CN219889019U - Hydraulic engineering construction pipeline installation shock mount - Google Patents

Abstract

The utility model discloses a hydraulic engineering construction pipeline installation shock mount, which comprises a support bottom plate and two pipe bodies, wherein a shock mount and two bottom plates are fixedly arranged on the support bottom plate, a plurality of conducting pipes are fixedly arranged in the shock mount through a partition plate, inert damping gas is fully filled in the lower part of the partition plate, lifting rods are slidably arranged in each conducting pipe through damping plates, lower shock absorbing plates are fixedly arranged on the lifting rods together, upper shock absorbing plates are arranged on the lower shock absorbing plates through positioning mechanisms, and supporting plates are arranged on the two bottom plates through damping mechanisms. The advantages are that: the hydraulic pipeline vibration damping device is integrally arranged at the joint of two hydraulic pipelines, and vibration suffered by the hydraulic pipelines can be effectively attenuated and counteracted in a friction, conversion, attenuation and absorption mode, so that the hydraulic pipeline vibration damping device has a good damping effect and a good protection effect.

Description

Hydraulic engineering construction pipeline installation shock mount

Technical Field

The utility model relates to the technical field of damping of construction pipelines, in particular to a damping seat for installing a hydraulic engineering construction pipeline.

Background

The hydraulic engineering is used for controlling and allocating surface water and underground water in the nature, so as to achieve the purposes of controlling water flow and preventing flood disasters, and a construction pipeline in the hydraulic engineering is easily damaged by external collision or impact during actual use, and the service life of the pipeline is influenced, so that a damping seat is usually arranged on the hydraulic construction pipeline to protect the hydraulic construction pipeline;

the existing shock mount can only carry out single-tube protection on water conservancy pipelines generally, the shock absorption protection can not be carried out on the joint between two water conservancy construction pipelines, and the joint between two water conservancy construction pipelines is most susceptible to shock damage and has certain limitation, so that the design of the shock mount for the water conservancy engineering construction pipelines is needed to solve the problems.

The information disclosed in this background section is only for enhancement of understanding of the general background of the utility model and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art already known to a person of ordinary skill in the art.

Disclosure of Invention

The utility model aims to solve the problems in the prior art and provides a hydraulic engineering construction pipeline installation shock mount.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides a hydraulic engineering construction pipeline installation shock mount, includes braced bottom plate, two body, fixed mounting has shock attenuation supporting seat, two bottom plates on the braced bottom plate, there are a plurality of conducting pipes through division board fixed mounting in the shock attenuation supporting seat, and the lower part of division board is full to be filled with inert damping gas, every all have the lifter through damping disc slidable mounting in the conducting pipe, a plurality of common fixed mounting has lower shock absorber plate on the lifter, and installs upper shock absorber plate through positioning mechanism on the lower shock absorber plate, two all install the backup pad through damping mechanism on the bottom plate.

In the above-mentioned hydraulic engineering construction pipeline installation shock mount, positioning mechanism includes a plurality of support frames of block installation on lower grade shock attenuation board, and is a plurality of common fixed mounting has the mount on the support frame, threaded rod is installed to the screw thread on the mount, fixed mounting has spacing pivot on the threaded rod, and the upper shock attenuation board rotates to be installed in spacing pivot, fixed mounting has two spacing spring rods between upper shock attenuation board and the mount.

In the hydraulic engineering construction pipeline installation shock mount, the shock pad is fixedly installed on the upper shock absorbing plate and the lower shock absorbing plate, and the end faces of the upper shock absorbing plate and the lower shock absorbing plate are arc-shaped.

In the above-mentioned hydraulic engineering construction pipeline installation shock mount, damping mechanism includes that fixed mounting is at the damping spring pole two of bottom plate lower part, fixed mounting has the lifter plate on the damping spring pole two, and backup pad fixed mounting is on the upper portion of lifter plate, fixed mounting has a plurality of damping spring poles one between lifter plate and the bottom plate, install friction structure between bottom plate and the lifter plate.

In the above-mentioned hydraulic engineering construction pipeline installation shock mount, friction structure includes a plurality of damping balls of fixed mounting on the lifter plate, fixed mounting has the damping rubber slab on the bottom plate, and a plurality of damping balls all rub the laminating mutually with the damping rubber slab.

Compared with the prior art, the utility model has the advantages that:

1: through setting up lower shock-absorbing plate, when installing, can remove the supporting baseplate earlier and drive lower shock-absorbing plate and two backup pads and remove to laminating mutually with two body lower parts to make lower shock-absorbing plate be located the junction seam crossing between two body.

2: through setting up upper shock-absorbing plate, install a plurality of support frames again on the upper shock-absorbing plate, rotate the threaded rod and drive upper shock-absorbing plate move down to contact extrusion with two body, upper shock-absorbing plate and lower shock-absorbing plate cooperate and can carry out stable connection with between the body to make upper shock-absorbing plate and lower shock-absorbing plate form wholly.

3: through setting up the shock attenuation supporting seat, vibrations can be conducted to a plurality of lifter departments through upper shock absorber plate and lower shock absorber plate when producing vibrations, a plurality of lifter receive vibrations and can drive the damping dish and reciprocate the lift removal in the conducting pipe to can extrude repeatedly and release inert damping gas, thereby can become the lifting mechanical energy with vibrations potential energy and inert damping gas and remove and absorptive heat energy, can offset the better attenuation of vibrations.

4: through setting up damping spring pole one, damping spring pole two, the vibrations that the body received can conduction backup pad department to can drive the lifter plate and remove, can synchronous pulling or compression damping spring pole one, damping spring pole two utilize damping spring pole one, damping spring pole two between interact can further offset vibrations.

5: through setting up the damping ball, when the lifter plate lift removes, can drive a plurality of damping balls reciprocating motion friction on damping rubber board, can produce great frictional resistance when removing the friction, can further weaken vibrations and offset, still can offset damping spring rod one, damping spring rod two elasticity counter-force that produces when compressing or stretching.

In summary, the hydraulic pipeline shock absorber is integrally arranged at the joint of two hydraulic pipelines, and vibration suffered by the hydraulic pipelines can be effectively weakened and counteracted in a friction, conversion, weakening and absorption mode, so that the hydraulic pipeline shock absorber has a good shock absorbing effect and a good protection effect.

Drawings

The utility model is described in further detail below with reference to the attached drawing figures, wherein:

fig. 1 is a schematic structural view of a shock mount for hydraulic engineering construction pipelines according to the present utility model;

FIG. 2 is an enlarged view of a node at the location A in FIG. 1;

fig. 3 is an enlarged view of the lifter plate, the base plate, and a portion of the connection therebetween of fig. 1.

In the figure: 1 supporting bottom plate, 2 body, 3 shock attenuation supporting seat, 4 lifter plate, 5 lower damping plate, 6 bottom plate, 7 mount, 8 upper damping plate, 9 spacing spring bar, 10 spacing pivot, 11 threaded rod, 12 conducting pipe, 13 lifter, 14 damping dish, 15 division board, 16 backup pad, 17 damping spring bar one, 18 damping spring bar two, 19 damping ball, 20 damping rubber board.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1-3, a shock mount for hydraulic engineering construction pipeline comprises a supporting base plate 1 and two pipe bodies 2, wherein a shock mount 3 and two base plates 6 are fixedly arranged on the supporting base plate 1, a plurality of conducting pipes 12 are fixedly arranged in the shock mount 3 through partition plates 15, inert damping gas is fully filled in the lower parts of the partition plates 15, lifting rods 13 are slidably arranged in each conducting pipe 12 through damping plates 14, lower shock absorbing plates 5 are fixedly arranged on the lifting rods 13 together, upper shock absorbing plates 8 are arranged on the lower shock absorbing plates 5 through positioning mechanisms, and supporting plates 16 are arranged on the two base plates 6 through damping mechanisms;

the following points are notable;

when in installation, the support bottom plate 1 can be moved to drive the lower shock-absorbing plate 5 and the two support plates 16 to be attached to the lower parts of the two pipe bodies 2, and the lower shock-absorbing plate 5 is positioned at the joint between the two pipe bodies 2.

The positioning mechanism comprises a plurality of supporting frames which are mounted on the lower shock-absorbing plate 5 in a clamping manner, a fixing frame 7 is fixedly mounted on the supporting frames, a threaded rod 11 is mounted on the fixing frame 7 in a threaded manner, a limiting rotating shaft 10 is fixedly mounted on the threaded rod 11, the upper shock-absorbing plate 8 is rotatably mounted on the limiting rotating shaft 10, the supporting frames are mounted on the upper shock-absorbing plate 8, the threaded rod 11 is rotated to drive the upper shock-absorbing plate 8 to move downwards to contact and extrude two pipe bodies 2, the upper shock-absorbing plate 8 is matched with the lower shock-absorbing plate 5 to be stably connected with the pipe bodies 2, and the upper shock-absorbing plate 8 and the lower shock-absorbing plate 5 form a whole, so that integral shock absorption is carried out.

Two limit spring rods 9 are fixedly arranged between the upper shock-absorbing plate 8 and the fixing frame 7, and a limit rotating shaft 10 is matched with the limit spring rods 9 to play a role of limiting the upper shock-absorbing plate 8, so that the upper shock-absorbing plate 8 can only reciprocate up and down and cannot rotate.

The upper shock-absorbing plate 8 and the lower shock-absorbing plate 5 are fixedly provided with shock-absorbing pads, the end faces of the upper shock-absorbing plate 8 and the lower shock-absorbing plate 5 are arc-shaped, so that the shock-absorbing plate is convenient to attach to the pipe body 2, and the shock-absorbing effect is further improved.

When vibration is generated, the vibration is conducted to the lifting rods 13 through the upper vibration-absorbing plate 8 and the lower vibration-absorbing plate 5, the lifting rods 13 can drive the damping disk 14 to lift up and down in the conducting pipe 12 in a reciprocating manner through vibration, so that inert damping gas can be repeatedly extruded and released, vibration potential energy can be converted into lifting mechanical energy and heat energy for moving and absorbing the inert damping gas, and the vibration can be well weakened and counteracted.

The damping mechanism comprises a damping spring rod II 18 fixedly arranged at the lower part of the bottom plate 6, a lifting plate 4 is fixedly arranged on the damping spring rod II 18, a supporting plate 16 is fixedly arranged at the upper part of the lifting plate 4, a plurality of damping spring rods I17 are fixedly arranged between the lifting plate 4 and the bottom plate 6, vibration received by the pipe body 2 can be conducted to the supporting plate 16, thereby driving the lifting plate 4 to move, the damping spring rods I17 and II 18 can be synchronously pulled or compressed, and the vibration can be further counteracted by utilizing interaction between the damping spring rods I17 and II 18.

Install friction structure between bottom plate 6 and lifter plate 4, friction structure includes a plurality of damping balls 19 of fixed mounting on lifter plate 4, fixed mounting has damping rubber plate 20 on the bottom plate 6, and a plurality of damping balls 19 all rub the laminating mutually with damping rubber plate 20, when lifter plate 4 goes up and down to remove, can drive a plurality of damping balls 19 and reciprocate the friction on damping rubber plate 20, can produce great frictional resistance when removing the friction, can further weaken vibrations and offset, still can offset damping spring rod one 17, damping spring rod two 18 elastic counter force that produces when compressing or stretching, avoid producing elasticity and shake.

Further, the above-described fixed connection is to be understood in a broad sense, unless explicitly stated and defined otherwise, as being, for example, welded, glued, or integrally formed, as is well known to those skilled in the art.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, 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, method, article, or apparatus.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (5)

1. The utility model provides a hydraulic engineering construction pipeline installation shock mount, includes supporting baseplate (1), two body (2), its characterized in that, fixed mounting has shock attenuation supporting seat (3), two bottom plates (6) on supporting baseplate (1), there are a plurality of conducting pipes (12) through division board (15) fixed mounting in shock attenuation supporting seat (3), and the lower part of division board (15) is full to be filled with inert damping gas, every all have lifter (13) through damping disc (14) slidable mounting in conducting pipe (12), a plurality of common fixed mounting has lower shock absorber plate (5) on lifter (13), and installs upper shock absorber plate (8) through positioning mechanism on lower shock absorber plate (5), two all install backup pad (16) through damping mechanism on bottom plate (6).

2. The hydraulic engineering construction pipeline installation shock mount according to claim 1, wherein the positioning mechanism comprises a plurality of support frames which are installed on the lower shock absorbing plate (5) in a clamping manner, a plurality of support frames are fixedly provided with a fixing frame (7) together, a threaded rod (11) is installed on the fixing frame (7) in a threaded manner, a limit rotating shaft (10) is fixedly installed on the threaded rod (11), the upper shock absorbing plate (8) is rotatably installed on the limit rotating shaft (10), and two limit spring rods (9) are fixedly installed between the upper shock absorbing plate (8) and the fixing frame (7).

3. The hydraulic engineering construction pipeline installation shock mount according to claim 2, wherein shock pads are fixedly installed on the upper shock absorbing plate (8) and the lower shock absorbing plate (5), and the end faces of the upper shock absorbing plate (8) and the lower shock absorbing plate (5) are arc-shaped.

4. The hydraulic engineering construction pipeline installation shock mount according to claim 1, wherein the damping mechanism comprises a damping spring rod II (18) fixedly installed at the lower part of the bottom plate (6), a lifting plate (4) is fixedly installed on the damping spring rod II (18), a supporting plate (16) is fixedly installed at the upper part of the lifting plate (4), a plurality of damping spring rods I (17) are fixedly installed between the lifting plate (4) and the bottom plate (6), and a friction structure is installed between the bottom plate (6) and the lifting plate (4).

5. The hydraulic engineering construction pipeline installation shock mount according to claim 4, wherein the friction structure comprises a plurality of damping balls (19) fixedly installed on the lifting plate (4), a damping rubber plate (20) is fixedly installed on the bottom plate (6), and the damping balls (19) are in friction fit with the damping rubber plate (20).