CN217561797U - Optical cable pipeline fixing mechanism - Google Patents

Abstract

The utility model discloses an optical cable pipeline fixing mechanism, which comprises a fixing frame; the damping device comprises a fixing plate, a fixing damping block and a plurality of fixing bolts, wherein the fixing bolts are inserted into the fixing plate, the fixing damping block is arranged on the fixing plate, and a damping structure is arranged on the inner side of the fixing damping block; the shock-absorbing structure includes: the device comprises a plurality of telescopic sleeved springs, a plurality of limiting shafts, two pairs of convex limiting blocks, a circular ring sleeve block, two pairs of telescopic consumption convex sliding blocks, two pairs of telescopic consumption concave sliding ways, four pairs of consumption spring columns and a circular arc rubber pad; the utility model relates to an optical cable pipeline technical field, through the cooperation of negative pressure structure and bolt to reach and carry out quick fixed with the fixed plate, later appear the phenomenon of rocking through shock-absorbing structure with the optical cable operation in-process, through consumption and directional spacing on the horizontal direction and the vertical direction, thereby avoided the phenomenon appearance that the operation in-process appears wearing and tearing.

Description

Optical cable pipeline fixing mechanism

Technical Field

The utility model relates to an optical cable pipeline's technical field specifically is an optical cable pipeline fixing mechanism.

Background

Fiber optic cables are manufactured to meet optical, mechanical, or environmental performance specifications and utilize one or more optical fibers disposed in a covering jacket as the transmission medium and may be used individually or in groups as telecommunication cable assemblies. The optical cable is mainly composed of optical fibers (thin glass filaments like hair), a plastic protective sleeve and a plastic sheath, and metals such as gold, silver, copper and aluminum are not contained in the optical cable, so that the optical cable generally has no recycling value. The optical cable is a communication line which is formed by a certain number of optical fibers into a cable core in a certain mode, is externally coated with a sheath, and is also coated with an outer protective layer for realizing optical signal transmission. Namely: a cable formed by subjecting an optical fiber (optical transmission carrier) to a certain process. The basic structure of an optical cable generally comprises a cable core, a reinforcing steel wire, filler, a sheath and the like, and further comprises a waterproof layer, a buffer layer, an insulated metal wire and other components according to requirements. In the actual cable installation process, cable ducts need to be laid in advance.

In the prior art, when an optical cable pipeline is laid, the joint of the optical cable pipeline deforms, and if the optical cable pipeline is not located and corrected in time, transmission signals of an optical cable are affected, however, the deformation position is difficult to detect actually, and therefore, the scheme is developed by carrying out deep research on the problems.

SUMMERY OF THE UTILITY MODEL

To solve the above problems, i.e. the problems of the prior art, the present invention provides an optical cable conduit fixing mechanism, which includes; the shock absorption device comprises a fixing plate, a fixed shock absorption block and a plurality of fixing bolts, wherein the fixing bolts are inserted into the fixing plate, the fixed shock absorption block is arranged on the fixing plate, and a shock absorption structure is arranged on the inner side of the fixed shock absorption block;

the shock-absorbing structure includes: the device comprises a plurality of telescopic sleeved springs, a plurality of limiting shafts, two pairs of convex limiting blocks, a circular ring sleeve block, two pairs of telescopic consumption convex sliding blocks, two pairs of telescopic consumption concave sliding ways, four pairs of consumption spring columns and a circular arc rubber pad;

the fixed shock absorption block is provided with two pairs of convex telescopic grooves and a plurality of limiting shafts which are respectively inserted in the two pairs of the inner sides of the convex telescopic grooves, the two pairs of the convex stoppers are respectively sleeved on the plurality of limiting shafts, the plurality of telescopic sleeved springs are respectively sleeved on the plurality of limiting shafts, the telescopic sleeved springs are respectively connected with the two pairs of the convex stoppers and the two pairs of the inner sides of the convex telescopic grooves, the two pairs of the telescopic consumption concave slideways are respectively installed on the side wall of the ring sleeve block, the two pairs of the telescopic consumption convex blocks are respectively installed on the two pairs of the convex stoppers, the two pairs of the telescopic consumption convex sliders are respectively movably inserted in the two pairs of the inner sides of the telescopic consumption concave slideways, the four pairs of the consumption spring columns are respectively installed on the inner sides of the two pairs of the telescopic consumption concave slideways, and the circular arc rubber pads are installed on the ring sleeve block.

The utility model discloses a further set up to: and an extrusion rubber pad is arranged on the fixing plate.

The utility model discloses a further set up to: a negative pressure structure is arranged on the fixing plate;

the negative pressure structure includes: two pairs of negative pressure concave blocks, two pairs of negative pressure plates, two pairs of T-shaped push-pull rods, two pairs of locking sleeved springs and four pairs of rotating rods;

the two pairs of negative pressure concave blocks are uniformly inserted on the fixed plate, the two pairs of T-shaped push-pull rods are movably inserted on the inner sides of the two pairs of negative pressure concave blocks, the two pairs of negative pressure plates are respectively installed on the two pairs of T-shaped push-pull rods, a pair of lifting L-shaped grooves are respectively formed in the two pairs of negative pressure concave blocks, four pairs of rotary rods are respectively installed on the two pairs of T-shaped push-pull rods, the four pairs of rotary rods are respectively movably inserted on the inner sides of the four pairs of lifting L-shaped grooves, two pairs of locking sleeving springs are respectively sleeved on the two pairs of T-shaped push-pull rods, and two pairs of locking sleeving springs are respectively connected to the two pairs of negative pressure concave blocks and the two pairs of negative pressure plates.

The utility model discloses a further set up to: and a right-angle anti-collision rubber pad is arranged on the outer side of the fixed damping block.

The utility model discloses a further set up to: and protective pads are respectively arranged on the two pairs of the telescopic consumption concave type slide ways.

The utility model discloses a further set up to: the ring sleeve block is provided with a plurality of cooling holes.

The utility model has the advantages of: through the cooperation of negative pressure structure and bolt to reach and carry out quick fixed with the fixed plate, later through shock-absorbing structure with the phenomenon that the optical cable operation in-process appears rocking, through consumption and directional spacing in the horizontal direction and the vertical direction, thereby avoided the phenomenon that the operation in-process appears wearing and tearing to appear.

Drawings

FIG. 1 shows a schematic front cross-sectional view of a cable duct securing mechanism.

Fig. 2 is an enlarged view of a portion "a" in fig. 1.

Reference numeral 1, a fixing plate; 2. fixing a damping block; 3. fixing the bolt; 4. a spring is sleeved in a telescopic way; 5. a limiting shaft; 6. a convex limiting block; 7. a circular ring sleeve block; 8. a telescopic consumption convex slide block; 9. a telescopic consumption concave slideway; 10. consuming the spring columns; 11. negative pressure concave block; 12. a negative pressure plate; 13. a T-shaped push-pull rod; 14. the spring is sleeved and locked; 15. the rod is rotated.

Detailed Description

Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and are not intended to limit the scope of the present invention.

Example 1

As shown in fig. 1-2, a plurality of fixing bolts 3 are inserted into the fixing plate 1, the fixing damper block 2 is mounted on the fixing plate 1, and a damping structure is mounted on the inner side of the fixing damper block 2;

specifically, the shock-absorbing structure includes: the device comprises a plurality of telescopic sleeved springs 4, a plurality of limiting shafts 5, two pairs of convex limiting blocks 6, a ring sleeve block 7, two pairs of telescopic consumption convex sliding blocks 8, two pairs of telescopic consumption concave sliding ways 9, four pairs of consumption spring columns 10 and a circular arc rubber pad;

specifically, two pairs of convex telescopic grooves and a plurality of convex telescopic grooves are formed in the fixed damping block 2, the limit shaft 5 is respectively inserted into the two pairs of convex telescopic grooves, the two pairs of convex stoppers 6 are respectively sleeved on the plurality of limit shaft 5, the plurality of telescopic sleeved springs 4 are respectively connected to the two pairs of convex stoppers 6 and the two pairs of convex telescopic grooves, the two pairs of telescopic consumption concave slideways 9 are respectively installed on the side wall of the ring sleeve block 7, the two pairs of telescopic consumption convex blocks are respectively installed on the two pairs of convex stoppers 6, the two pairs of telescopic consumption convex blocks 8 are respectively movably inserted into the two pairs of telescopic consumption concave slideways 9, the four pairs of consumption spring columns 10 are respectively installed on the two pairs of telescopic consumption concave slideways 9, and the circular arc rubber pads are installed on the ring sleeve block 7.

It is required to explain, in the foregoing, through inserting the optical cable inboard of ring cover 7, will rock the transmission for ring cover 7 when the optical cable on, transmit kinetic energy for two pairs of flexible protruding type slides that consume through ring cover 7, transmit kinetic energy for a plurality of flexible protruding type slider 8 that consumes through flexible protruding type slide that consumes, make ring cover 7 along the inboard removal of the relative flexible protruding type slide that consumes, the protruding type slider 8 that consumes is flexible to the other end simultaneously drives protruding type stopper 6 above that respectively, make a protruding type stopper 6 tensile, another protruding type stopper 6 extrusion, thereby reach and stretch out and draw back along a plurality of spacing axle 5 respectively with a pair of protruding type stopper 6, stretch out and draw back a plurality of flexible suit spring 4 simultaneously, thereby reach the kinetic energy on horizontal direction and vertical direction separately to convert, the phenomenon appearance that the equipment of the opposite side appears the loss has been avoided appearing in the displacement process appears and has appeared.

Preferably, the fixing plate 1 is provided with a pressing rubber pad.

Example 2

As shown in fig. 1-2, a negative pressure structure is arranged on the fixing plate 1;

specifically, the negative pressure structure includes: two pairs of negative pressure concave blocks 11, two pairs of negative pressure plates 12, two pairs of T-shaped push-pull rods 13, two pairs of locking sleeved springs 14 and four pairs of rotating rods 15;

specifically, two pairs of the negative pressure concave blocks 11 are uniformly inserted into the fixed plate 1, two pairs of the T-shaped push-pull rods 13 are movably inserted into the inner sides of the two pairs of the negative pressure concave blocks 11, two pairs of the negative pressure plates 12 are respectively installed on the two pairs of the T-shaped push-pull rods, a pair of the lifting L-shaped grooves are respectively formed in the two pairs of the negative pressure concave blocks 11, four pairs of the rotating rods 15 are respectively installed on the two pairs of the T-shaped push-pull rods 13, four pairs of the rotating rods 15 are respectively movably inserted into the inner sides of the four pairs of the lifting L-shaped grooves, two pairs of the locking sleeving springs 14 are respectively sleeved on the two pairs of the T-shaped push-pull rods 13, and two pairs of the locking sleeving springs 14 are respectively connected to the two pairs of the negative pressure concave blocks 11 and the two pairs of the negative pressure plates 12.

It should be noted that, in the above description, by stretching the two pairs of T-shaped push-pull rods 13, the two pairs of T-shaped push-pull rods 13 respectively drive the negative pressure plates 12 thereon, so as to change the air pressure inside the two pairs of negative pressure concave blocks 11 for adjustment, and by rotating the four pairs of rotating rods 15 on the two pairs of T-shaped push-pull rods 13, the effect of limiting is achieved.

Preferably, a right-angle crash cushion is arranged on the outer side of the fixed shock absorption block 2.

Preferably, two pairs of the telescopic consumption concave slideways 9 are respectively provided with a protective pad.

Preferably, the circular sleeve block 7 is provided with a plurality of cooling holes.

While the invention has been described with reference to a preferred embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention, and particularly, various features shown in the various embodiments may be combined in any combination as long as there is no structural conflict. The present invention is not limited to the particular embodiments disclosed herein, but encompasses all technical solutions falling within the scope of the claims.

In the description of the present invention, the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like, which indicate directions or positional relationships, are based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, article, or apparatus.

So far, the technical solution of the present invention has been described with reference to the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Without departing from the principle of the present invention, a person skilled in the art can make equivalent changes or substitutions to the related technical features, and the technical solutions after these changes or substitutions will fall within the protection scope of the present invention.

Claims (6)

1. A cable duct securing mechanism, comprising: the damping device comprises a fixing plate, a fixed damping block and a plurality of fixing bolts, and is characterized in that the fixing bolts are inserted into the fixing plate, the fixed damping block is arranged on the fixing plate, and a damping structure is arranged on the inner side of the fixed damping block;

the shock-absorbing structure includes: the device comprises a plurality of telescopic sleeved springs, a plurality of limiting shafts, two pairs of convex limiting blocks, a circular ring sleeve block, two pairs of telescopic consumption convex sliding blocks, two pairs of telescopic consumption concave sliding ways, four pairs of consumption spring columns and a circular arc rubber pad;

the fixed shock absorption block is provided with two pairs of convex telescopic grooves and a plurality of limiting shafts which are respectively inserted in the two pairs of the inner sides of the convex telescopic grooves, the two pairs of the convex stoppers are respectively sleeved on the plurality of limiting shafts, the plurality of telescopic sleeved springs are respectively sleeved on the plurality of limiting shafts, the telescopic sleeved springs are respectively connected with the two pairs of the convex stoppers and the two pairs of the inner sides of the convex telescopic grooves, the two pairs of the telescopic consumption concave slideways are respectively installed on the side wall of the ring sleeve block, the two pairs of the telescopic consumption convex blocks are respectively installed on the two pairs of the convex stoppers, the two pairs of the telescopic consumption convex sliders are respectively movably inserted in the two pairs of the inner sides of the telescopic consumption concave slideways, the four pairs of the consumption spring columns are respectively installed on the inner sides of the two pairs of the telescopic consumption concave slideways, and the circular arc rubber pads are installed on the ring sleeve block.

2. An optical cable duct fixing mechanism as claimed in claim 1, wherein the fixing plate is provided with an extruded rubber mat.

3. An optical cable conduit fixing mechanism as claimed in claim 1, wherein a negative pressure structure is provided on the fixing plate;

the negative pressure structure includes: two pairs of negative pressure concave blocks, two pairs of negative pressure plates, two pairs of T-shaped push-pull rods, two pairs of locking sleeved springs and four pairs of rotating rods;

the two pairs of negative pressure concave blocks are uniformly inserted on the fixed plate, the two pairs of T-shaped push-pull rods are movably inserted on the inner sides of the two pairs of negative pressure concave blocks, the two pairs of negative pressure plates are respectively installed on the two pairs of T-shaped push-pull rods, a pair of lifting L-shaped grooves are respectively formed in the two pairs of negative pressure concave blocks, four pairs of rotary rods are respectively installed on the two pairs of T-shaped push-pull rods, the four pairs of rotary rods are respectively movably inserted on the inner sides of the four pairs of lifting L-shaped grooves, two pairs of locking sleeving springs are respectively sleeved on the two pairs of T-shaped push-pull rods, and two pairs of locking sleeving springs are respectively connected to the two pairs of negative pressure concave blocks and the two pairs of negative pressure plates.

4. An optical cable pipeline fixing mechanism as claimed in claim 1, wherein a right-angle crash pad is disposed on an outer side of the fixed shock-absorbing block.

5. An optical cable duct securing mechanism as claimed in claim 1, wherein two pairs of said female telescopic consumable slides each have a protective pad disposed thereon.

6. The optical cable duct fixing mechanism of claim 1, wherein the ring block defines a plurality of cooling holes.

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