CN112361088A

CN112361088A - Pipeline installation antidetonation support for water conservancy water and electricity

Info

Publication number: CN112361088A
Application number: CN202011289727.8A
Authority: CN
Inventors: 周红
Original assignee: Chongqing Mengsai Technology Co ltd
Current assignee: Chongqing Mengsai Technology Co ltd
Priority date: 2020-11-18
Filing date: 2020-11-18
Publication date: 2021-02-12
Anticipated expiration: 2040-11-18
Also published as: CN112361088B

Abstract

The invention discloses a pipeline installation anti-seismic support for water conservancy and hydropower, which is characterized in that a support base is embedded at the bottom of a pipeline and positioned at the joint of two adjacent pipelines, the joint of two adjacent pipelines is sealed by the sealing hoop, and the two adjacent pipelines are clamped by the first locking hoop and the second locking hoop which are positioned at the front side and the rear side of the sealing hoop, the two sides of the first locking hoop and the second locking hoop are fixed by bolts through the first locking connecting rod and the second locking connecting rod, the locking sliding block is sleeved on the outer side of the first locking connecting rod at the bottom of the pipeline in a threaded manner, the locking slide block is positioned on the guide slide rail to slide and is supported by the supporting component, thereby support fixedly to two adjacent pipelines to slow down the vibrations of pipeline, thereby make the connection of two adjacent pipelines more firm.

Description

Pipeline installation antidetonation support for water conservancy water and electricity

Technical Field

The invention relates to the technical field of pipeline installation for water conservancy and hydropower, in particular to a pipeline installation anti-seismic support for water conservancy and hydropower.

Background

The pipeline that present water conservancy and water and electricity were used is inside hollow PVC rubber tube, and PVC rubber tube quality is light, and corrosion resistance, because the shearing resistance of PVC material is poor, the side direction atress damages easily, so the length of current water conservancy is the pipeline for water and electricity shorter, connects fixedly through connecting device to the tip of two adjacent pipelines to avoid pipeline side direction atress and fracture.

Because current water conservancy is pipeline for water and electricity is buried underground, fixes the pipeline through the soil layer, but has vehicle or mechanical equipment on the road surface for a long time through producing vibrations, vibrations transmit the pipeline buried underground to make the junction of two adjacent pipelines crack appears, thereby influence the leakproofness of pipeline.

Disclosure of Invention

The invention aims to provide a water conservancy and hydropower pipeline installation anti-seismic support, and aims to solve the technical problem that in the prior art, pipelines for water conservancy and hydropower are buried underground, and are fixed through soil layers, but vehicles or mechanical equipment on the road surface generate vibration for a long time, and the vibration is transmitted to the underground buried pipelines, so that the joints of two adjacent pipelines crack, and the sealing performance of the pipelines is influenced.

In order to achieve the purpose, the pipeline installation anti-seismic support for water conservancy and hydropower, which is adopted by the invention, comprises a supporting base and a locking device; the locking device comprises a sealing hoop, a first locking hoop, a second locking hoop and a connecting assembly, wherein the sealing hoop is fixedly connected with the supporting base and is positioned on one side of the supporting base, the first locking hoop is slidably connected with the supporting base and is positioned on one side of the supporting base close to the sealing hoop, and the second locking hoop is slidably connected with the supporting base and is detachably connected with the first locking hoop and is positioned on one side of the sealing hoop far away from the first locking hoop; the connecting assembly comprises a first locking connecting rod, a second locking connecting rod, a locking sliding block, a guiding sliding rail and a supporting member, one end of the first locking connecting rod is fixedly connected with the first locking hoop, the other end of the first locking connecting rod is fixedly connected with the second locking hoop and is positioned between the first locking hoop and the second locking hoop, one end of the second locking connecting rod is fixedly connected with the first locking hoop, the other end of the second locking connecting rod is fixedly connected with the second locking hoop and is positioned at one side of the first locking hoop far away from the first locking connecting rod, the locking sliding block is fixedly connected with the first locking connecting rod and is positioned between the first locking hoop and the second locking hoop, the guiding sliding rail is fixedly connected with the supporting base and is slidably connected with the locking sliding block and is positioned at one side of the supporting base close to the locking sliding block, and the supporting member is fixedly connected with the guiding sliding rail, and is fixedly connected with the locking slide block.

The locking slide block is provided with a lateral bulge, and the lateral bulge is positioned on one side, close to the guide slide rail, of the locking slide block; the guide sliding rail is provided with a matching groove, and the matching groove is positioned on one side, close to the locking sliding block, of the guide sliding rail and is matched with the locking sliding block.

The supporting component comprises a first supporting hydraulic rod and a first buffer spring, one end of the first supporting hydraulic rod is fixedly connected with the locking slide block, and the other end of the first supporting hydraulic rod is fixedly connected with the guide slide rail and is positioned between the guide slide rail and the locking slide block; one side of the first buffer spring is fixed with the guide sliding rail, and the other side of the first buffer spring is abutted to the locking sliding block and is positioned between the guide sliding rail and the locking sliding block.

The supporting component further comprises a second supporting hydraulic rod and a second buffer spring, one end of the second supporting hydraulic rod is fixedly connected with the locking slide block, the other end of the second supporting hydraulic rod is fixedly connected with the guide slide rail, and the second supporting hydraulic rod is positioned on one side, far away from the first supporting hydraulic rod, of the locking slide block; one side of the first buffer spring is fixed with the guide sliding rail, the other side of the first buffer spring is abutted to the locking sliding block, and the first buffer spring is located on one side, far away from the first support hydraulic rod, of the locking sliding block.

The connecting assembly further comprises a first locking bolt and a second locking bolt, the first locking bolt is rotatably connected with the first locking connecting rod, abuts against the first locking hoop and is positioned at one end, close to the first locking hoop, of the first locking connecting rod; the second locking bolt is rotatably connected with the first locking connecting rod, is abutted against the second locking hoop and is positioned at one end, close to the second locking hoop, of the first locking connecting rod.

The connecting assembly further comprises a third locking bolt and a fourth locking bolt, the third locking bolt is rotatably connected with the second locking connecting rod, is abutted against the first locking hoop and is positioned at one end, close to the first locking hoop, of the second locking connecting rod; the fourth locking bolt is rotatably connected with the second locking connecting rod, is abutted against the second locking hoop and is positioned at one end, close to the second locking hoop, of the second locking connecting rod.

The locking device further comprises a first rod sleeve, one side of the first rod sleeve is abutted to the first locking hoop, the other side of the first rod sleeve is abutted to the sealing hoop, and the first rod sleeve is sleeved outside the first locking connecting rod.

The locking device further comprises a second rod sleeve, one side of the second rod sleeve is abutted with the second locking hoop, the other side of the second rod sleeve is abutted with the sealing hoop, and the second rod sleeve is sleeved outside the second locking connecting rod.

The locking device further comprises a U-shaped limiting seat, wherein the U-shaped limiting seat is fixedly connected with the supporting base and is positioned on one side, close to the guide sliding rail, of the supporting base.

The invention relates to a pipeline installation anti-seismic support for water conservancy and hydropower, which is characterized in that a support base is embedded at the bottom of a pipeline and positioned at the joint of two adjacent pipelines, the joint of two adjacent pipelines is sealed by the sealing hoop, and the two adjacent pipelines are clamped by the first locking hoop and the second locking hoop which are positioned at the front side and the rear side of the sealing hoop, the two sides of the first locking hoop and the second locking hoop are fixed by bolts through the first locking connecting rod and the second locking connecting rod, the locking sliding block is sleeved on the outer side of the first locking connecting rod at the bottom of the pipeline in a threaded manner, the locking slide block is positioned on the guide slide rail to slide and is supported by the supporting component, thereby support fixedly to two adjacent pipelines to slow down the vibrations of pipeline, thereby make the connection of two adjacent pipelines more firm.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic view of the overall structure of the pipe-mounted anti-seismic support for water conservancy and hydropower of the present invention.

Fig. 2 is a schematic view of the construction of the connection assembly of the present invention.

Fig. 3 is a schematic view of the construction of the locking device of the present invention.

Fig. 4 is a schematic structural view of the support member of the present invention.

In the figure: 1-a supporting base, 2-a locking device, 3-a pipeline, 21-a sealing hoop, 22-a first locking hoop, 23-a second locking hoop, 24-a connecting component, 25-a first rod sleeve, 26-a second rod sleeve, 27-a U-shaped limiting seat, 100-a water conservancy and hydropower pipeline installation anti-seismic support, 241-a first locking connecting rod and 242-a second locking connecting rod, 243-locking slide block, 244-guiding slide rail, 245-supporting member, 246-first locking bolt, 247-second locking bolt, 248-third locking bolt, 249-fourth locking bolt, 2431-lateral bulge, 2441-matching groove, 2451-first supporting hydraulic rod, 2452-first buffer spring, 2453-second supporting hydraulic rod and 2454-second buffer spring.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1 to 4, the invention provides a pipe-mounted anti-seismic support 100 for water conservancy and hydropower, which comprises a support base 1 and a locking device 2; the locking device 2 comprises a sealing hoop 21, a first locking hoop 22, a second locking hoop 23 and a connecting assembly 24, wherein the sealing hoop 21 is fixedly connected with the support base 1 and is positioned on one side of the support base 1, the first locking hoop 22 is slidably connected with the support base 1 and is positioned on one side of the support base 1 close to the sealing hoop 21, and the second locking hoop 23 is slidably connected with the support base 1 and is detachably connected with the first locking hoop 22 and is positioned on one side of the sealing hoop 21 far away from the first locking hoop 22; the connecting assembly 24 includes a first locking link 241, a second locking link 242, a locking slider 243, a guiding slide rail 244 and a supporting member 245, one end of the first locking link 241 is fixedly connected to the first locking hoop 22, the other end of the first locking link 241 is fixedly connected to the second locking hoop 23 and is located between the first locking hoop 22 and the second locking hoop 23, one end of the second locking link 242 is fixedly connected to the first locking hoop 22, the other end of the second locking link 242 is fixedly connected to the second locking hoop 23 and is located at a side of the first locking hoop 22 far away from the first locking link 241, the locking slider 243 is fixedly connected to the first locking link 241 and is located between the first locking hoop 22 and the second locking hoop 23, the guiding slide rail 244 is fixedly connected to the supporting base 1 and is slidably connected to the locking slider 243, and is located on one side of the supporting base 1 close to the locking slider 243, and the supporting member 245 is fixedly connected with the guiding slide rail 244 and fixedly connected with the locking slider 243.

In this embodiment, the support base 1 is installed on the ground, the sealing hoop 21 is installed at the central position of the support base 1 in a threaded manner, the sealing hoop 21 is a circular ring with a hollow inner portion and can be sleeved on the outer side of the pipeline 3, the sealing hoop 21 is used for connecting two adjacent pipelines 3 and sealing the joint position of the two adjacent pipelines 3, and the support base 1 supports the bottoms of the two adjacent pipelines 3 respectively, so that the connecting ends of the two adjacent pipelines 3 can be horizontally connected to the sealing hoop 21; the guide slide rail 244 is installed on the top surface of the support base 1 in a threaded manner, the long direction of the guide slide rail 244 is arranged along the laying direction of the pipeline 3, and is located at the bottom of the pipeline 3, the guide rail 244 penetrates through the bottom of the locking band, and the locking slider 243 is slidably mounted in the guide rail 244, the locking slider 243 has a screw hole formed therein, the first locking bar penetrates the screw hole of the locking slider 243, and threadedly coupled with the first locking band 22 and the second locking band 23 respectively located outside the adjacent two pipes 3, the first locking clamp 22 and the second locking clamp 23 have the same shape, are both hollow circular rings, the first locking hoop 22 and the second locking hoop 23 are respectively positioned at two sides of the sealing hoop 21 to clamp the two side pipelines 3; locking blocks are integrally fixed at two ends of the outer sides of the first locking hoop 22 and the second locking hoop 23 respectively, and the first locking rod and the second locking rod are in threaded connection with two sides of the first locking hoop 22 and the second locking hoop 23 respectively, so that the first locking hoop 22 and the second locking hoop 23 are locked; thus, the supporting base 1 is embedded at the bottom of the pipeline 3 and is positioned at the joint of two adjacent pipelines 3, the joint of two adjacent pipes 3 is sealed by the sealing hoop 21, and the two adjacent pipes 3 are clamped by the first locking hoop 22 and the second locking hoop 23 which are positioned at the front side and the rear side of the sealing hoop 21, and the first locking link 241 and the second locking link 242 are used to bolt the two sides of the first locking hoop 22 and the second locking hoop 23, the locking slider 243 is screwed on the outer side of the first locking link 241 at the bottom of the pipeline 3, the locking slider 243 is slidably positioned on the guide rail 244, and is supported by the support member 245, thereby support two adjacent pipelines 3 fixedly to the vibrations to pipeline 3 slow down, thereby make two adjacent pipelines 3's connection more firm.

Further, referring to fig. 4, the locking slider 243 has a lateral protrusion 2431, and the lateral protrusion 2431 is located on a side of the locking slider 243 close to the guiding slide 244; the guide rail 244 has a fitting groove 2441, and the fitting groove 2441 is located on a side of the guide rail 244 close to the locking slider 243 and is fitted with the locking slider 243.

In this embodiment, the locking slider 243 has the lateral protrusions 2431 on both sides, so that the locking slider 243 has a "convex" shape; the inner side surface of the guide slide rail 244 is provided with two matching grooves 2441, the matching grooves 2441 are rectangular grooves, the length direction of the groove body is arranged along the length direction of the guide slide rail 244 and is in sliding fit with the lateral protrusions 2431 of the locking slide block 243, so that the locking slide block 243 can only slide along the length direction of the guide slide rail 244, and the joint of two adjacent pipelines 3 cannot slide laterally.

Further, referring to fig. 4, the supporting member 245 includes a first supporting hydraulic rod 2451 and a first buffer spring 2452, one end of the first supporting hydraulic rod 2451 is fixedly connected to the locking slider 243, and the other end is fixedly connected to the guiding slide 244 and is located between the guiding slide 244 and the locking slider 243; one side of the first buffer spring 2452 is fixed to the guide rail 244, and the other side thereof abuts against the locking slider 243 and is located between the guide rail 244 and the locking slider 243.

In this embodiment, one end of the first support hydraulic rod 2451 is fixed to the inner side surface of the guide rail 244 through a screw thread, the other end of the first support hydraulic rod 2451 is fixed to the locking slider 243 through a screw thread, and the first buffer spring 2452 is sleeved on the outer side of the first support hydraulic rod 2451 and abuts against the locking slider 243 to slow down the sliding of the locking slider 243, so as to slow down the vibration received by the pipeline 3.

Further, referring to fig. 4, the supporting member 245 further includes a second supporting hydraulic rod 2453 and a second buffer spring 2454, wherein one end of the second supporting hydraulic rod 2453 is fixedly connected to the locking slider 243, and the other end is fixedly connected to the guiding slide rail 244 and is located on a side of the locking slider 243 far away from the first supporting hydraulic rod 2451; one side of the first buffer spring 2452 is fixed to the guide rail 244, and the other side thereof abuts against the locking slider 243 and is located on the side of the locking slider 243 away from the first support hydraulic rod 2451.

In this embodiment, one end of the second supporting hydraulic rod 2453 is fixed to the inner side surface of the guiding slide rail 244 through a screw thread, the other end of the second supporting hydraulic rod 2453 is fixed to the locking slide block 243 through a screw thread, the second buffer spring 2454 is sleeved on the outer side of the second supporting hydraulic rod 2453 and abuts against the sliding of the locking slide block 243, so that the sliding sides of the locking slide block 243 are slowed down through the first supporting hydraulic rod 2451, the first buffer spring 2452, the second supporting hydraulic rod 2453 and the second supporting spring, and further the vibration on the pipeline 3 is slowed down.

Further, referring to fig. 3, the connecting assembly 24 further includes a first locking bolt 246 and a second locking bolt 247, wherein the first locking bolt 246 is rotatably connected to the first locking link 241, abuts against the first locking hoop 22, and is located at one end of the first locking link 241 close to the first locking hoop 22; the second locking bolt 247 is rotatably connected to the first locking link 241, abuts against the second locking hoop 23, and is located at one end of the first locking link 241 close to the second locking hoop 23.

In this embodiment, the first locking bolt 246 and the second locking bolt 247 are sleeved on the first locking link 241 and abut and limit the first locking hoop 22 and the second locking hoop 23, so that the connection between the first locking hoop 22 and the second locking hoop 23 is more stable, and the connection between adjacent pipes 3 is more stable.

Further, referring to fig. 3, the connecting assembly 24 further includes a third locking bolt 248 and a fourth locking bolt 249, wherein the third locking bolt 248 is rotatably connected to the second locking link 242, abuts against the first locking hoop 22, and is located at one end of the second locking link 242 close to the first locking hoop 22; the fourth locking bolt 249 is rotatably connected to the second locking link 242, abuts against the second locking hoop 23, and is located at one end of the second locking link 242 close to the second locking hoop 23.

In this embodiment, the third locking bolt 248 and the fourth locking bolt 249 are sleeved on the first locking link 241, and abut and limit the first locking hoop 22 and the second locking hoop 23, so that the connection between the first locking hoop 22 and the second locking hoop 23 is more stable, and further the connection between adjacent pipes 3 is more stable.

Further, referring to fig. 3, the locking device 2 further includes a first rod sleeve 25, one side of the first rod sleeve 25 abuts against the first locking hoop 22, and the other side abuts against the sealing hoop 21 and is sleeved on the outer side of the first locking connecting rod 241.

In the present embodiment, the first rod cover 25 is made of rubber, has good corrosion resistance, and is fitted over the outside of the first lock link 241 to protect the first lock link 241 and prevent the first lock link 241 from rusting due to corrosion.

Further, referring to fig. 3, the locking device 2 further includes a second rod sleeve 26, one side of the second rod sleeve 26 abuts against the second locking hoop 23, and the other side abuts against the sealing hoop 21 and is sleeved on the outer side of the second locking connecting rod 242.

In this embodiment, the second rod sleeve 26 is made of rubber, has good corrosion resistance, and is sleeved on the outer side of the second locking connecting rod 242 to protect the second locking connecting rod 242 and prevent the second locking connecting rod 242 from rusting due to corrosion.

Further, referring to fig. 1, the locking device 2 further includes a U-shaped limiting seat 27, and the U-shaped limiting seat 27 is fixedly connected to the supporting base 1 and is located on one side of the supporting base 1 close to the guiding slide rail 244.

In this embodiment, the U-shaped limiting seats 27 are fixed to the top of the supporting base 1 by bolts, are two in number, are respectively installed at two ends of the supporting base 1 along the length direction of the pipeline 3, and support the bottom of the pipeline 3, so that the central axes of two adjacent pipelines 3 are located on the same straight line.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. A pipeline installation anti-seismic support for water conservancy and hydropower is characterized by comprising a support base and a locking device;

the locking device comprises a sealing hoop, a first locking hoop, a second locking hoop and a connecting assembly, wherein the sealing hoop is fixedly connected with the supporting base and is positioned on one side of the supporting base, the first locking hoop is slidably connected with the supporting base and is positioned on one side of the supporting base close to the sealing hoop, the second locking hoop is slidably connected with the supporting base and is detachably connected with the first locking hoop, and the second locking hoop is positioned on one side of the sealing hoop far away from the first locking hoop;

coupling assembling includes first locking connecting rod, second locking connecting rod, locking slider, direction slide rail and supporting member, the one end of first locking connecting rod with first locking hoop fixed connection, the other end with second locking hoop fixed connection, the one end of second locking connecting rod with first locking hoop fixed connection, the other end with second locking hoop fixed connection, the locking slider with first locking connecting rod fixed connection, and be located first locking hoop with between the second locking hoop, the direction slide rail with support base fixed connection, and with locking slider sliding connection, just the direction slide rail is located the support base is close to one side of locking slider, the supporting member with direction slide rail fixed connection, and with locking slider fixed connection.

2. A pipe-mounted seismic support for water conservancy and hydropower according to claim 1,

the locking slide block is provided with a lateral bulge, and the lateral bulge is positioned on one side of the locking slide block close to the guide slide rail; the guide sliding rail is provided with a matching groove, and the matching groove is positioned on one side, close to the locking sliding block, of the guide sliding rail and is matched with the locking sliding block.

3. A pipe-mounted seismic support for water conservancy and hydropower according to claim 1,

the supporting component comprises a first supporting hydraulic rod and a first buffer spring, one end of the first supporting hydraulic rod is fixedly connected with the locking slide block, and the other end of the first supporting hydraulic rod is fixedly connected with the guide slide rail; one side of the first buffer spring is fixed with the guide sliding rail, and the other side of the first buffer spring is abutted to the locking sliding block.

4. A pipe-mounted seismic support for water conservancy and hydropower according to claim 3,

the supporting component further comprises a second supporting hydraulic rod and a second buffer spring, one end of the second supporting hydraulic rod is fixedly connected with the locking sliding block, the other end of the second supporting hydraulic rod is fixedly connected with the guide sliding rail, and the second supporting hydraulic rod is located on one side, far away from the first supporting hydraulic rod, of the locking sliding block; one side of the first buffer spring is fixed with the guide sliding rail, the other side of the first buffer spring is abutted to the locking sliding block, and the first buffer spring is located on one side, far away from the first support hydraulic rod, of the locking sliding block.

5. A pipe-mounted seismic support for water conservancy and hydropower according to claim 1,

6. A pipe-mounted seismic support for water conservancy and hydropower according to claim 1,

7. A pipe-mounted seismic support for water conservancy and hydropower according to claim 1 or 5,

8. A pipe-mounted seismic support for water conservancy and hydropower according to claim 1 or 6,

9. A pipe-mounted seismic support for water conservancy and hydropower according to claim 1,