CN216973739U - Assembled skeleton mounting structure - Google Patents

Abstract

The utility model provides an assembly type framework installation structure, which relates to the technical field of decoration design and comprises a base plate, wherein a hinged plate is arranged at the end part of the base plate, a shell is arranged at the side edge of the base plate, a clamping structure is arranged at the end part of the shell, a hinged shaft is arranged on the base plate, the clamping structure comprises a fixed plate, an inner cavity arranged in the fixed plate, a stepped groove plate arranged at the opening of the inner cavity and a first connecting plate arranged in the inner cavity, a second connecting plate connected with the first connecting plate through a hinged rod is arranged at one side of the fixed plate close to a beam body, a through hole is formed in the fixed plate, and an abutting rod used for penetrating through the through hole is arranged at one side of the first connecting plate far away from the beam body, so that when the hinged plate rotates to abut against the abutting rod, the first connecting plate and the second connecting plate are extruded by the hinged plate to displace towards the beam body until the second connecting plate is clamped at the side edge of the beam body. The utility model has simple structure, long service life and good repeated detachability, and does not adopt threaded punching to clamp and fix the beam body.

Description

Assembled skeleton mounting structure

Technical Field

The utility model relates to the technical field of decoration design,

more particularly, the present invention relates to an assembled framework mounting structure.

Background

The current decoration industry is developing towards the direction of industrialized modularized installation, generally speaking, the beam wrapping decoration is a decoration method commonly adopted in indoor design, and can increase the layering sense of indoor space and play a role in beautifying decoration.

For example, the chinese patent utility model CN210887916U relates to a connecting device for a beam body and a floor frame of an assembly building, which is used for connecting a main beam and a cross beam, the connecting device comprises a first connecting piece detachably connected with the main beam, a second connecting piece detachably connected with the cross beam, and a third connecting piece detachably connected with the floor frame, the first connecting piece comprises a first fixing plate and a second fixing plate which are oppositely arranged, and a first connecting plate arranged between the first fixing plate and the second fixing plate, a first clamping groove is formed between the first fixing plate, the second fixing plate and the first connecting plate, the first clamping groove is clamped on the main beam, the first fixing plate and the second fixing plate are respectively provided with a second connecting piece, the second connecting pieces are provided with second clamping grooves clamped on the cross beams, the first connecting plate is provided with a third connecting piece, the third connecting piece is provided with a third clamping groove clamped on the floor framework, and the mounting axes of the third clamping groove and the first clamping groove are vertically arranged. The structure has the advantages of high installation speed, flexible adjustment and production cost reduction.

However, the above-described connection device still has the following problems: the structure is complicated, need carry out the screw thread on the roof beam body and punch, and is big to the roof beam body harm, and life is short, and detachability is poor.

Therefore, in order to solve the above problems, it is necessary to design a reasonable and efficient assembling type framework installation structure.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an assembly type framework mounting structure which is simple in structure, long in service life and good in repeatable disassembly performance, and does not adopt threaded punching to clamp and fix a beam body.

In order to achieve the purpose, the utility model is realized by adopting the following technical scheme:

an assembled skeleton mounting structure comprises a substrate, a hinged plate is arranged at the end part of the substrate, a shell is arranged at the side edge of the substrate, a clamping structure for clamping the side edge of a beam body is arranged at one end, away from the substrate, of the shell, a hinged shaft for facilitating the installation and rotation of the hinged plate is arranged on the substrate, the clamping structure comprises a fixed plate arranged at one end, away from the substrate, of the shell, an inner cavity arranged in the fixed plate and facing to the beam body direction opening, a stepped groove plate arranged at the opening of the inner cavity and a first connecting plate arranged in the inner cavity, a second connecting plate connected with the first connecting plate through a hinged rod is arranged at one side, close to the beam body, of the fixed plate, a through hole is arranged at one side, away from the beam body, of the fixed plate, a butting rod for penetrating through the through hole is arranged at one side, away from the beam body, of the first connecting plate, when the hinged plate rotates to abut against the abutting rod, the first connecting plate and the second connecting plate are pressed by the hinged plate to be displaced towards the beam body until the second connecting plate is clamped on the side edge of the beam body.

Preferably, the two ends of the base plate are provided with hinged plates, and the end part of the shell is provided with two groups of clamping structures for clamping two sides of the beam body.

Preferably, a groove for facilitating rotation of the hinged plate and a spring groove with an opening facing the groove are formed in the end portion of the base plate, the hinged shaft is arranged between the spring groove and the groove, a clamping rod and a protruding spring for connecting the clamping rod with the groove bottom of the spring groove are arranged in the spring groove, and a clamping groove for facilitating clamping of the clamping rod is formed in one end, close to the hinged shaft, of the hinged plate.

Preferably, the end of the hinged plate is provided with a guide chute for facilitating the sliding of the clamping rod.

Preferably, the thickness of the first connecting plate is smaller than the depth of the inner cavity, and a limit spring is arranged between the first connecting plate and the stepped groove plate.

Preferably, a first sliding groove, a first sliding block and a second sliding block are arranged on one side, close to the second connecting plate, of the first connecting plate, and the first sliding block and the second sliding block are used for sliding in the first sliding groove; one side of the second connecting plate, which is close to the first connecting plate, is provided with a second sliding groove, a third sliding block and a fourth sliding block, the third sliding block and the fourth sliding block are used for sliding in the second sliding groove, and a second spring is arranged between the third sliding block and the fourth sliding block.

Preferably, the first slider is disposed on a side of the second slider away from the housing; the third sliding block is arranged on one side, far away from the shell, of the fourth sliding block.

Preferably, the hinge rod comprises a first hinge rod for connecting the first slider and the fourth slider and a second hinge rod for connecting the second slider and the third slider; the middle part of the first hinge rod is hinged with the middle part of the second hinge rod.

Preferably, a protrusion is disposed on a side of the second connecting plate away from the first connecting plate.

Preferably, one end of the contact rod, which is far away from the first connecting plate, is arranged in an arc shape.

The assembly type framework mounting structure has the beneficial effects that: simple structure does not adopt the screw thread to punch and carries out the centre gripping of the roof beam body fixed, long service life, and repeatedly the dismantlement is good.

Drawings

FIG. 1 is a schematic view of the overall structure of an embodiment of a fabricated skeletal mounting structure of the present invention when the beam is not clamped;

FIG. 2 is a schematic view of the overall structure of an embodiment of a fabricated skeletal mounting structure of the present invention when clamping a beam;

FIG. 3 is an enlarged schematic view at A in FIG. 1;

FIG. 4 is an enlarged schematic view at B in FIG. 1;

FIG. 5 is a schematic view of the end of a substrate in one embodiment of a fabricated skeletal mounting structure in accordance with the present invention;

in the figure: 1. the base plate, 11, the hinge plate, 111, the draw-in groove, 112, the guide chute, 12, the articulated shaft, 13, the recess, 14, the spring groove, 141, the kelly, 142, the spring, 2, the roof beam body, 3, the clamping structure, 31, the fixed plate, 32, the inner chamber, 33, the ladder groove board, 331, spacing spring, 34, first connecting plate, 341, first spout, 342, first slider, 343, the second slider, 344, first spring, 35, the second connecting plate, 351, the second spout, 352, the third slider, 353, the fourth slider, 354, the second spring, 355, the arch, 36, the hinge pole, 37, the contact pole, 4, the casing.

Detailed Description

The following are specific examples of the present invention and further describe the technical solutions of the present invention, but the present invention is not limited to these examples.

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: the relative arrangement of the modules and steps set forth in these embodiments and steps do not limit the scope of the utility model unless specifically stated otherwise.

Meanwhile, it should be understood that the flows in the drawings are not merely performed individually for convenience of description, but a plurality of steps are performed alternately with each other.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention are conventionally placed in use, and are only used for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the utility model, its application, or uses.

Techniques, methods, and systems known to those of ordinary skill in the relevant art may not be discussed in detail, but are intended to be part of the specification where appropriate.

The first embodiment is as follows: as shown in fig. 1 to 5, which are only one embodiment of the present invention, a fabricated skeleton mounting structure comprises a base plate 1, a hinge plate 11 is arranged at an end of the base plate 1, a housing 4 is arranged at a side edge of the base plate 1, a clamping structure 3 for clamping a side edge of a beam body 2 is arranged at an end of the housing 4 away from the base plate 1, a hinge shaft 12 for facilitating the installation and rotation of the hinge plate 11 is arranged on the base plate 1, the clamping structure 3 comprises a fixed plate 31 arranged at an end of the housing 4 away from the base plate 1, an inner cavity 32 arranged in the fixed plate 31 and opened towards the beam body 2, a stepped groove plate 33 arranged at the opening of the inner cavity 32, and a first connecting plate 34 arranged in the inner cavity 32, a second connecting plate 35 connected with the first connecting plate 34 through a hinge rod 36 is arranged at a side of the fixed plate 31 close to the beam body 2, one side of the fixed plate 31, which is far away from the beam body 2, is provided with a through hole, one side of the first connecting plate 34, which is far away from the beam body 2, is provided with a contact rod 37 for penetrating through the through hole, so that when the hinged plate 11 rotates to abut against the contact rod 37, the first connecting plate 34 and the second connecting plate 35 are extruded by the hinged plate 11 to displace towards the beam body 2 until the second connecting plate 35 is clamped on the side edge of the beam body 2.

In the utility model, the base plate 1 is a framework main body, the base plate 1 is lifted to the height of the beam body 2, the clamping structure 3 on the side edge of the base plate 1 is triggered by the extrusion of the hinged plate 11 to clamp the side edge of the beam body, the connection between the base plate 1 and the beam body 2 is not completed, and then other decorative structures can be installed on the base plate 1.

Firstly, the end part of the base plate 1 is provided with a hinged plate 11, the base plate 1 is provided with a hinged shaft 12 for facilitating the installation and rotation of the hinged plate 11, and the hinged plate 11 rotates around the axis of the hinged shaft 12.

Here, a groove 13 for facilitating rotation of the hinge plate 11 and a spring groove 14 with an opening facing the groove 13 are provided at an end of the base plate 1, the hinge shaft 12 is provided between the spring groove 14 and the groove 13, a clamping rod 141 and a protruding spring 142 for connecting the clamping rod 141 and a groove bottom of the spring groove 14 are provided in the spring groove 14, and a clamping groove 111 for facilitating clamping of the clamping rod 141 is provided at one end of the hinge plate 11 close to the hinge shaft 12; the hinge plate 11 rotates around the hinge shaft 12, when the hinge plate 11 rotates to be parallel to the end plane of the base plate 1, a part of the hinge plate 11 just lies in the groove 13, and the movable end of the hinge plate 11 is just far away from the clamping rod 141 at the moment, the clamping groove 111 aligns with the clamping rod 141 at the moment, the clamping rod 141 extends under the elastic force of the extension spring 142 and is clamped into the clamping groove 111, and at the moment, the hinge plate 11 cannot rotate again.

Then a clamping structure 3 is arranged, a shell 4 is arranged on the side edge of the base plate 1, a clamping structure 3 used for clamping the side edge of the beam body 2 is arranged at one end of the shell 4 far away from the base plate 1, the clamping structure 3 comprises a fixing plate 31 arranged at one end of the shell 4 far away from the base plate 1, an inner cavity 32 arranged in the fixing plate 31 and opened towards the beam body 2, a stepped groove plate 33 arranged at the opening of the inner cavity 32 and a first connecting plate 34 arranged in the inner cavity 32, a second connecting plate 35 connected with the first connecting plate 34 through a hinge rod 36 is arranged on one side of the fixing plate 31 close to the beam body 2, one side that the fixed plate 31 kept away from the roof beam body 2 is provided with the through-hole, one side that first connecting plate 34 kept away from the roof beam body 2 is provided with and is used for passing the conflict pole 37 of through-hole.

When the hinge plate 11 is rotated to abut against the abutting rod 37, the first connecting plate 34 and the second connecting plate 35 are pressed by the hinge plate 11 to be displaced toward the beam 2 until the second connecting plate 35 is clamped on the side of the beam 2.

Of course, the two ends of the base plate 1 are both provided with hinged plates 11, and the end of the housing 4 is provided with two sets of clamping structures 3 for clamping the two sides of the beam body 2.

The hinge plate 11 is disposed perpendicular to the end surface of the base plate 1 when it is not necessary to connect the base plate 1 to the beam body 2.

When the base plate 1 and the beam body 2 need to be connected, the hinged plate 11 only needs to be pulled to rotate around the hinged shaft 12 until the hinged plate 11 is parallel to the end surface of the base plate 1, and the clamping rod 141 is clamped into the clamping groove 111, at this time, the hinged plate 11 extrudes the abutting rod 37, the first connecting plate 34 and the second connecting plate 35 to displace towards the beam body 2, so that the beam body 2 is clamped on one side of the second connecting plate 35 away from the first connecting plate 34.

When the connection between the base plate 1 and the beam body 2 needs to be disassembled, only a tool needs to be used for pushing the clamping rod 141 into the spring groove 14 until the clamping rod 141 is separated from the clamping groove 111, at this time, the hinged plate 11 can rotate to be separated from the abutting contact rod 37, and then the beam body 2 is released by the second connecting plate 35.

In order to release the beam 2 from the second connecting plate 35, the thickness of the first connecting plate 34 is smaller than the depth of the cavity 32, and a limiting spring 331 is disposed between the first connecting plate 34 and the stepped groove plate 33, after the hinge plate 11 is separated from the contact rod 37, the first connecting plate 34 and the second connecting plate 35 are displaced in a direction away from the beam 2 by the elastic force of the limiting spring 331 (actually, a return spring), and the second connecting plate 35 releases the beam 2.

The assembly type framework mounting structure is simple in structure, long in service life and good in repeatable disassembly, and does not adopt threaded punching for clamping and fixing the beam body.

In the second embodiment, as shown in fig. 1 to 5, which is only one embodiment of the present invention, on the basis of the first embodiment, in the assembly type framework installation structure of the present invention, the end of the hinge plate 11 is provided with a guide chute 112 for facilitating the sliding of the clamping rod 141, so as to facilitate the sliding of the clamping rod 141 in the guide chute 112, and limit the sliding of the clamping rod 141, of course, the guide chute 112 is an arc chute.

In addition, a first sliding chute 341, a first sliding block 342 and a second sliding block 343 are arranged on one side of the first connecting plate 34 close to the second connecting plate 35, and are used for sliding in the first sliding chute 341, and a first spring 344 is arranged between the first sliding block 342 and the second sliding block 343; a second sliding groove 351, a third slider 352 and a fourth slider 353 are arranged on one side of the second connecting plate 35 close to the first connecting plate 34, and a second spring 354 is arranged between the third slider 352 and the fourth slider 353, wherein the third slider 352 and the fourth slider 353 are used for sliding in the second sliding groove 351.

Here, the first slider 342 is disposed on a side of the second slider 343 away from the housing 4; the third slider 352 is disposed on a side of the fourth slider 353 away from the housing 4.

Of course, the hinge lever 36 includes a first hinge lever for connecting the first slider 342 and the fourth slider 353 and a second hinge lever for connecting the second slider 343 and the third slider 352; the middle part of the first hinge rod is hinged with the middle part of the second hinge rod.

Finally, the second connecting plate 35 is provided with a projection 355 on the side away from the first connecting plate 34. The friction between the second connecting plate 35 and the beam body 2 can be increased, so that the clamping effect is better.

Finally, the end of the contact rod 37 away from the first connecting plate 34 is arc-shaped. Damage caused by scraping between the touch bar 37 and the hinge plate 11 is prevented, and the service life is longer.

The assembly type framework mounting structure is simple in structure, long in service life and good in repeatable disassembly, and does not adopt threaded punching for clamping and fixing the beam body.

The present invention is not limited to the above-described specific embodiments, and various modifications and variations are possible. Any modifications, equivalents, improvements and the like made to the above embodiments in accordance with the technical spirit of the present invention should be included in the scope of the present invention.

Claims (10)

1. The utility model provides an assembled skeleton mounting structure which characterized in that: including base plate (1), base plate (1) tip is provided with articulated slab (11), base plate (1) side is provided with casing (4), casing (4) are kept away from the one end of base plate (1) is provided with and is used for pressing from both sides tight structure (3) of pressing from both sides tight roof beam body (2) side, be provided with on base plate (1) and be used for conveniently articulated slab (11) installation and pivoted articulated shaft (12), press from both sides tight structure (3) including set up in casing (4) are kept away from fixed plate (31) of the one end of base plate (1), set up in fixed plate (31) towards roof beam body (2) direction open-ended inner chamber (32), set up in ladder frid (33) of inner chamber (32) opening part and set up in first connecting plate (34) in inner chamber (32), fixed plate (31) are close to one side of roof beam body (2) be provided with through articulated rod (36) with the second connection that first connecting plate (34) are connected is connected The hinge plate comprises a plate (35), a through hole is formed in one side, away from the beam body (2), of the fixing plate (31), a contact rod (37) used for penetrating through the through hole is arranged on one side, away from the beam body (2), of the first connecting plate (34), so that when the hinge plate (11) rotates to be in contact with the contact rod (37), the first connecting plate (34) and the second connecting plate (35) are extruded to be displaced towards the beam body (2) by the hinge plate (11) until the second connecting plate (35) is clamped on the side edge of the beam body (2).

2. The fabricated framework mounting structure of claim 1, wherein: the hinge plates (11) are arranged at two ends of the base plate (1), and two groups of clamping structures (3) used for clamping two sides of the beam body (2) are arranged at the end part of the shell (4).

3. The fabricated framework mounting structure of claim 1, wherein: base plate (1) tip is provided with and is used for the convenience articulated plate (11) pivoted recess (13) and opening orientation spring groove (14) that recess (13) set up, articulated shaft (12) set up in spring groove (14) with between recess (13), be provided with kelly (141) in spring groove (14) and be used for connecting kelly (141) with extension spring (142) of the tank bottom of spring groove (14), articulated plate (11) are close to the one end of articulated shaft (12) is provided with and is used for the convenience draw-in groove (111) that kelly (141) card was gone into.

4. A fabricated skeletal mounting structure, as defined in claim 3, wherein: the end part of the hinged plate (11) is provided with a guide chute (112) for facilitating the sliding of the clamping rod (141).

5. The fabricated framework mounting structure of claim 1, wherein: the thickness of the first connecting plate (34) is smaller than the depth of the inner cavity (32), and a limiting spring (331) is arranged between the first connecting plate (34) and the stepped groove plate (33).

6. The fabricated framework mounting structure of claim 1, wherein: a first sliding groove (341), a first sliding block (342) and a second sliding block (343) which are used for sliding in the first sliding groove (341) are arranged on one side, close to the second connecting plate (35), of the first connecting plate (34), and a first spring (344) is arranged between the first sliding block (342) and the second sliding block (343); one side, close to the first connecting plate (34), of the second connecting plate (35) is provided with a second sliding groove (351), a third sliding block (352) and a fourth sliding block (353) which are used for sliding in the second sliding groove (351), and a second spring (354) is arranged between the third sliding block (352) and the fourth sliding block (353).

7. The fabricated framework mounting structure of claim 6, wherein: the first sliding block (342) is arranged on one side, far away from the shell (4), of the second sliding block (343); the third sliding block (352) is arranged on one side, away from the shell (4), of the fourth sliding block (353).

8. The fabricated framework mounting structure of claim 7, wherein: the hinge rod (36) comprises a first hinge rod for connecting the first slider (342) and the fourth slider (353) and a second hinge rod for connecting the second slider (343) and the third slider (352); the middle part of the first hinge rod is hinged with the middle part of the second hinge rod.

9. The fabricated framework mounting structure of claim 1, wherein: a protrusion (355) is arranged on one side, away from the first connecting plate (34), of the second connecting plate (35).

10. The fabricated framework mounting structure of claim 1, wherein: the end, far away from the first connecting plate (34), of the contact rod (37) is arranged in an arc shape.

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