water filtering cylinder 7 is flush with the top end of the partition plate 31, and the communication end of the flow dividing pipe 211 and the reservoir 3 is positioned below the partition plate 31; the top of a section of thick bamboo 7 of straining is seted up along the axial of a section of thick bamboo 7 of straining and is offered the storage tank 71 with the inside intercommunication of a section of thick bamboo 7 of straining, is provided with first splint 72 in the storage tank 71, is provided with the mounting 73 that is used for fixed first splint 72 on the section of thick bamboo 7 of straining, and mounting 73 includes the bolt, and first splint 72 passes through the bolt to be fixed with a section of thick bamboo 7 of straining, and the bottom mounting of a section of thick bamboo 7 of straining is provided with second splint 74, has all seted up drainage hole 75 on first splint 72 and the second splint 74, is provided with the drainage cotton 76 between first splint 72 and the second splint 74.

Rainwater entering the reservoir 3 is gathered on the partition plate 31 and then enters the water filtering cylinder 7 through the water filtering holes 75 on the first clamping plate 72, and the rainwater is filtered through the water filtering cotton 76 in the water filtering cylinder 7; then, the filtered rainwater enters the lower part of the partition plate 31 through the water filtering holes 75 on the second clamping plate 74 and is guided into the water inlet pipe 21 through the shunt pipe 211; moreover, the first clamping plate 72 is detached from the water filtering cylinder 7 by loosening the fixing bolt, and the water filtering cotton 76 in the water filtering cylinder 7 can be replaced, so that the practicability is greatly improved.

Referring to fig. 5, the side wall of the water storage tank 2 is communicated with a water outlet pipe 22, the water outlet pipe 22 is communicated with the top wall of the heating water tank 4, the heating component 5 comprises a heating pipe 51, a storage battery 52 and a solar panel 53, the heating pipe 51 is fixedly arranged in the heating water tank 4, the storage battery 52 is fixedly arranged on the top wall of the water storage tank 2, the storage battery 52 is connected with the heating pipe 51, the top wall of the water storage tank 2 is fixedly provided with a support frame, the solar panel 53 is fixedly arranged on the support frame, and the solar panel 53 is connected with the storage battery 52; solar energy is converted into electric energy by the solar panel 53 and stored in the storage battery 52, and when heat supply to the indoor is required, water is introduced into the heating water tank 4, and the heating pipe 51 is electrified by the storage battery 52, so that the water in the heating water tank 4 is heated.

Referring to fig. 5 and 6, the side wall of the heating water tank 4 is communicated with a first water conduit 41, the wall body 1 is embedded with a heat conducting plate 13, the heat conducting plate 13 is made of metal, a water storage cavity 131 is arranged inside the heat conducting plate 13, a water inlet 132 communicated with the water storage cavity 131 is arranged on the side wall of the heat conducting plate 13 close to the top end, and a first connecting piece used for connecting the first water conduit 41 is arranged at the water inlet 132; the side wall of the heat conducting plate 13 far away from the water inlet 132 is further communicated with a drain pipe 133, the drain pipe 133 extends to the bottom of the water storage cavity 131, the top wall of the water storage cavity 2 is further communicated with a second water guide pipe 23, a second connecting piece for connecting the drain pipe 133 is arranged on the second water guide pipe 23, and a water suction pump 231 for pumping water in the water storage cavity 131 to the water storage cavity 2 is arranged on the second water guide pipe 23.

The heated water is guided into the water storage cavity 131 of the heat conducting plate 13 through the first water guide pipe 41, and then the heat conducting plate 13 transfers the heat to the wall body 1, so as to supply heat to the indoor space, and then the water is discharged through the water discharge pipe 133 and is pumped back into the water storage tank 2 through the water suction pump 231, so that the water circulation is realized, and the water utilization rate is greatly improved.

Referring to fig. 6, a cavity 14 is formed in the wall 1 and located on one side of the water storage cavity 131 close to the outdoor side, and heat insulation cotton 15 is arranged in the cavity 14; the temperature on the heat conducting plate 13 is transferred to the outdoor through the heat insulation cotton 15 to a certain extent, and forms heat exchange with the outdoor cold air, so that heat loss is caused.

Referring to fig. 6, the first connecting member includes a mounting sleeve 134, one end of the mounting sleeve 134 penetrates through the water inlet 132 and is rotatably connected with the heat conducting plate 13, an annular block is fixedly disposed on a side wall of the mounting sleeve 134, an annular groove communicated with the water inlet 132 is formed in a side wall of the water inlet 132, the annular block is rotatably disposed in the annular groove, an external thread is formed on a side wall of the mounting sleeve 134, which is located outside the water inlet 132, and an internal thread matched with the external thread on the mounting sleeve 134 is formed on an inner wall of the first water guiding pipe 41, which is away from the heating water tank 4; when the heat transfer plate 13 is connected to the first water introduction pipe 41, the installation sleeve 134 is inserted into the first water introduction pipe 41, and the installation sleeve 134 is rotated to fit the installation sleeve 134 with the internal thread of the first water introduction pipe 41, thereby connecting the first water introduction pipe 41 to the water inlet 132.

Referring to fig. 6, the outlet end of the drain pipe 133 is at the same level as the mounting sleeve 134, the inner wall of the drain pipe 133, which is far away from the heat-conducting plate 13, is also provided with an internal thread matched with the external thread on the mounting sleeve 134, the frame column 11 is provided with a caulking groove, the drain pipe 133 is arranged in the caulking groove in a penetrating manner, and the drain pipe 133 of the wall body 1 is connected with the water inlet 132 of the next-level wall body 1 through the mounting sleeve 134, so that one heating water tank 4 supplies heat to a plurality of wall bodies 1 at the same time, the indoor heat supply effect of the wall body 1 is greatly improved, and the cost is saved.

Referring to fig. 6, the second connecting member includes a connecting sleeve 232, the connecting sleeve 232 is coaxially and rotatably connected with one end of the second water guiding pipe 23 far away from the water storage tank 2, and an external thread adapted to the internal thread of the water discharging pipe 133 is disposed on a side wall of the connecting sleeve 232 located outside the second water guiding pipe 23; the second water introduction pipe 23 is connected to the water discharge pipe 133 by a connection sleeve 232, so that the water discharge pipe 133 communicates with the water storage tank 2.

Referring to fig. 6, a third water guide pipe 233 is communicated with one side of the second water guide pipe 23, which is located on the side of the water suction pump 231 away from the water discharge pipe 133, the third water guide pipe 233 is communicated with a drainage system in a house, a reversing valve 234 for communicating the third water guide pipe 233 is arranged on the second water guide pipe 23, when the second water guide pipe 23 is communicated with the third water guide pipe 233, a path from the second water guide pipe 23 to the water storage tank 2 is closed through the reversing valve 234, and the water suction pump 231 is started to guide the water in the water storage cavity 131 into the drainage system of the house through the third water guide pipe 233, so that the water in the water storage cavity 131 is replaced; in summer, the water in the water storage cavity 131 is completely pumped out through the water pump 231, and the heat insulation effect of the wall body 1 can be improved.

The implementation principle of the green energy-saving ecological building structure in the embodiment of the application is as follows: through the inlet tube 21 with the leading-in storage water tank 2 of water, when needs heat to indoor, through outlet pipe 22 with the leading-in heating water tank 4 of water in the storage water tank 2 in, through battery 52 to heating pipe 51 circular telegram, heat the water in the heating water tank 4, through the leading-in water storage chamber 131 of first aqueduct 41 of the water after the heating, give wall body 1 with heat transfer by heat-conducting plate 13 again to heat supply indoor.

When the temperature of the water in the water storage cavity 131 is reduced to a certain degree, the water in the water storage cavity 131 is discharged through the water discharge pipe 133 by turning on the water suction pump 231 and is guided back into the water storage tank 2 again through the second water guide pipe 23, so that heat supply is continuously performed indoors; when people live in the room, the room can be heated without an air conditioner, so that the health and safety of the people during the living are greatly improved.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. The utility model provides a green energy-conserving ecological building structure which characterized in that: comprises a wall body (1) and a water storage tank (2), wherein the water storage tank (2) is communicated with a water inlet pipe (21) and a water outlet pipe (22), the water inlet pipe (21) is used for being communicated with a domestic water source, the water outlet pipe (22) is communicated with a heating water tank (4), the heating water tank (4) is provided with a heating component (5) for heating the water in the heating water tank (4), a first water guide pipe (41) is communicated with the heating water tank (4), a heat conducting plate (13) is embedded in the wall body (1), a water storage cavity (131) is arranged inside the heat conducting plate (13), a water inlet (132) communicated with the water storage cavity (131) is arranged on the heat conducting plate (13), the first water guide pipe (41) is communicated with the water inlet (132), the water storage cavity (131) of the heat conduction plate (13) is also communicated with a drain pipe (133), the communication end of the drain pipe (133) and the heat conducting plate (13) is close to the top wall of the wall body (1).

2. The green energy-saving ecological building structure according to claim 1, characterized in that: the first water guide pipe (41) is detachably connected with the heat conducting plate (13), and a first connecting piece used for connecting the first water guide pipe (41) or the drain pipe (133) is arranged at the water inlet (132).

3. The green energy-saving ecological building structure according to claim 2, characterized in that: first connecting piece includes installation sleeve pipe (134), the one end of installation sleeve pipe (134) is worn to locate water inlet (132) and is rotated with heat-conducting plate (13) and is connected, the external screw thread has been seted up on installation sleeve pipe (134) and on being located the lateral wall in the water inlet (132) outside, the internal thread with external screw thread looks adaptation on installation sleeve pipe (134) is all seted up to the inner wall of first aqueduct (41) and drain pipe (133).

4. The green energy-saving ecological building structure according to claim 1, characterized in that: the water storage tank (2) is further communicated with a second water guide pipe (23), a second connecting piece used for being connected with a water discharge pipe (133) is arranged on the second water guide pipe (23), and a water suction pump (231) used for pumping water in the water storage cavity (131) to the water storage tank (2) is arranged on the second water guide pipe (23).

5. The green energy-saving ecological building structure according to claim 1, characterized in that: heating element (5) include heating pipe (51), battery (52) and solar panel (53), heating pipe (51) set up in heating water tank (4), battery (52) are connected with heating pipe (51), solar panel (53) are connected with battery (52).

6. The green energy-saving ecological building structure according to claim 1, characterized in that: inlet tube (21) intercommunication has shunt tubes (211), shunt tubes (211) intercommunication has cistern (3), the open-top setting of cistern (3), be provided with the drainage spare that is used for filtering aquatic impurity in cistern (3).

7. The green energy-saving ecological building structure according to claim 6, characterized in that: the water filtering piece comprises a water filtering cylinder (7), a partition plate (31) is fixedly arranged in the water storage tank (3), the water filtering cylinder (7) penetrates through the partition plate (31), a first clamping plate (72) is fixedly arranged at one end, close to the top wall of the water storage tank (3), of the water filtering cylinder (7), a second clamping plate (74) is fixedly arranged at one end, close to the bottom wall of the water storage tank (3), of the water filtering cylinder (7), water filtering holes (75) are formed in the first clamping plate (72) and the second clamping plate (74), and water filtering cotton (76) is arranged between the first clamping plate (72) and the second clamping plate (74); the communication end of the shunt pipe (211) and the water reservoir (3) is positioned on one side of the partition plate (31) close to the bottom wall of the water reservoir (3).

8. The green energy-saving ecological building structure according to claim 7, characterized in that: the first clamping plate (72) is detachably connected with the water filtering cylinder (7), and a fixing piece (73) used for fixing the first clamping plate (72) is arranged on the water filtering cylinder (7).

9. The green energy-saving ecological building structure according to claim 6, characterized in that: shunt tubes (211) internal fixation is provided with fixed block (6), limbers (61) have been seted up on fixed block (6), one side that the cistern (3) was kept away from in shunt tubes (211) and being located fixed block (6) is slided along the direction of being close to or keeping away from fixed block (6) and is provided with and keeps off and flow board (62), it is used for shutoff limbers (61) to keep off and flow board (62) to being close to gliding elastic component (63) of fixed block (6) direction to be provided with on fixed block (6) and be used for ordering about to keep off and flow board (62).

10. The green energy-saving ecological building structure according to claim 1, characterized in that: a cavity (14) is formed in one side, close to the outdoor, of the water storage cavity (131) in the wall body (1), and heat insulation cotton (15) is arranged in the cavity (14).