CN215166693U

CN215166693U - Heat preservation system for building energy conservation

Info

Publication number: CN215166693U
Application number: CN202121356478.XU
Authority: CN
Inventors: 卜战营; 谭亚光
Original assignee: Kaifeng Yellow River Engineering Quality Inspection Co ltd
Current assignee: Kaifeng Yellow River Engineering Quality Inspection Co ltd
Priority date: 2021-06-18
Filing date: 2021-06-18
Publication date: 2021-12-14
Anticipated expiration: 2031-06-18

Abstract

The utility model discloses a heat preservation system for building energy conservation, including the base, its characterized in that: the upper surface of the base is connected with a wall body, a heat preservation cavity is formed in the wall body, vent holes are formed in the outer surface of the wall body and communicated with the heat preservation cavity, and a first supporting plate are connected to the surfaces, close to each other, in the heat preservation cavity; a first heat insulation layer is arranged on the inner wall of the heat insulation cavity and is a silicon dioxide aerogel layer; and a second heat insulation layer is arranged on the outdoor side of the wall body, and is a foam plastic type heat insulation material.

Description

Heat preservation system for building energy conservation

Technical Field

The utility model relates to a building technical field specifically is a heat preservation system for building energy conservation.

Background

The building energy saving specifically refers to executing an energy saving standard in the planning, designing, newly building (rebuilding and expanding), reforming and using processes of a building, adopting energy-saving technology, process, equipment, materials and products, improving the heat preservation and insulation performance and the efficiency of a heating and heating system, an air-conditioning refrigeration and heating system, enhancing the operation management of an energy system for the building, and increasing the indoor and outdoor energy exchange thermal resistance on the premise of ensuring the quality of an indoor thermal environment so as to reduce the energy consumption of the heating system and the air-conditioning refrigeration and heating due to large heat consumption.

With the increasing requirements on energy conservation and emission reduction, the energy-saving effect of buildings is ensured, the comfort level is improved, energy-saving measures are required for some buildings to ensure the heat-preservation effect, and in some large buildings, wind circulation is required to be carried out in the buildings to ensure the purity of air in the buildings and the control of indoor temperature; in the prior art, the device has various defects of simple structure, incapability of manual intervention, excessive energy consumption in the use process and the like.

Based on the technical problem that exists among the prior art, the utility model provides a heat preservation system for building energy conservation can improve building energy conservation and keep warm the effect.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a pair of be used for building energy-conserving heat preservation system to solve the technical problem who proposes in the above-mentioned background art.

The utility model discloses a solve above-mentioned technical problem, provide following technical scheme:

the utility model provides a heat preservation system for building energy conservation, includes the base, the upper surface of base is connected with the wall body, the heat preservation chamber has been seted up to the inside of wall body, the air vent has been seted up to the surface of wall body, the air vent is linked together with the heat preservation chamber, the inside one side that is close to each other of heat preservation chamber is connected with first backup pad and first backup pad. A first heat insulation layer is arranged on the inner wall of the heat insulation cavity and is a silicon dioxide aerogel layer; and a second heat insulation layer is arranged on the outdoor side of the wall body, and is a foam plastic type heat insulation material. The foam plastic heat-insulating material is EPS, XPS, PUF, PET and the like.

Furthermore, a reflective heat-insulating coating is coated outside the second heat-insulating layer; the coating is a single-component bone white slurry, has the temperature resistance range of minus 30 to 120 ℃, is a novel space energy-saving reflective heat-insulating coating integrating high efficiency, thin layer, heat insulation, decoration, water resistance, fire resistance, corrosion resistance and insulation, and can be a three-dimensional network ceramic fibrous structure formed by connecting closed microbeads on the surface of an object.

Furthermore, the reflective heat-insulation coating is coated with multiple layers.

Further, the second heat-insulating layer is provided with a structure with a plurality of small micro-bubbles inside.

Further, symmetrical first spout has been seted up to the inside wall in heat preservation chamber, the second spout has been seted up to the inside wall in heat preservation chamber, the inside wall in heat preservation chamber is connected with first motor, the output pivot of first motor is connected with the carousel, the protruding piece of surface connection of carousel, the surface of protruding piece is connected with first bearing, the inside in heat preservation chamber is provided with the guide rail, the stabilizer hole has been seted up to the bottom of guide rail, the top of guide rail is connected with sector gear, be provided with the damper box between first backup pad and the first backup pad.

Furthermore, a third sliding groove is formed in the upper surface of the base, the inner portion of the third sliding groove is connected with a buffer plate in a sliding mode, and a damping steel plate is connected to the side, close to the wall, of the buffer plate.

Furthermore, fourth spout, every have all been seted up to the inner wall of surge tank the bottom of fourth spout all is connected with damping spring, every the equal sliding connection in inside of fourth spout has the shock attenuation slider.

Furthermore, the inside of surge tank is provided with the shock attenuation board, the shock attenuation board is connected with the shock attenuation slider, the surface of shock attenuation board is connected with the shock attenuation pole, the top of shock attenuation pole runs through surge tank, heat preservation chamber in proper order and is connected with the buffer board.

Furthermore, the top end of the convex block is connected with a blocking block, and the diameter value of the blocking block is larger than that of the convex block.

Furthermore, the inner side wall of the heat preservation cavity is connected with a fixed shaft, the outer surface of the fixed shaft is connected with a second bearing, and the outer ring of the second bearing is connected with the inner ring of the stabilizing hole.

Furthermore, the inside sliding connection of first spout has first slider, the upper surface of first slider is connected with the heated board.

Furthermore, a second sliding block is slidably connected to the inside of the second sliding block, a toothed plate is connected to the upper surface of the second sliding block, the toothed plate is connected with the heat insulation board, and the toothed plate is meshed with the sector gear.

Compared with the prior art, the heat preservation system for building energy conservation has the following beneficial effects:

1. the utility model discloses a be provided with the air vent, thereby utilize the permeability of air vent can have the quick replacement of the inside cold and hot air of assurance wall body effectively thereby the at utmost guarantee at the thermal insulation performance of wall body, thereby the thermal insulation performance that guarantees the wall body has reached energy saving's effect through being provided with the heated board heat insulating ability and the leakproofness that the heated board utilized can effectual assurance device guarantee at chilly weather that indoor hot-air is not the outflow.

2. The utility model discloses a thereby be provided with the image and speech cooperation of first spout and second spout and guaranteed the certainty of the operation in-process movement track of device and can reach the heat preservation and the indoor temperature of manual control wall body, guaranteed the heat preservation of wall body, through being provided with the stopper, thereby effectual having avoided being greater than the diameter value of protruding piece through the diameter value that utilizes the stopper and leading to protruding piece and guide rail to drop and can not carry out heat preservation work because the carousel operates at the excessive speed in the use.

3. The utility model discloses a be provided with the buffer board and utilize the buffer board at first to reach the first layer protection to the wall body with the impact thing collision, utilize the elasticity of shock attenuation steel sheet through being provided with the shock attenuation steel sheet, thereby can effectually guarantee the integrality of wall body by the buffer board carries out the first shock attenuation when receiving the striking, the characteristic through being provided with the surge tank and utilizing the surge tank can effectually carry out the secondary shock attenuation and reach the beneficial effect of protection wall body.

4. The utility model discloses a be provided with mutually supporting of sector gear and pinion rack can effectual assurance device power transmission's maximize in the use to the reduction has reached energy-conserving beneficial effect to the consumption of the energy, has guaranteed the continuity of device at the operation in-process through mutually supporting that is provided with stable hole, fixed axle and second bearing, thereby has reached heat retaining beneficial effect.

Drawings

Fig. 1 is a front view of the present invention.

Fig. 2 is an internal view of the wall body of the utility model.

Fig. 3 is the internal structure diagram of the shock-absorbing box of the utility model.

Fig. 4 is an enlarged view of a position a in the structure diagram 2 of the present invention.

In the figure: 1. a base; 2. a wall body; 3. a heat preservation cavity; 4. a vent hole; 5. a first support plate; 6. a second support plate; 7. a first chute; 8. a second chute; 9. a first motor; 10. a turntable; 11. a raised block; 12. a first bearing; 13. a guide rail; 14. a stabilization well; 15. a sector gear; 16. a damper box; 17. a third chute; 18. a buffer plate; 19. a damping steel plate; 20. a fourth chute; 21. a damping spring; 22. a shock-absorbing slide block; 23. a damper plate; 24. a shock-absorbing lever; 25. a blocking block; 26. a fixed shaft; 27. a second bearing; 28. a first slider; 29. a thermal insulation board; 30. a second slider; 31. a toothed plate.

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.

Example 1

The exterior of the second heat-insulating layer is coated with a reflective heat-insulating coating; the coating is a single-component bone white slurry, has a temperature resistance range of-30-120 ℃, is a novel space energy-saving reflective heat-insulating coating integrating high efficiency, thin layer, heat insulation, decoration, water resistance, fire resistance, corrosion resistance and insulation, can be in a three-dimensional network ceramic fibrous structure formed by connecting the surfaces of objects together through closed microbeads, has a heat insulation grade of R-30.1, a heat reflectivity of 90 percent and a heat conductivity coefficient of 0.04W/m.K, can effectively inhibit radiant heat and conduction heat of the sun and infrared rays, has a heat insulation inhibition efficiency of about 90 percent, and can keep 70 percent of heat in the object space from losing.

The reflective heat-insulation coating is coated with multiple layers. The second heat insulation layer is provided with a structure with a plurality of small micro-bubbles inside.

Example 2

Referring to fig. 1-4, a heat preservation system for building energy saving includes a base 1, a third sliding groove 17 is formed on the upper surface of the base 1, an inner portion of the third sliding groove 17 is slidably connected with a buffer plate 18, a damping steel plate 19 is connected to a surface of the buffer plate 18 close to a wall 2, the damping steel plate 19 utilizes elasticity of the damping steel plate 19, when the buffer plate 18 is impacted, damping is performed for the first time to protect the wall 1, the upper surface of the base 1 is connected with the wall 2, a heat preservation chamber 3 is formed inside the wall 2, an inner side wall of the heat preservation chamber 3 is connected with a fixing shaft 26, an outer surface of the fixing shaft 26 is connected with a second bearing 27, an outer ring of the second bearing 27 is connected with an inner ring of a stabilization hole 14, and rationality of the device is effectively guaranteed by the fixing shaft 26, the second bearing 27 and the stabilization hole 14 to achieve a heat preservation effect, the outer surface of the wall body 2 is provided with a vent hole 4.

The vent hole 4 is communicated with the heat preservation cavity 3, one surface of the heat preservation cavity 3, which is close to each other, is connected with a first supporting plate 5 and a first supporting plate 6, the inner side wall of the heat preservation cavity 3 is provided with a symmetrical first sliding chute 7, the first sliding chute 7 is connected with a first sliding block 28 in a sliding manner, the upper surface of the first sliding block 28 is connected with a heat preservation plate 29, the heat preservation effect of the device can be effectively ensured in the use process of the wall body 2 by arranging the heat preservation plate 29 and the first sliding block 28, the inner side wall of the heat preservation cavity 3 is provided with a second sliding chute 8 in the use process, the second sliding chute 8 is connected with a second sliding block 30 in a sliding manner, the upper surface of the second sliding block 30 is connected with a toothed plate 31, the toothed plate 31 is connected with the heat preservation plate 29, the toothed plate 31 is meshed with the sector gear 15, and the maximization of the power transmission of the device in the use process can be effectively ensured by arranging the toothed plate 31 and the sector gear 15 in a mutual meshing manner, thereby ensuring the heat preservation performance of the wall body 2 as far as possible.

The inner side wall of the heat preservation cavity 3 is connected with a first motor 9, an output rotating shaft of the first motor 9 is connected with a rotating disc 10, the surface of the rotating disc 10 is connected with a convex block 11, the top end of the convex block 11 is connected with a stop block 25, the diameter value of the stop block 25 is larger than that of the convex block 11, the stop block 25 is arranged to effectively ensure that a guide rail 13 falls off due to the fact that the rotating disc 10 rotates at an over-high speed in the using process and the heat preservation effect cannot be achieved by utilizing the diameter value of the stop block 25 larger than that of the convex block 11, the outer surface of the convex block 11 is connected with a first bearing 12, a guide rail 13 is arranged inside the heat preservation cavity 3, a stable hole 14 is formed in the bottom end of the guide rail 13, the top end of the guide rail 13 is connected with a sector gear 15, a shock absorption box 16 is arranged between the first support plate 5 and the first support plate 6, a shock absorption plate 23 is arranged inside the shock absorption box 16, and the shock absorption plate 23 is connected with a shock absorption slide block 22, shock attenuation board 23's surface is connected with shock attenuation pole 24, shock attenuation box 16 is run through in proper order on the top of shock attenuation pole 24, heat preservation chamber 3 is connected with buffer board 18, through being provided with shock attenuation pole 24 can effectual assurance buffer board 18 the fast decomposition of the impact force that receives reach the effect of protection wall body 2, fourth spout 20 has all been seted up to shock attenuation box 16's inner wall, the bottom of every fourth spout 20 all is connected with damping spring 21, the equal sliding connection in inside of every fourth spout 20 has damping slider 22, thereby through being provided with fourth spout 20, damping slider 22 and damping spring 21's effective cooperation can the at utmost decompose the impact force that buffer board 18 received thereby reach the beneficial effect of protection wall body 2.

During the use, with the power intercommunication of first motor 9 and looks adaptation, when meetting the collision, the rammer is at first collided the surface of buffer board 18, buffer board 18 receives to strike after the back to incline, is pressing shock attenuation steel sheet 19 and is carrying out the first shock attenuation, is pressing simultaneously shock attenuation pole 24 motion, drives shock attenuation board 23 and drives shock attenuation slider 22 after transporting and slide in the inside of fourth spout 20, and shock attenuation slider 22 slides after pressing damping spring 21 and carry out the secondary shock attenuation to reach the effect of protection wall body 2. When needing to keep warm, start first motor 9, and drive carousel 10 operation, and then drive protruding piece 11 and be circular motion, it is the swing motion to drive guide rail 13, and drive sector gear 15 and be the swing motion, second slider 30 slides in the inside of second spout 8 when meshing pinion rack 31 is linear motion simultaneously, drive heated board 29 after pinion rack 31 transports and move, first slider 28 slides in the inside of first spout 7 simultaneously, cover vent 4 after heated board 29 moves and can not distribute away and reach the heat preservation effect.

The above description is only a preferred embodiment of the application and is illustrative of the principles of the technology employed. It will be appreciated by a person skilled in the art that the scope of protection covered by the present application is not limited to the embodiments with a specific combination of features described above, but also covers other embodiments with any combination of features described above or their equivalents without departing from the inventive concept. For example, the above features may be replaced with (but not limited to) features having similar functions disclosed in the present application.

Claims

1. The utility model provides a heat preservation system for building energy conservation, includes base (1), its characterized in that: the upper surface of the base (1) is connected with a wall body (2), a heat preservation cavity (3) is formed in the wall body (2), vent holes (4) are formed in the outer surface of the wall body (2), the vent holes (4) are communicated with the heat preservation cavity (3), and a first supporting plate (5) and a second supporting plate (6) are connected to the surfaces, close to each other, in the heat preservation cavity (3);

a first heat insulation layer is arranged on the inner wall of the heat insulation cavity and is a silicon dioxide aerogel layer;

and a second heat insulation layer is arranged on the outdoor side of the wall body (2), and is a foam plastic type heat insulation material.

2. The heat preservation system for building energy saving according to claim 1, characterized in that: and a reflective heat-insulating coating is coated outside the second heat-insulating layer.

3. The heat preservation system for building energy saving according to claim 2, characterized in that: the reflective heat-insulation coating is coated with multiple layers.

4. The heat preservation system for building energy saving according to claim 1, characterized in that: the second heat insulation layer is provided with a structure with a plurality of small micro-bubbles inside.

5. The heat preservation system for building energy saving according to claim 1, characterized in that: symmetrical first spout (7) have been seted up to the inside wall in heat preservation chamber (3), second spout (8) have been seted up to the inside wall in heat preservation chamber (3), the inside wall in heat preservation chamber (3) is connected with first motor (9), the output pivot of first motor (9) is connected with carousel (10), protruding piece (11) are connected on the surface of carousel (10), the surface of protruding piece (11) is connected with first bearing (12), the inside in heat preservation chamber (3) is provided with guide rail (13), stabilizer hole (14) have been seted up to the bottom of guide rail (13), the top of guide rail (13) is connected with sector gear (15), be provided with damper (16) between first backup pad (5) and second backup pad (6).

6. The heat preservation system for building energy saving according to claim 5, characterized in that: third spout (17) have been seted up to the upper surface of base (1), the inside sliding connection buffer board (18) of third spout (17), the one side that buffer board (18) and wall body (2) are close to each other is connected with shock attenuation steel sheet (19).

7. The heat preservation system for building energy saving according to claim 5, characterized in that: the inside sliding connection of first spout (7) has first slider (28), the upper surface of first slider (28) is connected with heated board (29).