阅读说明：本技术 一种具有隔离散热结构的桥架及其使用方法 (Bridge frame with isolation and heat dissipation structure and using method thereof ) 是由 王征 王建华 于 2021-07-20 设计创作，主要内容包括：本发明提供一种具有隔离散热结构的桥架及其使用方法,包括桥架主体,桥架主体内部设置有多个可移动的导热夹板,导热夹板底部安装有多个移动块,桥架主体内部开设有多个用于与移动块进行连接的移动槽,移动块底部开设有连接槽,连接槽内部安装有防滑压板,移动块内部设置有用于对防滑压板进行施力的压紧机构,通过使用多个可移动的导热夹板,起到便于对电缆进行隔离和散热的作用,本发明结构合理,便于组合安装,隔开便捷,散热效果好,安全性高。(The invention provides a bridge with an isolation and heat dissipation structure and a using method thereof, wherein the bridge comprises a bridge main body, a plurality of movable heat conducting clamping plates are arranged in the bridge main body, a plurality of moving blocks are arranged at the bottoms of the heat conducting clamping plates, a plurality of moving grooves used for being connected with the moving blocks are formed in the bridge main body, connecting grooves are formed in the bottoms of the moving blocks, anti-skid pressing plates are arranged in the connecting grooves, a pressing mechanism used for applying force to the anti-skid pressing plates is arranged in the moving blocks, and the effects of conveniently isolating and dissipating heat of cables are achieved by using the plurality of movable heat conducting clamping plates.)

1. The utility model provides a crane span structure with keep apart heat radiation structure which characterized in that: including crane span structure main part (1), inside a plurality of mobilizable heat conduction splint (2) of being provided with of crane span structure main part (1), a plurality of movable blocks (6) are installed to heat conduction splint (2) bottom, inside a plurality of shifting chutes (5) of being used for being connected with movable block (6) of having seted up of crane span structure main part (1), spread groove (9) have been seted up to movable block (6) bottom, spread groove (9) internally mounted has non-slip clamp plate (10), inside being provided with of movable block (6) is used for carrying out the hold-down mechanism of application of force to non-slip clamp plate (10).

2. The bridge with the structure for isolating and dissipating heat of claim 1, wherein: the pressing mechanism comprises fastening screws (8), the fastening screws (8) are symmetrically installed inside the moving block (6) and are arranged on two sides of the heat conducting clamping plate (2), hexagonal rods (12) are installed at the bottoms of the fastening screws (8), and hexagonal bearings (11) are installed at the connection positions of the hexagonal rods (12) and the anti-skidding pressing plates (10).

3. The bridge with the structure for isolating and dissipating heat of claim 2, wherein: threaded holes (13) are formed in the moving block (6), the fastening screw rods (8) are connected with the moving block (6) through threads, avoidance holes (14) are formed in the top of the moving block (6), and the avoidance holes (14) are matched with the tops of the fastening screw rods (8).

4. The bridge with the structure for isolating and dissipating heat of claim 1, wherein: the movable block is characterized in that a guide post (3) used for limiting the movable block (6) is installed inside the movable groove (5), a guide hole (7) used for being connected with the guide post (3) is formed inside the movable block (6), and the diameter of the guide post (3) is matched with the inner diameter of the guide hole (7).

5. The bridge with the structure for isolating and dissipating heat of claim 1, wherein: the bridge frame main body (1) is internally provided with scale marks (4).

6. The bridge with the structure for isolating and dissipating heat of claim 1, wherein: the upper end surface of the moving block (6) is flush with the lower side of the inner wall of the bridge frame main body (1).

7. The bridge with the structure for isolating and dissipating heat of claim 1, wherein: the surface of the heat-conducting clamping plate (2) is provided with a heat-conducting coating (21).

8. The use method of the bridge with the isolated heat dissipation structure as recited in any one of claims 1 to 7, wherein: the method comprises the following steps:

step (A), adjusting the width between the heat-conducting clamping plates (2);

step (B), stopping and fixing the heat-conducting clamping plate (2);

and (C) placing the cable into the bridge frame main body (1).

9. The use method of the bridge with the isolated heat dissipation structure as recited in claim 8, wherein:

the step (A) specifically comprises the following steps

(A1) Observing the diameter of the cable, applying force to the heat conducting clamping plate (2) to enable a moving block (6) on the heat conducting clamping plate (2) to move in a moving groove (5), enabling the top of the moving block (6) to move along the lower side of the inner wall of the bridge frame main body (1), and enabling the guide column (3) to be used for limiting the moving block (6) when moving;

(A2) the distances between the adjacent heat conducting clamping plates (2) and between the heat conducting clamping plates (2) and the inner wall of the bridge frame main body (1) are the same as the diameter of the cable by observing the scale marks (4);

the step (B) specifically includes the following steps

(B1) After the width between the heat conducting clamping plates (2) is adjusted, the fastening screw (8) is rotated through a wrench, the fastening screw (8) rotates to drive the hexagonal rod (12) to move, and the hexagonal rod (12) moves to drive the anti-skidding pressing plate (10) to be tightly attached to the lower side of the inner wall of the moving groove (5);

(B2) using a spanner to execute the step (B1) on the fastening screw (8) on the moving block (6) after the rest width is adjusted;

the step (C) specifically comprises the following steps

(C1) Performing steps (a 1) to (B2) for the remaining non-adjusted heat conducting splint (2);

(C2) and placing the cable in the heat conducting clamping plate (2) after adjustment and fixation for clamping and fixing the cable, wherein when the cable generates heat, the heat is transferred to the bridge frame main body (1) along the heat conducting clamping plate (2) and the heat conducting coating (21), and finally discharged into the outside air.

Technical Field

The invention discloses a bridge with an isolation and heat dissipation structure and a using method thereof, and belongs to the technical field of bridges.

Background

The bridge is also called as cable bridge, and is divided into structures such as groove type cable bridge, tray type cable bridge, ladder type cable bridge and grid bridge, and is composed of bracket, support arm and mounting accessories. Can be independently erected and also can be laid on various buildings and pipe rack supports, and has the characteristics of simple structure, attractive appearance, flexible configuration, convenient maintenance and the like.

Among the prior art, the crane span structure is when using, generally concentrates on placing the cable inside the crane span structure, is not convenient for separate the cable, and the heat between the cable is piled up, is not convenient for discharge the heat, causes the conflagration easily, has the potential safety hazard, and the crane span structure that now urgently needs a kind to have isolation heat radiation structure solves the problem that above-mentioned appears.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a bridge frame with an isolation and heat dissipation structure and a using method thereof, so as to solve the problems in the background art.

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a crane span structure with keep apart heat radiation structure, includes the crane span structure main part, the inside a plurality of mobilizable heat conduction splint that are provided with of crane span structure main part, a plurality of movable blocks are installed to heat conduction splint bottom, a plurality of shifting chutes that are used for being connected with the movable block have been seted up to crane span structure main part inside, the spread groove has been seted up to the movable block bottom, spread groove internally mounted has anti-skidding clamp plate, the inside hold-down mechanism that is used for carrying out the application of force to anti-skidding clamp plate that is provided with of movable block.

Furthermore, the compressing mechanism comprises fastening screws, the fastening screws are symmetrically installed inside the moving block and are arranged on two sides of the heat conducting clamping plate, hexagonal rods are installed at the bottoms of the fastening screws, and hexagonal bearings are installed at the joints of the hexagonal rods and the anti-skidding pressing plate.

Furthermore, a threaded hole is formed in the moving block, the fastening screw is connected with the moving block through threads, an avoiding hole is formed in the top of the moving block, and the avoiding hole is matched with the top of the fastening screw.

Furthermore, a guide post used for limiting the moving block is installed inside the moving groove, a guide hole used for being connected with the guide post is formed inside the moving block, and the diameter of the guide post is matched with the inner diameter of the guide hole.

Furthermore, the bridge body is internally provided with scale marks.

Furthermore, the upper end face of the moving block is flush with the lower side of the inner wall of the bridge frame main body.

Further, the surface of the heat-conducting clamping plate is provided with a heat-conducting coating.

A use method of a bridge with an isolation and heat dissipation structure is characterized in that: the method comprises the following steps:

step (A), adjusting the width between the heat-conducting clamping plates;

step (B), stopping and fixing the heat-conducting clamping plate;

and (C) placing the cable into the bridge frame main body.

Further, the step (A) specifically includes the following steps

(A1) Observing the diameter of the cable, applying force to the heat-conducting clamping plate to enable a moving block on the heat-conducting clamping plate to move in the moving groove, enabling the top of the moving block to move along the lower side of the inner wall of the bridge frame main body, and limiting the moving block when the guide column moves;

(A2) observing the scale marks to ensure that the distances between the adjacent heat conducting clamping plates and between the heat conducting clamping plates and the inner wall of the bridge frame main body are the same as the diameter of the cable;

the step (B) specifically includes the following steps

(B1) After the width between the heat conducting clamping plates is adjusted, the fastening screw is rotated through the wrench, the fastening screw rotates to drive the hexagonal rod to move, and the hexagonal rod moves to drive the anti-skidding pressing plate to be tightly attached to the lower side of the inner wall of the moving groove;

(B2) performing the step (B1) on the fastening screw on the moving block after the rest width is adjusted by using a spanner;

the step (C) specifically comprises the following steps

(C1) Performing steps (a 1) to (B2) for the remaining non-adjusted heat-conducting cleats;

(C2) and placing the cable in the heat conducting clamping plate after adjustment and fixation for clamping and fixing the cable, wherein when the cable generates heat, the heat is transferred to the bridge frame main body along the heat conducting clamping plate and the heat conducting coating, and finally the heat is discharged into the outside air.

The invention has the beneficial effects that: when the bridge with the isolation and heat dissipation structure is used:

1. the plurality of movable heat conducting clamping plates are used, so that the effects of isolating and radiating cables are facilitated;

2. the fastening screw rod is used for driving the hexagonal rod to move, so that the anti-skidding pressing plate is driven to be attached to or separated from the moving groove, the heat-conducting clamping plate is convenient to fix, and the stability of a cable isolation position is improved;

3. the guide columns are used for guiding and limiting the heat-conducting clamping plates, so that the moving stability is improved;

4. through using the scale mark, be convenient for observe the regulation distance between the adjacent heat conduction splint.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a perspective view of a bridge with an isolated heat dissipation structure according to the present invention;

FIG. 2 is a perspective view of a bridge body and a guide post junction of a bridge with an isolated heat dissipation structure according to the present invention;

FIG. 3 is an enlarged view of A of FIG. 2 according to the present invention;

FIG. 4 is a perspective view of a connection between a heat-conducting clamp plate and a moving block in a bridge with an isolated heat-dissipating structure according to the present invention;

FIG. 5 is an enlarged view of B of FIG. 4 in accordance with the present invention;

FIG. 6 is a right side cross sectional view of a moving block in a bridge with an isolated heat sink structure according to the present invention;

FIG. 7 is a front cross-sectional view of a thermal clip in a bridge with an isolated heat sink structure according to the present invention;

in the figure: the anti-skidding type bridge comprises a bridge frame body 1, a heat-conducting clamping plate 2, a heat-conducting coating 21, a guide column 3, scale marks 4, a moving groove 5, a moving block 6, a guide hole 7, a fastening screw 8, a connecting groove 9, an anti-skidding pressing plate 10, a hexagonal bearing 11, a hexagonal rod 12, a threaded hole 13 and an avoiding hole 14.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1-7, the present invention provides a technical solution: the utility model provides a crane span structure with keep apart heat radiation structure, including crane span structure main part 1, 1 inside a plurality of mobilizable heat conduction splint 2 that are provided with of crane span structure main part, a plurality of movable blocks 6 are installed to heat conduction splint 2 bottom, 1 inside a plurality of shifting chutes 5 that are used for being connected with movable block 6 of seting up of crane span structure main part, spread groove 9 has been seted up to 6 bottoms of movable block, spread groove 9 internally mounted has anti-skidding clamp plate 10, 6 inside hold-down mechanism that are used for carrying out the application of force to anti-skidding clamp plate 10 that are provided with of movable block, through using a plurality of mobilizable heat conduction splint 2, play and be convenient for keep apart and radiating effect to the cable.

The pressing mechanism comprises fastening screws 8, the fastening screws 8 are symmetrically arranged inside a moving block 6 and are arranged on two sides of a heat conducting clamp plate 2, hexagonal rods 12 are arranged at the bottoms of the fastening screws 8, hexagonal bearings 11 are arranged at the joints of the hexagonal rods 12 and an anti-skid pressure plate 10, in the design, the fastening screws 8 are used for driving the hexagonal rods 12 to move, the hexagonal rods 12 are used for driving the anti-skid pressure plate 10 to move to be tightly attached to the lower sides of the inner walls of a moving groove 5, the moving block 6 is fixed, the heat conducting clamp plate 2 is further fixed conveniently, the fastening rods drive the hexagonal rods 12 to rotate through the hexagonal bearings 11, the anti-skid pressure plate 10 does not rotate along with the anti-skid pressure plate, threaded holes 13 are formed inside the moving block 6, the fastening screws 8 are connected with the moving block 6 through threads, avoidance holes 14 are formed in the top of the moving block 6, the avoidance holes 14 are matched with the tops of the fastening screws 8, and are connected through threads, the fastening screw 8 of being convenient for drives hexagonal rod 12 and removes, and then drives the laminating of antiskid clamp plate 10 and shifting chute 5 or separation, plays the effect of being convenient for fix heat conduction splint 2, improves the stability to cable isolation department.

Moving slot 5 internally mounted has and is used for carrying out spacing guide post 3 to movable block 6, the inside guiding hole 7 that is used for being connected with guide post 3 of offering of movable block 6, 3 diameters of guide post and 7 internal diameter phase-matchs in guiding hole, this design is connected with guiding hole 7 through using guide post 3, when moving block 6 removes, play direction and spacing effect, 1 inside scale mark 4 that is provided with of crane span structure main part, through using scale mark 4, be convenient for adjust the width of heat conduction splint 2 and observe, 6 up end of movable block flushes with 1 inner wall downside of crane span structure main part, the cable of being convenient for of this design laminates with 1 inner wall downside of crane span structure main part, 2 surfaces of heat conduction splint are provided with heat conduction coating 21, this design has improved heat conduction splint 2's heat conductivity.

A use method of a bridge with an isolation and heat dissipation structure is characterized in that: the method comprises the following steps:

step (A), adjusting the width between the heat-conducting clamping plates 2;

step (B), stopping and fixing the heat-conducting splint 2;

and (C) placing the cable into the bridge frame main body 1.

The step (A) specifically comprises the following steps

(A1) Observing the diameter of the cable, applying force to the heat conducting clamping plate 2 to enable the moving block 6 on the heat conducting clamping plate 2 to move in the moving groove 5, enabling the top of the moving block 6 to move along the lower side of the inner wall of the bridge frame main body 1, and enabling the guide columns 3 to be used for limiting the moving block 6 when moving, so that the moving stability is improved;

(A2) by observing the scale marks 4, the distances between the adjacent heat conducting clamping plates 2 and between the heat conducting clamping plates 2 and the inner wall of the bridge frame main body 1 are the same as the diameter of the cable;

the step (B) specifically includes the following steps

(B1) After the width between the heat conducting clamping plates 2 is adjusted, the fastening screw 8 is rotated through a wrench, the fastening screw 8 rotates to drive the hexagonal rod 12 to move, the hexagonal rod 12 moves to drive the anti-skidding pressing plate 10 to be tightly attached to the lower side of the inner wall of the moving groove 5, and the effect of conveniently fixing the adjusted heat conducting clamping plates 2 is achieved;

(B2) using a wrench to perform the step (B1) on the fastening screw 8 on the moving block 6 after the rest of the width is adjusted;

the step (C) specifically comprises the following steps

(C1) For the remaining heat-conducting splints 2 without adjustment, performing steps (a 1) to (B2);

(C2) place the cable inside adjusting fixed heat conduction splint 2 for press from both sides tight fixedly to the cable, play the effect of being convenient for carry out the isolation to the cable, when the cable generates heat, the heat transmits to crane span structure main part 1 along heat conduction splint 2 and heat conduction coating 21 on, during the outside air of discharging at last, prevents that the heat between the cable from piling up, reinforcing radiating effect.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics 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.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.