CN211231851U - Pipeline strutting arrangement for hydraulic engineering - Google Patents

Abstract

The utility model relates to the technical field of hydraulic engineering pipelines, in particular to a pipeline supporting device for hydraulic engineering, which comprises a base, a telescopic mechanism and a pushing mechanism, wherein the telescopic mechanism is arranged at the middle position of the top of the base and is connected with the base through screws, the pushing mechanism is arranged at the middle position of the top of the telescopic mechanism and is connected with the telescopic mechanism through screws, the top of the pushing mechanism is provided with a pipeline which is nested with the pushing mechanism, the support frame prevents the water conservancy pipeline from directly contacting the ground, corrosive substances on the ground cannot corrode the water conservancy pipeline, the service life of the water conservancy pipeline is greatly prolonged, the height of the support frame can be adjusted, the ground is usually provided with a plurality of small slopes, can adjust the support frame and make water conservancy pipeline at same height, can support the water conservancy pipeline of different diameters through adjusting the support frame, improve the installation effectiveness greatly.

Description

Pipeline strutting arrangement for hydraulic engineering

Technical Field

The utility model relates to a hydraulic engineering pipeline technical field specifically says a pipeline strutting arrangement for hydraulic engineering.

Background

The pipeline is a device which is connected by pipes, pipe connectors, valves and the like and used for conveying gas, liquid or fluid with solid particles, generally, the fluid flows from a high-pressure part to a low-pressure part of the pipeline after being pressurized by a blower, a compressor, a pump, a boiler and the like, and can also be conveyed by utilizing the pressure or gravity of the fluid, the pipeline has wide application range, is mainly used in water supply, drainage, heat supply, gas supply, long-distance petroleum and natural gas conveying, agricultural irrigation, hydraulic engineering and various industrial devices, the pipeline is generally used for conveying water in the hydraulic engineering, and the pipeline is easy to corrode when being in direct contact with the ground.

However, in hydraulic engineering, the hydraulic pipelines are directly installed on the ground or installed underground, and the ground corrosive substances can corrode the pipelines, so that the service life of the pipelines is greatly shortened.

SUMMERY OF THE UTILITY MODEL

Therefore, in order to solve the above-mentioned not enough, the utility model provides a pipeline strutting arrangement for hydraulic engineering herein makes water conservancy pipeline not with ground direct contact through the support frame, and the corrosive substance on ground can not corrode water conservancy pipeline, has improved water conservancy pipeline's life greatly, and the support frame can height-adjusting, and ground has a lot of hillocks usually, can adjust the support frame and make water conservancy pipeline at same height, can support the water conservancy pipeline of different diameters through adjusting the support frame, has improved the installation effectiveness greatly.

The utility model discloses a realize like this, construct a pipeline strutting arrangement for hydraulic engineering, including base, telescopic machanism and pushing mechanism, telescopic machanism sets up in the top intermediate position of base and passes through screwed connection with the base, and pushing mechanism sets up in telescopic machanism's top intermediate position and passes through screwed connection with telescopic machanism, and the pushing mechanism top is equipped with the pipeline, pipeline and pushing mechanism nested connection.

Furthermore, the telescopic mechanism comprises a Z-shaped connecting rod, a first screw rod, a connecting rod A, a connecting rod B, a supporting plate A, a nut, a reverse-tooth nut, a bearing A and a supporting plate B, the supporting plate A is arranged in the middle of the top of the base and is connected with the base through a screw, the connecting rods A with the same size are arranged at two ends of the top of the supporting plate A, the connecting rods A are rotatably connected with the supporting plate A through bearings, the supporting plate B is arranged in the middle of the bottom of the pushing mechanism and is connected with the pushing mechanism through a screw, the connecting rods B with the same size are arranged at two ends of the supporting plate B, the connecting rods B are rotatably connected with the supporting plate B through bearings, the bearing A is arranged at one end of the connecting rods A and one end of the connecting rods B in a penetrating manner, the connecting rods A are rotatably connected with the connecting rods B through, bearings B with the same specification are symmetrically arranged at the other end of the first screw rod of the bearing A, and one end of the first screw rod is welded with the Z-shaped connecting rod; drive the first screw rod of being connected rather than rotating Z type connecting rod, make nut and anti-tooth nut at the activity of first screw rod outside, drive the bearing A who is connected rather than removing, connecting rod A and connecting rod B who is connected with bearing A and bearing B simultaneously pass through bearing A and bearing B and rotate, make connecting rod A and connecting rod B keep ascending removal, drive the backup pad that is connected rather than simultaneously and move up, thereby the support frame can height-adjusting, ground has a lot of hillocks usually, can adjust the support frame and make water conservancy pipeline at same height.

Furthermore, a nut is arranged in the middle of one bearing A in a penetrating mode and is integrally formed with the bearing A, and a reverse-tooth nut is arranged in the middle of the bearing B in a penetrating mode and is integrally formed with the bearing B; the nut is arranged to drive the bearing A to move in the forward direction on the outer side of the first screw rod, the reverse-tooth nut is arranged to drive the bearing B to move in the reverse direction on the outer side of the first screw rod, and when the screw rod is rotated, the reverse-tooth nut moves in the reverse direction, so that the nut and the reverse-tooth nut drive the bearing A to be close to each other continuously.

Further, the pushing mechanism comprises a supporting platform and a slide way, the supporting platform is arranged at the top of the supporting plate A and is connected with the supporting plate A through screws, first fixing rods, handles, a protective layer and an arc-shaped plate which are the same in size are symmetrically arranged at two ends of the supporting platform, the handle is arranged at one end of the second screw rod and welded with the second screw rod, the arc-shaped plate is arranged at one end of the first fixed rod and is connected with the first fixed rod through a screw, the second screw rod is nested and arranged at the inner side of the threaded sleeve and keeps rotating with the threaded sleeve, the sliding block is arranged at the bottom of the first fixed rod and is connected with the first fixed rod through a screw, the second fixed rod is arranged at the other end of the top of the sliding block and is connected with the sliding block through a screw, and the threaded sleeve is arranged at one end of the supporting table and is integrally formed with the supporting table; make it drive the second screw rod through rotating the handle and rotate, make the second screw rod constantly be close to the slide intermediate position through the screw thread, the second screw rod promotes the slider and removes simultaneously, the slider drives first dead lever and the second dead lever of being connected rather than and removes, the arc of first dead lever one end drives the protective layer of being connected rather than and removes simultaneously, when the protective layer was laminated with the pipeline, stall to can support the water conservancy pipeline of different diameters through adjusting the support frame, installation effectiveness has been improved greatly.

Further, the slide way is hollowed out at the middle position of the inner side of the support table, and the slide block is nested at the inner side of the slide way and is in sliding connection with the slide way; the slide block slides in the inner side of the slide way, and the sliding friction force of the slide block is reduced.

Further, the protective layer is arranged on the inner side of the arc-shaped plate and connected with the arc-shaped plate through screws; the protective layer is made of rubber, and is in contact with the pipeline, so that the friction force of a contact surface is improved, and the pipeline is not easy to rotate.

The utility model discloses an improve and provide a pipeline strutting arrangement for hydraulic engineering here, compare with current pipeline strutting arrangement for hydraulic engineering, have following advantage: make water conservancy pipeline not with ground direct contact through the support frame, the corrosive substance on ground can not corrode water conservancy pipeline, has improved water conservancy pipeline's life greatly, and the support frame can height-adjusting, and ground has a lot of hillocks usually, can adjust the support frame and make water conservancy pipeline at same height, can support the water conservancy pipeline of different diameters through adjusting the support frame, has improved the installation effectiveness greatly, and the concrete embodiment is:

the method has the advantages that: the Z-shaped connecting rod is rotated to drive the first screw rod connected with the Z-shaped connecting rod to rotate, so that the nut and the inverse-tooth nut move outside the first screw rod to drive the bearing A connected with the nut to move, and meanwhile, the connecting rod A and the connecting rod B connected with the bearing A and the bearing B rotate through the bearing A and the bearing B to keep the connecting rod A and the connecting rod B moving upwards and drive the supporting plate connected with the connecting rod A to move upwards.

The method has the advantages that: the handle is rotated to drive the second screw rod to rotate, the second screw rod is continuously close to the middle position of the slideway through threads, the second screw rod pushes the sliding block to move, the sliding block drives the first fixing rod and the second fixing rod connected with the sliding block to move, the arc-shaped plate at one end of the first fixing rod drives the protective layer connected with the first fixing rod to move, when the protective layer is attached to the pipeline, the rotation is stopped,

the method has the advantages that: through screwed connection, the protective layer is made by rubber, through protective layer and pipeline contact, has improved the frictional force of contact surface, makes the difficult rotation of pipeline.

Drawings

Fig. 1 is a schematic structural view of a pipeline supporting device for hydraulic engineering of the present invention;

FIG. 2 is an enlarged view of the portion A of FIG. 1;

fig. 3 is a schematic structural view of the telescopic mechanism of the present invention;

fig. 4 is an enlarged view of a portion a in fig. 3 according to the present invention;

fig. 5 is a schematic view of a partial structure of a support table according to the present invention;

fig. 6 is a longitudinal sectional view of the slider according to the present invention.

The figure illustrates the format: 1. a base; 2. a telescoping mechanism; 21. a Z-shaped connecting rod; 22. a first screw; 23. a connecting rod A; 24. a connecting rod B; 25. a support plate A; 26. a nut; 27. a counter-threaded nut; 28. a bearing A; 29. a support plate B; 210. a bearing B; 3. a pushing mechanism; 31. a support table; 32. a first fixing lever; 33. a handle; 34. a protective layer; 35. an arc-shaped plate; 36. a second screw; 37. a slider; 38. a second fixing bar; 398. a threaded sleeve; 310. a slideway; 4. a pipeline.

Detailed Description

The present invention will be described in detail below with reference to the attached drawings, and the technical solutions in the embodiments of the present invention will be clearly and completely described. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative efforts belong to the protection scope of the present invention; furthermore, the terms "first," "second," "third," "upper, lower, left, right," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Meanwhile, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "connected" and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; the connection can be mechanical connection or electrical connection; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The utility model provides a pipeline supporting device for hydraulic engineering through improvement, as shown in the attached drawing of the specification, the pipeline supporting device can be implemented as follows; the device comprises a base 1, a telescopic mechanism 2 and a pushing mechanism 3, wherein the telescopic mechanism 2 is arranged in the middle position of the top of the base 1 and is connected with the base 1 through screws, the pushing mechanism 3 is arranged in the middle position of the top of the telescopic mechanism 2 and is connected with the telescopic mechanism 2 through screws, a pipeline 4 is arranged at the top of the pushing mechanism 3, and the pipeline 4 is connected with the pushing mechanism 3 in a nested manner;

as shown in fig. 3 and 4, the telescoping mechanism 2 includes a Z-shaped link 21, a first screw 22, a link a23, a link B24, a support plate a25, a nut 26, an anti-thread nut 27, a bearing a28 and a support plate B29, the support plate a25 is disposed at the middle position of the top of the base 1 and is connected with the base 1 through screws, the two ends of the top of the support plate a25 are respectively provided with a link a23 with the same size, the link a23 is rotatably connected with the support plate a25 through a bearing, the support plate B29 is disposed at the middle position of the bottom of the pushing mechanism 3 and is connected with the pushing mechanism 3 through screws, the two ends of the support plate B29 are respectively provided with a link B24 with the same size, the link B24 is rotatably connected with the support plate B29 through a bearing, the bearing a28 is disposed at one end of the link a23 and the link B24, the link a23 is rotatably connected with a link B24 through a bearing a28, the first screw 22 is nested inside of the nut 26, the bearing A28 is symmetrically provided with bearings B210 with the same specification at the other end of the first screw 22, and one end of the first screw 22 is welded with the Z-shaped connecting rod 21; the Z-shaped connecting rod 21 is rotated to drive the first screw rod 22 connected with the Z-shaped connecting rod to rotate, so that the nut 26 and the counter nut 27 move outside the first screw rod 22 and drive the bearing A28 and the bearing B210 connected with the nut to move, and meanwhile, the connecting rod A23 and the connecting rod B24 connected with the bearing A28 rotate through the bearing A28 and the bearing B210, so that the connecting rod A23 and the connecting rod B24 keep moving upwards and drive the supporting plate 25 connected with the connecting rod A24 to move upwards;

as shown in fig. 4, the nut 26 is inserted through the middle of one bearing a28 and is integrally formed with the bearing a28, and the counter nut 27 is inserted through the middle of the bearing B210 and is integrally formed with the bearing B210; the bearing A28 is driven to move forwards on the outer side of the first screw 22 by the arranged nut 26, the bearing B210 is driven to move reversely on the outer side of the first screw 22 by the arranged reverse-tooth nut 27, and when the screw is rotated, the reverse-tooth nut 27 moves reversely, so that the nut 26 and the reverse-tooth nut 27 drive the bearing A28 and the bearing B to continuously approach;

as shown in fig. 1, 4 and 5, the pushing mechanism 3 includes a supporting platform 31 and a sliding way 310, the supporting platform 31 is disposed on the top of a supporting plate a25 and is connected with a supporting plate a25 through screws, the supporting platform 31 is symmetrically provided with a first fixing rod 32, a handle 33, a protective layer 34, an arc-shaped plate 35, a second screw 36, a sliding block 37, a second fixing rod 38 and a threaded sleeve 39, the first fixing rod 32 is disposed at one end of the top of the sliding block 37 and is welded with the sliding block 37, the handle 33 is disposed at one end of the second screw 36 and is welded with the second screw 36, the arc-shaped plate 35 is disposed at one end of the first fixing rod 32 and is connected with the first fixing rod 32 through screws, the second screw 36 is nested inside the threaded sleeve 39 and is kept rotating with the threaded sleeve 39, the sliding block 37 is disposed at the bottom of the first fixing rod 32 and is connected with the first fixing rod 32 through screws, the second fixing rod 38 is disposed at, the threaded sleeve 39 is arranged at one end of the support platform 31 and is integrally formed with the support platform 31; the handle 33 is rotated to drive the second screw rod 36 to rotate, the second screw rod 36 is continuously close to the middle position of the slide way 310 through threads, meanwhile, the second screw rod 36 pushes the sliding block 37 to move, the sliding block 37 drives the first fixing rod 32 and the second fixing rod 38 connected with the sliding block to move, meanwhile, the arc-shaped plate 35 at one end of the first fixing rod 32 drives the protective layer 34 connected with the sliding block to move, and when the protective layer 34 is attached to the pipeline 4, the rotation is stopped;

as shown in fig. 4 and 5, the slide way 310 is hollowed out at the middle position of the inner side of the support platform 31, and the slider 37 is nested inside the slide way 310 and is slidably connected with the slide way 310; the slide block 37 slides in the slide way 310, and the friction force of the slide block 37 sliding is reduced;

as shown in fig. 1, the protective layer 34 is disposed on the inner side of the arc plate 35 and connected to the arc plate 35 by screws; the protective layer 34 is made of rubber, and the friction force of the contact surface is increased by the contact of the protective layer 34 and the pipeline 4, so that the pipeline 4 is not easy to rotate.

This kind of pipeline strutting arrangement for hydraulic engineering's theory of operation: the Z-shaped connecting rod 21 is rotated to drive the first screw rod 22 connected with the Z-shaped connecting rod to rotate, so that the nut 26 and the counter nut 27 move outside the first screw rod 22, the bearing A28 and the bearing B210 connected with the Z-shaped connecting rod are driven to move, meanwhile, the connecting rod A23 and the connecting rod B24 connected with the bearing A28 rotate through the bearing A28 and the bearing B210, the connecting rod A23 and the connecting rod B24 are kept moving upwards, the supporting plate 25 connected with the connecting rod is driven to move upwards, the handle 33 is rotated to drive the second screw rod 36 to rotate, the second screw rod 36 is continuously close to the middle position of the slide way 310 through threads, meanwhile, the second screw rod 36 pushes the sliding block 37 to move, the sliding block 37 drives the first fixing rod 32 and the second fixing rod 38 connected with the sliding block 37 to move, meanwhile, the arc-shaped plate 35 at one end of the first fixing rod 32 drives the protective layer 34 connected with the first fixing rod.

In conclusion; pipeline strutting arrangement for hydraulic engineering compares with current pipeline strutting arrangement for hydraulic engineering, makes water conservancy pipeline not with ground direct contact through the support frame, and the corrosive substance on ground can not corrode water conservancy pipeline, has improved water conservancy pipeline's life greatly, and the support frame can height-adjusting, and ground has a lot of hillocks usually, can adjust the support frame and make water conservancy pipeline at same height, can support the water conservancy pipeline of different diameters through adjusting the support frame, has improved the installation effectiveness greatly

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (6)

1. The utility model provides a pipeline strutting arrangement for hydraulic engineering, includes base (1), telescopic machanism (2) and pushing mechanism (3), its characterized in that: telescopic machanism (2) set up in the top intermediate position of base (1) and pass through screwed connection with base (1), pushing mechanism (3) set up in the top intermediate position of telescopic machanism (2) and pass through screwed connection with telescopic machanism (2), pushing mechanism (3) top is equipped with pipeline (4), pipeline (4) and pushing mechanism (3) nested connection.

2. The pipeline supporting device for the hydraulic engineering according to claim 1, characterized in that: the telescopic mechanism (2) comprises a Z-shaped connecting rod (21), a first screw rod (22), a connecting rod A (23), a connecting rod B (24), a supporting plate A (25), a nut (26), a reverse nut (27), a bearing A (28) and a supporting plate B (29), wherein the supporting plate A (25) is arranged at the middle position of the top of the base (1) and is connected with the base (1) through screws, the connecting rods A (23) with the same size are arranged at the two ends of the top of the supporting plate A (25), the connecting rod A (23) is rotatably connected with the supporting plate A (25) through bearings, the supporting plate B (29) is arranged at the middle position of the bottom of the pushing mechanism (3) and is connected with the pushing mechanism (3) through screws, the connecting rods B (24) with the same size are arranged at the two ends of the supporting plate B (29), and the connecting rod B (24) is rotatably connected with the supporting plate B, the bearing A (28) penetrates through one end of the connecting rod A (23) and one end of the connecting rod B (24), the connecting rod A (23) is rotatably connected with the connecting rod B (24) through the bearing A (28), the first screw (22) is nested on the inner sides of the nut (26) and the reverse-tooth nut (27) and is movably connected with the nut (26) and the reverse-tooth nut (27) respectively, the bearing B (210) with the same specification is symmetrically arranged at the other end of the first screw (22) of the bearing A (28), and one end of the first screw (22) is welded with the Z-shaped connecting rod (21).

3. The pipeline supporting device for the hydraulic engineering according to claim 2, characterized in that: the nut (26) penetrates through the middle of one bearing A (28) and is integrally formed with the bearing A (28), and the counter nut (27) penetrates through the middle of the bearing B (210) and is integrally formed with the bearing B (210).

4. The pipeline supporting device for the hydraulic engineering according to claim 1, characterized in that: the pushing mechanism (3) comprises a supporting table (31) and a slide way (310), the supporting table (31) is arranged at the top of the supporting plate A (25) and is connected with the supporting plate A (25) through screws, two ends of the supporting table (31) are symmetrically provided with a first fixing rod (32), a handle (33), a protective layer (34), an arc-shaped plate (35), a second screw rod (36), a sliding block (37), a second fixing rod (38) and a thread bush (39) which are the same in size, the first fixing rod (32) is arranged at one end of the top of the sliding block (37) and is welded with the sliding block (37), the handle (33) is arranged at one end of the second screw rod (36) and is welded with the second screw rod (36), the arc-shaped plate (35) is arranged at one end of the first fixing rod (32) and is connected with the first fixing rod (32) through screws, the second screw rod (36) is nested in the inner side of the thread bush (39) and keeps rotating, the sliding block (37) is arranged at the bottom of the first fixing rod (32) and is connected with the first fixing rod (32) through screws, the second fixing rod (38) is arranged at the other end of the top of the sliding block (37) and is connected with the sliding block (37) through screws, and the thread sleeve (39) is arranged at one end of the supporting table (31) and is integrally formed with the supporting table (31).

5. The pipeline supporting device for the hydraulic engineering according to claim 4, wherein: the slide way (310) is arranged at the middle position of the inner side of the support platform (31) in a hollow mode, and the sliding block (37) is arranged on the inner side of the slide way (310) in a nested mode and is in sliding connection with the slide way (310).

6. The pipeline supporting device for the hydraulic engineering according to claim 4, wherein: the protective layer (34) is arranged on the inner side of the arc-shaped plate (35) and is connected with the arc-shaped plate (35) through screws.

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