CN115434446A - External wall sandwich heat-insulation and anti-seismic integrated structure - Google Patents

Abstract

The invention provides an external wall sandwich heat-insulation and anti-seismic integrated structure, which relates to the technical field of external wall processing and solves the problems that the existing external wall sandwich heat-insulation and anti-seismic integrated structure is mainly formed by splicing heat-insulation and anti-seismic split type of an external wall in practical application, gaps which are difficult to avoid exist among all parts and use defects exist.

Description

External wall sandwich heat-insulation and anti-seismic integrated structure

Technical Field

The invention belongs to the technical field of outer wall processing, and particularly relates to an outer wall sandwich heat-insulation and earthquake-resistance integrated structure.

Background

The outer wall is defined by a judgment method, A-B is set as a wall, if the A-B wall line can cut the related building enclosure, the wall is an inner wall, otherwise, the wall is an outer wall. From the architectural perspective, the boundary member for enclosing a building to form an indoor space and an outdoor space is called an outer wall. It has the functions of: bear certain load, shelter from wind and rain, heat preservation is thermal-insulated, noise prevention, fire prevention safety etc. and wall body material generally has many tiny holes, or because the installation is not closely knit or the material shrinks etc. can produce some connectivity gaps. Due to the holes and the gaps, cold air permeates into the room from the windward wall surface by the pressure of outdoor wind in winter, temperature difference exists between the indoor and the outdoor, and indoor hot air permeates into the outer wall from the inner wall, so that the air permeation of the outer wall is realized by the wind pressure and the hot pressing, and the outer wall sandwich heat insulation structure is further required to be used.

For example, application No.: CN201410340503.3, a prefabricated sandwich external wall panel with a shear key slot box and a processing method thereof, wherein an inner leaf plate of the prefabricated sandwich external wall panel is provided with a pre-embedded shear key slot box connected with a superposed beam, the shear key slot box comprises a box body and a connecting cable, the box body is formed by enclosing an upper top plate, a lower bottom plate and three side plates, and the open side of the shear key slot box is superposed with the inner side surface of the inner leaf plate. The processing method of the prefabricated sandwich external wall panel with the shear key groove box comprises the following steps: making a mold on the bench mold, arranging a reinforcing mesh of an inner blade plate in the mold, and attaching the shear key groove box to the bench mold; pouring inner blade plate concrete; an insulating layer and a reinforcing mesh are distributed on the inner leaf plate; pouring outer leaf plate concrete; manufacturing a decorative surface on the outer side of the outer blade plate; and demolding to obtain the product. The shear key groove box is adopted to replace an overhanging anchoring steel bar to be connected with the superposed beam, the production mould of the external wall panel is simplified, the production efficiency is improved, the decoration of the external decorative surface can be completed during production, the construction and the transportation are convenient, and when the shear key groove box is connected with a superposed building and a wall panel, the anti-seismic capacity is strong and the structural performance is good.

The external wall sandwich heat-insulation anti-seismic structure similar to the application has the following defects:

1. current outer wall sandwich heat preservation antidetonation structure is mostly the split type piece together of heat preservation antidetonation of outer wall when in practical application and constitutes, and then can make to have the gap that is difficult to avoid between each part, and then can have the use defect.

2. Current outer wall sandwich heat preservation antidetonation structure is mostly to leave buffer space in advance or increase the elasticity shock absorber and move away to avoid possible earthquakes when practical application, but above-mentioned mode can make the tightness variation of wall body, and then has the potential safety hazard.

Therefore, in view of the above, research and improvement are made for the existing structure and defects, and an integrated structure for exterior wall sandwich insulation and earthquake resistance is provided, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides an external wall sandwich heat-insulation and anti-seismic integrated structure, which is used for solving the problems that the existing external wall sandwich heat-insulation and anti-seismic integrated structure is mainly formed by splicing and splicing heat-insulation and anti-seismic split type of an external wall in practical application, gaps which are difficult to avoid exist among all parts, use defects exist, and buffer space is reserved or an elastic shock absorber is added for shock absorption in practical application mostly for shock absorption in anti-seismic mode, but the firmness of a wall body is poor due to the mode, and further potential safety hazards exist.

The invention relates to an external wall sandwich heat-insulation earthquake-resistant integrated structure, which is achieved by the following specific technical means:

an external wall sandwich heat-preservation earthquake-resistant integrated structure comprises a bearing mechanism,

the main part of bearing the weight of the mechanism is the hollow frame-shaped structural design of inside, and the inside four corners position of main part of bearing the weight of the mechanism has all seted up the mounting hole, still installs transmission mechanism in the inside of bearing the weight of the mechanism.

Further, the mounting mechanism includes:

the main body of the mounting assembly is designed into an L-shaped structure, the longitudinal members in the two mounting assemblies are arranged at the left side and the right side of the rear end surface of the supporting assembly through transverse members, and square grooves are formed in the longitudinal members in the mounting assembly;

further, the transmission mechanism includes:

the main body of the guide component is in a cross-shaped structural design, the front end face of the guide component is also provided with a cross-shaped groove, the front end of the guide component is in a closed transparent structural design, and the length and width of the guide component are consistent with those of the inner groove of the support component;

further, the fossil fragments mechanism still includes:

the main body of the transfer component is designed into a cuboid structure, an interface is further mounted in the center of the rear end face of the transfer component and matched with the pumping pressure component, the length of the transfer component is consistent with the distance between the two supporting components, the transfer component is mounted at the inner side positions of the two transfer components, and a mounting mechanism is further mounted on the rear side of the transfer component;

further, the bearing mechanism comprises:

the main body of the supporting component is of a hollow frame-shaped structural design, mounting holes are formed in four corners of the interior of the supporting component, a rectangular mounting groove is formed in the front end face of the supporting component, and a filling component is further mounted on the rear side of the supporting component;

further, the keel mechanism includes:

the main body of the supporting component is designed into an arc-shaped structure, the two supporting components are installed in a transverse array mode, force transmission components with elastic reset components are installed on the upper side and the lower side of the rear end face of the two supporting components, the supporting component is internally designed into a hollow structure and is provided with hydraulic oil, and the distance between the upper side and the lower side of the supporting component is consistent with the length of the supporting component;

further, the transmission mechanism further includes:

the main body of the anti-seismic assembly is provided with hydraulic rods and damping plates, wherein the four damping plates face the intersections of the crossed guide assemblies, the hydraulic rods are arranged on the outer sides of the damping plates in the four anti-seismic assemblies, and the four anti-seismic assemblies are arranged at the inner sides of the guide assemblies in an annular array;

further, the mounting mechanism further includes:

the main body of the limiting component is of a special-shaped structure, two limiting components are installed in opposite directions, elastic components are arranged on the outer sides of the two limiting components, and the inner parts of longitudinal components in the two limiting components are matched with square grooves in the mounting component;

further, the bearing mechanism further comprises:

the main body of the filling assembly is designed into a cuboid structure with a hollow interior, a T-shaped groove which is communicated in two directions is formed in the filling assembly, mounting holes matched with the supporting assembly are formed in two narrow-diameter transverse components in the filling assembly in a longitudinal array mode, and a transmission mechanism is arranged on the rear side of the filling assembly;

further, the transmission mechanism further includes:

the main body of the pumping pressure component is a telescopic sleeve structure design with a pumping liquid pipe inside, wherein four spray holes are formed in the outer peripheral surface of the sleeve with the smaller diameter in an annular array mode, the four spray holes are consistent with the four positions of the guide component in direction, and a keel mechanism is further mounted on the front side of the pumping pressure component.

Compared with the prior art, the invention has the following beneficial effects:

1. because the supporting component is arranged, the heat insulation material can be inserted into the inner position of the groove, so that the heat insulation material, the supporting component and the outer wall form a whole, and the heat insulation material cannot break to generate a interlinking reaction due to the fact that the outer wall is stressed too much when the outer wall is stressed.

2. Owing to be provided with the carry mechanism, consequently can insert the inboard position of carrying the subassembly of carrying in the carry mechanism with the outer wall, can carry out the chucking spacing after the inside of carrying the subassembly is inserted to the outer wall through spacing subassembly with the outer wall extrusion, then fasten through adding the mounting to the inboard of carrying subassembly and spacing subassembly again, and then reach more convenient purpose.

3. Owing to be provided with fossil fragments mechanism, the antidetonation subassembly is by propping up the subassembly through in pumping pressure subassembly and the fossil fragments mechanism and link to each other, and then when installing the subassembly that props up at the supporting component front side and receive extrusion or vibration, can disperse the pressure that will receive through the pumping pressure subassembly with the oil pressure all around through the transmission subassembly, and then reach the purpose of protection wall body, at last through to the inside filling of filling subassembly seal can.

Drawings

FIG. 1 is a schematic diagram of the right side view of the present invention in a half-section state.

Fig. 2 is a schematic bottom side view of the present invention in a half-section configuration.

Fig. 3 is a schematic axial side view of a part of the structure of the present invention in a half-section.

Fig. 4 is a schematic rear side view of the present invention in a half-section state.

Fig. 5 is a right side view structural diagram in the disassembled state of the present invention.

Fig. 6 is a schematic view of the assembly structure of the bearing mechanism and the transmission mechanism of the invention.

Fig. 7 is a schematic structural diagram of the bearing mechanism of the invention.

Fig. 8 is a schematic structural view of the mounting mechanism of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a carrying mechanism; 101. a support assembly; 102. filling the assembly; 2. a transfer mechanism; 201. a guide assembly; 202. an anti-seismic assembly; 203. a pumping assembly; 3. a keel mechanism; 301. a prop-up assembly; 302. a transfer assembly; 4. a mounting mechanism; 401. mounting the component; 402. and a limiting component.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

The embodiment is as follows:

as shown in figures 1 to 8:

the invention provides an external wall sandwich heat-insulation and earthquake-resistance integrated structure, which comprises: the support means 1 is provided with a support means,

the main part of bearing mechanism 1 is the hollow frame shape structural design in inside, and bears the inside four corners position of main part of mechanism 1 and all seted up the mounting hole, still installs transfer mechanism 2 in the inside of bearing mechanism 1.

Wherein, the transmission mechanism 2 includes:

the main part of direction subassembly 201, direction subassembly 201 are "ten" font structural design, and the preceding terminal surface of direction subassembly 201 has still seted up "ten" font groove, are the design of closed transparent structure at the front end of direction subassembly 201 to the length and width of direction subassembly 201 all is unanimous with the slotted length and width in inside of supporting component 101.

Wherein, fossil fragments mechanism 3 still includes:

the main body of the transfer component 302 is designed into a cuboid structure, an interface is further mounted at the center of the rear end face of the transfer component 302 and is matched with the pumping component 203, the length of the transfer component 302 is consistent with the distance between the two supporting components 301, the transfer component 302 is mounted at the inner side positions of the two transfer components 302, and the mounting mechanism 4 is further mounted at the rear side of the transfer component 302.

Wherein, load bearing mechanism 1 still includes:

the main body of the filling assembly 102 is a cuboid structure with a hollow interior, a two-way through T-shaped groove is further formed in the filling assembly 102, mounting holes matched with the supporting assembly 101 are further formed in the transverse members with two narrow diameters in the filling assembly 102 in a longitudinal array mode, and the rear side of the filling assembly 102 is further provided with a transmission mechanism 2.

Wherein, transfer mechanism 2 still includes:

the main body of the pumping pressure component 203 is designed into a telescopic sleeve structure with a pumping pipe inside, wherein the outer peripheral surface of the sleeve with a smaller diameter is provided with four spray holes in an annular array, the directions of the four spray holes are consistent with those of the four positions of the guide component 201, and the front side of the pumping pressure component 203 is also provided with a keel mechanism 3.

Wherein, load bearing mechanism 1 includes:

supporting component 101, supporting component 101's main part is inside hollow frame shape structural design, and the inside four corners position of supporting component 101 has all seted up the mounting hole, the mounting groove of rectangle has still been seted up at supporting component 101's preceding terminal surface, filling subassembly 102 is still installed at supporting component 101's rear side, consequently, can insert the inside position of recess with insulation material, make insulation material and supporting component 101 and outer wall form a whole, can not cause insulation material to break and produce the interlinkage reaction because of the outer wall atress is too big when the outer wall atress.

Wherein, mount mechanism 4 still includes:

spacing subassembly 402, the main part of spacing subassembly 402 is the dysmorphism structure, and wherein two spacing subassemblies 402 are the subtend installation, and the outside of two spacing subassemblies 402 all is provided with elastic component, and the longitudinal member in two spacing subassemblies 402 is inside to be seted up with the square groove phase-match in the mount subassembly 401.

Wherein, mount mechanism 4 includes:

the mounting component 401 is characterized in that the main body of the mounting component 401 is of an L-shaped structural design, longitudinal members in the mounting component 401 at two positions are installed at the left and right sides of the rear end face of the supporting component 101 through transverse members, a square groove is further formed in the interior of the longitudinal member in the mounting component 401, an outer wall is inserted into the inner side of the mounting component 401 in the mounting mechanism 4, after the outer wall is inserted into the interior of the mounting component 401, the outer wall can be extruded through the limiting component 402 to be clamped and limited, then fixing pieces are added to the inner sides of the mounting component 401 and the limiting component 402 to be fastened, and the purpose of being more convenient is achieved.

Wherein, transfer mechanism 2 still includes:

the main body of the anti-seismic assembly 202 is a hydraulic rod and a damping plate, wherein the four damping plates face the intersection of the cross-shaped guide assembly 201, the hydraulic rods are arranged on the outer sides of the damping plates in the four anti-seismic assemblies 202, and the four anti-seismic assemblies 202 are arranged on the inner side of the guide assembly 201 in an annular array.

Wherein, fossil fragments mechanism 3 includes:

prop up subassembly 301, the main part that props up subassembly 301 is the arc structural design, and two places prop up subassembly 301 and are the installation of horizontal array, prop up the power transmission subassembly that has the elasticity subassembly that resets at both sides about the rear end face of subassembly 301 in two places, the inside that props up subassembly 301 is the hollow structure design, and install hydraulic oil, prop up the interval between the upper and lower both sides of subassembly 301 and the length unanimity of supporting component 101, antidetonation subassembly 202 is by propping up subassembly 301 in passing through pumping pressure subassembly 203 and keel mechanism 3 and linking to each other, and then when the subassembly 301 that props up of installing at the supporting component 101 front side receives the extrusion or vibration, can disperse the pressure that will receive through pumping pressure subassembly 203 with oil pressure to all around through transmission subassembly 302, and then reach the purpose of protection wall body, finally through the inside sealed filling to filling subassembly 102 can.

When in use: the outer side surface of a frame-shaped supporting component 101 in the bearing mechanism 1 faces the outer side of a wall body, an outer wall component is assembled on the rear side surface of the supporting component 101 and is installed through the inner positions of four round holes formed in the four corners of the inner portion of the supporting component 101, and a groove is formed in the front side of a main body of the supporting component 101, so that a heat insulation material can be inserted into the inner position of the groove, the heat insulation material, the supporting component 101 and the outer wall form a whole, and when the outer wall is stressed, the heat insulation material cannot be broken to generate a link reaction due to overlarge stress of the outer wall;

when the outer wall is assembled, the outer wall is inserted into the inner side position of the mounting component 401 in the mounting mechanism 4, after the outer wall is inserted into the mounting component 401, the outer wall is extruded through the limiting component 402 and then clamped and limited, and then the outer wall is fastened by adding fixing pieces to the inner sides of the mounting component 401 and the limiting component 402, so that the purpose of being more convenient is achieved;

and the inner side of the frame-shaped supporting component 101 is also provided with a guide component 201 in the transmission mechanism 2, the inner side of the guide component 201 is also provided with an anti-seismic component 202, the anti-seismic component 202 is connected with a supporting component 301 in the keel mechanism 3 through a pumping component 203, so that when the supporting component 301 arranged at the front side of the supporting component 101 is extruded or vibrated, the oil pressure is dispersed to the periphery through the transmission component 302 by the pressure applied by the pumping component 203, the purpose of protecting the wall body is further achieved, and finally, the filling and sealing are carried out on the interior of the filling component 102.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to practitioners skilled in this art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (10)

1. The utility model provides an external wall with filling heat preservation antidetonation integral structure which characterized in that: comprises a bearing mechanism, a bearing mechanism and a bearing mechanism,

the main part of bearing the weight of the mechanism is the hollow frame-shaped structural design of inside, and the inside four corners position of main part of bearing the weight of the mechanism has all seted up the mounting hole, still installs transmission mechanism in the inside of bearing the weight of the mechanism.

2. The exterior wall sandwich heat-insulation earthquake-resistant integrated structure as claimed in claim 1, wherein: the bearing mechanism comprises:

the supporting component, supporting component's main part are inside hollow frame shape structural design, and supporting component's inside four corners position has all seted up the mounting hole, still seted up the mounting groove of rectangle at supporting component's preceding terminal surface, still installs the filling subassembly in supporting component's rear side.

3. The external wall sandwich heat-insulation earthquake-resistant integrated structure as claimed in claim 2, wherein: the bearing mechanism further comprises:

the filling subassembly, the main part of filling subassembly are inside hollow cuboid structural design, and the inside of filling subassembly still sets up two-way "T" shape groove that link up, and the transverse component of two narrow footpaths in the filling subassembly is inside still to be longitudinal array and set up with supporting component assorted mounting hole, still is provided with transmission mechanism in the rear side of filling subassembly.

4. The external wall sandwich heat-insulation earthquake-resistant integrated structure as claimed in claim 3, wherein: the transfer mechanism includes:

the main part of direction subassembly, direction subassembly are "ten" font structural design, and "ten" word groove has still been seted up to the preceding terminal surface of direction subassembly, are sealed transparent structural design at the front end of direction subassembly to the length and width of direction subassembly all is unanimous with the grooved length and width in inside of supporting component.

5. The exterior wall sandwich heat-insulation earthquake-resistant integrated structure as claimed in claim 4, wherein: the transfer mechanism further comprises:

the main body of the anti-seismic assembly is a hydraulic rod and damping plates, wherein the four damping plates face to the cross position of the cross-shaped guide assembly, the hydraulic rods are arranged on the outer sides of the damping plates in the four anti-seismic assemblies, and the four anti-seismic assemblies are arranged on the inner side of the guide assembly in an annular array mode.

6. The external wall sandwich heat-insulation earthquake-resistant integrated structure as claimed in claim 5, wherein: the transfer mechanism further comprises:

the main body of the pumping pressure component is a telescopic sleeve structure design with a pumping liquid pipe inside, wherein four spray holes are formed in the outer peripheral surface of the sleeve with the smaller diameter in an annular array mode, the four spray holes are consistent with the four positions of the guide component in direction, and a keel mechanism is further mounted on the front side of the pumping pressure component.

7. The external wall sandwich heat-insulation earthquake-resistant integrated structure as claimed in claim 6, wherein: the fossil fragments mechanism includes:

the supporting component is in arc structural design, the supporting component is installed in two positions and is in transverse array installation, force transmission components with elastic reset components are installed on the upper side and the lower side of the rear end face of the supporting component in the two positions, the supporting component is in hollow structural design, hydraulic oil is installed, and the distance between the upper side and the lower side of the supporting component is consistent with the length of the supporting component.

8. The external wall sandwich heat-insulation earthquake-resistant integrated structure as claimed in claim 7, wherein: the keel mechanism further comprises:

the main part of transmission subassembly, transmission subassembly are cuboid structural design, and transmission subassembly's rear end face central point puts and still installs the interface to with pump pressure subassembly phase-match, and transmission subassembly's length and two places prop up the interval between the subassembly unanimous, and install the inboard position at two transmission subassemblies, still install the carry mechanism at transmission subassembly's rear side.

9. The external wall sandwich heat-insulating and earthquake-resistant integrated structure as claimed in claim 8, wherein: the mount mechanism includes:

the main body of the mounting component is designed into an L-shaped structure, the longitudinal members in the mounting component at two positions are arranged at the left side and the right side of the rear end face of the supporting component through transverse members, and square grooves are formed in the longitudinal members in the mounting component.

10. The external wall sandwich heat-insulating and earthquake-resistant integrated structure as claimed in claim 9, wherein: the mount mechanism further includes:

the main body of the limiting assembly is of a special-shaped structure, the two limiting assemblies are installed oppositely, the outer sides of the two limiting assemblies are provided with elastic assemblies, and the longitudinal members in the two limiting assemblies are internally provided with square grooves matched with the square grooves in the hanging assembly.

Images