CN112443071B

CN112443071B - Top keel support of plasterboard suspended ceiling

Info

Publication number: CN112443071B
Application number: CN202011386611.6A
Authority: CN
Inventors: 吴晓华
Original assignee: Wen'an Jinkai Building Material Co ltd
Current assignee: Wen'an Jinkai Building Material Co ltd
Priority date: 2020-12-01
Filing date: 2020-12-01
Publication date: 2022-07-15
Anticipated expiration: 2040-12-01
Also published as: CN112443071A

Abstract

The invention discloses a top keel bracket of a gypsum board suspended ceiling, which comprises keel brackets arranged at the top of a gypsum board suspended ceiling board, wherein each keel bracket comprises a frame, more than one supporting plate is arranged in the middle of each frame side by side, a longitudinal sliding block is arranged on each of two sides of each supporting plate, a corresponding longitudinal sliding groove is arranged on the inner side surface of each frame corresponding to the longitudinal sliding block, and the longitudinal sliding block is arranged in the longitudinal sliding groove; the keel bracket of the invention can thicken a certain area when needed, so that the area can bear larger suspended weight.

Description

Top keel support of plasterboard suspended ceiling

Technical Field

The invention relates to a keel support, in particular to a top keel support of a gypsum board suspended ceiling.

Background

Gypsum furred ceiling is common furred ceiling mode in present modern fitment, although gypsum furred ceiling is pleasing to the eye, but gypsum furred ceiling's bearing capacity is than less, and wooden fossil fragments support is generally laid to gypsum furred ceiling inside, and fossil fragments support has increased gypsum furred ceiling's bearing capacity, even so, because fossil fragments support cost is huge, the timber is with high costs, generally can not be in order to increase the bearing capacity and too much use timber, gypsum furred ceiling later stage is rarely has the condition of bearing external load, so the thickness of general fossil fragments support is not very thick. However, under the condition, the general load suspension can be met, in later life, some electronic equipment is required to be suspended and installed on the ceiling frequently due to various requirements, but the bearing capacity of the keel support is low, and a large load cannot be borne in later life, so that the installation requirement cannot be met, and certain problems exist.

Disclosure of Invention

The technical problem to be solved by the invention is to provide the top keel support for the gypsum board suspended ceiling, which can thicken a local area when needed, meet the requirement of bearing suspension and solve the defects in the prior art.

The invention is realized by the following technical scheme: a top keel support of a gypsum board suspended ceiling comprises a keel support arranged at the top of a gypsum board suspended ceiling board, wherein the keel support comprises a frame, more than one support plate is arranged in the middle of the frame side by side, a longitudinal sliding block is arranged on each of two sides of each support plate, a corresponding longitudinal sliding groove is arranged on the inner side surface of the frame corresponding to the longitudinal sliding block, and the longitudinal sliding block is arranged in the longitudinal sliding groove;

the supporting plate comprises a bottom plate and a top plate, the longitudinal sliding blocks are arranged on two sides of the bottom plate, the top plate is transversely installed on the bottom plate in a sliding mode through an elastic sliding structure, and after the bottom plate is jacked upwards, the top plate slides towards the supporting plate on one side through the elastic sliding structure and covers the upper end face of the adjacent supporting plate to increase the total thickness of the supporting plate.

Preferably, the two side surfaces of the support plate are in close fit contact with the inner wall surface of the frame.

As the preferred technical scheme, the elastic sliding structure comprises more than one transverse sliding block arranged at the lower end of the top plate and a transverse sliding groove arranged on the upper end surface of the bottom plate, the transverse sliding blocks are slidably arranged in the transverse sliding grooves, and the cross sections of the transverse sliding blocks and the transverse sliding groove are in a T shape.

As a preferred technical scheme, one side in each transverse sliding groove is provided with a compressed spring, and when the bottom surface of the top plate exceeds the upper end surface of the adjacent side supporting plate, the top plate is ejected towards the direction of the adjacent side supporting plate through the compressed spring and covers the upper end surface of the adjacent side supporting plate.

According to the preferable technical scheme, the upper end face of the top plate is provided with a guide sliding groove, one side face of the guide sliding groove is open, the upper end face of the bottom plate on the same straight line with the guide sliding groove is provided with a butt-joint sliding groove, one end of the butt-joint sliding groove opposite to the guide sliding groove is open, and when the bottom plate rises to align with the top plate on the adjacent side, the butt-joint sliding groove is in butt joint with the guide sliding groove to form a complete guide rail groove.

As a preferred technical scheme, the lower end face of the top plate is provided with a guide slide block corresponding to the butt-joint sliding groove, the guide slide block is buckled in the butt-joint sliding groove in a sliding manner, when the butt-joint sliding groove is in butt joint with the guide sliding groove to form a complete guide rail groove, the guide slide block slides into the guide sliding groove from the butt-joint sliding groove, and the guide slide block and the transverse slide block are arranged in a staggered manner.

As a preferable technical scheme, the sections of the guide sliding block, the butt joint sliding groove and the guide rail groove are all in a T shape.

The invention has the beneficial effects that: when the invention needs to be locally thickened to bear larger suspension load, the supporting plate on one side can be jacked up, so that the top plate on the supporting plate is displaced towards the position needing to be suspended, the thickness of the bracket at the suspension position is increased, and the suspension bearing capacity is increased.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a partial cross-sectional schematic view of the present invention.

Detailed Description

As shown in fig. 1, the top keel support of the gypsum board suspended ceiling comprises a keel support 10 installed at the top of a gypsum board suspended ceiling, wherein the keel support 10 comprises a frame 1, more than one support plate is arranged in the middle of the frame 1 side by side, two sides of each support plate are respectively provided with a longitudinal sliding block 2, a longitudinal sliding groove 6 is arranged on the inner side surface of the frame 1 corresponding to the longitudinal sliding block 2, and the longitudinal sliding block 2 is arranged in the longitudinal sliding groove 6;

the backup pad includes a bottom plate 5 and a roof 3, and vertical slider 2 sets up in the both sides of bottom plate 5, and roof 3 is through a elasticity sliding structure lateral sliding installation on bottom plate 5, and when bottom plate 5 jack-up back upwards, roof 3 slides and covers the gross thickness that increases the backup pad at the up end of adjacent backup pad towards the backup pad of one side through the elasticity sliding structure.

When the thickness of thickening certain support, we only need utilize outside instrument earlier to destroy the gypsum furred ceiling board of suspension point one side, then insert the flat ejector pin of a head, then jack-up monoblock backup pad with strength for the backup pad passes through longitudinal sliding block along longitudinal sliding groove rebound, after longitudinal sliding block moved to longitudinal sliding groove topmost position, one side of roof lost the confining force, ejecting towards one side under the spring action.

In this embodiment, close-fitting contact between the internal face of the both sides face of backup pad and frame, through close-fitting contact, increase the frictional contact force between backup pad and the frame, the thrust of such a portion can not jack-up the backup pad, for example strike a nail etc. in somewhere, this kind of power is not enough jack-up backup pad for the backup pad is other backup pad upward movement relatively.

In this embodiment, as shown in fig. 2, the elastic sliding structure includes more than one horizontal sliding block 8 disposed at the lower end of the top plate 3, and a horizontal sliding groove 9 disposed on the upper end surface of the bottom plate 5, the horizontal sliding block is slidably mounted in the horizontal sliding groove, the cross sections of the horizontal sliding block and the horizontal sliding groove are both "T" shaped, the "T" shaped structure is used to prevent the separation and the loosening between the sliding block and the sliding groove, and after one of the supporting plates is lifted upwards, the top plate is lifted to a certain position, and one side of the top plate loses the limit.

In this embodiment, a compressed spring 7 is disposed on one side of each transverse sliding slot 9, and when the bottom surface of the top plate 3 exceeds the upper end surface of the adjacent side supporting plate, the top plate is ejected towards the direction of the adjacent side supporting plate by the compressed spring 7 and covers the upper end surface of the adjacent side supporting plate, as shown in fig. 2, after the top plate of the ejected supporting plate displaces, the thickness of the supporting plate on one side is increased, that is, the thickness of the supporting plate at the position becomes h, which is thicker than the thickness of the original supporting plate, so that some suspension devices, such as a television, a projector, a fan, a ceiling lamp and the like, can be mounted on the thickened supporting plate, and thus the bearing capacity of the bracket is greatly increased.

In the embodiment, the upper end face of the top plate is provided with a guide chute 4, one side face of the guide chute 4 is open, the upper end face of the bottom plate on the same straight line with the guide chute 4 is provided with a butt-joint chute (not shown), one end of the butt-joint chute opposite to the guide chute is open, when the bottom plate 5 rises to align with the top plate 3 on the adjacent side, the butt-joint chute is in butt joint with the guide chute to form a complete guide rail groove, the lower end face of the top plate is provided with a guide slide block 11 corresponding to the butt-joint chute, the guide slide block 11 is slidably buckled in the butt-joint chute, when the butt-joint chute is in butt joint with the guide chute to form a complete guide rail groove, the guide slide block slides into the guide chute from the butt-joint chute, the guide slide block and the transverse slide block are arranged in a staggered manner, the bottom of the top plate after displacement can realize two-side limitation through the guide slide block and the transverse slide block, and prevent the top side from being jacked up after displacement, the use stability after displacement is increased.

In this embodiment, the cross-sections of the guide sliding block 11, the butt joint sliding groove and the guide rail groove are all in a shape like a letter "T", and one side of the top plate is prevented from tilting through the structure like a letter "T".

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a gypsum board suspended ceiling's top fossil fragments support which characterized in that: the keel support comprises a framework, more than one support plate is arranged in the middle of the framework side by side, a longitudinal sliding block is arranged on each of two sides of each support plate, a corresponding longitudinal sliding groove is arranged on the inner side surface of the framework corresponding to the longitudinal sliding block, and the longitudinal sliding block is arranged in the longitudinal sliding groove;

the supporting plates comprise a bottom plate and a top plate, the longitudinal sliding blocks are arranged on two sides of the bottom plate, the top plate is transversely installed on the bottom plate in a sliding mode through an elastic sliding structure, and after the bottom plate is jacked upwards, the top plate slides towards the supporting plate on one side through the elastic sliding structure and covers the upper end face of the adjacent supporting plate to increase the total thickness of the supporting plates;

the elastic sliding structure comprises more than one transverse sliding block arranged at the lower end of the top plate and a transverse sliding groove arranged on the upper end surface of the bottom plate, the transverse sliding blocks are arranged in the transverse sliding groove in a sliding mode, and the cross sections of the transverse sliding blocks and the transverse sliding groove are T-shaped;

one side all sets up a compressed spring in every horizontal spout, and when the bottom surface of roof exceeded the up end of adjacent collateral branch fagging, ejecting and cover the up end at adjacent collateral branch fagging with the roof towards the direction of adjacent collateral branch fagging through the spring of compression.

2. The top keel support of a drywall suspended ceiling of claim 1, wherein: and the two side surfaces of the supporting plate are in tight fit contact with the inner wall surface of the frame.

3. The top keel support for a drywall suspended ceiling of claim 1, wherein: the upper end face of the top plate is provided with a guide sliding groove, a side face of the guide sliding groove is opened, the upper end face of the bottom plate on the same straight line with the guide sliding groove is provided with a butt joint sliding groove, one end of the butt joint sliding groove is opened relative to the guide sliding groove, and when the bottom plate rises and aligns with the top plate on the adjacent side, the butt joint sliding groove and the guide sliding groove are in butt joint to form a complete guide rail groove.

4. The top keel support of a drywall suspended ceiling of claim 3, wherein: the lower end face of the top plate is provided with a guide sliding block corresponding to the butt-joint sliding groove, the guide sliding block is buckled in the butt-joint sliding groove in a sliding mode, when the butt-joint sliding groove is in butt joint with the guide sliding groove to form a complete guide rail groove, the guide sliding block slides into the guide sliding groove from the butt-joint sliding groove, and the guide sliding block and the transverse sliding block are arranged in a staggered mode.

5. The top keel support of a drywall suspended ceiling of claim 4, wherein: the cross sections of the guide sliding block, the butt joint sliding groove and the guide rail groove are all in a T shape.