CN214429149U - Energy-saving cable bridge mounting structure - Google Patents

Abstract

The application relates to an energy-saving cable bridge mounting structure, which belongs to the technical field of cable bridges and comprises a plurality of mounting blocks fixed on a building mounting surface, wherein cavities are formed in the interior of the mounting blocks, two sections of sliding holes are formed in the outer surfaces, deviating from the mounting surface, of the mounting blocks, the two sections of sliding holes are positioned on the same straight line and are communicated with the cavities, and oppositely arranged clamping plates are connected in the two sections of sliding holes in a sliding manner; the bridge frame body is placed on the outer surface of the mounting block, which is far away from the mounting surface, and is clamped between the two clamping plates, and a driving assembly for driving the two clamping plates to approach or separate from each other simultaneously is arranged in the cavity; the outer surface that the installation piece deviates from the installation face is equipped with a plurality of construction bolts, and construction bolt runs through the back with the crane span structure body with installation piece threaded connection, and this application has and can installs the cable crane span structure of different models to reduce the extravagant effect of resource.

Description

Energy-saving cable bridge mounting structure

Technical Field

The application relates to the technical field of cable bridges, in particular to an energy-saving cable bridge mounting structure.

Background

The cable bridge is divided into structures such as a groove type structure, a tray type structure, a ladder type structure, a grid type structure and the like; the groove type cable bridge can be independently erected in a building, and also can be laid on various buildings and pipe rack supports.

The existing Chinese patent with reference to publication number CN201496662U discloses a cable bridge vertical mounting structure, which comprises a plurality of sections of channel steel and a plurality of sections of angle steel, wherein one side surfaces of the plurality of sections of channel steel are horizontally arranged at intervals along a wall or a vertical shaft wall, and the two ends of the plurality of sections of channel steel are aligned with each other; the installation is convenient and reliable, meets the standard requirement, and is convenient for the subsequent maintenance and overhaul operation of the cable bridge.

Aiming at the related technologies, the inventor thinks that the defects that the installation structure can only be used for installing cable bridges of the same type due to the fixed shapes and sizes of the channel steel and the angle steel, and if cable bridges of different types are needed, channel steel and angle steel of different shapes and sizes need to be manufactured, so that the resource is wasted exist.

SUMMERY OF THE UTILITY MODEL

In order to embody the installation of cable bridges of different models and reduce the waste of resources, the application provides an energy-saving cable bridge installation structure.

The application provides an energy-saving cable testing bridge mounting structure adopts following technical scheme:

an energy-saving cable bridge mounting structure comprises a plurality of mounting blocks fixed on a building mounting surface, wherein cavities are formed in the interior of the mounting blocks, two sections of sliding holes are formed in the outer surfaces, away from the mounting surface, of the mounting blocks, the two sections of sliding holes are located on the same straight line and are communicated with the cavities, and oppositely arranged clamping plates are connected in the two sections of sliding holes in a sliding mode; the bridge frame body is placed on the outer surface of the mounting block, which is far away from the mounting surface, and is clamped between the two clamping plates, and a driving assembly for driving the two clamping plates to approach or separate from each other simultaneously is arranged in the cavity; the outer surface of the mounting block, which is far away from the mounting surface, is provided with a plurality of mounting bolts, and the mounting bolts penetrate through the bridge body and are in threaded connection with the mounting block.

By adopting the technical scheme, the bridge frame body is arranged on the mounting blocks, so that a distance exists between the bridge frame body and the mounting surface, and the heat dissipation performance of the bridge frame body is improved; after placing the crane span structure body on the installation piece, make two splint be close to each other until pressing from both sides the crane span structure body tight through drive assembly, run through the crane span structure body with the construction bolt again the back screw thread screw up in the installation piece, under the firm prerequisite of crane span structure body installation, can install fixedly to the crane span structure body of different models, need not to dispose the not installation piece of equidimension according to the crane span structure body of different models, reduced the waste of resource to all can stably install on level, vertical or the installation face of slope.

Optionally, the driving assembly comprises a bidirectional screw and a hand wheel, the bidirectional screw is rotatably connected in the cavity, a rotation axis of the bidirectional screw is parallel to the moving direction of the clamping plate, and one end of the bidirectional screw extends out of the mounting block and is fixed with the hand wheel; the two-way screw rod is arranged opposite to the two sliding holes, the circumferential side wall of the two-way screw rod is divided into two sections of threads with opposite rotating directions by the middle part, and one ends of the two clamping plates extend into the cavity and are respectively in threaded connection with different threads of the two-way screw rod.

Through adopting above-mentioned technical scheme, rotate the hand wheel and make two-way screw rod rotate, and then make two splint slide in two sliding holes respectively to be close to each other or keep away from, make two splint more convenient to the fixed of crane span structure body.

Optionally, one end of the mounting bolt in threaded connection with the mounting block extends into the cavity and abuts against the circumferential side wall of the bidirectional screw.

Through adopting above-mentioned technical scheme, the crane span structure body is fixed back on the installation piece, and the construction bolt can be with two-way screw rod top tightly in case two-way screw rod rotates, and then makes two splint more stable to the fixed of crane span structure body.

Optionally, the mounting bolt is located between the two sliding holes, and the thread section of the bidirectional screw is just opposite to the sliding hole.

Through adopting above-mentioned technical scheme for the position of two-way screw rod circumference lateral wall and mounting bolt contact is threadless, and then makes the contact between mounting bolt and the two-way screw rod more stable.

Optionally, an elastic block is fixed at one end of the mounting bolt, which is in contact with the bidirectional screw rod.

By adopting the technical scheme, the elastic block can reduce the abrasion of the bidirectional screw and the mounting bolt, the service lives of the bidirectional screw and the mounting bolt are prolonged, and the stress of the bidirectional screw is more stable.

Optionally, the inner wall of the cavity far away from the bridge body is fixedly provided with a support column, one end of the support column is abutted against the circumferential side wall of the bidirectional screw, and the position of the support column abutted against the bidirectional screw is opposite to the mounting bolt.

Through adopting above-mentioned technical scheme, the support column can support the pressure department that two-way screw rod received the construction bolt, has prolonged two-way screw rod's life.

Optionally, the contact surface of the supporting column and the bidirectional screw rod is arc-shaped.

Through adopting above-mentioned technical scheme, circular-arc setting can increase the area of contact of support column and two-way screw rod, and then makes that the support column can be better support two-way screw rod.

Optionally, two opposite side walls of the clamping plate are provided with long-strip-shaped side holes, a plurality of heat dissipation holes are formed in the opposite side walls of the bridge frame body, and the heat dissipation holes are communicated with the side holes.

Through adopting above-mentioned technical scheme, this internal heat of crane span structure can loop through side opening and louvre and diffuse to the external world, has improved this internal radiating efficiency of crane span structure.

In summary, the present application includes at least one of the following beneficial technical effects:

1. after the bridge frame body is placed on the mounting block, the two clamping plates are close to each other through the driving assembly until the bridge frame body is clamped tightly, the mounting bolt penetrates through the bridge frame body and then is screwed in the mounting block in a threaded manner, on the premise that the bridge frame body is firmly mounted, the bridge frame bodies of different models can be mounted and fixed, mounting blocks of different sizes do not need to be configured according to the bridge frame bodies of different models, and waste of resources is reduced;

2. the hand wheel is rotated to rotate the bidirectional screw rod, so that the two clamping plates respectively slide in the two sliding holes and are close to or far away from each other, and the two clamping plates can fix the bridge frame body more conveniently;

3. after the crane span structure body is fixed on the installation piece, the mounting bolt can tightly push the two-way screw rod to prevent the two-way screw rod from rotating, and then makes the fixing of two splint to the crane span structure body more stable.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present application;

FIG. 2 is a partial cross-sectional view showing a drive assembly;

FIG. 3 is a schematic diagram showing the structure of the driving assembly;

fig. 4 is a schematic diagram showing the structure of the supporting column.

In the figure, 1, a mounting surface; 2. a bridge frame body; 21. heat dissipation holes; 3. mounting blocks; 31. a cavity; 32. a slide hole; 4. a splint; 41. a side hole; 5. a drive assembly; 51. a bidirectional screw; 52. a hand wheel; 6. installing a bolt; 61. an elastic block; 7. and (4) a support column.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses an energy-saving cable bridge mounting structure.

Referring to fig. 1 and 2, the energy-saving cable bridge mounting structure includes a plurality of mounting blocks 3 fixed on a mounting surface 1, the mounting blocks 3 are arranged along a length direction of a bridge body 2, in this embodiment, the mounting surface 1 is taken as a horizontal plane as an example, the bridge body 2 is placed on upper surfaces of the mounting blocks 3, each mounting block 3 is provided with a clamping adjusting mechanism for clamping two sides of the bridge body 2, the bridge body 2 is vertically provided with a plurality of mounting bolts 6, and the mounting bolts 6 penetrate through the bridge body 2 and are in threaded connection with the mounting blocks 3; can press from both sides tightly fixedly to the crane span structure body 2 of different models through pressing from both sides tight adjustment mechanism, mounting bolt 6 carries out the final fixed of crane span structure body 2, has reached the effect of saving the resource.

Referring to fig. 2 and 3, the clamping adjustment mechanism includes two oppositely disposed clamping plates 4 and a driving assembly 5 for driving the two clamping plates 4 to approach or separate from each other, the upper surface of the mounting block 3 is provided with two sliding holes 32 located on the same straight line, the length direction of the sliding holes 32 is horizontally arranged and perpendicular to the length direction of the bridge body 2, and the two clamping plates 4 are respectively located in different sliding holes 32 and slide along the length direction of the sliding holes 32; the driving assembly 5 comprises a bidirectional screw 51 and a hand wheel 52, a cavity 31 is formed in the mounting block 3, the two sliding holes 32 are communicated with the cavity 31, the bidirectional screw 51 is rotatably connected in the cavity 31 and parallel to the length direction of the sliding holes 32, the bidirectional screw 51 is positioned under the two sliding holes 32, the circumferential side walls of the bidirectional screw 51 positioned under the two different sliding holes 32 are provided with threads with opposite rotation directions, the bottom ends of the two clamping plates 4 extend downwards into the cavity 31 and are respectively in threaded connection with the threads of the bidirectional screw 51 in different rotation directions, and one end of the bidirectional screw 51 extends out of the cavity 31 and is fixed with the hand wheel 52; the hand wheel 52 is rotated to rotate the bidirectional screw 51, so that the two clamping plates 4 are close to each other in the two sliding holes 32 and clamp and fix the bridge body 2, and the installation efficiency of the bridge body 2 is improved.

Referring to fig. 2 and 4, the bottom end of the mounting bolt 6 extends into the cavity 31 and is fixedly connected with an elastic block 61, in this embodiment, the elastic block 61 is made of rubber, the mounting bolt 6 is located between the two sliding holes 32, and the elastic block 61 is pressed at a position without threads in the middle of the bidirectional screw 51; a supporting column 7 is vertically and fixedly arranged on the inner bottom wall of the cavity 31, the upper end face of the supporting column 7 is arc-shaped and is attached to the middle of the circumferential side wall of the bidirectional screw 51, and the supporting column 7 is positioned right below the mounting screw; after the mounting bolt 6 is screwed on the mounting block 3, the bidirectional screw 51 is pressed by the elastic block 61, so that the bridge frame body 2 is more stably fixed, the support column 7 provides a supporting force for the middle part of the bidirectional screw 51, and the safety of the support column 7 is improved.

Referring to fig. 1 and 2, a plurality of heat dissipation holes 21 are formed in the side walls of the bridge body 2 which deviate from each other along the length direction of the bridge body, strip-shaped side holes 41 are formed in the inner walls of every two opposite clamping plates 4, and each side hole 41 is communicated with different heat dissipation holes 21, so that the heat dissipation efficiency of the bridge body 2 is improved.

The implementation principle of the energy-saving cable bridge mounting structure in the embodiment of the application is as follows: placing the bridge frame body 2 on the upper surfaces of the mounting blocks 3, rotating the hand wheel 52 to enable the bidirectional screw 51 to rotate, enabling the two clamping plates 4 to approach each other in the two sliding holes 32 and clamp and fix the bridge frame body 2, penetrating the mounting bolt 6 through the bridge frame body 2 and then screwing the mounting bolt 6 into the mounting blocks 3, enabling the mounting bolt 6 to enable the elastic blocks 61 to be pressed on the middle parts of the circumferential side walls of the bidirectional screw 51, and enabling the support columns 7 to support the middle parts of the bidirectional screw 51; finally, the bridge bodies 2 of different models can be installed and fixed without arranging the installation blocks 3 of different sizes according to the bridge bodies 2 of different models, so that the waste of resources is reduced.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an energy-saving cable testing bridge mounting structure which characterized in that: the mounting structure comprises a plurality of mounting blocks (3) fixed on a building mounting surface (1), wherein cavities (31) are formed in the mounting blocks (3), two sections of sliding holes (32) are formed in the outer surfaces, deviating from the mounting surface (1), of the mounting blocks (3), the two sections of sliding holes (32) are located on the same straight line and are communicated with the cavities (31), and oppositely arranged clamping plates (4) are connected in the two sections of sliding holes (32) in a sliding mode; the bridge frame body (2) is placed on the outer surface, away from the mounting surface (1), of the mounting block (3) and clamped between the two clamping plates (4), and a driving assembly (5) for driving the two clamping plates (4) to approach or separate from each other simultaneously is arranged in the cavity (31); the outer surface of the mounting block (3) departing from the mounting surface (1) is provided with a plurality of mounting bolts (6), and the mounting bolts (6) penetrate through the bridge body (2) and are in threaded connection with the mounting block (3).

2. The energy-saving cable tray mounting structure of claim 1, wherein: the driving assembly (5) comprises a bidirectional screw rod (51) and a hand wheel (52), the bidirectional screw rod (51) is rotatably connected in the cavity (31), the rotating axis of the bidirectional screw rod (51) is parallel to the moving direction of the clamping plate (4), and one end of the bidirectional screw rod (51) extends out of the mounting block (3) and is fixed with the hand wheel (52); the two-way screw (51) is arranged opposite to the two sliding holes (32), the circumferential side wall of the two-way screw (51) is divided into two sections of threads with opposite rotating directions by the middle part, and one ends of the two clamping plates (4) extend into the cavity (31) and are respectively in threaded connection with different threads of the two-way screw (51).

3. The energy-saving cable tray mounting structure of claim 2, wherein: one end of the mounting bolt (6) in threaded connection with the mounting block (3) extends into the cavity (31) and is tightly propped against the circumferential side wall of the bidirectional screw (51).

4. The energy-saving cable tray mounting structure of claim 3, wherein: the mounting bolt (6) is positioned between the two sliding holes (32), and the thread section of the bidirectional screw (51) is just opposite to the sliding holes (32).

5. The energy-saving cable tray mounting structure of claim 3, wherein: and an elastic block (61) is fixed at one end of the mounting bolt (6) which is in contact with the bidirectional screw (51).

6. The energy-saving cable tray mounting structure of claim 3, wherein: the inner wall of cavity (31) far away from crane span structure body (2) has set firmly support column (7), the circumference lateral wall butt of one end and two-way screw rod (51) of support column (7), and support column (7) butt is just right with construction bolt (6) in the position of two-way screw rod (51).

7. The energy-saving cable tray mounting structure of claim 6, wherein: the contact surface of the support column (7) and the bidirectional screw (51) is arc-shaped.

8. The energy-saving cable tray mounting structure of claim 1, wherein: two the long banding side opening (41) have been seted up to splint (4) relative lateral wall, have seted up a plurality of louvres (21) on the relative lateral wall of crane span structure body (2), louvre (21) and side opening (41) intercommunication.

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