CN115977264A - Passive zero-energy-consumption building heat-insulation structure and using method thereof - Google Patents

Abstract

The invention discloses a passive zero-energy-consumption building heat insulation structure and a using method thereof, and belongs to the field of building heat insulation. A passive zero energy building insulation structure comprising: the wall body still includes: the heat insulation plate is fixedly arranged on the wall body; the inserting groove is formed in the upper end of the heat insulation plate; the first sliding groove is formed in one end, far away from the inserting groove, of the heat insulation plate; the sealing plate is arranged in the first sliding groove in a sliding manner; the inserting block is fixedly arranged on the sealing plate and matched with the inserting groove; according to the invention, the downward force is effectively removed when the insulation board is used for a long time, so that the lower side insulation board is stressed unevenly in sequence, the insulation board is effectively prevented from falling downwards, and the service life of the insulation board is effectively prolonged.

Description

Passive zero-energy-consumption building heat-insulation structure and using method thereof

Technical Field

The invention relates to the technical field of building heat preservation, in particular to a passive zero-energy-consumption building heat preservation structure and a using method thereof.

Background

With the increasing of national building energy-saving requirement standards and the development of building industry, in recent years, many families and building industry commonly use composite materials to produce heat-insulating exterior walls, the heat-insulating exterior walls are formed by compounding polymer mortar, glass fiber gridding cloth, flame-retardant molded polystyrene sheet foam boards and other materials, and the composite heat-insulating exterior walls can effectively insulate walls.

At present, because the insulation board is installed in a single-block assembly mode, after installation, when force is removed from a certain insulation board installation assembly, downward gravity can be generated, the stress of the insulation board on the lower layer is possibly too large, force is removed, and the service life of the insulation board is possibly influenced.

Disclosure of Invention

The technical problem underlying the present invention is to overcome the drawbacks of the prior art and to provide a passive zero energy building insulation structure that overcomes or at least partially solves the above mentioned problems.

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

a passive zero-energy-consumption building insulation structure, comprising: the wall body still includes: the heat insulation plate is fixedly arranged on the wall body; the inserting groove is formed in the upper end of the heat insulation plate; the first sliding groove is formed in one end, far away from the inserting groove, of the heat insulation plate; the sealing plate is arranged in the first sliding groove in a sliding manner; the inserting block is fixedly arranged on the sealing plate and matched with the inserting groove; the first driving assembly is arranged in the heat insulation board and used for driving the sealing plate to move up and down, and when the heat insulation board approaches to the wall direction, the first driving assembly drives the sealing plate to move down to enable the splicing block to be spliced in the splicing groove on the heat insulation board below; and the heat insulation layer is fixedly connected to one side of the heat insulation plate far away from the wall body.

In order to fix the heat-insulating plate, preferably, the heat-insulating plate is symmetrically and fixedly connected with positioning plates, and the positioning plates are fixedly connected with the wall body through positioning bolts.

In order to facilitate the lifting of the driving sealing plate, preferably, the first driving assembly comprises a driving rod arranged at the upper end of the first sliding groove in a sliding manner, a first cavity is arranged in the heat insulation plate, one end of the driving rod penetrates into the first cavity, a driving column is rotatably connected in the first cavity, and a second driving assembly used for driving the driving column is arranged in the heat insulation plate.

For the convenience of driving the driving column to rotate, preferably, the second driving assembly comprises a gear fixedly arranged on the driving column, a second sliding groove is formed in one side, close to the wall body, of the heat insulation board, a sliding rod is arranged between the second sliding groove and the first cavity in a sliding mode, a first spring is fixedly connected between the sliding rod and the second sliding groove, a toothed plate is fixedly connected to one end of the sliding rod in the first cavity, the toothed plate is matched with the gear, a limiting assembly is arranged on one side, far away from the wall body, of the heat insulation board, the limiting assembly is matched with the toothed plate, and a driving unit used for driving the sliding rod is arranged on the positioning plate.

In order to facilitate the extrusion of the sliding rod, preferably, the driving unit comprises a positioning column fixedly arranged on the positioning plate, the positioning column is matched with the second sliding groove, and a third groove matched with the positioning plate is arranged on one side, close to the wall body, of the heat-insulating plate.

For the convenience of limiting the toothed plate, preferably, the limiting assembly comprises a first groove formed in one side, far away from the wall body, of the heat insulation plate, a limiting bolt is connected to the inner thread of the first groove, one end, in the first cavity, of the limiting bolt is fixedly connected with a control block, a sliding block is arranged in the control block in a sliding mode, a second spring is fixedly connected between the sliding block and the control block, and a limiting plate matched with the sliding block is fixedly connected with one end, far away from the sliding rod, of the toothed plate.

In order to fix the heat-insulating layer, preferably, the heat-insulating layer is symmetrically and fixedly connected with mounting blocks, the mounting blocks are arranged in the heat-insulating plate in a sliding manner, and fixing assemblies for fixing the mounting blocks are arranged in the heat-insulating plate.

In order to fix the mounting block conveniently, preferably, the fixing assembly comprises a connecting rod fixedly arranged at the top of the driving column, a clamping plate is fixedly connected to the connecting rod, a cross groove matched with the connecting rod is formed in the mounting block, and a fixing block matched with the clamping plate is fixedly connected to the cross groove.

In order to facilitate the limitation of the heat-insulating plate, preferably, fixing grooves are symmetrically formed in two sides of the heat-insulating plate, and the two adjacent fixing grooves are fixedly connected through a positioning block.

A heat preservation method of a passive zero-energy-consumption building mainly comprises the following steps:

step one, fixing one of the heat insulation plates at the bottom of a wall body;

secondly, another insulation board is installed on the wall body, and the two insulation boards are aligned to each other in the vertical direction;

step three, when another insulation board is installed, the sealing plate is driven to slide downwards through the first driving assembly;

and step four, the sealing plate pushes the insertion block to slide towards the insertion groove on the lower side, so that the upper insulation board and the lower insulation board are fixed with each other.

Compared with the prior art, the invention provides a passive zero-energy-consumption building heat-insulation structure, which has the following beneficial effects:

1. this zero energy consumption building insulation construction of passive form through actuating lever drive closing plate lapse, closing plate drive grafting piece lapse, makes in the grafting piece inserts the inserting groove completely, and the grafting piece that sets up through the slope cooperatees with the inserting groove, carries on spacingly to the heated board of downside, and it leads to downside heated board atress inhomogeneous in proper order to unload the power downwards when using for a long time effectively to avoid the heated board to drop downwards effectively, and then improve the life of heated board effectively.

2. This zero energy consumption of passive form building insulation construction slides to first cavity through the drive pinion rack of slide bar, and pinion rack drive gear rotates, and the gear drives the drive column and rotates, then carries on spacingly to the pinion rack through spacing subassembly, prevents that the heated board from outwards sliding, and promotes the installation effectiveness to the heated board effectively.

3. This zero energy consumption building insulation construction of passive form drives the connecting rod through the drive post and rotates, and the connecting rod drives the joint board and rotates, and the joint board cooperatees with the fixed block and fixes the heat preservation to promote the efficiency of heat preservation installation effectively.

The parts which are not involved in the device are the same as those in the prior art or can be realized by adopting the prior art, and the downward force unloading of the effective insulation board for a long time leads the sequential uneven stress of the insulation board at the lower side, thereby effectively avoiding the downward falling of the insulation board and further effectively prolonging the service life of the insulation board.

Drawings

FIG. 1 is a schematic cross-sectional view of a passive zero-energy-consumption building insulation structure according to the present invention;

FIG. 2 is an enlarged schematic view of the point A in FIG. 1 of a passive zero-energy-consumption building insulation structure according to the present invention;

FIG. 3 is a schematic cross-sectional view of an installation block of a passive zero-energy-consumption building insulation structure according to the present invention;

FIG. 4 is a top view of a passive zero-energy building insulation structure according to the present invention;

FIG. 5 is a side view of a passive zero-energy building insulation structure according to the present invention;

fig. 6 is a schematic cross-sectional view of a toothed plate of a passive zero-energy-consumption building insulation structure according to the present invention;

FIG. 7 is an enlarged schematic view of the passive zero-energy-consumption building insulation structure shown at B in FIG. 6;

FIG. 8 is a front view of a passive zero-energy building insulation structure according to the present invention;

fig. 9 is a top view of a positioning block of the passive zero-energy-consumption building insulation structure provided by the invention.

In the figure: 1. a wall body; 2. a heat-insulating board; 201. inserting grooves; 202. positioning a plate; 203. a positioning column; 204. positioning the bolt; 205. fixing grooves; 206. positioning blocks; 3. a first chute; 301. a sealing plate; 302. an insertion block; 303. a drive rod; 304. a drive column; 305. a gear; 306. a slide bar; 307. a toothed plate; 308. a limiting plate; 309. a first spring; 4. a first cavity; 401. a first groove; 402. a limit bolt; 403. a control block; 404. a second spring; 405. a slider; 5. a heat-insulating layer; 501. mounting blocks; 502. a cross groove; 503. a fixed block; 504. a connecting rod; 505. the joint board.

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.

Example 1: referring to fig. 1-9, a passive zero-energy-consumption building insulation structure includes: wall body 1 still includes: the insulation board 2 is fixedly arranged on the wall body 1; the inserting groove 201 is formed in the upper end of the heat insulation plate 2; the first sliding groove 3 is formed in one end, far away from the inserting groove 201, of the heat insulation board 2; a sealing plate 301 slidably disposed in the first chute 3; the plug-in block 302 is fixedly arranged on the sealing plate 301, and the plug-in block 302 is matched with the plug-in groove 201; the first driving assembly is arranged in the insulation board 2 and used for driving the sealing board 301 to move up and down, and when the insulation board 2 approaches to the wall 1, the first driving assembly drives the sealing board 301 to move down, so that the insertion block 302 is inserted into the insertion groove 201 on the insulation board 2 below; and the heat preservation layer 5 is fixedly connected to one side of the heat preservation plate 2, which is far away from the wall body 1.

The insulation board 2 is symmetrically and fixedly connected with positioning plates 202, and the positioning plates 202 are fixedly connected with the wall body 1 through positioning bolts 204.

First drive assembly is provided with first cavity 4 including the actuating lever 303 of slip setting in first spout 3 upper end in the heated board 2, and the one end of actuating lever 303 runs through to first cavity 4 in, and the internal rotation of first cavity 4 is connected with drive post 304, is provided with the second drive assembly who is used for driving drive post 304 in the heated board 2.

When heat preservation treatment is carried out on a building, the heat preservation plates 2 are sequentially arranged on the lower side of the wall body 1, the lower row of the heat preservation plates 2 are fixed on the wall body 1 through the positioning bolts 204, and then the heat preservation layer 5 is installed and fixed, wherein the heat preservation layer 5 can adopt an adhesive or other fixing modes;

when heated board 2 to the upper strata is installed, after upper heated board 2 aligns with lower floor's heated board 2, promote heated board 2 level to 1 direction of wall body, rotate through second drive assembly drive post 304, be provided with the drive groove in the drive post 304, be provided with the drive block that matches with the drive groove on the actuating lever 303, the drive groove cooperatees with the drive block this moment, make actuating lever 303 lapse, actuating lever 303 drive closing plate 301 lapse, closing plate 301 drive splicing block 302 lapse, make splicing block 302 insert splicing groove 201 completely, splicing block 302 and splicing groove 201 that set up through the slope cooperate, heated board 2 to the downside carries on spacingly, downwards unload power when heated board 2 uses effectively for a long time and lead to downside heated board 2 atress inhomogeneous in proper order, thereby avoid heated board 2 to drop downwards effectively, and then improve heated board 2's life effectively.

Example 2: referring to fig. 1 to 9, a passive zero-energy-consumption building insulation structure, which is substantially the same as that in embodiment 1, further, the second driving assembly includes a gear 305 fixedly disposed on the driving column 304, a second sliding groove is disposed on one side of the insulation board 2 close to the wall 1, a sliding rod 306 is slidably disposed between the second sliding groove and the first cavity 4, a first spring 309 is fixedly connected between the sliding rod 306 and the second sliding groove, a toothed plate 307 is fixedly connected to one end of the sliding rod 306 in the first cavity 4, the toothed plate 307 is matched with the gear 305, a limiting assembly is disposed on one side of the insulation board 2 away from the wall 1, the limiting assembly is matched with the toothed plate 307, and a driving unit for driving the sliding rod 306 is disposed on the positioning plate 202.

The driving unit comprises a positioning column 203 fixedly arranged on the positioning plate 202, the positioning column 203 is matched with the second sliding groove, and a third groove matched with the positioning plate 202 is formed in one side, close to the wall body 1, of the heat insulation plate 2.

When promoting heated board 2, reference column 203 extrusion slide bar 306 on the downside heated board 2, slide bar 306 drives pinion rack 307 and slides to first cavity 4, and pinion rack 307 drive gear 305 rotates, and gear 305 drives drive column 304 and rotates, then carries on spacingly to pinion rack 307 through spacing subassembly, prevents heated board 2 outside slip, and promotes the installation effectiveness to heated board 2 effectively.

Example 3: referring to fig. 1 to 9, a passive zero-energy-consumption building insulation structure is substantially the same as that in embodiment 1, further, the limiting component includes a first groove 401 provided on one side of the insulation board 2 away from the wall 1, a limiting bolt 402 is connected to the first groove 401 through an internal thread, one end of the limiting bolt 402 in the first cavity 4 is fixedly connected with a control block 403, a sliding block 405 is slidably provided in the control block 403, a second spring 404 is fixedly connected between the sliding block 405 and the control block 403, and a limiting plate 308 matched with the sliding block 405 is fixedly connected to one end of the toothed plate 307 away from the sliding rod 306.

When the toothed plate 307 slides into the first cavity 4, the limit plate 308 on the toothed plate 307 presses the sliding block 405, the sliding block 405 slides into the control block 403, at this time, the sliding block 405 presses the second spring 404, the second spring 404 is in an energy storage state, and when the limit plate 308 crosses the sliding block 405, the sliding block 405 rebounds under the action of the second spring 404 to limit the limit plate 308;

when dismantling, rotate limit bolt 402 through external instrument, contact slider 405 is spacing to limiting plate 308, removes fixing of positioning bolt 204 through external force, can demolish heated board 2 in proper order to be convenient for dismantle heated board 2.

Example 4: referring to fig. 1 to 9, a passive zero-energy-consumption building insulation structure is substantially the same as that in embodiment 1, and further, installation blocks 501 are symmetrically and fixedly connected to an insulation layer 5, the installation blocks 501 are slidably disposed in an insulation board 2, and a fixing component for fixing the installation blocks 501 is disposed in the insulation board 2.

The fixing component comprises a connecting rod 504 fixedly arranged at the top of the driving column 304, a clamping plate 505 is fixedly connected onto the connecting rod 504, a cross groove 502 matched with the connecting rod 504 is formed in the mounting block 501, and a fixing block 503 matched with the clamping plate 505 is fixedly connected into the cross groove 502.

Fixing grooves 205 are symmetrically formed in two sides of the heat insulation plate 2, and two adjacent fixing grooves 205 are fixedly connected through positioning blocks 206.

After two left and right adjacent insulation boards 2 are installed, the positioning blocks 206 are inserted into the fixing grooves 205 to fix the two adjacent insulation boards 2, so that the insulation boards 2 are effectively positioned;

when installation heated board 2, insert heated board 2 with installation piece 501 on the heat preservation 5 in, when drive post 304 rotates, drive post 304 drives connecting rod 504 and rotates, and connecting rod 504 drives joint board 505 and rotates, and joint board 505 cooperatees with fixed block 503 and fixes heat preservation 5 to promote the efficiency of heat preservation 5 installation effectively.

Example 5: a heat preservation method of a passive zero-energy-consumption building mainly comprises the following steps:

firstly, fixing one insulation board 2 at the bottom of a wall body 1;

secondly, another insulation board 2 is installed on the wall body 1, so that the two insulation boards 2 are opposite to each other in the vertical direction;

step three, when another insulation board 2 is installed, the sealing plate 301 is driven to slide downwards through the first driving assembly;

and step four, the sealing plate 301 pushes the insertion block 302 to slide towards the insertion groove 201 on the lower side, so that the upper and lower insulation boards 2 are fixed with each other.

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 the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. A passive zero energy building insulation structure comprising: wall body (1), its characterized in that still includes:

the heat insulation plate (2) is fixedly arranged on the wall body (1);

the inserting groove (201) is formed in the upper end of the heat insulation plate (2);

the first sliding chute (3) is formed in one end, far away from the inserting groove (201), of the heat insulation plate (2);

a sealing plate (301) slidably disposed in the first chute (3);

the plug block (302) is fixedly arranged on the sealing plate (301), and the plug block (302) is matched with the plug groove (201);

the first driving assembly is arranged in the heat insulation board (2) and used for driving the sealing plate (301) to move up and down, and when the heat insulation board (2) approaches to the wall body (1), the first driving assembly drives the sealing plate (301) to move down to enable the insertion block (302) to be inserted into the insertion groove (201) in the heat insulation board (2) below;

and the heat insulation layer (5) is fixedly connected to one side, far away from the wall body (1), of the heat insulation plate (2).

2. The passive zero-energy-consumption building heat-insulation structure as claimed in claim 1, wherein the heat-insulation board (2) is symmetrically and fixedly connected with positioning plates (202), and the positioning plates (202) are fixedly connected with the wall body (1) through positioning bolts (204).

3. The passive zero-energy-consumption building heat-insulation structure is characterized in that the first driving assembly comprises a driving rod (303) which is slidably arranged at the upper end of the first sliding chute (3), a first cavity (4) is arranged in the heat-insulation board (2), one end of the driving rod (303) penetrates into the first cavity (4), a driving column (304) is rotatably connected in the first cavity (4), and a second driving assembly for driving the driving column (304) is arranged in the heat-insulation board (2).

4. The passive zero-energy-consumption building heat-insulation structure according to claim 3, wherein the second driving assembly comprises a gear (305) fixedly arranged on the driving column (304), a second sliding groove is formed in one side, close to the wall (1), of the heat-insulation board (2), a sliding rod (306) is arranged between the second sliding groove and the first cavity (4) in a sliding manner, a first spring (309) is fixedly connected between the sliding rod (306) and the second sliding groove, a toothed plate (307) is fixedly connected to one end, in the first cavity (4), of the sliding rod (306), the toothed plate (307) is matched with the gear (305), a limiting assembly is arranged on one side, far away from the wall (1), of the heat-insulation board (2), the limiting assembly is matched with the toothed plate (307), and a driving unit for driving the sliding rod (306) is arranged on the positioning plate (202).

5. The passive zero-energy-consumption building insulation structure according to claim 4, wherein the driving unit comprises a positioning column (203) fixedly arranged on the positioning plate (202), the positioning column (203) is matched with the second sliding groove, and a third groove matched with the positioning plate (202) is arranged on one side, close to the wall body (1), of the insulation plate (2).

6. The passive zero-energy-consumption building insulation structure of claim 5, characterized in that the limiting component comprises a first groove (401) formed in one side of the insulation board (2) far away from the wall body (1), a limiting bolt (402) is connected to the first groove (401) in a threaded manner, a control block (403) is fixedly connected to one end of the limiting bolt (402) in the first cavity (4), a sliding block (405) is arranged in the control block (403) in a sliding manner, a second spring (404) is fixedly connected between the sliding block (405) and the control block (403), and a limiting plate (308) matched with the sliding block (405) is fixedly connected to one end of the toothed plate (307) far away from the sliding rod (306).

7. The passive zero-energy-consumption building insulation structure according to claim 6, characterized in that the insulation layer (5) is symmetrically and fixedly connected with mounting blocks (501), the mounting blocks (501) are slidably arranged in the insulation board (2), and a fixing component for fixing the mounting blocks (501) is arranged in the insulation board (2).

8. The passive zero-energy-consumption building heat-insulation structure is characterized in that the fixing assembly comprises a connecting rod (504) fixedly arranged at the top of the driving column (304), a clamping plate (505) is fixedly connected to the connecting rod (504), a cross groove (502) matched with the connecting rod (504) is formed in the mounting block (501), and a fixing block (503) matched with the clamping plate (505) is fixedly connected to the inside of the cross groove (502).

9. The passive zero-energy-consumption building heat-insulation structure as claimed in claim 8, wherein fixing grooves (205) are symmetrically formed in two sides of the heat-insulation board (2), and two adjacent fixing grooves (205) are fixedly connected through a positioning block (206).

10. The heat preservation method of the passive zero-energy-consumption building adopts the heat preservation structure of the passive zero-energy-consumption building as claimed in claim 1, and is characterized by mainly comprising the following steps:

firstly, fixing one of the heat insulation plates (2) at the bottom of a wall body (1);

secondly, another insulation board (2) is installed on the wall body (1) so that the two insulation boards (2) are opposite to each other in the vertical direction;

step three, when another insulation board (2) is installed, the sealing plate (301) is driven to slide downwards through the first driving assembly;

and step four, the sealing plate (301) pushes the insertion block (302) to slide towards the insertion groove (201) on the lower side, so that the upper and lower insulation boards (2) are fixed with each other.

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