CN218762105U - Shared anti-seismic pipe clamp - Google Patents

Abstract

The utility model relates to an antidetonation pipe clamp technical field's an antidetonation pipe clamp of sharing form, including last clamp splice and lower clamp splice, it is the same with lower clamp splice structure to go up the clamp splice, it has seted up the spout to go up clamp splice upper end corner, spout internal surface sliding connection has the slide bar, be provided with respectively between slide bar lower extreme inner chamber and the spout inner chamber bottom indulge damping spring and indulge the shock absorber, 4 slide bar upper end fixedly connected with connecting plates, the I-shaped slide has been seted up to connecting plate upper end both sides, I-shaped slide internal surface middle part sliding connection has the I-shaped slider, be provided with horizontal damping spring and horizontal shock absorber between I-shaped slider surface and the I-shaped slide internal surface one side respectively. The pipeline antidetonation effect improves greatly, even the pipeline atress is rocked and is leaded to the mount pad to rock easily, also can not lead to construction bolt and wall body not hard up, prevents that the pipeline from damaging, and simultaneously, this pipe clamp antidetonation direction is many, and the antidetonation is effectual.

Description

Shared anti-seismic pipe clamp

Technical Field

The utility model relates to an antidetonation pipe clamp technical field especially relates to an antidetonation pipe clamp of sharing form.

Background

Like the grant publication number for CN202122348124.7 an interlock formula components of a whole that can function independently antidetonation pipe clamp moves about freely and quickly, including last clamping piece and lower clamping piece, the cushion chamber has all been seted up to the inside of going up clamping piece and lower clamping piece, the inside of cushion chamber is evenly fixed and is provided with a plurality of buffering abrasionproof subassembly, this interlock formula components of a whole that can function independently antidetonation pipe clamp moves about freely and quickly, through the mutual cooperation of cushion chamber, first spring, connecting rod and buffering abrasionproof piece mechanism, can realize pressing from both sides tightly the pipeline of different diameters, application range increases, and the flexibility is stronger, utilize the second spring, consolidate lantern ring subassembly and joint end, the tight effect of clamp of pipeline has been strengthened, through the mutual cooperation of first spring, soft resin pad, abrasionproof damage pad and buffering convex pad, nevertheless the antidetonation pipe clamp of a sharing form that appears on the market still has various not enough, can not satisfy the demand of production.

The pipe clamp that has now is at the in-service use in-process, and the pipeline antidetonation effect is imperfect, and the pipeline atress is rocked and is leaded to the mount pad to rock easily to lead to construction bolt and wall body not hard up, lead to the pipeline to damage, simultaneously, current pipe clamp antidetonation direction is single, the not good problem of antidetonation effect, for this we propose the antidetonation pipe clamp of a sharing form.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides a sharing form's antidetonation pipe clamp to provide in solving above-mentioned background art, the pipe clamp antidetonation direction is single, the not good problem of antidetonation effect.

The technical scheme of the utility model is that:

a shared anti-seismic pipe clamp comprises an upper clamping block and a lower clamping block, wherein the upper clamping block and the lower clamping block are the same in structure, a sliding groove is formed in a corner of the upper end of the upper clamping block, a sliding rod is connected to the inner surface of the sliding groove in a sliding mode, a longitudinal damping spring and a longitudinal shock absorber are arranged between the inner cavity of the lower end of the sliding rod and the bottom of the inner cavity of the sliding groove respectively, 4 connecting plates are fixedly connected to the upper ends of the sliding rods, I-shaped sliding ways are formed in two sides of the upper end of each connecting plate, I-shaped sliding blocks are connected to the middle portions of the inner surfaces of the I-shaped sliding ways in a sliding mode, and transverse damping springs and transverse shock absorbers are arranged between the surfaces of the I-shaped sliding blocks and one side of the inner surfaces of the I-shaped sliding ways respectively.

The working principle of the technical scheme is as follows:

the longitudinal shock absorber and the longitudinal shock absorber realize two processes of compression and extension, the longitudinal shock absorber absorbs and stores vibration energy in a compression stroke and then releases the vibration energy in an extension stroke, the vibration energy is consumed in the process no matter in the compression stroke or the extension stroke of the longitudinal shock absorber, the shock absorbing effect is realized in the process, the arranged transverse shock absorber and the transverse shock absorber have the same working principle as the working principle, and the shock absorbing effect of the equipment is improved.

In a further technical scheme, the transverse damping spring is fixedly connected with one end of the transverse damper and one side of the inner surface of the I-shaped slide way, the transverse damping spring is fixedly connected with the other end of the transverse damper and one side of the surface of the I-shaped slide block, and the transverse damper is located in the middle of the transverse damping spring.

The transverse damping spring and the transverse damper realize two processes of compression and extension, the longitudinal damping spring absorbs and stores vibration energy in a compression stroke and then releases the vibration energy in an extension stroke, and the longitudinal damper consumes the vibration energy no matter in the compression stroke or the extension stroke, so that the vibration damping effect is realized in the process.

In a further technical scheme, one end of the longitudinal damping spring and one end of the longitudinal damper are fixedly connected with the bottom of the inner cavity of the sliding chute, the other end of the longitudinal damping spring and the other end of the longitudinal damper are fixedly connected with the lower end of the sliding rod, and the longitudinal damper is positioned in the middle of the longitudinal damping spring.

The longitudinal damping spring absorbs and stores vibration energy in a compression stroke and then releases the vibration energy in an extension stroke, and the longitudinal damper consumes the vibration energy no matter in the compression stroke or the extension stroke, so that the damping effect is realized, and no matter in the compression stroke or the extension stroke of the longitudinal damper, oil in the cavity of the longitudinal damper repeatedly passes through the small flow-stopping hole in the valve system and flows into the other cavity from one cavity; at the moment, the friction between the hole wall and the oil and the internal friction between oil molecules can generate damping force to the vibration, so that the vibration resistance effect is realized.

In a further technical scheme, an upper fixing frame is fixedly connected to the upper end of an I-shaped sliding block arranged on the upper clamping block, a lower fixing frame is fixedly connected to the upper end of an I-shaped sliding block arranged on the lower clamping block, and two sides of the lower fixing frame are connected with two sides of the upper fixing frame through bolts.

The upper fixing frame and the lower fixing frame are connected through bolts, and the pipeline can be fixed.

In a further technical scheme, arc-shaped grooves are formed in two sides of the lower end of the upper clamping block and two sides of the lower end of the lower clamping block, rubber rings are embedded in two sides of the inner surface of each arc-shaped groove, and a pipeline is arranged between the two arc-shaped grooves.

The rubber circle that sets up can make pipeline and last clamp splice and lower clamp splice fixed more firm, simultaneously, plays the effect of buffering damping, and pipeline antidetonation effect improves greatly.

The beneficial effects of the utility model are that:

1. the longitudinal shock absorber and the longitudinal shock absorbing spring can absorb longitudinal impact force, so that longitudinal shock absorption is realized, and the shock resistance of the equipment is improved;

2. energy absorption to transverse impact force can be achieved through the transverse damping spring and the transverse damper, so that transverse damping is achieved, and the equipment can have multidirectional anti-vibration capability due to the arrangement.

Drawings

Fig. 1 is a schematic three-dimensional structure of the present invention;

FIG. 2 is a schematic structural view of the position of the lateral damping spring and the lateral damper of the present invention;

FIG. 3 is a schematic structural view of the longitudinal damper and the longitudinal damping spring of the present invention;

fig. 4 is a schematic structural diagram of the side view of the present invention.

Description of reference numerals:

1. an upper clamping block; 2. a lower clamping block; 3. an arc-shaped slot; 4. a rubber ring; 5. an upper fixing frame; 6. a connecting plate; 7. a lower fixed frame; 8. a pipeline; 9. an I-shaped slide block; 10. a slide bar; 11. an i-shaped chute; 12. a lateral damping spring; 13. a longitudinal damper; 14. a chute; 15. a longitudinal damping spring; 16. a transverse vibration absorber.

Detailed Description

The embodiments of the present invention will be further explained with reference to the drawings.

Example 1:

as shown in fig. 1-4, the utility model provides a sharing type antidetonation pipe clamp, including last clamp splice 1 and lower clamp splice 2, it is the same with lower clamp splice 2 structure to go up clamp splice 1, go up clamp splice 1 upper end corner and seted up spout 14, spout 14 internal surface sliding connection has slide bar 10, be provided with respectively between slide bar 10 lower extreme inner chamber and the 14 inner chamber bottoms of spout and indulge damping spring 15 and indulge shock absorber 13,4 slide bar 10 upper end fixedly connected with connecting plate 6, I-shaped slide 11 has been seted up to connecting plate 6 upper end both sides, I-shaped slide 11 internal surface middle part sliding connection has I-shaped slider 9, be provided with respectively horizontal damping spring 12 and horizontal shock absorber 16 between I-shaped slider 9 surface and I-shaped slide 11 internal surface one side.

Specifically, a transverse damping spring 12 is fixedly connected with one end of a transverse damper 16 and one side of the inner surface of an I-shaped slide rail 11, the transverse damping spring 12 is fixedly connected with the other end of the transverse damper 16 and one side of the surface of an I-shaped slide block 9, the transverse damper 16 is positioned in the middle of the transverse damping spring 12, one ends of a longitudinal damping spring 15 and a longitudinal damper 13 are fixedly connected with the bottom of an inner cavity of a slide groove 14, the other ends of the longitudinal damping spring 15 and the longitudinal damper 13 are fixedly connected with the lower end of a slide rod 10, the longitudinal damper 13 is positioned in the middle of the longitudinal damping spring 15, the upper end of the I-shaped slide block 9 arranged on an upper clamping block 1 is fixedly connected with an upper fixed frame 5, the upper end of the I-shaped slide block 9 arranged on a lower clamping block 2 is fixedly connected with a lower fixed frame 7, two sides of the lower fixed frame 7 are connected with two sides of the upper fixed frame 5 through bolts, arc-shaped grooves 3 are respectively formed in two sides of the lower end of the upper clamping block 1 and two sides of the lower end of the lower clamping block 2, rubber rings 4 are embedded in two sides of the inner surface of the arc-shaped grooves 3, and a pipeline 8 is arranged between the two arc-shaped grooves 3.

The working principle and the beneficial effects of the embodiment are achieved.

When the pipeline 8 shakes, longitudinal and transverse impact force can be generated, the longitudinal impact force is transmitted to the upper clamping block 1 and the lower clamping block 2 through the pipeline 8, so that the sliding grooves 14 of the upper clamping block 1 and the lower clamping block 2 move on the surface of the sliding rod 10, at the moment, the longitudinal shock absorber 13 and the longitudinal shock absorber 15 can realize two processes of compression and extension, the longitudinal shock absorber 15 absorbs and stores vibration energy in a compression stroke and then releases the vibration energy in an extension stroke, the vibration energy is consumed in the longitudinal shock absorber 13 in both the compression stroke and the extension stroke, the vibration absorbing effect can be realized in the process, and oil in the cavity of the longitudinal shock absorber 13 repeatedly passes through a small flow-stopping hole in the valve system and flows into the other cavity from one cavity through the small flow-stopping hole in the valve system in the compression stroke and the extension stroke of the longitudinal shock absorber 13; at the moment, the friction between the hole wall and oil and the internal friction between oil molecules can generate damping force on vibration; when the pipe clamp is subjected to transverse impact force, the arranged transverse damping springs 12 and the transverse dampers 16 are the same as the working principle, finally, the energy transmitted by the pipeline 8 or the upper fixing frame 5 and the lower fixing frame 7 is converted into oil heat energy and then transmitted to the cylinder barrel and dissipated, so that the purposes of energy consumption, vibration reduction and vibration resistance are achieved, the pipeline 8 can be more firmly fixed with the upper clamping block 1 and the lower clamping block 2 through the arranged rubber rings 4, meanwhile, the buffer vibration reduction effect is achieved, the anti-seismic effect of the pipeline 8 is greatly improved, even if the pipeline 8 is stressed and shaken, the installation seat is easily shaken, the installation bolt and the wall body cannot be loosened, the pipeline 8 is prevented from being damaged, meanwhile, the pipe clamp has multiple anti-seismic directions and a good anti-seismic effect, the upper fixing frame 5 and the lower fixing frame 7 are connected through bolts, and the pipeline 8 can be fixed.

The above embodiments only express the specific embodiments of the present invention, and the description thereof is specific and detailed, but not to be understood as the limitation of the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (5)

1. The utility model provides a antidetonation pipe clamp of sharing form, includes clamp splice and lower clamp splice, its characterized in that: the structure of the upper clamping block is the same as that of the lower clamping block, a sliding groove is formed in the corner of the upper end of the upper clamping block, a sliding rod is connected to the inner surface of the sliding groove in a sliding mode, a longitudinal damping spring and a longitudinal damper are arranged between the inner cavity of the lower end of the sliding rod and the bottom of the inner cavity of the sliding groove respectively, 4 connecting plates are fixedly connected to the upper ends of the sliding rods, I-shaped slideways are formed in two sides of the upper end of each connecting plate, I-shaped sliding blocks are connected to the middle of the inner surfaces of the I-shaped slideways in a sliding mode, and transverse damping springs and transverse dampers are arranged between the surfaces of the I-shaped sliding blocks and one side of the inner surfaces of the I-shaped slideways respectively.

2. A common form of seismic pipe clamp as in claim 1, wherein: the transverse damping spring is fixedly connected with one end of the transverse damper and one side of the inner surface of the I-shaped slide way, the transverse damping spring is fixedly connected with the other end of the transverse damper and one side of the surface of the I-shaped slide block, and the transverse damper is positioned in the middle of the transverse damping spring.

3. A common form of seismic pipe clamp as in claim 1, wherein: the longitudinal damping spring and one end of the longitudinal damper are fixedly connected with the bottom of the inner cavity of the sliding chute, the longitudinal damping spring and the other end of the longitudinal damper are fixedly connected with the lower end of the sliding rod, and the longitudinal damper is positioned in the middle of the longitudinal damping spring.

4. A common form of seismic pipe clamp as in claim 1, wherein: the upper end of the I-shaped sliding block arranged on the upper clamping block is fixedly connected with an upper fixing frame, the upper end of the I-shaped sliding block arranged on the lower clamping block is fixedly connected with a lower fixing frame, and two sides of the lower fixing frame are connected with two sides of the upper fixing frame through bolts.

5. A common form of seismic pipe clamp as in claim 1, wherein: arc-shaped grooves are formed in two sides of the lower end of the upper clamping block and two sides of the lower end of the lower clamping block, rubber rings are embedded in two sides of the inner surface of each arc-shaped groove, and a pipeline is arranged between the two arc-shaped grooves.

Images