CN213115297U - Lightweight heat-preservation integrated aluminum plate convenient to mount - Google Patents

Abstract

The utility model provides an integrative aluminum plate of lightweight heat preservation convenient to installation belongs to heat preservation aluminum plate technical field for solve the fixed inefficiency of current heat preservation aluminum plate and the difficult technical problem who adjusts. The heat preservation mechanism comprises a vacuum heat preservation plate, a foam plate is fixed below the vacuum heat preservation plate, an aluminum plate is fixed above the vacuum heat preservation plate, an inserting plate is fixed on one side of the vacuum heat preservation plate and one side of the foam plate, a sliding groove is formed in the other side of the vacuum heat preservation plate and the other side of the foam plate, inserting plates of adjacent heat preservation mechanisms are clamped in the sliding groove, a first clamping mechanism is arranged on the side face of the vacuum heat preservation plate of the heat preservation mechanism at the most edge, a splicing mechanism is arranged on the other side of the vacuum heat preservation plate and the other side of the foam plate, a second clamping mechanism is arranged above the splicing mechanism, the adjacent heat preservation mechanisms are connected in a matched mode; the utility model discloses heat preservation aluminum plate fixes efficient and convenient height-adjusting.

Description

Lightweight heat-preservation integrated aluminum plate convenient to mount

Technical Field

The utility model belongs to the technical field of heat preservation aluminum plate, a lightweight heat preservation integrative aluminum plate convenient to installation is related to.

Background

The aluminum plate combines architectural and aesthetic structure designs, and the multiple functions of the aluminum plate are also perfectly embodied. The glass curtain wall material has unique texture, rich and durable color and luster, and diversified appearance and shape, and can be perfectly combined with glass curtain wall materials and stone curtain wall materials. The glass curtain wall has the advantages of perfect appearance, excellent quality, light dead weight which is one fifth of marble and one third of glass curtain wall, low maintenance cost and high cost performance, and greatly reduces the load of building structures and foundations.

Traditional heat preservation aluminum plate is fixed and is adopted inflation screw and adhesive to fix heat preservation aluminum plate on the wall more, however, is loaded down with trivial details through inflation screw and the fixed mode of adhesive, inconvenient quick fixation, and the fault-tolerant rate is low, receives the influence of wall unevenness easily simultaneously, makes heat preservation aluminum plate be difficult to make level, consequently, we provide the integrative aluminum plate of lightweight heat preservation convenient to installation.

SUMMERY OF THE UTILITY MODEL

The utility model aims at having the above-mentioned problem to current technique, provided a lightweight heat preservation integrative aluminum plate convenient to installation, the technical problem that the device will solve is: how to fix the heat preservation aluminum plate with high efficiency and conveniently adjust the heat preservation aluminum plate.

The purpose of the utility model can be realized by the following technical proposal:

the utility model provides an integrative aluminum plate of lightweight heat preservation convenient to installation, heat preservation mechanism includes vacuum insulation board, vacuum insulation board's below is fixed with the cystosepiment, vacuum insulation board's top is fixed with aluminum plate, one side of vacuum insulation board and cystosepiment is fixed with the insertion plate, the sliding tray has been seted up to the opposite side of vacuum insulation board and cystosepiment, the inside joint of sliding tray has the insertion plate of adjacent heat preservation mechanism, the vacuum insulation board side of the heat preservation mechanism of most marginal is provided with first latch mechanism, the opposite side of vacuum insulation board and cystosepiment is provided with splicing mechanism, splicing mechanism's top is provided with second latch mechanism, adjacent heat preservation mechanism passes through splicing mechanism cooperation and connects, adjacent heat preservation mechanism junction lock joint has closed.

The utility model discloses a theory of operation is: fix first clamping mechanism on the wall, later will insert the inside that closes the board and insert first clamping mechanism, later with second clamping mechanism joint in the sliding tray, later through second clamping mechanism height-adjusting to adjust vacuum insulation board and cystosepiment level and smooth, later with the inside that the board that closes of inserting of next heat preservation mechanism inserts splicing mechanism, with the closing mechanism lock joint in splicing mechanism's top, carry out the joint through second clamping mechanism to last heat preservation mechanism at last and fix.

The first clamping mechanism comprises a first clamping plate, a plurality of clamping grooves are formed in the side face of the first clamping plate, and the inserting plate is arranged inside the clamping grooves in a sliding mode.

By adopting the structure, the plurality of clamping grooves can provide fixed positions for the plurality of heat preservation mechanisms.

Splicing mechanism includes the connecting plate, and the both ends of connecting plate are fixed with the splice, and the catching groove has all been seted up to the top of splice, and the inside in catching groove all is provided with a plurality of splices, and the splice groove has all been seted up to one side of splice, and the opposite side of splice all is fixed with the sliding block, and the sliding block all slides and sets up the inside at the sliding tray.

Structure more than adopting, with the sliding block insert the sliding tray inside after lock, the lock joint piece provides hookup location for connecting two heat preservation mechanism, and the splice groove is convenient fixes the inserting plate.

A plurality of screw holes are all seted up to the top of concatenation piece, and the equal spiro union in inside of screw hole has the screw rod, and the cross recess has been seted up to the top of screw rod, and the below of screw rod is rotated and is provided with the dwang, and the bottom of dwang is fixed with the baffle.

By adopting the structure, the screw rod is rotated by the tool through the cross groove, the screw rod drives the rotating rod to move, and the rotating rod drives the baffle plate to move, so that the level of the heat preservation mechanism is adjusted.

The second clamping mechanism comprises a second clamping plate, a plurality of inserting blocks are arranged below the second clamping plate, a plurality of clamping blocks are fixed on the side faces of the inserting blocks, and the inserting blocks are located inside the buckling grooves.

By adopting the structure, the inserting block is inserted into the buckling groove, and then the second clamping plate is fixed on the side surface of the splicing mechanism, so that the splicing mechanism is fixed.

The closing mechanism comprises a closing plate, a pressing hole is formed in the upper portion of the closing plate, a clamping cylinder is fixed below the pressing hole, a partition plate is fixed inside the clamping cylinder, a pressing rod is arranged on the partition plate in a sliding mode, a pressing plate is fixed above the pressing rod and arranged inside the pressing hole in a sliding mode, a pressing plate is fixed below the pressing rod, a pressing plate is arranged inside the pressing hole in a sliding mode, a pressing plate is fixed below the pressing rod, and a spring is arranged between the clamping cylinder and the pressing plate.

By adopting the structure, the pressing plate is pressed to drive the pressing rod to slide on the partition plate, the pressing rod drives the abutting plate to extrude the spring, the abutting plate drives the triangular clamping block to contract towards the inside of the clamping cylinder, and the locking of the buckling block is released.

Compared with the prior art, this lightweight heat preservation integrative aluminum plate convenient to installation has following advantage:

1. the first clamping mechanism, the heat insulation mechanism, the second clamping mechanism and the splicing mechanism are matched, so that a plurality of vacuum heat insulation plates and the foam board can be conveniently and quickly clamped into a whole, the mounting steps are simplified, and the mounting efficiency of the vacuum heat insulation plates and the foam board is improved;

2. the splicing mechanism can adjust the distance between the vacuum insulation board and the foam board and the wall surface through the matching of the screw and the resisting baffle, thereby avoiding the horizontal influence of the unevenness of the wall surface on the vacuum insulation board and the foam board and being suitable for different wall surfaces;

3. the first clamping mechanism is matched with the second clamping mechanism, so that a plurality of vacuum heat-insulation plates and foam plates can be fixed, and errors in mounting of the heat-insulation aluminum plates are avoided;

4. the splicing mechanism is matched with the closing mechanism, so that the height of the closing plate can be adjusted to be horizontally spliced with the splicing block, and the universality is improved.

Drawings

Fig. 1 is a schematic view of the assembly structure of the present invention;

FIG. 2 is a schematic perspective view of a part of the components of the present invention;

fig. 3 is a schematic view of a three-dimensional structure of the middle splicing mechanism of the present invention;

fig. 4 is a schematic view of a partial cross-sectional structure of the middle splicing mechanism of the present invention;

fig. 5 is a schematic view of a partial three-dimensional structure of the middle splicing mechanism of the present invention;

fig. 6 is a schematic sectional structure view of the closing mechanism of the present invention;

in the figure: 1-a first clamping mechanism, 101-a clamping groove, 102-a first clamping plate, 2-a heat preservation mechanism, 201-a vacuum heat preservation plate, 202-an inserting plate, 203-a foam plate, 204-a sliding groove, 3-a second clamping mechanism, 301-a second clamping plate, 302-an inserting block, 4-a splicing mechanism, 401-a threaded hole, 402-a splicing groove, 403-a buckling groove, 404-a splicing block, 405-a connecting plate, 406-a sliding block, 407-a buckling block, 408-a resisting plate, 409-a screw rod, 410-a cross groove, 411-a rotating rod, 5-a closing mechanism, 501-a pressing rod, 502-a closing plate, 503-a pressing plate, 504-a triangular clamping block, 505-a spring, 506-a resisting plate, 507-a partition plate, 508-Snap-on Cartridge.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

In the description of this patent, it is to be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientations and positional relationships indicated in the drawings for the convenience of describing the patent and for the simplicity of description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the patent.

In the description of this patent, it is noted that unless otherwise specifically stated or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly and can include, for example, fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed. The specific meaning of the above terms in this patent may be understood by those of ordinary skill in the art as appropriate.

Referring to fig. 1-6, the embodiment provides a lightweight heat-insulating integrated aluminum plate convenient to mount, a heat-insulating mechanism 2 includes a vacuum heat-insulating plate 201, a foam plate 203 is fixed below the vacuum heat-insulating plate 201, an aluminum plate is fixed above the vacuum heat-insulating plate 201, an insertion plate 202 is fixed on one side of the vacuum heat-insulating plate 201 and one side of the foam plate 203, a sliding groove 204 is formed on the other side of the vacuum heat-insulating plate 201 and the other side of the foam plate 203, the insertion plate 202 of the adjacent heat-insulating mechanism 2 is clamped inside the sliding groove 204, a first clamping mechanism 1 is arranged on the side surface of the vacuum heat-insulating plate 201 of the heat-insulating mechanism 2 at the outermost edge, a splicing mechanism 4 is arranged on the other side of the vacuum heat-insulating plate 201 and the foam plate 203, a second clamping mechanism 3 is arranged above the splicing mechanism 4, the adjacent heat-; fix first latch mechanism 1 on the wall, later insert the inside of first latch mechanism 1 with inserting board 202, later with the 3 joints of second latch mechanism in sliding tray 204, later through 3 height-adjusting of second latch mechanism, thereby adjust vacuum insulation board 201 and cystosepiment 203 levelly and smoothly, later insert the inside of splicing mechanism 4 with inserting board 202 of next heat preservation mechanism 2, with the 5 lock joints of closure mechanism in the top of splicing mechanism 4, it is fixed to carry out the joint to last heat preservation mechanism 2 through second latch mechanism 3 at last.

The first clamping mechanism 1 comprises a first clamping plate 102, a plurality of clamping grooves 101 are formed in the side face of the first clamping plate 102, and the inserting plates 202 are arranged inside the clamping grooves 101 in a sliding mode; several snap-in grooves 101 may provide a fixed location for multiple warming mechanisms 2.

The splicing mechanism 4 comprises a connecting plate 405, splicing blocks 404 are fixed at two ends of the connecting plate 405, buckling grooves 403 are formed above the splicing blocks 404, a plurality of buckling blocks 407 are arranged inside the buckling grooves 403, splicing grooves 402 are formed in one side of each splicing block 404, sliding blocks 406 are fixed on the other side of each splicing block 404, and the sliding blocks 406 are arranged inside the sliding grooves 204 in a sliding mode; the sliding block 406 is inserted into the sliding groove 204 and then locked, the fastening block 407 provides a connecting position for connecting the two heat preservation mechanisms 2, and the splicing groove 402 facilitates fixing the splicing plate 202.

A plurality of threaded holes 401 are formed above the splicing blocks 404, threaded rods 409 are screwed in the threaded holes 401, cross grooves 410 are formed above the threaded rods 409, rotating rods 411 are rotatably arranged below the threaded rods 409, and the bottom of each rotating rod 411 is fixedly provided with a resisting baffle 408; the screw rod 409 is rotated by a tool through the cross slot 410, the screw rod 409 drives the rotating rod 411 to move, and the rotating rod 411 drives the baffle 408 to move, so that the level of the heat preservation mechanism 2 is adjusted.

The second clamping mechanism 3 comprises a second clamping plate 301, a plurality of inserting and combining blocks 302 are arranged below the second clamping plate 301, a plurality of clamping blocks are fixed on the side surfaces of the inserting and combining blocks 302, and the inserting and combining blocks 302 are located inside the buckling grooves 403; the insertion block 302 is inserted into the inside of the fastening groove 403, and then the second chucking plate 301 is fixed to the side surface of the splicing mechanism 4, thereby fixing the splicing mechanism 4.

The closing mechanism 5 comprises a closing plate 502, a pressing hole is formed above the closing plate 502, a clamping cylinder 508 is fixed below the pressing hole, a partition 507 is fixed inside the clamping cylinder 508, a pressing rod 501 is arranged on the partition 507 in a sliding mode, a pressing plate 503 is fixed above the pressing rod 501, the pressing plate 503 is arranged inside the pressing hole in a sliding mode, a pressing plate 506 is fixed below the pressing rod 501, and a spring 505 is arranged between the clamping cylinder 508 and the pressing plate 506; pressing the pressing plate 503, the pressing plate 503 drives the pressing rod 501 to slide on the partition 507, the pressing rod 501 drives the pressing plate 506 to press the spring 505, the pressing plate 506 drives the triangular fixture block 504 to contract towards the inside of the clamping cylinder 508, and the locking of the clamping block 407 is released.

Two triangular clamping blocks 504 are rotatably arranged on the pressing plate 506, two shrinkage holes are formed in the side surface of the clamping cylinder 508, and the triangular clamping blocks 504 slide in the shrinkage holes; the locking cylinder 508 is inserted into the locking groove 403, and the triangular latch 504 is locked and fixed with the locking block 407.

The utility model discloses a theory of operation:

fixing a first clamping plate 102 on a wall surface, then inserting an inserting plate 202 into a clamping groove 101 of the first clamping plate 102, then inserting an inserting block 302 into a buckling groove 403, then fixing a second clamping plate 301 on the side surface of a vacuum heat-insulating plate 201 and a foam plate 203, inserting a sliding block 406 into the sliding groove 204, then locking, rotating a screw 409 through a cross groove 410 by using a tool, driving a rotating rod 411 to move by using the screw 409, driving a baffle 408 to move by using the rotating rod 411, thereby adjusting the proper height, keeping the vacuum heat-insulating plate 201 and the foam plate 203 horizontal, then inserting a clamping cylinder 508 into the buckling groove 403, clamping and fixing a triangular clamping block 504 and the buckling block 407, picking up the next vacuum heat-insulating plate 201 and the foam plate 203, inserting the inserting plate 202 on one side of the vacuum heat-insulating plate 201 and the foam plate 203 into the splicing groove 402, fixing the last splicing mechanism 4 on the other side of the vacuum heat-insulating plate 201 and the foam plate 203, finally, the insertion block 302 is inserted into the buckling groove 403, and then the second clamping plate 301 is fixed on the wall surface, so that the vacuum insulation board 201 and the foam board 203 are fixed through the fixing and splicing mechanism 4.

In conclusion, the first clamping mechanism 1, the heat insulation mechanism 2, the second clamping mechanism 3 and the splicing mechanism 4 are matched, so that the vacuum heat insulation plates 201 and the foam plates 203 can be conveniently and quickly clamped into a whole, the installation steps are simplified, and the installation efficiency of the vacuum heat insulation plates 201 and the foam plates 203 is improved; the splicing mechanism 4 is matched with the resisting baffle 408 through the screw 409, so that the distance between the vacuum heat-insulation board 201 and the foam board 203 and the wall surface can be adjusted, the horizontal influence of the uneven wall surface on the vacuum heat-insulation board 201 and the foam board 203 is avoided, and the splicing mechanism can be suitable for different wall surfaces; the first clamping mechanism 1 is matched with the second clamping mechanism, so that the vacuum heat-insulation plates 201 and the foam plates 203 can be fixed, and errors in installation of the heat-insulation aluminum plates are avoided; the splicing mechanism 4 and the closing mechanism 5 are matched, so that the height of the closing plate 502 can be adjusted to be horizontally spliced with the splicing block 404, and the universality is improved.

Although the preferred embodiments of the present patent have been described in detail, the present patent is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present patent within the knowledge of those skilled in the art.

Claims (7)

1. A lightweight heat-insulation integrated aluminum plate convenient to mount comprises a plurality of heat-insulation mechanisms (2) and is characterized in that each heat-insulation mechanism (2) comprises a vacuum heat-insulation plate (201), a foam plate (203) is fixed below the vacuum heat-insulation plate (201), an aluminum plate is fixed above the vacuum heat-insulation plate (201), an insertion plate (202) is fixed on one side of each of the vacuum heat-insulation plate (201) and the foam plate (203), a sliding groove (204) is formed in the other side of each of the vacuum heat-insulation plate (201) and the foam plate (203), the insertion plates (202) of adjacent heat-insulation mechanisms (2) are clamped in the sliding groove (204), a first clamping mechanism (1) is arranged on the side face of the vacuum heat-insulation plate (201) of the heat-insulation mechanism (2) at the outermost edge, a splicing mechanism (4) is arranged on the other side of each of the vacuum heat-insulation plate (201) and the foam plate, the adjacent heat preservation mechanisms (2) are connected in a matching way through the splicing mechanism (4), and the joint of the adjacent heat preservation mechanisms (2) is buckled with the closing mechanism (5).

2. The light-weight heat-preservation integrated aluminum plate convenient to mount as claimed in claim 1, wherein the first clamping mechanism (1) comprises a first clamping plate (102), a plurality of clamping grooves (101) are formed in the side surface of the first clamping plate (102), and the inserting plates (202) are slidably arranged inside the clamping grooves (101).

3. The light-weight heat-preservation integrated aluminum plate convenient to mount according to claim 1, wherein the splicing mechanism (4) comprises a connecting plate (405), splicing blocks (404) are fixed to two ends of the connecting plate (405), fastening grooves (403) are formed in the upper portions of the splicing blocks (404), a plurality of fastening blocks (407) are arranged in the fastening grooves (403), the splicing grooves (402) are formed in one sides of the splicing blocks (404), sliding blocks (406) are fixed to the other sides of the splicing blocks (404), and the sliding blocks (406) are arranged in the sliding grooves (204) in a sliding mode.

4. The light-weight heat-preservation integrated aluminum plate convenient to mount according to claim 3, wherein a plurality of threaded holes (401) are formed above the splicing blocks (404), threaded rods (409) are screwed inside the threaded holes (401), cross grooves (410) are formed above the threaded rods (409), a rotating rod (411) is rotatably arranged below the threaded rods (409), and a baffle plate (408) is fixed at the bottom of the rotating rod (411).

5. The light-weight heat-preservation integrated aluminum plate convenient to mount according to claim 3 or 4, wherein the second clamping mechanism (3) comprises a second clamping plate (301), a plurality of inserting and combining blocks (302) are arranged below the second clamping plate (301), a plurality of clamping blocks are fixed on the side surfaces of the inserting and combining blocks (302), and the inserting and combining blocks (302) are located inside the buckling grooves (403).

6. The light-weight heat-preservation integrated aluminum plate convenient to mount according to claim 1, wherein the closing mechanism (5) comprises a closing plate (502), a pressing hole is formed in the upper portion of the closing plate (502), a clamping cylinder (508) is fixed below the pressing hole, a partition plate (507) is fixed inside the clamping cylinder (508), a pressing rod (501) is slidably arranged on the partition plate (507), a pressing plate (503) is fixed above the pressing rod (501), the pressing plate (503) is slidably arranged inside the pressing hole, a pressing plate (506) is fixed below the pressing rod (501), and a spring (505) is arranged between the clamping cylinder (508) and the pressing plate (506).

7. The light-weight heat-preservation integrated aluminum plate convenient to mount as claimed in claim 6, wherein two triangular clamping blocks (504) are rotatably arranged on the pressing plate (506), two shrinkage holes are formed in the side surface of the clamping cylinder (508), and the triangular clamping blocks (504) slide in the shrinkage holes.

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