CN113006298A - Anti-seismic reinforced heat-insulating layer for building outer wall and construction method thereof - Google Patents

Abstract

The invention discloses an earthquake-resistant reinforced heat-insulating layer for an exterior wall of a building, which comprises a frame, wherein a plurality of partition plates are arranged in the frame in a crossed manner, the frame is divided into a plurality of square mounting holes by the partition plates, a heat-insulating plate is embedded in each mounting hole, and the surface of the heat-insulating plate is flush with the surface of the frame; the heat insulation plate comprises a circular main plate and four side plates, the side plates are triangular, one side of each side plate, which is abutted against the main plate, is arranged in an arc shape, and a locking mechanism is arranged among the main plate, the side plates and the mounting holes; the inside wall of mainboard is provided with the circular shape recess, and the roof of recess hangs and is provided with the stay cord, is provided with the antidetonation ball on the stay cord, and the central point that the antidetonation ball is located the mainboard puts the department. The invention has the following advantages and effects: through set up antidetonation ball in the heated board, utilize the inertial action of antidetonation ball, make the atress of heated board more even, prevent that the phenomenon of droing from appearing in the heated board, reached high shock resistance's effect.

Description

Anti-seismic reinforced heat-insulating layer for building outer wall and construction method thereof

Technical Field

The invention relates to the field of house construction, in particular to an earthquake-resistant reinforced heat-insulating layer of a building outer wall and a construction method thereof.

Background

The building construction refers to the construction of buildings such as houses on the land where the infrastructure construction is completed, and in the traditional building construction, an insulation layer is generally required to be arranged on the surface of an outer wall, wherein the insulation layer is divided into inner wall insulation and outer wall insulation so as to enhance the insulation performance of the outer wall.

When a conventional outer wall insulation layer is installed, a frame is generally fixed to the surface of an outer wall, and then the insulation layer is fixed by bolts. However, the shock resistance of the heat insulation layer is weak, so that the heat insulation layer is easy to fall off, the service life of the heat insulation layer is influenced, and improvement is needed.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide an anti-seismic reinforced heat-insulation layer for an exterior wall of a building, which has the effect of high anti-seismic property.

The technical purpose of the invention is realized by the following technical scheme: an earthquake-resistant reinforced heat-insulating layer for an exterior wall of a building comprises a frame, wherein a plurality of partition plates are arranged in the frame in a crossed manner, the frame is divided into a plurality of square mounting holes by the partition plates, a heat-insulating plate is embedded in each mounting hole, and the surface of each heat-insulating plate is flush with the surface of the frame; the heat insulation plate comprises a circular main plate and four side plates, the side plates are triangular, one side of each side plate, which is abutted against the main plate, is arranged in an arc shape, and a locking mechanism is arranged among the main plate, the side plates and the mounting holes; the inner side wall of the main board is provided with a circular groove, a pull rope is arranged on the top wall of the groove in a hanging mode, an anti-seismic ball is arranged on the pull rope, and the anti-seismic ball is located at the center of the main board.

By adopting the technical scheme, when the heat-insulating layer is fixedly installed, the frame is fixed on the surface of the outer wall, then each heat-insulating plate is taken out, and the four side plates are respectively embedded in the four corners of the installation hole. Then the main board is taken out, the main board is embedded in the gaps among the four side boards, and the pull rope is in a vertical state, so that the vertical suspension of the anti-seismic ball is realized. And finally, fixing the main board and the side boards by using a locking mechanism, so that the installation and fixation of the insulation board can be realized. Meanwhile, when the insulation board is used, if an earthquake or other seismic sources are encountered, the inertia effect of the anti-seismic ball can be utilized, so that the stress of the insulation board is more uniform, the vibration of the insulation board is reduced, the insulation board is prevented from falling off, and the effect of high anti-seismic performance is achieved.

The present invention in a preferred example may be further configured to: the locking mechanism comprises four locking rods, the locking rods penetrate through the vertex angle positions of the side plates from the middle positions of the arc surfaces of the side plates, and locking holes for the locking rods to be inserted are formed in the four corners of the mounting holes; the outward flange position of mainboard is provided with the round confession the draw-in groove of locking lever embedding, the lateral wall of draw-in groove with the inner of locking lever all is the slope form setting, the inner wall of draw-in groove is provided with the confession the locking groove of the inner grafting of locking lever, and the diapire in locking hole is provided with the control the locking lever is pegged graft the spring of locking groove.

Through adopting above-mentioned technical scheme, when installing the heated board, inlay earlier four blocks of curb plates and locate in the mounting hole to make the locking lever on the curb plate aim at the locking hole in the mounting hole. Then the mainboard is embedded in the gap between the side plates, and in the embedding process of the mainboard, the inner wall of the clamping groove on the mainboard is matched with the side wall at the inner end of the locking rod, and the locking rod is driven to move outwards and is inserted into the locking hole. And after the main board is completely embedded, the inner end of the locking rod is aligned to the locking groove on the inner wall of the clamping groove, and the locking rod is controlled to move reversely for a certain distance under the action of the spring, so that the two ends of the locking rod are respectively inserted into the locking hole and the locking groove, and the main board and the side board are locked and fixed. Therefore, the self-locking mechanism is arranged, and the automatic fixing of the insulation board is realized by utilizing the matching between the main board and the side board, so that the installation process of the insulation board is easier and more convenient.

The present invention in a preferred example may be further configured to: the spring is characterized in that a steel rod is arranged in the spring, the length of the steel rod is smaller than that of the spring, a wire is wound on the outer wall of the steel rod, and two ends of the wire penetrate through the frame and are located on the surface of the frame.

Through adopting above-mentioned technical scheme, when the heated board is dismantled to needs, directly to the wire circular telegram, make and form the electro-magnet between wire and the steel pole to produce the adsorption affinity to the locking lever, make the locking lever break away from the locking groove, thereby realize that the locking between locking lever and the mainboard is relieved. And finally, the main board and the side boards are disassembled, so that the insulation boards can be disassembled, maintained and replaced. Therefore, the insulation board can be quickly disassembled by adopting the electromagnet principle, so that the maintenance and replacement processes of the insulation board are easier and more convenient.

The present invention in a preferred example may be further configured to: the frame is characterized in that fixing holes are formed in four corners of the inner side wall of the frame, fixing rods are inserted into the fixing holes, the fixing rods are located at the outer ends of the fixing holes and used for being fixed on the surface of an outer wall, a plurality of elastic hooks are arranged on the outer wall of one end of the inner wall of each fixing hole, and fixing grooves for the elastic hooks to be embedded into are formed in the inner wall of each fixing hole.

Through adopting above-mentioned technical scheme, when the installation frame, be fixed in the outer wall surface with the dead lever, then drive the frame, make the dead lever grafting fixed orifices. And finally, the frame can be quickly installed and fixed by utilizing the clamping fit of the elastic clamping hook and the fixing groove, so that the installation and fixing processes of the frame are easier and more convenient.

The present invention in a preferred example may be further configured to: the fixed rod comprises a rod body and a pair of pipe bodies, and the pair of pipe bodies are in threaded connection with the two ends of the rod body respectively.

Through adopting above-mentioned technical scheme, through setting up the dead lever into the body of rod and a pair of body, make the total length of dead lever can adjust, consequently can realize the automatic leveling of dead lever and frame for the installation of frame is lighter, realizes simultaneously that the level and smooth installation of frame is fixed.

The present invention in a preferred example may be further configured to: the rod body is provided with a through hole for the rod piece to be inserted.

By adopting the technical scheme, the through holes for the rod pieces to penetrate through are formed, the lever principle can be utilized to drive the rod body to rotate, and the rotation driving process of the rod body is more convenient.

The invention also aims to provide a construction method of the anti-seismic reinforced heat-insulating layer of the building outer wall, which has the effect of high-efficiency construction.

The technical purpose of the invention is realized by the following technical scheme: a construction method for an earthquake-resistant reinforced heat-insulating layer of an exterior wall of a building comprises the following steps:

s1, cleaning the outer wall, namely cleaning the surface of the outer wall and cleaning residues and cement blocks on the surface of the outer wall;

s2, installing and positioning, namely placing the frame on the surface of the outer wall and positioning the periphery of the frame;

s3, mounting a fixing rod, fixing the fixing rod on the surface of the outer wall, and adjusting the total length of the fixing rod to realize the leveling of the fixing rod;

s4, installing a frame, lifting the frame to enable the fixing rod to be inserted into the fixing hole, and realizing self-locking of the fixing rod and installation of the frame;

and S5, mounting the heat-insulating plate, and embedding the heat-insulating plate in the mounting hole on the frame to realize the fixed mounting of the heat-insulating plate.

By adopting the technical scheme, the construction process is simple and convenient and fast to construct the heat-insulation wallboard through the construction process which is convenient to operate, and the effect of efficient construction is achieved.

In conclusion, the invention has the following beneficial effects:

1. the anti-seismic balls are arranged in the heat insulation plate, so that the stress of the heat insulation plate is more uniform by utilizing the inertia effect of the anti-seismic balls, the phenomenon that the heat insulation plate falls off is prevented, and the effect of high anti-seismic property is achieved;

2. the self-locking mechanism is arranged, and the matching between the main board and the side board is utilized to realize the automatic fixation of the heat-insulating board, so that the heat-insulating board is easier and more convenient to mount;

3. through adopting the electro-magnet principle, realize the quick dismantlement of heated board for the maintenance change process of heated board is light convenient more.

Drawings

FIG. 1 is a schematic structural view of an embodiment;

FIG. 2 is a schematic structural view of a fixing bar of an embodiment;

FIG. 3 is a schematic structural diagram of an insulation board of an embodiment;

FIG. 4 is a schematic structural diagram of a motherboard according to an embodiment;

fig. 5 is a schematic view of the internal structure of the bezel of the embodiment.

Reference numerals: 1. a frame; 11. a partition plate; 12. a fixing hole; 13. fixing the rod; 14. an elastic hook; 15. fixing grooves; 16. a rod body; 17. a pipe body; 18. a through hole; 2. mounting holes; 3. a thermal insulation board; 31. a main board; 32. a side plate; 33. a groove; 34. pulling a rope; 35. an anti-seismic ball; 4. a locking mechanism; 41. a locking lever; 42. a locking hole; 43. a card slot; 44. a locking groove; 45. a spring; 46. a steel rod; 47. and (4) conducting wires.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example 1: as shown in figure 1, a building outer wall antidetonation reinforcement heat preservation, including the frame 1 of square, the crisscross a plurality of baffles 11 that are provided with of crossing in the frame 1 anyhow, a plurality of baffles 11 separate into the mounting hole 2 of a plurality of squares with frame 1 to every mounting hole 2 is independent each other. Wherein all inlay in every mounting hole 2 and be equipped with heated board 3 to the surface of heated board 3 is parallel and level mutually with the surface of frame 1.

When installing fixedly to the heat preservation, be fixed in outer wall surface with frame 1, then take out every heated board 3 to in embedding a plurality of mounting holes 2 with every heated board 3 one-to-one, in order to realize the installation of heated board 3, thereby realize that the installation of heat preservation is fixed.

As shown in fig. 1 and 2, fixing holes 12 are formed at four corners of the inner side wall of the frame 1, and fixing rods 13 are inserted into the fixing holes 12. Wherein, one end of the fixing rod 13 outside the fixing hole 12 is used for fixing on the surface of the outer wall to fix the frame 1.

As shown in fig. 1 and 2, the outer wall of the fixing rod 13 at one end of the inner wall of the fixing hole 12 is provided with a plurality of elastic hooks 14, and the inner wall of the fixing hole 12 is provided with a fixing groove 15 for the elastic hooks 14 to be embedded into, so as to realize the clamping fixation between the fixing rod 13 and the frame 1.

As shown in fig. 1 and 2, the fixing rod 13 includes a rod body 16 and a pair of tube bodies 17, the pair of tube bodies 17 are respectively connected to two ends of the rod body 16 by threads, and a through hole 18 for inserting the rod body is formed in the rod body 16 in a penetrating manner, so as to realize convenient rotation control of the rod body 16.

When the frame 1 is installed, one end of the fixing rod 13 is fixed on the surface of an outer wall, then the rod piece is inserted into the through hole 18 on the rod body 16, the rod body 16 is driven to rotate, the total length of the fixing rod 13 is adjusted, and therefore the fixing rod is adaptive to uneven wall surfaces, and the end, provided with the elastic clamping hook 14, of the fixing rod 13 is located on the same horizontal plane.

Then the frame 1 is driven to make the fixed rod 13 inserted into the fixed hole 12. Finally, the elastic clamping hook 14 is matched with the fixing groove 15 in a clamping manner, so that the frame 1 can be quickly installed and fixed, and the installation and fixing processes of the frame 1 are easier and more convenient.

As shown in fig. 2 and 3, the heat insulation board 3 includes a circular main board 31 and four side boards 32, the side boards 32 are triangular, one side of the side boards abutting against the main board 31 is arc-shaped, and a locking mechanism 4 is provided between the main board 31, the side boards 32 and the mounting hole 2.

As shown in fig. 3, a circular groove 33 is provided on the inner side wall of the main plate 31, a pull rope 34 is provided on the top wall of the groove 33 in a suspended manner, and an anti-vibration ball 35 is provided on the pull rope 34, the anti-vibration ball 35 being located at the center of the main plate 31 and in a vertically suspended state.

When the heat insulation board 3 is installed, the four side plates 32 are respectively embedded in the four corners of the installation hole 2. The main plate 31 is then taken out, the main plate 31 is embedded in the gap between the four side plates 32, and the pull rope 34 is in a vertical state, so that the vertical suspension of the anti-seismic ball 35 is realized. And finally, the main board 31 and the side boards 32 are fixed by using the locking mechanism 4, so that the installation and fixation of the heat-insulating board 3 can be realized.

Meanwhile, when the insulation board 3 is used, if an earthquake or other seismic sources are encountered, the inertia effect of the anti-seismic ball 35 can be utilized, so that the stress of the insulation board 3 is more uniform, the vibration of the insulation board 3 is reduced, the phenomenon that the insulation board 3 drops is prevented, and the effect of high anti-seismic performance is achieved.

As shown in fig. 3, 4, and 5, the locking mechanism 4 includes four locking levers 41, the locking levers 41 penetrate through the vertex angles of the side plates 32 from the middle positions of the arc surfaces of the side plates 32, and locking holes 42 into which the locking levers 41 are inserted are provided at the four corners of the mounting holes 2.

As shown in fig. 3, 4, and 5, a ring of locking grooves 43 into which the locking rods 41 are inserted are formed at an outer edge of the main plate 31, and side walls of the locking grooves 43 and inner ends of the locking rods 41 are both inclined. The inner wall of the locking groove 43 is provided with a locking groove 44 for the inner end of the locking rod 41 to be inserted.

As shown in fig. 3, 4 and 5, a spring 45 for controlling the locking rod 41 to be inserted into the locking groove 44 is disposed on the bottom wall of the locking hole 42, a steel rod 46 is disposed in the spring 45, the length of the steel rod 46 is smaller than that of the spring 45, a conducting wire 47 is wound on the outer wall of the steel rod 46, and two ends of the conducting wire 47 penetrate through the frame 1 and are located on the surface of the frame 1.

When the heat insulation board 3 is installed, the four side plates 32 are first embedded in the installation hole 2, and the locking rods 41 on the side plates 32 are aligned with the locking holes 42 in the installation hole 2. Then the main board 31 is embedded in the gap between the side plates 32, and during the embedding process of the main board 31, the inner wall of the slot 43 on the main board 31 is matched with the side wall of the inner end of the locking rod 41, and the locking rod 41 is driven to move outwards and is inserted into the locking hole 42.

After the main board 31 is completely embedded, the inner end of the locking lever 41 aligns with the locking groove 44 on the inner wall of the locking groove 43, and at this time, under the action of the spring 45, the locking lever 41 is controlled to move in the reverse direction for a certain distance, so that the two ends of the locking lever 41 are respectively inserted into the locking hole 42 and the locking groove 44, and the main board 31 and the side board 32 are locked and fixed.

When the heat insulation board 3 needs to be detached, the wire 47 is directly electrified, so that an electromagnet is formed between the wire 47 and the steel rod 46, the locking rod 41 generates adsorption force, the locking rod 41 is separated from the locking groove 44, and the locking between the locking rod 41 and the main board 31 is released. And finally, the main board 31 and the side boards 32 are disassembled, so that the insulation board 3 can be disassembled, maintained and replaced.

Example 2: a construction method of an earthquake-resistant reinforced heat-insulating layer of an exterior wall of a building is used for constructing the heat-insulating layer and comprises the following steps:

s1, cleaning the outer wall, namely cleaning the surface of the outer wall and cleaning residues and cement blocks on the surface of the outer wall;

s2, installing and positioning, namely placing the frame 1 on the surface of the outer wall, and positioning the periphery of the frame 1;

s3, installing the fixing rod 13, fixing the fixing rod 13 on the surface of the outer wall, and adjusting the total length of the fixing rod 13 to realize the leveling of the fixing rod 13;

s4, installing the frame 1, lifting the frame 1 to enable the fixing rod 13 to be inserted into the fixing hole 12, and achieving self-locking of the fixing rod 13 and installation of the frame 1;

and S5, installing the heat-insulating plate 3, and embedding the heat-insulating plate 3 in the mounting hole 2 on the frame 1 to realize the fixed mounting of the heat-insulating plate 3.

The specific embodiments are only for explaining the present invention, and the present invention is not limited thereto, and those skilled in the art can make modifications without inventive contribution to the present embodiments as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

Claims (7)

1. The utility model provides a building outer wall antidetonation reinforcement heat preservation which characterized in that: the heat-insulation board comprises a frame (1), wherein a plurality of partition boards (11) are arranged in the frame (1) in a crossed manner, the frame (1) is divided into a plurality of square mounting holes (2) by the partition boards (11), a heat-insulation board (3) is embedded in each mounting hole (2), and the surface of the heat-insulation board (3) is flush with the surface of the frame (1);

the heat insulation plate (3) comprises a circular main plate (31) and four side plates (32), the side plates (32) are triangular, one side of each side plate abutting against the main plate (31) is arc-shaped, and a locking mechanism (4) is arranged among the main plate (31), the side plates (32) and the mounting holes (2);

the inner side wall of the main plate (31) is provided with a circular groove (33), the top wall of the groove (33) is provided with a pull rope (34) in a hanging mode, an anti-seismic ball (35) is arranged on the pull rope (34), and the anti-seismic ball (35) is located at the center of the main plate (31).

2. The anti-seismic reinforced heat-insulating layer for the exterior wall of the building according to claim 1, which is characterized in that: the locking mechanism (4) comprises four locking rods (41), the locking rods (41) penetrate through the vertex angles of the side plates (32) from the middle positions of the arc surfaces of the side plates (32), and locking holes (42) for the locking rods (41) to be inserted are formed in the four corners of the mounting holes (2);

the outward flange position of mainboard (31) is provided with the round confession locking lever (41) embedded draw-in groove (43), the lateral wall of draw-in groove (43) with the inner of locking lever (41) all is the slope form and sets up, the inner wall of draw-in groove (43) is provided with the confession locking groove (44) that the inner of locking lever (41) was pegged graft, and the diapire of locking hole (42) is provided with the control locking lever (41) are pegged graft spring (45) of locking groove (44).

3. The earthquake-resistant reinforced heat-insulating layer for the exterior wall of the building as claimed in claim 2, wherein: be provided with steel pole (46) in spring (45), the length of steel pole (46) is less than the length of spring (45), the outer wall winding of steel pole (46) has wire (47), the both ends of wire (47) are run through frame (1) and are located the surface of frame (1).

4. The anti-seismic reinforced heat-insulating layer for the exterior wall of the building according to claim 1, which is characterized in that: the four corners position of frame (1) inside wall all is provided with fixed orifices (12), it has dead lever (13) to peg graft in fixed orifices (12), dead lever (13) are located the outside one end of fixed orifices (12) is used for being fixed in the outer wall surface, and is located the one end outer wall of fixed orifices (12) inner wall is provided with a plurality of elasticity pothooks (14), and the inner wall of fixed orifices (12) is provided with the confession fixed slot (15) of elasticity pothook (14) embedding.

5. The earthquake-resistant reinforced heat-insulating layer for the exterior wall of the building as claimed in claim 4, wherein: the fixing rod (13) comprises a rod body (16) and a pair of pipe bodies (17), wherein the pair of pipe bodies (17) are in threaded connection with two ends of the rod body (16) respectively.

6. The anti-seismic reinforced heat-insulating layer for the exterior wall of the house building according to claim 5, which is characterized in that: the rod body (16) is provided with a through hole (18) for the rod piece to be inserted.

7. A construction method of an earthquake-resistant reinforced heat-insulating layer of an exterior wall of a building, which is used for constructing the heat-insulating layer according to any one of claims 1 to 6, and is characterized in that: the method comprises the following steps:

s1, cleaning the outer wall, namely cleaning the surface of the outer wall and cleaning residues and cement blocks on the surface of the outer wall;

s2, installing and positioning, namely placing the frame (1) on the surface of the outer wall, and positioning the periphery of the frame (1);

s3, mounting the fixing rod (13), fixing the fixing rod (13) on the surface of the outer wall, and adjusting the total length of the fixing rod (13) to realize leveling of the fixing rod (13);

s4, installing the frame (1), lifting the frame (1) to enable the fixing rod (13) to be inserted into the fixing hole (12), and realizing self-locking of the fixing rod (13) and installation of the frame (1);

and S5, installing the heat insulation board (3), and embedding the heat insulation board (3) in the installation hole (2) on the frame (1) to realize the fixed installation of the heat insulation board (3).

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