CN215949051U - Arched impact-resistant steel workshop connection structure - Google Patents

Abstract

The utility model belongs to the field of impact-resistant steel factory building installation, and particularly relates to an arched impact-resistant steel factory building connecting structure which comprises a first factory building plate, a second factory building plate and a connecting mechanism; the connecting mechanism is arranged between the first factory building board and the second factory building board; by arranging the connecting mechanism, when the device is used, personnel need to align the first factory board with the second factory board, and then insert the first connecting plate and the second connecting plate into connecting grooves formed in the inner walls of the first factory board and the second factory board respectively; simultaneously first connecting plate and second connecting plate will drive the plugboard and the butt joint piece removes, later the movable block will be fixed first connecting plate and second connecting plate in the spread groove, insert one side of plugboard again in the butt joint piece, utilize the bolt with the plugboard with the butt joint piece fixed together can to with first factory building board and second factory building board installation together fixed, and then be convenient for personnel install the factory building part fast, required time when reducing the installation factory building.

Description

Arched impact-resistant steel workshop connection structure

Technical Field

The utility model relates to the field of impact-resistant steel factory building installation, in particular to an arched impact-resistant steel factory building connecting structure.

Background

The arched impact-resistant steel factory building is a common factory building, and when the arched impact-resistant steel factory building is installed, the parts of the arched impact-resistant steel factory building are connected together by using a connecting device.

In the prior art, the arched anti-impact steel factory building connecting structure has the advantages of being convenient to carry and transport and the like, and is widely used by personnel in connection of anti-impact steel factory buildings.

The existing arched impact-resistant steel workshop connecting mechanism is complex in installation and operation steps, needs to spend more time during installation, and is inconvenient for people to use.

SUMMERY OF THE UTILITY MODEL

In order to make up for the defects of the prior art and solve the problems that the installation operation steps of the existing arched impact-resistant steel workshop connecting mechanism are more complicated and more time is needed during installation, the utility model provides the arched impact-resistant steel workshop connecting structure.

The technical scheme adopted by the utility model for solving the technical problems is as follows: the utility model relates to an arched impact-resistant steel workshop connection structure which comprises a first workshop plate, a second workshop plate and a connection mechanism, wherein the first workshop plate is provided with a first connecting plate; the connecting mechanism is arranged between the first factory building board and the second factory building board;

the connecting mechanism comprises a first connecting plate, a second connecting plate, a plugboard butt-joint block and a moving block; connecting grooves are formed in the inner walls of the first plant board and the second plant board; the first connecting plate and the second connecting plate are movably connected in the connecting groove; the inserting plates are fixedly connected to two sides of the first connecting plate; the butt joint blocks are fixedly connected to two sides of the second connecting plate; the moving block is fixedly connected to one side of the first connecting plate and one side of the second connecting plate; the insertion plate is movably connected with the butt joint block through a bolt; one side of the butt joint block is provided with a butt joint groove matched with the plug board, and the first connecting board, the second connecting board, the plug board, the butt joint block and the butt joint block are arranged, so that personnel can quickly install and connect the plant parts together.

Preferably, the symmetrical positions of the inner wall of the connecting groove are provided with mounting grooves; the insertion plate and the butt joint block are both arranged in the mounting groove; the inner wall of the connecting groove is provided with a moving groove matched with the moving block, the connecting block and the plugboard can be limited by the aid of the mounting groove, and the moving block can be limited by the aid of the moving groove.

Preferably, both sides of the moving block are provided with fastening grooves; the inner wall of the fastening groove is provided with a stabilizing groove; a fastening spring is arranged on the inner side wall of the fastening groove; the one end fixedly connected with chamfer piece of fastening spring through having seted up the fastening groove, the chamfer piece of being convenient for moves to the movable block, through having seted up the firm groove, has the effect that can improve the steadiness when chamfer piece removes.

Preferably, one side of the chamfer block is fixedly connected with a fastening block matched with the fastening groove; one side fixedly connected with of fastening block with the firm piece of firm groove looks adaptation has can be to the spacing effect of chamfer piece through being provided with the fastening block, through being provided with the firm piece, has the effect that can improve the steadiness of fastening block.

Preferably, the inner walls of the first factory building board and the second factory building board are provided with impact grooves; an impact mounting plate is arranged inside the impact groove; impact resisting mechanisms are arranged on one sides of the impact mounting plate, the first connecting plate and the second connecting plate; the shock resistance mechanism comprises a buffer spring, rubber and a plate, a buffer tube and a buffer limiting block; buffer holes are formed in the surfaces of the first connecting plate and the second connecting plate; the buffer spring is arranged inside the buffer hole; one end of the buffer tube is arranged on the buffer spring; the other end of the buffer tube is arranged on the rubber and the plate; the buffer limiting block is arranged on the surface of the buffer tube; rectangular grooves are formed in the surfaces of the rubber and the plates; the inner wall of the buffer hole is provided with a buffer fixing groove matched with the buffer limiting block, and the buffer hole has the effect of improving the shock resistance of a workshop by arranging a rubber plate, a buffer pipe and the buffer limiting block.

Preferably, the surfaces of the first connecting plate and the second connecting plate are both provided with buffer telescopic grooves; one side of the rubber and the plate is provided with a buffer telescopic block matched with the buffer telescopic groove, and the rubber and the plate can be limited by the buffer telescopic block.

The utility model has the advantages that:

1. by arranging the connecting mechanism, when the device is used, personnel need to align the first factory building board with the second factory building board, and then insert the first connecting board and the second connecting board into connecting grooves formed in the inner walls of the first factory building board and the second factory building board respectively; simultaneously first connecting plate and second connecting plate will drive the plugboard and the butt joint piece removes, later the movable block will be fixed first connecting plate and second connecting plate in the spread groove, insert one side of plugboard again in the butt joint piece, utilize the bolt with the plugboard with the butt joint piece fixed together can to with first factory building board and second factory building board installation together fixed, and then be convenient for personnel install the factory building part fast, required time when reducing the installation factory building.

2. According to the utility model, by arranging the impact resistance mechanism, when the first factory building board and the second factory building board are impacted by an external force, one side of the rubber and the board is extruded, then the other side of the rubber and the board is extruded to the buffer tube, so that the buffer tube drives the buffer limiting block to move together, one end of the buffer tube extrudes the buffer spring, the buffer spring is contracted to generate elastic potential energy, then the buffer spring needs to push the rubber and the board to move to reset, and therefore, a force for blocking the movement of the external force is generated, the impact force on the first factory building board and the second factory building board is buffered, and the impact resistance of the factory building is improved.

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, and 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 these drawings without inventive exercise.

FIG. 1 is a schematic top view illustrating a first embodiment;

FIG. 2 is an enlarged schematic view of a portion A of FIG. 1 according to the first embodiment;

FIG. 3 is a schematic structural diagram of a second plant board according to the first embodiment;

FIG. 4 is a schematic diagram of a first plant board structure according to the first embodiment;

fig. 5 is a schematic view of the ball structure of the second embodiment.

In the figure: 1. a first plant board; 101. connecting grooves; 102. mounting grooves; 103. a moving groove; 104. an impact groove; 105. impacting the mounting plate; 201. a first connecting plate; 202. a second connecting plate; 203. a plugboard; 204. a butt joint block; 205. a moving block; 2051. a fastening groove; 2052. a stabilizing groove; 2053. a fastening spring; 2054. a fastening block; 2055. a stabilizing block; 2056. chamfering blocks; 3. a second plant board; 401. a buffer spring; 402. rubber and plates are mixed; 403. a buffer tube; 404. a buffer limiting block; 5. a buffer hole; 6. a buffer telescopic slot; 601. buffering the telescopic block; 7. and a ball.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

Referring to fig. 1-4, an arch-shaped impact-resistant steel factory building connection structure includes a first factory floor 1, a second factory floor 3 and a connection mechanism; the connecting mechanism is arranged between the first plant board 1 and the second plant board 3;

the connecting mechanism comprises a first connecting plate 201, a second connecting plate 202, a plug board 203 butt joint block 204 and a moving block 205; the inner walls of the first plant board 1 and the second plant board 3 are both provided with connecting grooves 101; the first connecting plate 201 and the second connecting plate 202 are movably connected in the connecting groove 101; the inserting plates 203 are fixedly connected to two sides of the first connecting plate 201; the butt-joint block 204 is fixedly connected to two sides of the second connecting plate 202; the moving block 205 is fixedly connected to one side of the first connecting plate 201 and one side of the second connecting plate 202; the plug board 203 is movably connected with the butt-joint block 204 through bolts; one side of the butt joint block 204 is provided with a butt joint groove matched with the plug board 203;

during work, personnel need to align the first plant board 1 with the second plant board 3, and then insert the first connecting board 201 and the second connecting board 202 into the connecting grooves 101 formed in the inner walls of the first plant board 1 and the second plant board 3 respectively; simultaneously first connecting plate 201 and second connecting plate 202 will drive plugboard 203 and butt joint piece 204 and remove, later the movable block 205 will be fixed first connecting plate 201 and second connecting plate 202 in spread groove 101, insert one side of plugboard 203 in butt joint piece 204 again, utilize the bolt with plugboard 203 with butt joint piece 204 fixed together can, thereby be in the same place first factory building board 1 and the installation of second factory building board 3 together, and then be convenient for personnel install factory building part fast, required time when reducing the installation factory building.

Mounting grooves 102 are formed in the symmetrical positions of the inner wall of the connecting groove 101; the plug board 203 and the butt joint block 204 are both arranged in the mounting groove 102; the inner wall of the connecting groove 101 is provided with a moving groove 103 matched with the moving block 205;

in operation, in the process that the first connecting plate 201 and the second connecting plate 202 move in the connecting groove 101, the first connecting plate 201 and the second connecting plate 202 respectively drive the inserting plate 203 and the butting block 204 to move in the mounting groove 102, and after the first connecting plate 201 and the second connecting plate 202 completely enter the connecting groove 101, the moving block 205 enters the moving groove 103.

Fastening grooves 2051 are formed in both sides of the moving block 205; a stabilizing groove 2052 is formed on the inner wall of the fastening groove 2051; a fastening spring 2053 is arranged on the inner side wall of the fastening groove 2051; one end of the fastening spring 2053 is fixedly connected with a chamfering block 2056;

during operation, in the process that the moving block enters the moving groove 103, the inner wall of the moving groove 103 extrudes the chamfering block 2056, so that the chamfering block extrudes the fastening spring 2053, the moving block 205 enters the moving groove 103, and finally one end of the fastening spring 2053 pushes the chamfering block 2056 to extrude the inside of the moving groove 103, so that the stability of the moving block 205 is improved.

One side of the chamfer block 2056 is fixedly connected with a fastening block 2054 matched with the fastening groove 2051; a stabilizing block 2055 matched with the stabilizing groove 2052 is fixedly connected to one side of the fastening block 2054;

in operation, when the chamfering block 2056 moves toward the moving block 205, it will drive the fastening block 2054 to move toward the fastening slot 2051, and when the fastening block 2054 moves toward the fastening slot 2051, it will drive the fastening block 2055 to move toward the fastening slot 2052.

The inner walls of the first plant board 1 and the second plant board 3 are provided with impact grooves 104; an impact mounting plate 105 is arranged inside the impact groove 104; an impact resisting mechanism is arranged on one side of each of the impact mounting plate 105, the first connecting plate 201 and the second connecting plate 202; the impact resistance mechanism comprises a buffer spring 401, rubber and a plate 402, a buffer tube 403 and a buffer limiting block 404; the surfaces of the first connecting plate 201 and the second connecting plate 202 are both provided with buffer holes 5; the buffer spring 401 is arranged inside the buffer hole 5; one end of the buffer tube 403 is disposed on the buffer spring 401; the other end of the buffer tube 403 is disposed on a rubber foam board 402; the buffer stopper 404 is disposed on the surface of the buffer tube 403; a rectangular groove is formed in the surface of the rubber attachment plate 402; a buffer fixing groove matched with the buffer limiting block (404) is formed in the inner wall of the buffer hole (5)

During operation, when first factory building board 1 and second factory building board 3 received external force striking, rubber will receive the extrusion with one side of board 402, later rubber will extrude buffer tube 403 with the opposite side of board 402, make buffer tube 403 drive buffer stop block 404 together remove, and the one end of buffer tube 403 will extrude buffer spring 401, make buffer spring 401 shrink, elastic potential energy has been produced, later buffer spring 401 will need to promote rubber and board 402 to remove, in order to reset, thereby produce a power that hinders external force and remove, and then cushion the impact force that first factory building board 1 and second factory building board 3 received, improve the shock resistance of factory building.

The surfaces of the first connecting plate 201 and the second connecting plate 202 are both provided with a buffer telescopic groove 6; one side of the rubber attachment plate 402 is provided with a buffer telescopic block 601 matched with the buffer telescopic groove 6;

in operation, during the process that one side of the rubber attachment plate 402 moves towards the first connecting plate 202 and the second connecting plate 202, the rubber attachment plate 402 drives the buffer telescopic block 601 to move in the buffer telescopic slot 6.

Example two

Referring to fig. 5, in a first comparative example, as another embodiment of the present invention, balls 7 are disposed on an inner wall of the mounting groove 102;

in operation, when the plug board 203 and the docking block 204 move on the ball 7, the ball 7 starts to rotate, thereby facilitating the movement of the plug board 203 and the docking block 204 in the mounting groove 102.

The working principle is as follows: aiming at the problems that the installation operation steps of the existing arched impact-resistant steel factory building connecting mechanism are complex and more time is needed during installation, 1, personnel need to align a first factory floor 1 with a second factory floor 3, and then insert a first connecting plate 201 and a second connecting plate 202 into connecting grooves 101 formed in the inner walls of the first factory floor 1 and the second factory floor 3 respectively; meanwhile, the first connecting plate 201 and the second connecting plate 202 drive the plug board 203 and the butt joint block 204 to move, then the first connecting plate 201 and the second connecting plate 202 are fixed in the connecting groove 101 by the moving block 205, one side of the plug board 203 is inserted into the butt joint block 204, the plug board 203 and the butt joint block 204 are fixed together by bolts, so that the first factory building board 1 and the second factory building board 3 are fixedly installed together, and then the factory building components can be conveniently and quickly installed by personnel, the time required in factory building installation is reduced, the existing arched impact-resistant steel factory building connecting mechanism is solved, the installation operation steps are more complicated, and more time is needed in installation.

2. When first factory building board 1 and second factory building board 3 received external force striking, rubber will receive the extrusion with one side of board 402, later rubber will extrude buffer tube 403 with the opposite side of board 402, make buffer tube 403 drive buffer stop block 404 together remove, and the one end of buffer tube 403 will extrude buffer spring 401, make buffer spring 401 shrink, elastic potential energy has been produced, later buffer spring 401 will need to promote rubber and board 402 to remove, in order to reset, thereby produce a power that hinders external force and remove, and then cushion the impact force that first factory building board 1 and second factory building board 3 received, improve the shock resistance of factory building.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing shows and describes the general principles, essential features, and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed.

Claims (6)

1. The utility model provides an arch steel factory building connection structure that shocks resistance which characterized in that: comprises a first factory board (1), a second factory board (3) and a connecting mechanism; the connecting mechanism is arranged between the first plant board (1) and the second plant board (3);

the connecting mechanism comprises a first connecting plate (201), a second connecting plate (202), a splicing block (204) of a splicing plate (203) and a moving block (205); the inner walls of the first plant board (1) and the second plant board (3) are respectively provided with a connecting groove (101); the first connecting plate (201) and the second connecting plate (202) are movably connected in the connecting groove (101); the inserting plates (203) are fixedly connected to two sides of the first connecting plate (201); the butt joint blocks (204) are fixedly connected to two sides of the second connecting plate (202); the moving block (205) is fixedly connected to one side of the first connecting plate (201) and one side of the second connecting plate (202); the plug board (203) is movably connected with the butt-joint block (204) through a bolt; one side of the butt joint block (204) is provided with a butt joint groove matched with the plug board (203).

2. The arched impact-resistant steel factory building connection structure of claim 1, wherein: mounting grooves (102) are formed in the symmetrical positions of the inner wall of the connecting groove (101); the plug board (203) and the butt joint block (204) are both arranged in the mounting groove (102); the inner wall of the connecting groove (101) is provided with a moving groove (103) matched with the moving block (205).

3. The arched impact-resistant steel factory building connection structure of claim 2, wherein: fastening grooves (2051) are formed in the two sides of the moving block (205); a stabilizing groove (2052) is arranged on the inner wall of the fastening groove (2051); a fastening spring (2053) is arranged on the inner side wall of the fastening groove (2051); one end of the fastening spring (2053) is fixedly connected with a chamfer block (2056).

4. The arched impact-resistant steel factory building connection structure of claim 3, wherein: one side of the chamfering block (2056) is fixedly connected with a fastening block (2054) matched with the fastening groove (2051); one side of the fastening block (2054) is fixedly connected with a stabilizing block (2055) matched with the stabilizing groove (2052).

5. The arched impact-resistant steel factory building connection structure of claim 4, wherein: the inner walls of the first plant board (1) and the second plant board (3) are provided with impact grooves (104); an impact mounting plate (105) is arranged in the impact groove (104); impact resisting mechanisms are arranged on one sides of the impact mounting plate (105), the first connecting plate (201) and the second connecting plate (202); the shock resistance mechanism comprises a buffer spring (401), a rubber attachment plate (402), a buffer tube (403) and a buffer limiting block (404); buffer holes (5) are formed in the surfaces of the first connecting plate (201) and the second connecting plate (202); the buffer spring (401) is arranged inside the buffer hole (5); one end of the buffer tube (403) is arranged on the buffer spring (401); the other end of the buffer tube (403) is arranged on a rubber sponge plate (402); the buffer limiting block (404) is arranged on the surface of the buffer tube (403); the surface of the rubber and the plate (402) is provided with a rectangular groove; and a buffer fixing groove matched with the buffer limiting block (404) is formed in the inner wall of the buffer hole (5).

6. The arched impact-resistant steel factory building connection structure of claim 5, wherein: the surfaces of the first connecting plate (201) and the second connecting plate (202) are both provided with a buffer telescopic groove (6); one side of the rubber and the plate (402) is provided with a buffer telescopic block (601) matched with the buffer telescopic groove (6).

Images