CN108086571B - Edge-closing drop-stage suspended ceiling - Google Patents

Abstract

The utility model discloses a side-closing drop-level suspended ceiling, which comprises: the first end of the bearing cantilever is fixed on the wall surface, and the second end of the bearing cantilever extends towards the direction far away from the wall surface; the first plane plate is positioned below the bearing cantilever, the first end of the first plane plate is fixed on the wall surface, and the second end of the first plane plate extends in a direction away from the wall surface; the first vertical plate is arranged opposite to the third vertical plate, the first vertical plate is hung on the bearing cantilever, and the end part, far away from the second vertical plate, of the third vertical plate is spliced with the second end of the first plane plate. The edge-closing and falling suspended ceiling provided by the utility model can be used for rapidly completing the installation of the panel of the edge suspended ceiling.

Description

Edge-closing drop-stage suspended ceiling

Technical Field

The utility model relates to the technical field of decoration of indoor top surfaces of buildings, in particular to a side-closing and side-falling suspended ceiling.

Background

The edge-closing drop-level suspended ceiling generally comprises two or more horizontal plates, wherein the horizontal plates are connected through vertical plates to form a step-shaped structure. At present, in a traditional edge-folding and falling suspended ceiling, each horizontal plate and each vertical plate need independent vertical hanging rods to hang, and a plurality of vertical hanging rods are needed even for plates with larger areas to ensure the stability of a hanging structure.

For this design, the following drawbacks exist: firstly, the suspended ceiling has large weight, the suspended ceiling keel is easy to deform at the position connected with the vertical hanging piece due to concentrated stress when the suspended ceiling is hung on the top surface through the vertical hanging piece, and the stability of the suspended ceiling after installation is poor; secondly, the suspended ceiling keel is arranged on the suspended ceiling, once the suspended ceiling is hung on the top surface, the position of the suspended ceiling keel cannot be adjusted, and the suspended ceiling is required to be integrally detached and adjusted when an error occurs in the installation, so that the workload is increased, the construction period is prolonged, and the standardized rapid construction is not facilitated; thirdly, the deflection of the suspender is large, a plurality of hole sites are required to be formed in the original concrete on the top surface for reverse support, and the damage degree to the original concrete on the top surface is large.

Disclosure of Invention

In view of the above, the utility model provides a drop-in drop-out suspended ceiling, which aims to overcome the defects in the prior art.

The edge-closing and falling suspended ceiling provided by the utility model comprises the following components: the first end of the bearing cantilever is fixed on the wall surface, and the second end of the bearing cantilever extends towards the direction far away from the wall surface; the first plane plate is positioned below the bearing cantilever, the first end of the first plane plate is fixed on the wall surface, and the second end of the first plane plate extends in a direction away from the wall surface; the first vertical plate is arranged opposite to the third vertical plate, the first vertical plate is hung on the bearing cantilever, and the end part, far away from the second vertical plate, of the third vertical plate is spliced with the second end of the first plane plate.

The edge-folding and falling suspended ceiling further comprises a second flat panel, wherein the second flat panel is connected with the upper surface of the first vertical panel in a fitting manner, and the second end of the second flat panel extends in a direction away from the wall surface.

The edge-folding and falling suspended ceiling further comprises a wood-plastic strip, and the first end of the first plane plate is connected to the wall surface through the wood-plastic strip.

The edge-folding and falling suspended ceiling comprises a wall surface, and is characterized in that the edge-folding and falling suspended ceiling further comprises two wood plastic plates which are integrally formed and perpendicular to each other, wherein one wood plastic plate is attached to the wall surface, and the plate surface, close to the first end, of the first plane plate is attached to the lower surface of the other wood plastic plate.

The edge-closing and falling suspended ceiling is characterized in that the third vertical plate is spliced with the first plane plate through cutting.

The edge-receiving and falling suspended ceiling is characterized in that the second end of the first plane plate is provided with a first clamping groove along the plate surface direction, the end part, far away from the second vertical plate, of the third vertical plate is provided with a second clamping groove along the plate surface direction, the first clamping groove and the second clamping groove are oppositely arranged, and one side of the cutting is inserted into the first clamping groove, and the other side of the cutting is inserted into the second clamping groove.

The edge-closing and falling suspended ceiling is characterized in that the cutting is further provided with a limiting strip, and the limiting strip is clamped between the third vertical plate and the first plane plate to limit the width of a gap between the third vertical plate and the first plane plate.

The edge-closing and falling suspended ceiling comprises a supporting cantilever, wherein the supporting cantilever comprises a connecting part and a supporting piece, the connecting part is fixed on the surface of a wall body and comprises a connecting plate, and the connecting plate is horizontally arranged; the first end of the bearing piece is fixed on the connecting plate, and the second end of the bearing piece extends out of the connecting plate in a direction away from the wall surface; the first vertical plate is hung on the bearing piece.

The edge-folding and falling suspended ceiling is characterized in that an angle code is connected between the first plane plate and the third vertical plate, one side of the angle code is fixedly connected with the upper surface of the first plane plate in a lap joint mode, and the other side of the angle code is fixedly connected with the upper surface of the third vertical plate in a lap joint mode.

The edge-folding and falling suspended ceiling is further characterized in that the junction of the lower surface of the first plane plate and the second end of the first plane plate is in arc transition; and/or the junction of the lower surface of the third vertical plate and the end surface of the third vertical plate far away from the second vertical plate is in arc transition.

The edge-closing and falling suspended ceiling provided by the utility model does not need to be provided with a vertical suspender, reduces the damage to the original concrete on the top surface, reduces the deformation of the suspended ceiling keel, ensures the position of the suspended ceiling keel to be adjustable, shortens the construction period and is beneficial to standardized rapid construction. And the aesthetic property of the edge folding decoration module can be guaranteed, the edge hanging panel can be quickly installed, the same length of the edge hanging plate and the top plate in one direction is guaranteed, the utilization rate of the standard plate is increased, and the edge wrapping process is reduced.

Drawings

The objects and advantages of the present utility model will be better understood by describing in detail preferred embodiments thereof with reference to the accompanying drawings in which:

fig. 1 is a schematic structural diagram of a drop ceiling according to an embodiment of the present utility model.

Fig. 2 is a partial enlarged view of fig. 1.

Fig. 3 is a schematic structural view of a load-bearing cantilever according to an embodiment of the present utility model.

Fig. 4 is a schematic view of a part of the components in fig. 3.

Fig. 5 is a diagram showing the fitting structure of the first plane plate and the corner bracket in fig. 1.

Detailed Description

The present utility model will be described in detail with reference to examples. Wherein like parts are designated by like reference numerals. It should be noted that the words "front", "rear", "left", "right", "upper" and "lower" used in the following description refer to directions in the drawings, and the words "inner" and "outer" refer to directions toward or away from, respectively, the geometric center of a particular component.

Fig. 1 is a schematic structural view of a drop ceiling according to an embodiment of the present utility model, and fig. 2 is a partial enlarged view of fig. 1. As shown in fig. 1 and 2, the edge-closing drop-stage suspended ceiling provided by the embodiment of the utility model includes: a load bearing boom 100, a first planar plate 200, and a drop stand 300.

The first end of the load-bearing cantilever 100 is fixed to a wall surface for carrying other structures of a suspended ceiling. The second end of the bearing cantilever 100 extends away from the wall surface. The wall surface can be the inner surface of a building wall body, the wall body can be a bearing wall inherent in the building, and also can be a partition wall arranged in the later decoration process of the building.

The first plane plate 200 is located below the bearing cantilever 100, and a first end of the first plane plate 200 is fixed on the wall surface, and a second end of the first plane plate 200 extends in a direction away from the wall surface. In a specific embodiment, the first plane board 200 and the load-bearing cantilever 100 may be horizontally disposed, and both are fixed on a wall surface.

The step-down stand 300 includes a first stand 310, a second stand 320, and a third stand 330 that extend in the same direction and are sequentially connected, the first stand 310 is disposed opposite to the third stand 330, the first stand 310 is hung on the bearing cantilever 100, and an end portion of the third stand 330 far away from the second stand 320 is spliced with a second end of the first plane board 200. In a specific embodiment, the extending direction of the stepped standing frame 300 is a direction perpendicular to the paper surface in fig. 1, and the cross section of the stepped standing frame 300 is U-shaped. The second vertical plate 320 is vertically disposed, and the first vertical plate 310 and the third vertical plate 330 are horizontally disposed. After the third vertical plate 330 is spliced with the first plane plate 200, the lower surfaces of the third vertical plate and the first plane plate are flush, so that a stepped structure is formed. The edge-closing drop-level suspended ceiling provided by the embodiment of the utility model is suitable for mounting various panels, in particular to the panel with the width smaller than 300 mm.

As shown in fig. 1-2, the drop ceiling provided by the embodiment of the utility model further includes a second flat panel 400, a board surface close to the first end on the second flat panel 400 is attached to the upper surface of the first vertical plate 310, and the second end of the second flat panel 400 extends in a direction away from the wall surface. The second plane plate 400, the step up stand 300, and the first plane plate 200 together form a complete step up structure. In a specific implementation, the second panel 400 may be processed through processing, i.e. may extend to the other strong wall, or may extend to other components of the suspended ceiling. The second flat plate 400 may have an equal length to the stepped vertical frame 300, i.e., an equal length in a direction perpendicular to the paper in fig. 1.

In the installation process, the bearing cantilever 100 and the first plane board 200 may be fixed on a wall surface, then the step-down vertical frame 300 is installed, the first vertical board 310 is lapped on the bearing cantilever 100, the third vertical board 330 is spliced on the first plane board 200, and then the second plane board 400 is fixed above the step-down vertical frame 300.

The edge-closing and falling suspended ceiling provided by the utility model does not need to be provided with a vertical suspender, reduces the damage to the original concrete on the top surface, reduces the deformation of the suspended ceiling keel, ensures the position of the suspended ceiling keel to be adjustable, shortens the construction period and is beneficial to standardized rapid construction. And the aesthetic property of the edge folding decoration module can be guaranteed, the edge hanging panel can be quickly installed, the same length of the edge hanging plate and the top plate in one direction is guaranteed, the utilization rate of the standard plate is increased, and the edge wrapping process is reduced.

In an alternative embodiment, the edge-folding drop-level suspended ceiling provided by the utility model further comprises a wood plastic strip 210, and the first end of the first plane board 200 is connected to the wall surface through the wood plastic strip 210. The wood-plastic strip 210 may be L-shaped, and comprises two integrally formed and mutually perpendicular wood-plastic plates, wherein one wood-plastic plate is attached to the wall surface and is fixed by self-tapping screws or expansion bolts; the plate surface of the first plane plate 200 near the first end is attached to the lower surface of another wood-plastic plate, and can be fixed by self-tapping screws. In this design, the wood plastic strip 210 is hidden above the first plane board 200, which gives both the strength of connection and the appearance. In addition, a certain gap can be reserved between the first plane plate 200 and the wall surface, so that the overall attractive appearance is improved, the deformation of the first plane plate 200 in the later stage can be adapted, and the protrusion is avoided.

As shown in fig. 1-2, the third vertical plate 330 is spliced with the first plane plate 200 through the cutting 501, and the cutting 501 may be T-shaped. The second end of the first flat board 200 is provided with a first clamping groove 601 along the board surface direction, the end part of the third vertical board 330 far away from the second vertical board 320 is provided with a second clamping groove 602 along the board surface direction, the first clamping groove 601 and the second clamping groove 602 are oppositely arranged, and one side of the cutting 501 is inserted into the first clamping groove 601, and the other side is inserted into the second clamping groove 602. The cutting 501 is provided with a limit bar 502, and the limit bar 502 is clamped between the third vertical plate 330 and the first plane plate 200, so as to limit the width of the gap between the third vertical plate 330 and the first plane plate 200. In the installation process, the first clamping groove 601 and the second clamping groove 602 may be aligned, and then the cutting 501 may be inserted to complete the splicing of the first plane board 200 and the third vertical board 330. The installation is very simple and quick, and is suitable for industrialized quick installation. In addition, the width of the gap between the third vertical plate 330 and the first plane plate 200 can be limited by the limit bar 502, so that the width is consistent with the width of the limit bar 502, and the gap is not required to be reserved in a manual measurement mode, thereby simplifying the installation steps.

Further, the junction between the lower surface of the first plane plate 200 and the second end of the first plane plate 200 is in arc transition; the junction between the lower surface of the third vertical plate 330 and the end surface of the third vertical plate 330 far from the second vertical plate 320 is in arc transition. On the one hand, the design of the arc transition can provide the whole aesthetic degree, and on the other hand, the finger is not easy to scratch in the installation process.

Fig. 3 is a schematic structural view of a load-bearing cantilever 100 according to an embodiment of the present utility model; fig. 4 is a schematic view of a part of the components in fig. 3. As shown in fig. 1 to 4, the load-bearing cantilever 100 includes a connection portion 110 and a load-bearing member 120, and the load-bearing member 120 is fixed on a wall surface 130 through the connection portion 110, so as to implement a load-bearing function.

Specifically, the connection part 110 is fixed on the wall 130, the connection part 110 includes a connection plate 111, the connection plate 111 is horizontally disposed, and an upper surface of the connection plate 111 may be used to connect with the bearing member 120, thereby supporting the bearing member 120. The first end of the bearing member 120 is fixed on the connection plate 111, and the second end of the bearing member 120 extends out of the connection plate 111 in a direction away from the wall 130. The distance from the second end of the bearing member 120 to the wall surface 130 is greater than the distance from the right end of the connecting plate 111 to the wall surface 130.

With the load-bearing cantilever 100 of the above embodiment, various module structures of the integrated ceiling can be directly mounted on the load-bearing member 120 without providing a vertical hanging rod. In a specific application example, the bearing cantilever 100 in the embodiment above can be installed on two opposite wall surfaces respectively, then two ends of the keel are respectively and fixedly connected to the two bearing pieces 120 in a lap joint mode, and then various module structures of the integrated suspended ceiling are directly installed on the keel.

In the embodiment shown in fig. 1 to 4, the connecting portion 110 further includes a fixing plate 112, the fixing plate 112 is vertically connected with the connecting plate 111, the fixing plate 112 is attached to the wall 130, so that the contact area between the fixing plate 112 and the wall 130 is increased, the fixing plate 112 can be fixed to the wall 130 through expansion bolts 140, so as to improve the connection rigidity of the overall structure and increase the overall bearing capacity of the bearing cantilever 100.

In addition, the fixing plate 112 is fixed to the wall surface 130 by self-tapping screws. When the fixing plate 112 is specifically used, the fixing plate 112 can be fixed by being provided with a positioning hole, and when the fixing plate is installed, the fixing plate 112 can be fixed by only screwing an automatic screw into the wall 130 through the positioning hole, so that the drilling operation is omitted, the working procedure is simplified, and the fixing plate is particularly suitable for hoisting parts with low bearing requirements, such as: light components such as curtain boxes, decorative lines and the like.

As shown in fig. 1-4, a first end of the connecting plate 111 is connected to an upper edge of the fixing plate 112, a second end of the connecting plate 111 extends away from the wall 130, and a first end of the bearing member 120 is fixed to an upper surface of the fixing plate 112. Preferably, the connection portion 110 may be an angle iron, and the two plates forming the angle iron are the fixing plate 112 and the connection plate 111 described above, respectively. With this design, after the fixing plate 112 is stably connected to the wall 130, the connecting plate 111 receives downward pressure from the bearing 120, so that the lower edge of the fixing plate 112 has a tendency to move toward the wall 130, and the wall 130 can effectively support the lower edge of the fixing plate 112. Thus, this design is very advantageous in providing the load-bearing capacity of the overall structure and in making the structure more stable.

Preferably, the load bearing member 120 may be square steel, for example 40mm by 20mm square steel. The bearing member 120 may be fixed to the upper surface of the fixing plate 112 by fastening bolts 150. Specifically, the square steel may be disposed along the extension direction of the connection plate 111, and through holes matched with the fastening bolts 150 may be disposed on the square steel and on the connection plate 111, and axes of the through holes may be perpendicular to the length direction of the square steel and then fixed by the fastening bolts 150. Various module structures of the integrated suspended ceiling can be directly hung on square steel, and the whole structure is very stable.

In an alternative embodiment, as shown in fig. 1-4, a gap is left between the first end of the load bearing member 120 and the wall surface 130. In the process of installing the suspended ceiling, the width of the gap can be adjusted according to the accumulated error generated in the actual hanging process, so that various problems caused by the accumulated error are avoided, for example: the suspended ceiling is abrupt, gaps among the suspended ceiling tiles are too large, and the like.

By adopting the bearing cantilever 100 provided by the embodiment of the utility model, various module structures of the integrated suspended ceiling can be directly installed on the bearing cantilever 100, a vertical suspender is not required to be specially arranged, the damage to the original concrete on the top surface is reduced, the deformation of the suspended ceiling keel is reduced, the position of the suspended ceiling keel is ensured to be adjustable, the construction period is shortened, and the standardized rapid construction is facilitated. In addition, the utility model can use the keel to increase the supporting strength of the cantilever support, can also increase the cantilever bearing structure to strengthen after the top surface is installed, and can also use an integral factory preparation and a direct assembly and installation mode on site. The cantilever extending out of the wall surface has a certain range of error allowance (40 mm for example) due to the C-shaped special structure of the falling-level vertical frame, and the requirement on the dimensional precision is not high; the wall surface is used for making an auxiliary supporting system, and a hanging rod structure is not needed. Compared with a hanging rod structure, the time for installing leveling screws and the like is reduced, and the installation efficiency is ensured; the factory-like direct production of accessories and the on-site direct installation can be realized.

Fig. 5 is a diagram showing the structure of the first plane plate 200 and the corner bracket 701 in fig. 1. Referring to fig. 1, 2 and 5, an angle bracket 701 is connected between the first plane plate 200 and the third vertical plate 330, one side of the angle bracket 701 is fixedly overlapped on the upper surface of the first plane plate 200, and the other side of the angle bracket 701 is fixedly overlapped on the upper surface of the third vertical plate 330. On the one hand, such a design may provide overall structural stability; on the other hand, the upper surface of the first plane plate 200 and the upper surface of the third vertical plate 330 can be limited on the same plane, and under the condition of equal thickness, the lower surfaces of the first plane plate 200 and the third vertical plate are flush only by installing the corner connector 701, so that the operation is very simple.

In another embodiment, the corner bracket 701 comprises two steel plates that are perpendicular to each other and coplanar, each steel plate is provided with two through holes, and a through hole is formed at the junction of the two steel plates. Mounting the corner bracket 701 on the first plane plate 200 through four through holes in two steel plates by four screws; the through hole at the joint of the two steel plates is aligned with the third vertical plate 330, and a self-tapping screw can pass through the through hole to realize the connection of the corner bracket 701 and the third vertical plate 330, thereby realizing the stable connection of the first plane plate 200 and the third vertical plate 330.

The edge-closing and falling suspended ceiling provided by the utility model does not need to be provided with a vertical suspender, reduces the damage to the original concrete on the top surface, reduces the deformation of the suspended ceiling keel, ensures the position of the suspended ceiling keel to be adjustable, shortens the construction period and is beneficial to standardized rapid construction. And the aesthetic property of the edge folding decoration module can be guaranteed, the edge hanging panel can be quickly installed, the same length of the edge hanging plate and the top plate in one direction is guaranteed, the utilization rate of the standard plate is increased, and the edge wrapping process is reduced.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the utility model.

Claims (10)

1. A receipts limit falls a grade furred ceiling, characterized in that includes:

the first end of the bearing cantilever is fixed on the wall surface, and the second end of the bearing cantilever extends towards the direction far away from the wall surface;

the first plane plate is positioned below the bearing cantilever, the first end of the first plane plate is fixed on the wall surface, and the second end of the first plane plate extends in a direction away from the wall surface;

the first vertical plate is arranged opposite to the third vertical plate, the first vertical plate is hung on the bearing cantilever, and the end part, far away from the second vertical plate, of the third vertical plate is spliced with the second end of the first plane plate.

2. The drop ceiling of claim 1, further comprising a second panel, wherein a plate surface of the second panel adjacent to the first end is attached to the upper surface of the first vertical plate, and a second end of the second panel extends away from the wall surface.

3. The drop side drop ceiling of claim 1, further comprising a wood-plastic strip, wherein the first end of the first planar panel is connected to the wall surface via the wood-plastic strip.

4. The drop ceiling of claim 3, wherein the wood-plastic strip comprises two integrally formed and mutually perpendicular wood-plastic plates, wherein one wood-plastic plate is attached to the wall surface, and the plate surface of the first planar plate adjacent to the first end is attached to the lower surface of the other wood-plastic plate.

5. The drop ceiling of claim 1, wherein the third riser is spliced with the first planar panel by an insert.

6. The drop-in ceiling according to claim 5, wherein a first clamping groove is formed in the second end of the first plane plate along the direction of the plate surface, a second clamping groove is formed in the end, away from the second vertical plate, of the third vertical plate along the direction of the plate surface, the first clamping groove and the second clamping groove are oppositely arranged, and one side of the cutting is inserted into the first clamping groove, and the other side of the cutting is inserted into the second clamping groove.

7. The drop ceiling of claim 6, wherein the cutting is provided with a stop bar, the stop bar being sandwiched between the third riser and the first planar plate, defining a width of a gap between the third riser and the first planar plate.

8. The drop ceiling of claim 1, wherein the load-bearing cantilever comprises a connecting portion and a load-bearing member, the connecting portion is fixed on the surface of the wall, the connecting portion comprises a connecting plate, and the connecting plate is horizontally arranged; the first end of the bearing piece is fixed on the connecting plate, and the second end of the bearing piece extends out of the connecting plate in a direction away from the wall surface; the first vertical plate is hung on the bearing piece.

9. The drop ceiling of claim 1, wherein an angle brace is connected between the first planar plate and the third vertical plate, one side of the angle brace is fixedly connected to the upper surface of the first planar plate in a lap joint manner, and the other side of the angle brace is fixedly connected to the upper surface of the third vertical plate in a lap joint manner.

10. The drop ceiling of any one of claims 1-9, wherein the intersection of the lower surface of the first planar plate and the second end of the first planar plate is a circular arc transition; and/or the junction of the lower surface of the third vertical plate and the end surface of the third vertical plate far away from the second vertical plate is in arc transition.