CN114696275A

CN114696275A - Heat-resistant corrosion-resistant cable bridge and use method thereof

Info

Publication number: CN114696275A
Application number: CN202210504911.2A
Authority: CN
Inventors: 高晓斌
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-05-10
Filing date: 2022-05-10
Publication date: 2022-07-01

Abstract

The invention discloses a heat-resistant corrosion-resistant cable bridge and a using method thereof, relates to the technical field of cable bridges, and solves the problems that when the cable bridge is used, the labor and the material resources needed during maintenance or replacement are very large due to difficulty in disassembly and assembly, and a supporting plate at the bottom end of the bridge often falls off when a hanging rod supports the bridge, so that accidents occur. The cable bridge comprises bridge shells, wherein two hanging rods are movably mounted on the outer surfaces of the two bridge shells, and movable blocks are movably mounted on the inner side surfaces of the hanging rods. According to the device, the outer buckle of the supporting plate is clamped into the inner part of the top groove of the movable block when the crane span structure shell needs to be fixed by the suspender through a fastening mode of the outer buckle of the supporting plate in the inner part of the top groove of the movable block, so that the outer buckle of the supporting plate is inwards shrunk through the elastic potential energy of the compression spring and fastened in the inner part of the top groove of the movable block, and the situation that the supporting plate is loosened and falls off is prevented.

Description

Heat-resistant corrosion-resistant cable bridge and use method thereof

Technical Field

The invention relates to the technical field of cable bridges, in particular to a heat-resistant and corrosion-resistant cable bridge and a using method thereof.

Background

With the rapid development of social economy, the use of cable bridges has become one of the very common articles in daily life of people, and the cable bridges are divided into structures of a groove type, a tray type, a ladder type, a grid type and the like, and are composed of a support, a support arm, an installation accessory and the like. The inner bridge frame of the building can be independently erected and also can be laid on various buildings and pipe gallery supports, the characteristics of simple structure, attractive appearance, flexible configuration, convenient maintenance and the like are reflected, all parts need to be galvanized, and the inner bridge frame is arranged outside the building in the open air.

However, when the existing cable bridge is used, the labor and the material resources required for maintenance or replacement are very large due to the fact that the existing cable bridge is difficult to disassemble and assemble, the cable bridge is very inconvenient to use, and when the hanger rod supports the bridge, the supporting plate at the bottom end of the bridge often falls off to cause accidents; therefore, the existing requirements are not met, and a heat-resistant and corrosion-resistant cable bridge and a using method thereof are provided.

Disclosure of Invention

The invention aims to provide a heat-resistant and corrosion-resistant cable bridge and a using method thereof, and aims to solve the problems that when the cable bridge provided in the background art is used, the difficulty in disassembly and assembly often causes great manpower and material resources required during maintenance or replacement, the cable bridge is very inconvenient to use, and when a hanger rod supports the cable bridge, a supporting plate at the bottom end of the cable bridge often falls off to cause accidents and the like.

In order to achieve the purpose, the invention provides the following technical scheme: a heat-resistant corrosion-resistant cable bridge comprises a bridge shell, wherein two suspenders are movably mounted on the outer surface of the bridge shell, movable blocks are movably mounted on the inner side surfaces of the suspenders, movable block top grooves are formed in the top end surfaces of the movable blocks, a supporting plate is movably mounted at the bottom end of the bridge shell, supporting plate outer buckles are movably mounted on the outer surface of the supporting plate, supporting plate outer grooves are formed in the outer surface of the supporting plate, supporting plate inner grooves are formed in the inner surfaces of the supporting plate outer grooves, the supporting plate outer buckles are clamped into the inner parts of the supporting plate inner grooves through the supporting plate outer grooves, two supporting plate limiting buckles are fixedly mounted on the surfaces of the supporting plate outer buckles positioned in the supporting plate inner grooves, the supporting plate limiting buckles are clamped into the supporting plate inner grooves, two compression springs are movably mounted in the supporting plate inner grooves, and the supporting plate limiting buckles are attached to the compression springs, the outer ends of the outer buckles of the supporting plate are clamped into the movable block top groove.

Preferably, two movable mounting has the link between the crane span structure shell, the inside of link is all gone into to the equal card of one end of crane span structure shell, the inside both sides inner wall surface of link all is equipped with the link inside groove, the equal movable mounting in inside of link inside groove has the bending spring, the inside one end surface of link is gone into to crane span structure shell card all is equipped with two shell kerfs, the inside surface of shell kerve all is equipped with the shell spacing groove, the equal movable mounting in inside of link inside groove has the pivot, the equal movable mounting of surface of pivot has movable cardboard, movable cardboard all goes into the inside of shell spacing groove through shell kerve card, the inner wall that the pivot all runs through the link extends to the top outside of link, the equal movable mounting in top of pivot has the rotation handle.

Preferably, the equal fixed mounting in inside of crane span structure shell has six fixed arc boards, the equal movable mounting in top surface of fixed arc board has movable arc board, the top surface of fixed arc board all is equipped with fixed arc board top groove, the equal fixed mounting in bottom surface of activity arc board has movable arc board end to detain, detain the inside of fixed arc board top groove all to block into at the bottom of the activity arc board.

Preferably, the outer surface of the movable block is fixedly provided with an outer T-shaped buckle of the movable block, and the outer T-shaped buckle of the movable block is movably clamped into the T-shaped groove of the suspender.

Preferably, two baffles are fixedly mounted on the surfaces of the inner walls of the two sides in the bridge shell, and the movable clamping plates are attached to the surfaces of the baffles.

Preferably, the inside of the fixed arc plate is movably provided with a cable, and the top end of the suspender is fixedly provided with a suspender fixing plate.

Preferably, the bridge housing and the bridge top cover are both made of aluminum alloy materials.

Compared with the prior art, the heat-resistant and corrosion-resistant cable bridge has the beneficial effects that:

according to the device, the outer buckle of the supporting plate is fastened in the movable block top groove in a manner of matching the compression spring with the limiting buckle of the supporting plate, so that when the device needs a suspender to fix a bridge shell, the outer buckle of the supporting plate can be clamped into the movable block top groove, the outer buckle of the supporting plate is inwards shrunk through the elastic potential energy of the compression spring to be fastened in the movable block top groove, the supporting plate is further fastened at the bottom end of the bridge shell, the supporting plate is prevented from loosening and falling off, and the stability of the device is improved while the device can be rapidly disassembled and assembled.

The use method of the heat-resistant corrosion-resistant cable bridge comprises the following steps:

(A) inserting one end of a first bridge shell into one end of a connecting frame, enabling the surface of the bridge shell to impact the outer surface of a movable clamping plate inside an inner groove of the connecting frame, enabling the movable clamping plate to rotate to the inside of the inner groove of the connecting frame due to a rotating shaft, enabling the movable clamping plate to move to the inside of a limiting groove of the shell through the inside of an outer groove of the shell, enabling the movable clamping plate to rebound and be clamped into the inside of the limiting groove of the shell due to elastic potential energy of a bending spring and be attached to the surface of a baffle plate to complete assembly of the first bridge shell, and then repeatedly operating to clamp a second bridge shell into the other end of the connecting frame;

(B) the movable arc plate is shifted to enable the movable arc plate to rotate on the top end surface of the fixed arc plate, so that the cable can be clamped into the fixed arc plate, the movable arc plate is shifted again to enable the movable arc plate to seal the fixed arc plate to prevent the cable from falling off from the inside of the fixed arc plate, and therefore the cable is fixed while being conveniently arranged;

(C) placing two hanging rods on the surfaces of two sides of a bridge shell, pressing down a movable block on the inner side of each hanging rod to enable the movable block to generate a larger gap with the bottom end of the bridge shell, placing a supporting plate at the bottom end of the bridge shell, pulling out a supporting plate outer buckle on the outer surface of the supporting plate towards two sides, enabling the supporting plate outer buckle to be clamped into a movable block top groove on the surface of the top end of the movable block, then enabling the supporting plate outer buckle to contract inwards through elastic potential energy of a compression spring and fasten the movable block in the movable block top groove, further enabling the supporting plate to fasten, then adjusting the height of the movable block, and after adjusting to a required position, fixing the movable block through a bolt;

(D) and finally, transversely inserting the bridge top cover into the connecting frame to seal the top end of the bridge shell, and fixing the suspender fixing plate at the top end of the suspender on a ceiling or other designated places through bolts to finish the assembly of the device.

Preferably, the outer surfaces of the two sides of the connecting frame are provided with concave grooves, and the bridge top cover is clamped into the concave grooves.

Preferably, the top surface of movable block is equipped with globular fixed block, the terminal position that the layer board was buckled the outside all is equipped with globular fixed block, the installation of mutually supporting of globular fixed block.

Compared with the prior art, the using method has the beneficial effects that:

according to the invention, through the way that a plurality of parts are mutually matched, the device can realize simple and quick assembly and disassembly, the operation time and the operation difficulty required by workers are reduced, and the cable bridge is convenient, quick and effective to assemble and disassemble.

Drawings

FIG. 1 is a schematic structural view of the present invention as a whole;

FIG. 2 is a cross-sectional side view of the present invention in its entirety;

FIG. 3 is a cross-sectional top view of the present invention as a whole;

FIG. 4 is a partial cross-sectional side view of portion A of the present invention;

FIG. 5 is a side view, partially in section, of part B of the present invention;

fig. 6 is a partial cutaway top view of section C of the present invention.

In the figure: 1. a bridge housing; 2. a bridge top cover; 3. a connecting frame; 4. a boom; 5. a suspender fixing plate; 6. a T-shaped groove of the suspender; 7. a cable; 8. a support plate; 9. fixing the arc plate; 10. a movable arc plate; 11. fixing the arc plate top groove; 12. the bottom of the movable arc plate is buckled; 13. an inner groove of the connecting frame; 14. a bending spring; 15. a baffle plate; 16. an outer casing groove; 17. a housing limiting groove; 18. a movable clamping plate; 19. a rotating shaft; 20. a movable block; 21. the movable block is externally provided with a T-shaped buckle; 22. a movable block top groove; 23. the supporting plate is externally buckled; 24. a supporting plate limiting buckle; 25. a pallet outer groove; 26. an inner groove of the supporting plate; 27. a compression spring; 28. the handle is rotated.

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.

Referring to fig. 1 to 6, an embodiment of the present invention includes: a heat-resistant corrosion-resistant cable bridge comprises a bridge shell 1, wherein two suspenders 4 are movably mounted on the outer surfaces of the two bridge shells 1, movable blocks 20 are movably mounted on the inner side surfaces of the suspenders 4, movable block top grooves 22 are formed in the top end surfaces of the movable blocks 20, a supporting plate 8 is movably mounted at the bottom end of the bridge shell 1, supporting plate outer buckles 23 are movably mounted on the outer surface of the supporting plate 8, supporting plate outer grooves 25 are formed in the outer surface of the supporting plate 8, supporting plate inner grooves 26 are formed in the inner surfaces of the supporting plate outer grooves 25, the supporting plate outer buckles 23 are clamped into the supporting plate inner grooves 26 through the supporting plate outer grooves 25, two supporting plate limit buckles 24 are fixedly mounted on the surfaces of the supporting plate outer buckles 23 positioned in the supporting plate inner grooves 26, the supporting plate limit buckles 24 are clamped into the supporting plate inner grooves 26, two compression springs 27 are movably mounted in the supporting plate inner grooves 26, and the supporting plate limit buckles 24 are attached to the compression springs 27, the outer ends of the outer buckles 23 of the supporting plate are clamped into the movable block top grooves 22.

Further, a connecting frame 3 is movably installed between the two bridge housings 1, one end of each bridge housing 1 is clamped into the connecting frame 3, inner wall surfaces of two sides of the inside of each connecting frame 3 are respectively provided with a connecting frame inner groove 13, a bending spring 14 is movably installed inside each connecting frame inner groove 13, one end surface of each bridge housing 1 clamped into the inside of each connecting frame 3 is respectively provided with two housing outer grooves 16, the inner surfaces of the housing outer grooves 16 are respectively provided with a housing limiting groove 17, a rotating shaft 19 is movably installed inside each connecting frame inner groove 13, movable clamping plates 18 are movably installed on the outer surfaces of the rotating shafts 19, the movable clamping plates 18 are respectively clamped into the housing limiting grooves 17 through the housing outer grooves 16, the rotating shafts 19 respectively penetrate through the inner walls of the connecting frames 3 and extend to the outer side of the top ends of the connecting frames 3, rotating handles 28 are movably installed at the top ends of the rotating shafts 19, and are matched with the rotating handles 28 and the rotating shafts 19, when the device needs to remove the bridge shell 1 and the connecting frame 3, the movable clamping plate 18 can rotate in the shell limiting groove 17 by rotating the rotating handle 28, so that the two bridge shells 1 can be pulled out outwards, and accidents caused by mistakenly pulling out the bridge shell 1 due to mistaken touch of people are prevented.

Further, the equal fixed mounting in inside of crane span structure shell 1 has six fixed arc boards 9, the equal movable mounting in top surface of fixed arc board 9 has movable arc board 10, the top surface of fixed arc board 9 all is equipped with fixed arc board kerve 11, the equal fixed mounting in bottom surface of movable arc board 10 has movable arc board bottom to detain 12, detain 12 at the bottom of the movable arc board and all block the inside of fixed arc board kerve 11, cooperation through fixed arc board 9 and movable arc board 10, thereby fix cable 7 when making things convenient for the winding displacement to cable 7.

Further, the outer T type of the movable block 20 is fixed on the outer surface of the movable block and is buckled with 21, the outer T type of the movable block is buckled with 21, the movable block is movably clamped into the T type groove 6 of the suspender, and the movable block 20 can move up and down on the surface of the suspender 4 through the matching of the outer T type of the movable block and the T type groove 6 of the suspender, so that the bridge shell 1 at different heights can be conveniently installed and fixed.

Further, the equal fixed mounting in inside both sides inner wall surface of crane span structure shell 1 has two baffles 15, and activity cardboard 18 all blocks activity cardboard 18 with the surface laminating of baffle 15 through baffle 15, prevents that activity cardboard 18 from because elastic potential energy and rotation amplitude are too big and bursting apart, leads to the accident to take place.

Furthermore, the inside of the fixed arc plate 9 is movably provided with a cable 7, and the top end of the suspender 4 is fixedly provided with a suspender fixing plate 5.

Further, the bridge shell 1 and the bridge top cover 2 are both made of aluminum alloy, and the bridge shell 1 and the bridge top cover 2 made of the aluminum alloy enable the device to have good heat resistance and corrosion resistance.

A method for using a heat-resistant corrosion-resistant cable bridge comprises the following steps:

(A) firstly, inserting one end of a first bridge shell 1 into one end of a connecting frame 3, enabling the surface of the bridge shell 1 to impact the outer surface of a movable clamping plate 18 in an inner groove 13 of the connecting frame, enabling the movable clamping plate 18 to rotate to the inside of the inner groove 13 of the connecting frame due to a rotating shaft 19, enabling the movable clamping plate 18 to move to the inside of a shell limiting groove 17 through the inside of an outer groove 16 of the shell, then enabling the movable clamping plate 18 to rebound to be clamped into the inside of the shell limiting groove 17 due to the elastic potential energy of a bending spring 14 and to be attached to the surface of a baffle 15, completing the assembly of the first bridge shell 1, and then repeatedly operating to clamp a second bridge shell 1 into the other end of the connecting frame 3;

(B) the movable arc plate 10 is shifted to enable the movable arc plate 10 to rotate on the top end surface of the fixed arc plate 9, the cable 7 can be clamped into the fixed arc plate 9, the movable arc plate 10 is shifted again, the movable arc plate 10 seals the fixed arc plate 9 to prevent the cable 7 from falling off from the inside of the fixed arc plate 9, and therefore the cable 7 is fixed while the cable 7 is conveniently arranged;

(C) placing two hanger rods 4 on the surfaces of two sides of a bridge shell 1, pressing down a movable block 20 on the inner side of each hanger rod 4 to enable the movable block to generate a larger gap with the bottom end of the bridge shell 1, placing a supporting plate 8 at the bottom end of the bridge shell 1, pulling out a supporting plate outer buckle 23 on the outer surface of the supporting plate 8 towards two sides, enabling the supporting plate outer buckle 23 to be clamped into a movable block top groove 22 on the surface of the top end of each movable block 20, then enabling the supporting plate outer buckle 23 to contract inwards through elastic potential energy of a compression spring 27 to fasten the inside of the movable block top groove 22, further enabling the supporting plate 8 to fasten, then adjusting the height of each movable block 20, and after adjusting to a required position, fixing the movable blocks 20 through bolts;

(D) finally, the bridge top cover 2 is transversely inserted into the connecting frame 3 to seal the top end of the bridge shell 1, and then the suspender fixing plate 5 at the top end of the suspender 4 is fixed on a ceiling or other designated places through bolts to complete the assembly of the device.

Furthermore, the outer surfaces of the two sides of the connecting frame 3 are respectively provided with a concave groove, and the bridge top cover 2 is clamped into the concave grooves.

Further, the top surface of movable block 20 is equipped with globular fixed block, and the terminal position that 23 outsides were detained outward to the layer board all is equipped with globular fixed block, and the installation is mutually supported to globular fixed block.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a heat-resisting corrosion-resistant cable testing bridge, includes crane span structure shell (1), its characterized in that: two the outer surface of the bridge shell (1) is movably provided with two hanging rods (4), the inner side surface of each hanging rod (4) is movably provided with a movable block (20), the top end surface of each movable block (20) is provided with a movable block top groove (22), the bottom end of the bridge shell (1) is movably provided with a supporting plate (8), the outer surface of each supporting plate (8) is movably provided with a supporting plate outer buckle (23), the outer surface of each supporting plate (8) is provided with a supporting plate outer groove (25), the inner surface of each supporting plate outer groove (25) is provided with a supporting plate inner groove (26), each supporting plate outer buckle (23) is clamped into the inner part of each supporting plate inner groove (26) through the supporting plate outer groove (25), the surface of each supporting plate inner groove outer buckle (23) positioned in the supporting plate (26) is fixedly provided with two supporting plate limit buckles (24), and each supporting plate limit buckle (24) is clamped into the inner part of each supporting plate (26), the inside of layer board inside groove (26) all movable mounting have two compression spring (27), layer board limit buckle (24) all laminate with compression spring (27), the inside in movable block top groove (22) is all gone into to the outer end of layer board detaining (23) outward.

2. A heat and corrosion resistant cable tray according to claim 1, wherein: movably mounted between two crane span structure shells (1) has link (3), the inside of link (3) is all gone into to the one end of crane span structure shell (1), the inside both sides inner wall surface of link (3) inside all is equipped with link inside groove (13), the equal movably mounted in inside of link inside groove (13) has bending spring (14), the crane span structure shell (1) card is gone into the one end surface of link (3) inside and all is equipped with two shell kerfs (16), the inside surface of shell kerfs (16) all is equipped with shell spacing groove (17), the equal movably mounted in inside of link inside groove (13) has pivot (19), the equal movably mounted in surface of pivot (19) has activity cardboard (18), activity cardboard (18) all go into the inside of shell spacing groove (17) through shell kerfs (16), pivot (19) all run through the inner wall of link (3) and extend to the top outside of link (3), the top end of the rotating shaft (19) is movably provided with a rotating handle (28).

3. A heat and corrosion resistant cable tray according to claim 1, wherein: the equal fixed mounting in inside of crane span structure shell (1) has six fixed arc boards (9), the equal movable mounting in top surface of fixed arc board (9) has movable arc board (10), the top surface of fixed arc board (9) all is equipped with fixed arc board top groove (11), the equal fixed mounting in bottom surface of activity arc board (10) has movable arc board end to detain (12), detain at the bottom of the activity arc board (12) and all block into the inside of fixed arc board top groove (11).

4. A heat and corrosion resistant cable tray according to claim 1, wherein: the outside surface of movable block (20) all fixed mounting have the outer T type of movable block to detain (21), the outer T type of movable block detains (21) and all moves about and block in the inside of jib T type groove (6).

5. The heat and corrosion resistant cable tray of claim 1, wherein: the inner wall surfaces of two sides in the bridge shell (1) are fixedly provided with two baffles (15), and the movable clamping plates (18) are attached to the surfaces of the baffles (15).

6. A heat and corrosion resistant cable tray according to claim 1, wherein: the cable (7) is movably mounted in the fixed arc plate (9), and the suspender fixing plate (5) is fixedly mounted at the top end of the suspender (4).

7. A heat and corrosion resistant cable tray according to claim 1, wherein: the bridge shell (1) and the bridge top cover (2) are both made of aluminum alloy materials.

8. A method for using a heat-resistant and corrosion-resistant cable bridge is characterized by comprising the following steps: the use method of the heat-resistant corrosion-resistant cable bridge comprises the following steps:

(A) firstly, inserting one end of a first bridge shell (1) into one end of a connecting frame (3), enabling the surface of the bridge shell (1) to impact the outer surface of a movable clamping plate (18) inside a connecting frame inner groove (13), enabling the movable clamping plate (18) to rotate to the inside of the connecting frame inner groove (13) due to a rotating shaft (19), enabling the movable clamping plate (18) to move to the inside of a shell limiting groove (17) through the inside of a shell outer groove (16), then enabling the movable clamping plate (18) to rebound to be clamped into the inside of the shell limiting groove (17) due to the elastic potential energy of a bending spring (14) and to be attached to the surface of a baffle (15), completing the assembly of the first bridge shell (1), and then repeatedly operating to clamp a second bridge shell (1) into the other end of the connecting frame (3);

(B) the movable arc plate (10) is shifted to enable the movable arc plate (10) to rotate on the top end surface of the fixed arc plate (9), the cable (7) can be clamped into the fixed arc plate (9), the movable arc plate (10) is shifted again, the movable arc plate (10) seals the fixed arc plate (9) to prevent the cable (7) from falling off from the inside of the fixed arc plate (9), and therefore the cable (7) is fixed while being conveniently arranged;

(C) placing two suspension rods (4) on the surfaces of two sides of a bridge shell (1), pressing down movable blocks (20) on the inner sides of the suspension rods (4) to enable the movable blocks to generate a larger gap with the bottom end of the bridge shell (1), placing a supporting plate (8) at the bottom end of the bridge shell (1), pulling out supporting plate outer buckles (23) on the outer surfaces of the supporting plate (8) towards two sides, enabling the supporting plate outer buckles (23) to be clamped into movable block top grooves (22) on the top end surfaces of the movable blocks (20), then enabling the supporting plate outer buckles (23) to contract inwards through elastic potential energy of compression springs (27) to be fastened in the movable block top grooves (22), further enabling the supporting plate (8) to be fastened, then adjusting the height of the movable blocks (20), and after adjusting to a required position, fixing the movable blocks (20) through bolts;

(D) and finally, transversely inserting the bridge top cover (2) into the connecting frame (3) to seal the top end of the bridge shell (1), and fixing a suspender fixing plate (5) at the top end of the suspender (4) on a ceiling or other designated places through bolts to complete the assembly of the device.

9. The use method of the heat-resistant corrosion-resistant cable bridge frame according to claim 8, wherein the method comprises the following steps: the outer surfaces of two sides of the connecting frame (3) are provided with concave grooves, and the bridge top cover (2) is clamped into the concave grooves.

10. The use method of the heat-resistant corrosion-resistant cable bridge frame according to claim 8, wherein the method comprises the following steps: the top surface of movable block (20) is equipped with globular fixed block, the terminal position in the layer board outer knot (23) outside all is equipped with globular fixed block, the installation of globular fixed block mutually supporting.