CN215978135U - Heat-insulating energy-saving building roof - Google Patents

Abstract

The application relates to a heat-insulating energy-saving building roof. This application thermal-insulated energy-saving building roofing include: the heat insulation device comprises a heat insulation assembly and brick stacks, wherein the two brick stacks are arranged at intervals, and the heat insulation assembly is arranged above the two brick stacks; the thermal-insulated subassembly includes thermal-insulated square frame, division board, pipe, goes up extension strip and lower extension strip, be formed with the ventilative passageway that link up on the thermal-insulated square frame, it is a plurality of the vertical setting of division board and equipartition are in the ventilative passageway, and the division board will ventilative passageway partition is for a plurality of partition passageways, every be provided with along length direction in the partition passageway the pipe. The application the energy-saving building roofing of thermal-insulated have thermal-insulated and the better advantage of radiating effect.

Description

Heat-insulating energy-saving building roof

Technical Field

The application relates to a roof, in particular to a heat-insulating energy-saving building roof.

Background

The existing roof, especially the roof in hot areas, often has the trouble of high temperature, and if the solid roof is adopted, the temperature of the surface of the roof is higher, and the heat dissipation is not easy. Therefore, in order to reduce the overall temperature of the roof, the roof is set to be a ventilation structure, the overall temperature of the ventilation roof is reduced compared with the temperature of the solid building, and the heat dissipation capacity is also improved. However, the ventilation roof in the prior art is single in structural form, and is usually provided with a heat insulation layer and a building pier, the heat insulation layer is paved on the building pier, the heat insulation layer can be a straight plate or an arc tile, and the like.

Disclosure of Invention

Based on this, the purpose of this application lies in, provides thermal-insulated energy-saving building roofing, and it has thermal-insulated and the better advantage of radiating effect.

One aspect of the application provides a heat-insulating energy-saving building roof, which comprises a heat-insulating assembly and brick piles, wherein the two brick piles are arranged at intervals, and the heat-insulating assembly is arranged above the two brick piles;

the heat insulation assembly comprises a heat insulation square frame, partition plates, round pipes, upper extension strips and lower extension strips, a through ventilation channel is formed in the heat insulation square frame, the partition plates are vertically arranged and uniformly distributed in the ventilation channel, the ventilation channel is divided into a plurality of partition channels by the partition plates, and the round pipes are arranged in each partition channel along the length direction;

the top of one side of the heat insulation square frame is provided with the upper extension strip along the length direction, and the bottom of the other side of the heat insulation square frame is provided with the lower extension strip along the length direction;

the bottom surface of the heat insulation square frame is placed on the two brick piles;

the heat insulation assemblies are arranged in multiple rows and multiple columns, and the ventilation channels of the heat insulation assemblies in the same column are communicated.

The application thermal-insulated energy-saving building roofing, through setting up the division board, separate into a plurality of little cavities with the ventilative passageway of thermal-insulated square frame, and form the partition passageway respectively, like this, be formed with the ventiduct that runs through the ventilation between the brick pillar, air current and wind can circulate through the ventiduct between the brick pillar usually, thereby can take away the hot-air on the roof rapidly, make the cooling rate on roof accelerate, and through setting up thermal-insulated square frame, make the roofing can not the direct heat radiation of sunshine, block the direct heat radiation of sunshine. Furthermore, through the thermal isolation of the heat insulation square frame and the ventilation and heat dissipation of the brick piles, the temperature of the roof is reduced, the energy consumption of the whole building for heat dissipation and cooling is reduced, and the energy-saving effect is achieved through a physical structure. In addition, the round pipe arranged in the separation channel plays a role in increasing the heat insulation structure and improving the heat insulation effect on the one hand, and also plays a role in ensuring the ventilation effect on the other hand, and the round pipe is convenient to wash and prevents blockage.

Further, the side wall of one of the heat insulation assemblies in the same column is arranged on one side of the side wall of the other heat insulation assembly, and an air permeable gap is formed between the upper extension strip of one of the heat insulation assemblies and the side wall of the other heat insulation assembly.

Further, the round pipe is a steel pipe, a ceramic pipe or a concrete pipe.

Further, the heat insulation assemblies in the same column are arranged at the same height; the heat insulation assemblies in the same row are arranged at the same height.

Furthermore, the heat insulation assemblies in the same column are arranged in a vertically staggered mode, and the heat insulation assemblies in the same row are arranged at the same height.

The lifting device further comprises a lifting assembly, wherein the lifting assembly comprises a transverse plate and vertical plates, and the vertical plates are respectively fixed on the bottom surface of the transverse plate;

the width of the transverse plate is larger than that of the heat insulation square frame.

Further, the top surface of the transverse plate is flush with the top surface of the adjacent heat insulation square frame.

Furthermore, a plurality of through holes are formed in the brick piles.

Further, the heat insulation frame is a concrete frame.

Furthermore, a water pipe is arranged in the round pipe.

For a better understanding and practice, the present application is described in detail below with reference to the accompanying drawings.

Drawings

FIG. 1 is a front view of an exemplary insulated energy efficient building roof of the present application in a row-two-in-line assembled relationship;

FIG. 2 is a perspective view of an exemplary insulated energy efficient building roof of the present application in a row-three assembly relationship;

FIG. 3 is a front view of a row two-in-row assembly of another exemplary insulated, energy efficient building roof of the present application;

FIG. 4 is a perspective view of another exemplary insulated, energy efficient building roof of the present application in a row-three assembly relationship;

FIG. 5 is a schematic perspective view from another perspective of a one-row-three-in-three assembly of another exemplary insulated energy efficient building roof of the present application;

fig. 6 is a schematic perspective view of yet another exemplary insulated energy efficient building roof according to the present application.

Detailed Description

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be considered limiting of the present application. In the description of the present application, "a plurality" means two or more unless otherwise specified.

FIG. 1 is a front view of an exemplary insulated energy efficient building roof of the present application in a row-two-in-line assembled relationship; FIG. 2 is a perspective view of an exemplary insulated energy efficient building roof of the present application in a row-three assembly relationship; FIG. 3 is a front view of a row two-in-row assembly of another exemplary insulated, energy efficient building roof of the present application; FIG. 4 is a perspective view of another exemplary insulated, energy efficient building roof of the present application in a row-three assembly relationship; FIG. 5 is a schematic perspective view from another perspective of a one-row-three-in-three assembly of another exemplary insulated energy efficient building roof of the present application; fig. 6 is a schematic perspective view of yet another exemplary insulated energy efficient building roof according to the present application.

Referring to fig. 1-6, an exemplary heat-insulating energy-saving building roof of the present application includes a heat-insulating assembly 10 and a brick pile 20, two brick piles 20 are spaced apart from each other, and the heat-insulating assembly 10 is disposed above the two brick piles 20;

the heat insulation assembly 10 comprises a heat insulation square frame 11, partition plates 12, a circular tube 13, upper extension strips 14 and lower extension strips 15, a through ventilation channel is formed in the heat insulation square frame 11, the partition plates 12 are vertically arranged and uniformly distributed in the ventilation channel, the partition plates 12 divide the ventilation channel into a plurality of partition channels M, and the circular tube 13 is arranged in each partition channel M along the length direction;

the top of one side of the heat insulation block 11 is provided with the upper extension strip 14 along the length direction, and the bottom of the other side of the heat insulation block 11 is provided with the lower extension strip 15 along the length direction;

the bottom surface of the heat insulation square frame 11 is placed on two brick piles 20;

the heat insulation assemblies 10 are arranged in multiple rows and multiple columns, and ventilation channels of the heat insulation assemblies 10 in the same column are communicated.

Thermal-insulated energy-saving building roofing, through setting up division board 12, separate into a plurality of little cavities with the ventilative passageway of thermal-insulated square frame 11, and form respectively and separate passageway M, thus, be formed with the ventiduct that runs through between brick pillar 20, air current and wind can circulate through the ventiduct between brick pillar 20 usually, thereby can take away the hot-air on the roof rapidly, make the cooling rate on roof accelerate, and through setting up thermal-insulated square frame 11, make the roofing can not the direct heating, block the direct heat radiation of sunshine. Furthermore, through the thermal isolation of the heat insulation frame 11 and the ventilation and heat dissipation of the brick piles 20, the temperature of the roof is reduced, the energy consumption of the whole building on heat dissipation and cooling is reduced, and the energy-saving effect is realized through the physical structure. In addition, the round pipe 13 arranged in the separation channel M plays a role in increasing a heat insulation structure and improving a heat insulation effect on one hand, and also plays a role in ensuring a ventilation effect on the other hand, and is convenient to wash and resistant to blockage.

The round pipe 13 is arranged, on one hand, the whole thickness of the heat insulation assembly 10 can be increased, and a multi-layer heat insulation structure is formed by combining the heat insulation square frame 11, so that the heat insulation effect is improved; on the other hand, the circular tube 13 has the ventilation function, and the outer part of the circular tube 13 also provides a ventilation channel, so that the ventilation effect is ensured, and the heat dissipation effect is further ensured; on the other hand, the inner resistance of the circular tube 13 is small, and the circular tube is easy to wash and conduct, so that the circular tube 13 is convenient to dredge and clean even if the circular tube is blocked, and the ventilation and heat dissipation effects are ensured.

In the present application, heat is dissipated primarily through the brick work 20, and the thermal insulation assembly 10 primarily provides multiple thermal insulation effects and functions and assists in providing heat dissipation.

In some preferred embodiments, the side wall of one of the thermal insulation assemblies 10 in the same row is disposed on one side of the side wall of the other of the thermal insulation assemblies 10, and an air permeable gap is formed between the upper extension strip 14 of one of the thermal insulation assemblies 10 and the side wall of the other of the thermal insulation assemblies 10. In the preferred embodiment, a plurality of insulation assemblies 10 are spaced apart, with the upper extension 14 of one insulation assembly 10 being disposed adjacent to and spaced apart from the side wall of another insulation assembly 10, and the lower extension 15 of another insulation assembly 10 being spaced apart from the side wall of that insulation assembly 10, such that an air permeable gap is formed between the two insulation assemblies 10 through which the heated air rises to facilitate the discharge of the heated air. The ventilation gap between the two heat insulation assemblies 10 is in a lightning shape, so that the sun cannot directly reach the roof and is shielded by the upper extension strip 14 or the lower extension strip 15, ventilation is guaranteed, and meanwhile, a good heat insulation effect is achieved.

In some preferred embodiments, the circular pipe 13 is a steel pipe, a ceramic pipe, or a concrete pipe. The circular tube 13 is mainly made of a high-temperature-resistant and corrosion-resistant material.

With continued reference to fig. 1-2, in some preferred embodiments, the same column of insulation assemblies 10 is disposed at the same elevation; the insulation assemblies 10 in the same row are disposed at the same height. In this example, the top surfaces of the plurality of insulation assemblies 10 are flush. Further, a gap is formed between any two adjacent insulation assemblies 10. That is, there is no close connection between the two insulation assemblies 10, thereby providing a path for the hot air to rise to accelerate heat dissipation.

With continued reference to fig. 3-5, in some preferred embodiments, the insulation assemblies 10 in the same column are staggered from top to bottom, and the insulation assemblies 10 in the same row are disposed at the same height. In this example, two adjacent insulation assemblies 10 in the same column are staggered in height, with one insulation assembly 10 being higher and the other insulation assembly 10 being lower, and are installed with a brick pile 20 of different heights.

In some preferred embodiments, the height increasing assembly 30 further comprises a transverse plate 31 and a vertical plate 32, wherein the vertical plates 32 are respectively fixed on the bottom surface of the transverse plate 31; the width of the transverse plate 31 is larger than that of the heat insulation block 11. The elevation assembly 30 is provided to fill the height of the lower insulation assembly 10 such that the top surface of the roof forms a flat surface. In order to improve the heat insulation effect of the heightening assembly 30, a transverse plate 31 and a vertical plate 32 are provided, and a heat insulation space is formed between the vertical plates 32 for ventilation and heat dissipation.

In some preferred embodiments, the top surface of the cross plate 31 is flush with the top surface of the adjacent insulating block 11.

In some preferred embodiments, the brick pile 20 is formed with a plurality of through holes N. The through-holes N are used for circulation of hot air between the plurality of brick piles 20 to accelerate heat dissipation and to prevent local overheating.

In some preferred embodiments, the insulating block 11 is a concrete block.

In some preferred embodiments, referring to fig. 6, a water pipe 40 is disposed inside the circular tube 13. The water pipe 40 is provided to take away heat by the flow of water in the water pipe 40, and to heat the water in the water pipe 40 by absorbing heat. The water in the water tube 40 may flow from the water in the roof tank.

In some preferred embodiments, the building further comprises a protective layer 51, an insulating layer 52, a leveling layer 53 and a roof structure layer 54, wherein the protective layer 51, the insulating layer 52, the leveling layer 53 and the roof structure layer 54 are arranged from top to bottom. The brick work 20 is stacked on the protective layer 51.

In some preferred embodiments, the edge of the outermost insulation assembly 10 is spaced from the roof cofferdam by a distance greater than 250 cm.

In the present application, the longitudinal direction means the axial direction of the circular tube 13, and the width means the width

The application discloses a use principle of an exemplary heat-insulating energy-saving building roof:

the partition channels M of the heat insulation assembly 10 provide a wind flow passage, the circular pipe 13 also provides a wind flow passage, and the plurality of brick piles 20 form a wind flow passage therebetween, and the wind flow passages are uniformly oriented. When the device is installed, one end of the channel faces the upwind direction, and the other end of the channel faces the downwind direction, which is determined according to the local actual situation. These wind paths provide lateral heat dissipation, while the resulting gaps between the insulation assemblies 10 provide vertical heat dissipation, and the insulation assemblies 10 provide multiple levels of insulation. The combination of multiple aspects realizes the good functions of effective heat insulation and quick heat dissipation, thereby reducing the temperature of buildings, particularly the temperature of roofs, reducing the energy consumption and playing a role in energy conservation. In addition, the air quantity is large at night, so that the temperature can be effectively and quickly reduced, and further energy is saved.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application.

Claims (10)

1. The utility model provides a thermal-insulated energy-saving building roofing which characterized in that: the heat insulation device comprises a heat insulation assembly and brick piles, wherein the two brick piles are arranged at intervals, and the heat insulation assembly is arranged above the two brick piles;

the heat insulation assembly comprises a heat insulation square frame, partition plates, round pipes, upper extension strips and lower extension strips, a through ventilation channel is formed in the heat insulation square frame, the partition plates are vertically arranged and uniformly distributed in the ventilation channel, the ventilation channel is divided into a plurality of partition channels by the partition plates, and the round pipes are arranged in each partition channel along the length direction;

the top of one side of the heat insulation square frame is provided with the upper extension strip along the length direction, and the bottom of the other side of the heat insulation square frame is provided with the lower extension strip along the length direction;

the bottom surface of the heat insulation square frame is placed on the two brick piles;

the heat insulation assemblies are arranged in multiple rows and multiple columns, and the ventilation channels of the heat insulation assemblies in the same column are communicated.

2. The insulated, energy-saving building roof as claimed in claim 1, wherein: the side wall of one of the heat insulation assemblies in the same column is arranged on one side of the side wall of the other heat insulation assembly, and an air permeable gap is formed between the upper extension strip of one of the heat insulation assemblies and the side wall of the other heat insulation assembly.

3. The insulated, energy-saving building roof as claimed in claim 2, wherein: the round pipe is a steel pipe, a ceramic pipe or a concrete pipe.

4. The insulated, energy-saving building roof as claimed in claim 2, wherein: the heat insulation assemblies in the same column are arranged at the same height; the heat insulation assemblies in the same row are arranged at the same height.

5. The insulated, energy-saving building roof as claimed in claim 2, wherein: the heat insulation assemblies in the same column are arranged in a vertically staggered mode, and the heat insulation assemblies in the same row are arranged at the same height.

6. The insulated, energy-efficient building roof of claim 5, wherein: the lifting device also comprises a lifting component, wherein the lifting component comprises a transverse plate and vertical plates, and the vertical plates are respectively fixed on the bottom surface of the transverse plate;

the width of the transverse plate is larger than that of the heat insulation square frame.

7. The insulated, energy-saving building roof as claimed in claim 6, wherein: the top surface of the transverse plate is flush with the top surface of the adjacent heat insulation square frame.

8. The insulated, energy-efficient building roof as claimed in any one of claims 1 to 7, wherein: a plurality of through holes are formed in the brick pile.

9. The insulated, energy-efficient building roof of claim 8, wherein: the heat insulation frame is a concrete frame.

10. The insulated, energy-saving building roof as claimed in claim 1, wherein: the round pipe is internally provided with a water pipe.

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