CN216380032U

CN216380032U - Assembled constant temperature energy-saving building

Info

Publication number: CN216380032U
Application number: CN202123096735.3U
Authority: CN
Inventors: 赵侠; 文云清; 田康; 姚康龙; 王建瑞; 李之瑞
Original assignee: Shanxi Cihe Xinneng Integrated Construction Technology Co ltd
Current assignee: Shanxi Cihe Xinneng Integrated Construction Technology Co ltd
Priority date: 2021-12-10
Filing date: 2021-12-10
Publication date: 2022-04-26
Anticipated expiration: 2031-12-10

Abstract

The utility model discloses an assembled constant-temperature energy-saving building which comprises a building body, wherein an arc-shaped heat insulation top is fixedly installed at the top of the building body, an air circulation buffer mechanism is fixedly installed inside the building body, a plurality of light intensity monitoring mechanisms are fixedly installed on the surface side wall of the arc-shaped heat insulation top, a solar panel sliding groove is further formed in the side wall of the arc-shaped heat insulation top, and an arc-shaped solar panel is movably sleeved on the inner side of the solar panel sliding groove. According to the utility model, the light intensity at each position of the top of the arc-shaped heat insulation top can be monitored by the light intensity monitoring mechanism, the power-on and rotation directions of the first driving motor are controlled at the same time, the first driving gear is driven to rotate while the first driving gear is driven to rotate along the surface of the arc-shaped outer gear ring, the arc-shaped solar panel is driven to slide along the surface of the solar panel sliding groove by the solar panel driving shaft, so that the arc-shaped solar panel is always in a good illumination angle, and the light energy absorption rate and the conversion rate of the arc-shaped solar panel are improved.

Description

Assembled constant temperature energy-saving building

Technical Field

The utility model relates to the technical field of building design, in particular to an assembled constant-temperature energy-saving building.

Background

The assembly type building is a building which is formed by transferring a large amount of field operation work in the traditional building mode to a factory, processing and manufacturing building components and accessories such as floor slabs, wall plates, stairs, balconies and the like in the factory, transporting the components and the accessories to a building construction site, and assembling and installing the components and the accessories on the site in a reliable connection mode, wherein the assembly type building is started to arouse the interest of people at the beginning of the 20 th century and is realized in the end of the sixties; the first attempt made in English, French, Soviet Union and other countries is rapidly promoted worldwide due to the rapid construction speed and low production cost of the fabricated building.

However, the implementation and utilization of the existing assembly type building are still not popular enough, the assembly type building is mainly used in regions, assembly can be completed without excessive labor force, the traditional assembly type building is light in material, and therefore good heat preservation effect is difficult to achieve.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects in the prior art and provides an assembled constant-temperature energy-saving building.

In order to achieve the purpose, the utility model adopts the following technical scheme:

an assembled constant-temperature energy-saving building comprises a building body, wherein an arc-shaped heat insulation top is fixedly arranged at the top of the building body, an air circulation buffer mechanism is fixedly arranged in the building body, a plurality of light intensity monitoring mechanisms are fixedly arranged on the surface side wall of the arc-shaped heat insulation top, the side wall of the arc-shaped heat insulation top is also provided with a solar panel sliding groove, the inner side of the solar panel sliding groove is movably sleeved with an arc-shaped solar panel, the two sides of the arc-shaped heat insulation top are also symmetrically provided with internal gas circulation channel devices, the inner side of the arc-shaped heat insulation top is fixedly provided with an arc-shaped outer gear ring, the inner side of the arc-shaped heat insulation top is also fixedly provided with a motor chute channel, the side surface of the arc-shaped solar panel is fixedly sleeved with a solar panel driving shaft through a bearing, and the solar panel driving shaft extends to the inside of the arc-shaped heat insulation top, and an arc-shaped groove matched with the diameter of the solar panel driving shaft is further formed in the inside of the arc-shaped heat insulation top.

Preferably, the activity of solar panel drive shaft cup joint in the inside wall of arc wall, the fixed cover of lateral wall of solar panel drive shaft has been cup jointed a drive gear, just a drive gear with the outer ring gear of arc meshes mutually, a driving motor has been cup jointed in the inboard activity of motor spout passageway, just a driving motor's output shaft with the top end of solar panel drive shaft is fixed to be cup jointed.

Preferably, the inside gas circulation passageway device includes the business turn over gas access entrance, the business turn over gas access entrance symmetry is seted up in the side on arc heat insulation top, the other end of business turn over gas access entrance is connected with the water conservancy diversion pipeline, the lateral wall of water conservancy diversion pipeline has cup jointed the connecting rod through sealed rolling bearing activity fixed, the connecting rod extends to the inboard of water conservancy diversion pipeline just the equal symmetry fixed mounting in both ends of connecting rod has the water conservancy diversion flabellum, the inboard on arc heat insulation top still fixed mounting has supplementary stand-by motor, the top fixed mounting of building body has thermal-insulated plywood.

Preferably, the output end of the auxiliary standby motor is fixedly sleeved with a second transmission gear, a third transmission gear is fixedly mounted on the surface side wall of the connecting rod, and the second transmission gear is meshed with the third transmission gear.

Preferably, the fixed cover in end of water conservancy diversion pipeline has connect into the pipeline of giving vent to anger, the bottom of the pipeline of giving vent to anger with air cycle buffer gear's inner chamber is linked together, air cycle buffer gear's inboard fixed mounting has a plurality of groups electric heat silk screen, the air channel has been seted up to air cycle buffer gear's bottom, just the bottom of air channel is fixed mounting still has switch grid window.

Preferably, the inner side wall of the switch grille window is fixedly sleeved with a grille rotating shaft through a bearing, and the side wall of the grille rotating shaft is fixedly sleeved with a fourth transmission gear and an adjusting grille.

Preferably, the grid axis of rotation, fourth drive gear with adjust the grid align to grid distribute in the inside wall of switch grid window, just the meshing has fifth drive gear between the fourth drive gear, fifth drive gear through rotatable axle fixed cup joint in the inside of switch grid window, the side fixed mounting of switch grid window has second driving motor, second driving motor's output shaft activity cup joint with the top grid axis of rotation is fixed cup joint mutually.

Preferably, the side surfaces of the building body are provided with heat insulation walls.

Compared with the prior art, the utility model has the beneficial effects that:

1. can monitor the thermal-insulated top of arc illumination intensity everywhere through light intensity monitoring mechanism, the circular telegram of the first driving motor of simultaneous control and rotation direction drive first transmission gear along the surperficial rotation of arc outer ring gear when driving first transmission gear rotation, drive the surperficial slip of arc solar panel along the solar panel spout through the solar panel drive shaft, make arc solar panel be in good illumination angle all the time, improve arc solar panel's light energy absorption rate and conversion rate.

2. The heat insulation wall arranged on the side surface of the building body, the arc-shaped heat insulation top fixedly arranged on the top of the building body and the heat insulation laminated plate can play a good heat insulation effect on the interior of the building body from various angles and directions;

air exchange is carried out inside the building body, external air can enter the diversion pipeline through the air inlet and outlet channel opening, and enters the building body through the air inlet and outlet pipeline, the electric heating wire mesh and the switch grid window, meanwhile, the electric heating wire mesh can be electrified and heated by electric energy generated by the arc-shaped solar panel, so that the air passing through the electric heating wire mesh is heated, meanwhile, the second driving motor can be controlled to rotate to drive the adjusting grid to rotate, the flow of the air entering the building body is adjusted, the interior of the building body is always in a good constant temperature state, and the living experience of a user can be effectively improved;

meanwhile, when air enters from the air inlet and outlet channel port, the guide fan blades are driven to rotate, meanwhile, the guide fan blades on the other side are driven to rotate through the connecting rod, meanwhile, the guide directions of the guide fan blades on the two sides are opposite, the guide fan blades on the other side can rotate to play a guide effect on the air inside the building body, meanwhile, an acceleration rotating effect can be played on the connecting rod through controlling the auxiliary standby motor, an air circulation effect in windless weather is guaranteed, the whole system does not need extra electric power, electric power and wind power driving are achieved through the arc-shaped solar panel, energy consumption is effectively saved, and living experience of a user is guaranteed.

Drawings

FIG. 1 is a schematic view of the overall structure of an assembled constant-temperature energy-saving building according to the present invention;

FIG. 2 is a schematic view of the internal structure of an arc-shaped heat-insulating roof of an assembled constant-temperature energy-saving building provided by the utility model;

FIG. 3 is a schematic structural view of an internal gas circulation passage device of an assembled constant-temperature energy-saving building according to the present invention;

FIG. 4 is a schematic structural diagram of an auxiliary standby motor of an assembled constant-temperature energy-saving building according to the present invention;

FIG. 5 is a schematic structural view of an air circulation buffer mechanism of an assembled constant-temperature energy-saving building according to the present invention;

fig. 6 is a schematic structural view of a switch grille window of an assembled constant-temperature energy-saving building according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-6, an assembled constant temperature energy-saving building comprises a building body 1, an arc-shaped heat insulation roof 2 is fixedly installed at the top of the building body 1, an air circulation buffer mechanism 6 is fixedly installed inside the building body 1, a plurality of light intensity monitoring mechanisms 25 are fixedly installed on the surface side wall of the arc-shaped heat insulation roof 2, a solar panel chute 3 is further formed in the side wall of the arc-shaped heat insulation roof 2, an arc-shaped solar panel 4 is movably sleeved on the inner side of the solar panel chute 3, internal gas circulation channel devices 5 are further symmetrically arranged on two sides of the arc-shaped heat insulation roof 2, an arc-shaped outer gear ring 21 is fixedly installed on the inner side of the arc-shaped heat insulation roof 2, a motor chute channel 26 is further fixedly installed on the inner side of the arc-shaped heat insulation roof 2, a solar panel driving shaft 41 is fixedly sleeved on the side of the arc-shaped solar panel 4 through a bearing, and the solar panel driving shaft 41 extends to the inside of the arc-shaped heat insulation roof 2, the inside of the arc-shaped heat insulation top 2 is also provided with an arc-shaped groove 22 matched with the diameter of the solar panel driving shaft 41.

As shown in fig. 2, the solar panel driving shaft 41 is movably sleeved on the inner side wall of the arc-shaped groove 22, the first transmission gear 23 is fixedly sleeved on the side wall of the solar panel driving shaft 41, the first transmission gear 23 is meshed with the arc-shaped outer gear ring 21, the first driving motor 24 is movably sleeved on the inner side of the motor chute channel 26, and the output shaft of the first driving motor 24 is fixedly sleeved on the top end of the solar panel driving shaft 41.

As shown in fig. 3, the internal gas circulation passage device 5 includes an inlet and outlet passage port 51, the inlet and outlet passage port 51 is symmetrically opened on the side surface of the arc-shaped heat insulation roof 2, the other end of the inlet and outlet passage port 51 is connected with a flow guide pipeline 52, the side wall of the flow guide pipeline 52 is movably and fixedly sleeved with a connecting rod 55 through a sealing rotary bearing, the connecting rod 55 extends to the inner side of the flow guide pipeline 52, and two ends of the connecting rod 55 are symmetrically and fixedly installed with flow guide fan blades 56, the inner side of the arc-shaped heat insulation roof 2 is also fixedly installed with an auxiliary standby motor 54, and the top end of the building body 1 is fixedly installed with a heat insulation layer plate 53.

As shown in fig. 4, a second transmission gear 57 is fixedly sleeved on an output end of the auxiliary standby motor 54, a third transmission gear 58 is fixedly installed on a surface side wall of the connecting rod 55, and the second transmission gear 57 is meshed with the third transmission gear 58.

As shown in fig. 5, the end of the diversion pipeline 52 is fixedly sleeved with an air inlet and outlet pipeline 61, the bottom end of the air inlet and outlet pipeline 61 is communicated with the inner cavity of the air circulation buffer mechanism 6, the inner side of the air circulation buffer mechanism 6 is fixedly provided with a plurality of groups of electric heating wire nets 62, the bottom of the air circulation buffer mechanism 6 is provided with an air channel, and the bottom of the air channel is also fixedly provided with a switch grid window 63.

As shown in fig. 6, the inner side wall of the opening/closing grill window 63 is fixedly sleeved with a grill rotating shaft 68 through a bearing, and the side wall of the grill rotating shaft 68 is fixedly sleeved with the fourth transmission gear 65 and the adjusting grill 66.

As shown in fig. 6, the grille rotating shafts 68, the fourth transmission gears 65 and the adjusting grille 66 are uniformly distributed on the inner side walls of the opening and closing grille windows 63, the fifth transmission gears 67 are engaged between the fourth transmission gears 65, the fifth transmission gears 67 are fixedly sleeved inside the opening and closing grille windows 63 through rotatable shafts, the side surfaces of the opening and closing grille windows 63 are fixedly provided with the second driving motors 64, and output shafts of the second driving motors 64 are movably sleeved with the top grille rotating shafts 68.

Referring to fig. 1, heat insulation walls are installed on the side surfaces of a building body 1.

In the utility model, the light intensity at each position of the top of the arc-shaped heat insulation top 2 can be monitored by the light intensity monitoring mechanism 25, the power-on and rotation direction of the first driving motor 24 is controlled at the same time, the first driving gear 23 is driven to rotate and the first driving gear 23 is driven to rotate along the surface of the arc-shaped outer gear ring 21, the arc-shaped solar panel 4 is driven to slide along the surface of the solar panel sliding groove 3 by the solar panel driving shaft 41, so that the arc-shaped solar panel 4 is always in a good illumination angle, and the light energy absorption rate and the conversion rate of the arc-shaped solar panel 4 are improved;

the thermal insulation wall arranged on the side surface of the building body 1, the arc thermal insulation top 2 fixedly arranged on the top of the building body 1 and the thermal insulation laminated plate 53 can play a good thermal insulation effect on the interior of the building body 1 from various angles and directions;

air exchange is carried out inside the building body 1, external air can enter the inside of the diversion pipeline 52 through the air inlet and outlet channel opening 51 and enter the inside of the building body 1 through the air inlet and outlet pipeline 61, the electric heating wire mesh 62 and the switch grid window 63, meanwhile, the electric heating wire mesh 62 can be electrified and heated by using electric energy generated by the arc-shaped solar panel 4, so that the air passing through the electric heating wire mesh 62 is heated, meanwhile, the second driving motor 64 can be controlled to rotate to drive the adjusting grid 66 to rotate, the flow of the air entering the inside of the building body 1 is adjusted, the inside of the building body 1 is ensured to be always in a good constant temperature state, and the living experience of a user can be effectively improved;

meanwhile, air drives the guide fan blades 56 to rotate when entering from the air inlet and outlet passage port 51, meanwhile, the guide fan blades 56 on the other side are driven to rotate through the connecting rod 55, meanwhile, the guide directions of the guide fan blades 56 on the two sides are opposite, the guide fan blades 56 on the other side can rotate to play a guide effect on the air inside the building body 1, meanwhile, an acceleration rotating effect can be played on the connecting rod 55 through controlling the auxiliary standby motor 54, an air circulation effect in windless weather is guaranteed, the whole system does not need extra electric power, and the electric power and the wind power generated by the arc-shaped solar panel 4 are used for driving, so that the energy consumption is effectively saved, and the living experience of a user is guaranteed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims

1. An assembled constant-temperature energy-saving building comprises a building body and is characterized in that an arc-shaped heat insulation top is fixedly installed at the top of the building body, an air circulation buffer mechanism is fixedly installed in the building body, a plurality of light intensity monitoring mechanisms are fixedly installed on the surface side wall of the arc-shaped heat insulation top, a solar panel sliding groove is further formed in the side wall of the arc-shaped heat insulation top, an arc-shaped solar panel is movably sleeved on the inner side of the solar panel sliding groove, inner gas circulation channel devices are further symmetrically arranged on two sides of the arc-shaped heat insulation top, an arc-shaped outer gear ring is fixedly installed on the inner side of the arc-shaped heat insulation top, a motor sliding groove channel is further fixedly installed on the inner side of the arc-shaped heat insulation top, a solar panel driving shaft is fixedly sleeved on the side surface of the arc-shaped solar panel through a bearing, and the solar panel driving shaft extends to the inner part of the arc-shaped heat insulation top, the inside of arc heat insulation top still seted up with solar panel drive shaft diameter looks adaptation's arc groove.

2. The fabricated constant-temperature energy-saving building as claimed in claim 1, wherein the solar panel driving shaft is movably sleeved on the inner side wall of the arc-shaped groove, the side wall of the solar panel driving shaft is fixedly sleeved with a first transmission gear, the first transmission gear is meshed with the arc-shaped outer gear ring, the inner side of the motor chute channel is movably sleeved with a first driving motor, and the output shaft of the first driving motor is fixedly sleeved with the top end of the solar panel driving shaft.

3. The assembled constant-temperature energy-saving building according to claim 1, wherein the internal gas circulation passage device comprises gas inlet and outlet passage ports, the gas inlet and outlet passage ports are symmetrically arranged on the side surface of the arc-shaped heat insulation top, the other end of the gas inlet and outlet passage port is connected with a flow guide pipeline, the side wall of the flow guide pipeline is movably and fixedly sleeved with a connecting rod through a sealing rotating bearing, the connecting rod extends to the inner side of the flow guide pipeline, flow guide fan blades are symmetrically and fixedly mounted at both ends of the connecting rod, an auxiliary standby motor is further fixedly mounted on the inner side of the arc-shaped heat insulation top, and a heat insulation laminate is fixedly mounted at the top end of the building body.

4. The assembled constant-temperature energy-saving building as claimed in claim 3, wherein a second transmission gear is fixedly sleeved at the output end of the auxiliary standby motor, a third transmission gear is fixedly installed on the surface side wall of the connecting rod, and the second transmission gear is meshed with the third transmission gear.

5. The assembled constant-temperature energy-saving building as claimed in claim 3, wherein the end of the diversion pipeline is fixedly sleeved with an air inlet and outlet pipeline, the bottom end of the air inlet and outlet pipeline is communicated with the inner cavity of the air circulation buffering mechanism, a plurality of groups of electric heating wire nets are fixedly mounted on the inner side of the air circulation buffering mechanism, the bottom of the air circulation buffering mechanism is provided with an air channel, and the bottom of the air channel is further fixedly provided with a switch grid window.

6. The fabricated constant-temperature energy-saving building as claimed in claim 5, wherein the inner side wall of the opening and closing grille window is fixedly sleeved with a grille rotating shaft through a bearing, and the side wall of the grille rotating shaft is fixedly sleeved with a fourth transmission gear and an adjusting grille.

7. The fabricated constant-temperature energy-saving building as claimed in claim 6, wherein the grid rotation shaft, the fourth transmission gear and the adjusting grid are uniformly distributed on the inner side wall of the switch grid window, a fifth transmission gear is meshed between the fourth transmission gears, the fifth transmission gear is fixedly sleeved inside the switch grid window through a rotatable shaft, a second driving motor is fixedly mounted on the side surface of the switch grid window, and an output shaft of the second driving motor is movably sleeved with the grid rotation shaft at the top end.

8. The fabricated constant-temperature energy-saving building as claimed in claim 1, wherein the side surfaces of the building body are provided with heat insulation walls.