CN117781071A - Transportation pipeline support with damping function and construction method thereof - Google Patents

Abstract

The application discloses a transportation pipeline support with a damping function and a construction method thereof, and relates to the technical field of pipeline supports, wherein the pipeline support comprises a support body, a plurality of rotating parts, a plurality of supporting components, a plurality of positioning parts and a connecting component; the frame body is provided with a yielding port; the rotating piece is in a circular ring structure, the rotating piece is rotationally connected with the frame body, the rotating axis of the rotating piece passes through the abdication opening, and the rotating axes of the rotating pieces are overlapped; the connecting component connects the positioning pieces with each other to enable the positioning pieces to encircle the pipeline passing through the yielding port; the supporting component enables the corresponding positioning piece to be movably connected with one rotating piece; at least two locating pieces are movably connected to the rotating piece. The vibration that this application can effectively reduce pipeline in the pipeline transportation process to can reduce pipeline vibration and normally go on to pipeline transportation's influence.

Description

Transportation pipeline support with damping function and construction method thereof

Technical Field

The application relates to the technical field of pipeline supports, in particular to a transportation pipeline support with a damping function and a construction method thereof.

Background

Pipes are devices for transporting gas, liquid or fluid with solid particles, which are coupled by pipes, pipe couplings, valves, etc. In general, after the fluid is pressurized by a blower, a compressor, a pump, a boiler, etc., the fluid flows from a high pressure place to a low pressure place of a pipeline, and the fluid can be conveyed by the pressure or gravity of the fluid. The piping is used in a wide variety of applications, mainly in water supply, water drainage, heat supply, gas supply, long distance transportation of petroleum and natural gas, agricultural irrigation, hydraulic engineering and various industrial devices.

In the pipeline construction process, the pipeline support needs to be supported and positioned through a plurality of pipeline supports, so that a plurality of pipelines can be connected with each other to form a required transportation path.

In the pipeline transportation process, the pressure in the pipeline is changed by the pressurizing equipment, and vibration in the operation process of the pressurizing equipment can cause vibration of the pipeline. And current pipeline support supports the in-process of location at the pipeline, and pipeline vibrations will lead to the collision aggravation between pipeline and the pipeline support, still lead to pipeline and pipeline support to fracture because of metal fatigue in the striking position easily when producing great noise to can bring great influence for the pipeline transportation, there is great potential safety hazard, and will destroy pipeline transportation's continuity.

Disclosure of Invention

The utility model provides a transportation pipeline support with shock-absorbing function and construction method thereof can effectively reduce the vibrations that the pipeline takes place in the pipeline transportation to can reduce the pipeline vibrations and normally go on to pipeline transportation's influence.

On the one hand, the application provides a transportation pipeline support with shock-absorbing function, adopts following technical scheme:

a transportation pipeline bracket with a damping function comprises a bracket body, a plurality of rotating parts, a plurality of supporting components, a plurality of positioning parts and a connecting component;

the frame body is provided with a yielding port for the pipeline to pass through;

the rotating piece is in a circular ring structure, the rotating piece is rotationally connected with the frame body, the rotating axis of the rotating piece passes through the abdication opening, and the rotating axes of the rotating pieces are overlapped;

the positioning pieces are positioned in the yielding port, and the connecting assembly connects the positioning pieces with each other so that the positioning pieces encircle the pipeline passing through the yielding port;

the supporting components are in one-to-one correspondence with the positioning pieces, and the corresponding positioning pieces are movably connected with one rotating piece by the supporting components;

at least two locating pieces are movably connected to the rotating piece, when the pipeline vibrates to drive one locating piece to move relative to the corresponding rotating piece, the corresponding rotating piece is driven to rotate by the supporting component, other locating pieces movably connected with the same rotating piece move along with the corresponding rotating piece, and the locating pieces driven by the pipeline are restrained to move by the connecting component.

Through adopting above-mentioned technical scheme, the pipeline is surrounded the location by a plurality of setting elements and is supported the location through a plurality of supporting components after, when the in-process of pipeline transportation leads to pipeline vibrations, the pipeline will take place to rock along radial direction and order about at least one setting element and take place to remove thereupon, the setting element has through supporting component order about rotating the pivoted trend, the rotating element rotates and will order about another setting element on the same rotating element to take place to remove for the pipeline, this setting element removes and will be driven by the pipeline to rock the setting element that orders about the removal towards rather than receiving the pipeline to rock the direction different direction that influences and remove by the pipeline through coupling assembling, thereby can restrain the pipeline to rock and order about the setting element to remove, can effectively reduce the vibrations that the pipeline takes place in the pipeline transportation, and then can reduce the influence that pipeline vibrations normally goes on pipeline transportation.

Optionally, the number of the rotating parts is two, and the number of the supporting components and the number of the positioning parts are four;

the rotating piece is connected with two positioning pieces in a co-movable mode, and the positions, connected with the rotating piece through the supporting component, of the two positioning pieces are located at two ends of the rotating piece in the same radial direction.

By adopting the technical scheme, the supporting and positioning effects of the pipeline on the pipeline support can be more uniform after the pipeline is installed; meanwhile, when the pipeline shakes to drive the positioning piece to move due to vibration, the corresponding other positioning piece moves along with the positioning piece and drives the pipeline to shake towards the opposite direction through the connecting component, so that the effect of inhibiting the pipeline from shaking can be improved, and the damping effect of the pipeline can be further improved.

Optionally, the rotation piece restriction the rotation of support body, and a plurality of the rotation piece for the in-process of support body rotation, a plurality of the setting element can keep encircling the pipeline.

Through adopting above-mentioned technical scheme, when the pipeline is not in pipeline support on-mounting, the rotation piece receives self gravity effect free rotation's angle limited for the support body, and a plurality of locating pieces and a plurality of supporting component are also comparatively stable in the position distribution in the mouth of stepping down to can make things convenient for follow-up pipeline to pass the mouth of stepping down, make the pipeline by a plurality of locating pieces through coupling assembling encircling location and through a plurality of supporting component support the process of location more convenient and fast.

Optionally, the device further comprises a plurality of elastic pieces, wherein the elastic pieces are arranged in the frame body, two ends of each elastic piece are respectively connected with the frame body and the rotating piece, and the elastic pieces can drive the rotating piece to rotate to a limit position and keep the rotating piece.

By adopting the technical scheme, the rotating piece has higher position stability relative to the frame body under the condition that whether the pipeline is arranged on the pipeline support or not, so that the pipeline is conveniently arranged on the pipeline support; meanwhile, when the pipeline shakes to drive the positioning piece to move so that the rotating piece has a rotating trend, the plurality of elastic pieces can inhibit the rotating piece from rotating, so that the positioning piece can be inhibited from moving along with the shaking of the pipeline, the shaking of the pipeline can be inhibited, and the damping effect is further realized.

Optionally, the support assembly includes a fixed part and a movable part, where the fixed part and the movable part are movably connected with the corresponding rotating part and the corresponding positioning part, and the movable part is slidably connected with the fixed part.

Through adopting above-mentioned technical scheme, can make things convenient for the staff to control the radial dimension of the pipeline that four setting elements can encircle through coupling assembling through adjusting support assembly to can adjust four setting elements and locate the effect through coupling assembling to encircling of pipeline, make the pipeline support can adapt to the pipeline of more radial dimension specification.

Optionally, in the two supporting assemblies corresponding to the same rotating piece, one supporting assembly further comprises an adjusting piece, the adjusting piece is rotationally connected with the fixed piece, the rotation axis of the adjusting piece is parallel to the sliding direction of the movable piece, the adjusting piece is sleeved outside the movable piece and is in threaded fit with the movable piece, and the movable piece can be controlled to slide relative to the fixed piece by rotating the adjusting piece;

the other support component further comprises a plurality of locking pieces, wherein the locking pieces are detachably connected with the fixing pieces, and the locking pieces can prop against the movable pieces after being connected with the fixing pieces so that the relative positions of the movable pieces and the fixing pieces are fixed.

Through adopting above-mentioned technical scheme, when the staff controls the radial dimension of four setting elements through the pipeline that coupling assembling can encircle through adjusting support assembly, control the regulating part on a supporting assembly rotate can, another supporting assembly will adjust by oneself thereupon, can fix the state through the locking piece after adjusting to can make above-mentioned operation process more simple and convenient.

Optionally, the connecting assembly includes a connecting band having elasticity, two ends of the connecting band are connected with the same positioning piece, and the connecting band passes through other positioning pieces.

Through adopting above-mentioned technical scheme, when the pipeline rocks and drives the setting element and remove because of vibrations, the setting element that removes will drive the setting element that does not receive the pipeline vibrations influence to move towards the direction that is close to the pipeline through the connecting band and support tight pipeline to can restrain the pipeline and rock, further play the shock attenuation effect to the pipeline.

Optionally, the connecting assembly further comprises a winding member, the winding member is arranged on the positioning member connected with the end portion of the connecting belt, the winding member is rotationally connected with the positioning member, and one end of the connecting belt is connected with the winding member and can wind on the winding member.

Through adopting above-mentioned technical scheme, the connecting band passes the part length adjustable of other setting elements, can make things convenient for four setting elements to pass through the pipeline of coupling assembling adaptation different radial dimensions to can further improve the suitability of pipeline support to the pipeline of different radial dimensions.

Optionally, the anti-slip device further comprises a plurality of anti-slip pads with elastic deformation capability, the anti-slip pads are in one-to-one correspondence with the positioning pieces, and the anti-slip pads are arranged at positions where the positioning pieces contact and abut against the pipeline.

Through adopting above-mentioned technical scheme, can reduce the damage that a plurality of setting elements caused to the pipeline surface when playing the location effect to the pipeline, can improve the pipeline simultaneously and install back setting element for the positional stability of pipeline on the pipeline support to can further make things convenient for the pipeline to install on the pipeline support.

On the other hand, the application also provides a construction method, which adopts the following technical scheme:

a construction method is used for constructing the transportation pipeline bracket with the damping function, and comprises the following steps:

fixedly connecting the frame body with a carrier;

and enabling the pipeline to pass through the yielding port, and enabling the positioning pieces to encircle the pipeline through the connecting assembly.

In summary, the present application includes at least one of the following beneficial effects:

1. vibration of the pipeline in the pipeline transportation process can be effectively reduced, so that the influence of the vibration of the pipeline on normal pipeline transportation can be reduced;

2. the pipeline can be conveniently installed on the pipeline support by a worker, and the operation difficulty in the installation process is reduced;

3. the use requirements of more pipelines with different radial dimensions can be met, and the adjusting process is convenient and quick;

4. the impact of the pipeline vibration on the pipeline support can be reduced, so that the damage of the pipeline vibration to the pipeline support can be reduced.

Drawings

FIG. 1 is a schematic view of a transportation pipeline bracket with shock absorbing function according to an embodiment of the present application;

FIG. 2 is an enlarged view at A in FIG. 1;

FIG. 3 is a cross-sectional view of a position of a rotating member in a transport conduit bracket having a shock absorbing function according to an embodiment of the present application;

FIG. 4 is a cross-sectional view of a support assembly in a transport conduit bracket with shock absorbing function according to an embodiment of the present application;

fig. 5 is an enlarged view at B in fig. 4;

fig. 6 is an enlarged view at C in fig. 4.

Reference numerals illustrate: 1. a frame body; 11. a yielding port; 12. a connection part; 13. a limit groove; 2. a rotating member; 21. a limit part; 3. a support assembly; 31. a fixing member; 32. a movable member; 33. an adjusting member; 34. a locking member; 4. a positioning piece; 5. a connection assembly; 51. a connecting belt; 52. a winding piece; 521. an operation unit; 6. an elastic member; 7. an anti-slip pad; 8. a pipeline.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-6.

The embodiment of the application discloses transportation pipeline support with shock-absorbing function, pipeline are after the pipeline is installed on pipeline support, and in the pipeline transportation process, when vibrations appear in the pipeline, can effectively reduce the vibrations that the pipeline takes place, effectively play the shock attenuation effect to the pipeline to can reduce the pipeline vibrations and normally go on to the pipeline transportation.

Referring to fig. 1 and 2, the pipe bracket includes a frame body 1, a plurality of rotating members 2, a plurality of supporting members 3, a plurality of positioning members 4, and a connecting member 5. In this embodiment, the pipe bracket preferably includes two rotating members 2, four supporting members 3, and four positioning members 4.

Referring to fig. 1 and 3, the frame 1 is in a circular ring structure, a yielding port 11 through which the pipe 8 is installed is formed in the center of the frame 1, the yielding port 11 is cylindrical, and the axis of the yielding port 11 coincides with the axis of the frame 1. The frame body 1 extends outwards along the radial direction to form a connecting part 12 for connecting and fixing the frame body 1 on a carrier, in practical application, the carrier can be a ground, a wall body and the like, in this embodiment, the frame body is not further limited, and the carrier is omitted from expression in the drawings.

The whole rotating piece 2 is also in a circular ring structure, the rotating piece 2 is rotationally connected with the frame body 1, the rotating axis of the rotating piece 2 coincides with the axis of the rotating piece 2, and the two rotating pieces 2 are distributed on the frame body 1 at equal intervals along the axis direction of the frame body 1.

Further, it is preferable that the rotation member 2 restricts the rotation of the frame body 1. The outside of the rotating piece 2 extends outwards along the radial direction to form a limiting part 21, and a limiting groove 13 matched with the limiting part 21 is correspondingly formed in the frame body 1. In this embodiment, for easy observation, it is preferable that the limiting groove 13 is capable of limiting the rotation of the rotating member 2 by 30 ° with respect to the frame body 1; in practical application, the limiting groove 13 limits the rotation angle of the rotating member 2 relative to the frame body 1 to be very small, preferably 1-5 degrees.

Further, the pipe bracket also comprises a plurality of elastic elements 6. In this embodiment, the pipe bracket preferably includes two elastic members 6 in total, and the two elastic members 6 are preferably in one-to-one correspondence with the two rotating members 2.

The elastic piece 6 is installed in the frame body 1, two ends of the elastic piece 6 are fixedly connected with the frame body 1 and the limiting part 21 respectively, and the elastic piece 6 can drive the rotating piece 2 to rotate relative to the frame body 1 until the limiting part 21 abuts against and is kept with one side groove wall of the limiting groove 13, namely, the rotating piece 2 can be kept in a limiting state. In this embodiment, the elastic members 6 are preferably arc springs and tension springs, and the directions in which the two elastic members 6 drive the two rotating members 2 to rotate are preferably the same.

Four supporting component 3 and four setting element 4 all are arranged in the mouth 11 of stepping down, and supporting component 3 makes and is connected between setting element 4 and the rotating member 2, and four supporting component 3 and four setting element 4 one-to-one, and every rotating member 2 all corresponds with two supporting component 3 and two setting element 4.

Referring to fig. 2 and 4, the support assembly 3 has a rod-shaped structure as a whole, and the support assembly 3 includes a rod-shaped fixed member 31 and a rod-shaped movable member 32.

Referring to fig. 5 and 6, one end of the fixing member 31 in the length direction is rotatably connected to the rotating member 2, the rotation axis of the fixing member 31 relative to the rotating member 2 is parallel to the rotation axis of the rotating member 2, and the rotation connection positions of the two fixing members 31 on the same rotating member 2 are located inside the rotating member 2 and located at both ends of the rotating member 2 in the same radial direction.

One end of the movable member 32 in the length direction is rotatably connected to the corresponding positioning member 4, and the rotation axis of the movable member 32 with respect to the positioning member 4 is parallel to the rotation axis of the rotating member 2.

The other end of the movable part 32 in the length direction penetrates into the fixed part 31 and is matched with the fixed part 31 in a penetrating way, the movable part 32 is in sliding connection with the fixed part 31, the sliding direction of the movable part 32 relative to the fixed part 31 is parallel to the length direction of the movable part 32 and the length direction of the fixed part 31, and the movable part 32 is limited to rotate by taking the axis of the movable part as a shaft in the sliding process of the movable part 32 relative to the fixed part 31.

Further, the movable member 32 has a limit in the sliding process relative to the fixed member 31, and the end of the movable member 32 away from the positioning member 4 has a limit structure, which can limit the movable member 32 to slide relative to the fixed member 31 to separate the movable member 32 from the fixed member 31.

Furthermore, the two supporting assemblies 3 corresponding to the same rotating member 2 are different in structure.

Wherein, a supporting component 3 still includes regulating part 33, and regulating part 33 installs in the one end that rotating part 2 was kept away from to mounting part 31, and regulating part 33 and mounting part 31 rotate to be connected, and the axis of rotation of regulating part 33 is parallel with the length direction of mounting part 31. The corresponding movable member 32 is in threaded engagement with the adjusting member 33, the inner side surface of the adjusting member 33 and the outer side surface of the corresponding movable member 32 are both threaded, and the adjusting member 33 is in threaded engagement with the corresponding movable member 32. At this time, the rotation of the control adjusting member 33 relative to the fixed member 31 can control the sliding of the corresponding movable member 32 relative to the fixed member 31.

The other support assembly 3 further comprises a locking member 34, the locking member 34 being removably connected to the corresponding fixing member 31. In this embodiment, the locking member 34 is preferably a bolt structure, and the locking member 34 is preferably detachably connected with the corresponding fixing member 31 in a threaded engagement manner.

After the locking member 34 is mounted on the fixed member 31, the locking member 34 can abut against the surface of the movable member 32, so that the sliding position of the movable member 32 relative to the fixed member 31 is fixed. In this embodiment, it is preferable that the axis of the locking member 34 is perpendicular to the longitudinal direction of the fixing member 31 after the locking member 34 is mounted.

Referring to fig. 2 and 3, the positioning member 4 is in an arc plate structure as a whole, one end of the movable member 32 away from the fixed member 31 is rotatably connected with the convex arc surface of the positioning member 4, and preferably, the position where the movable member 32 is rotatably connected with the positioning member 4 is located at the midpoint of the positioning member 4 along the arc track of the movable member. The concave cambered surface of locating part 4 is used for holding tightly pipeline 8, and four locating parts 4 are with pipeline 8 embracing the location jointly, and four locating parts 4 are in circumference array distribution in the week side of pipeline 8 with the axis of pipeline 8 as the axle this moment.

Further, it is preferable that the concave cambered surface of the positioning member 4 is fixedly provided with an anti-slip pad 7, the anti-slip pad 7 is integrally in an arc-shaped sheet structure matched with the concave cambered surface of the positioning member 4, and the anti-slip pad 7 is preferably made of rubber material and has a certain elastic deformation capability.

When locating piece 4 offsets through the surface contact of slipmat 7 and pipeline 8, slipmat 7 can take place elastic deformation according to the shape adaptability on pipeline 8 surface, makes four locating pieces 4 can reduce the damage to pipeline 8 surface when holding pipeline 8 tightly, can also further guarantee the area of contact of locating piece 4 and pipeline 8, improves locating piece 4 to pipeline 8's location effect.

Referring to fig. 2 and 5, the connection assembly 5 includes a connection band 51 and a winding member 52.

The connecting band 51 is of a sheet-shaped structure as a whole, and the connecting band 51 is elastic and can be bent, so that the winding is convenient. In this embodiment, it is preferable that the connection strap 51 is also made of a rubber material.

The winding piece 52 is integrally in a cylindrical structure, one end of the connecting belt 51 in the length direction is fixedly connected with the winding piece 52, and the connecting belt 51 can be wound on the winding piece 52.

The winding member 52 is installed inside a positioning member 4, and is located at one end of the positioning member 4 along its own arc track. The winding member 52 is rotatably connected to the positioning member 4, and the rotational axis of the winding member 52 coincides with the axis of the winding member itself and is parallel to the rotational axis of the rotating member 2.

Referring to fig. 4 and 5, one end of the connecting belt 51, which is far from the winding member 52, extends out of the positioning member 4 where the winding member 52 is located, sequentially passes through the other three positioning members 4 along the arc track direction of the positioning member 4, and is then connected with one end, which is far from the winding member 52, of the positioning member 4 where the winding member 52 is located. In this embodiment, preferably, one end of the connecting belt 51 far away from the winding member 52 is fixedly connected with the corresponding positioning member 4; in other embodiments, the end of the connecting belt 51 away from the winding member 52 and the corresponding positioning member 4 may be detachably connected by a buckle or the like.

Referring to fig. 2 and 5, further, the winding member 52 extends outward along the direction of its own axis with an operation portion 521, and the operation portion 521 penetrates through the positioning member 4 where the winding member 52 is located, and has a handle structure for facilitating the operator to control the rotation of the winding member 52.

Further, the operation portion 521 is detachably connected with a structure for fixing the winding member 52, that is, a structure capable of stopping the rotation of the winding member 52 relative to the corresponding positioning member 4. In this embodiment, the above structure is preferably a bolt, which abuts against one side surface of the positioning member 4 after being screwed with the operation portion 521, and the rolling member 52 is restricted from rotating relative to the corresponding positioning member 4 by friction between the bolt and the surface of the positioning member 4.

Referring to fig. 1 and 4, the space formed by the four positioning members 4 can be adjusted by adjusting the four supporting members 3 and the connecting members 5, so that the pipe support can be suitable for pipes 8 with different radial dimensions.

When the supporting component 3 is adjusted, the movable piece 32 is controlled to slide relative to the fixed piece 31 towards the direction approaching to the corresponding fixed piece 31, so that the space formed by the encircling of the four positioning pieces 4 can be enlarged; the space formed by the four positioning members 4 can be reduced by controlling the movable member 32 to slide relative to the fixed member 31 in a direction away from the corresponding fixed member 31.

When the connecting assembly 5 is adjusted, the rolling piece 52 is controlled to rotate relative to the corresponding positioning piece 4, so that the extending length of the connecting belt 51 is increased, and the space formed by the encircling of the four positioning pieces 4 can be enlarged; the rolling piece 52 is controlled to rotate relative to the corresponding positioning piece 4, so that the extending length of the connecting belt 51 is reduced, and the space formed by the encircling of the four positioning pieces 4 can be reduced.

Meanwhile, the connecting assembly 5 can also adjust the encircling positioning effect of the four positioning pieces 4 on the pipeline 8, and the control rolling piece 52 rotates relative to the corresponding positioning piece 4 to enable the extending length of the connecting belt 51 to be reduced within a certain range, so that the encircling degree of the positioning piece 4 on the pipeline 8 can be improved.

With reference to fig. 3 and 4, it is further preferred that, after the pipe 8 is mounted on the pipe support, the length direction of the support assembly 3 is inclined with respect to the radial direction of the pipe 8, and the end of the support assembly 3 remote from the pipe 8 is inclined in a direction in which the corresponding rotating member 2 can rotate. In this embodiment, for convenience of illustration, the supporting component 3 is shown in the drawings to be inclined at a large angle; in practice, the degree of inclination of the support assembly 3 may be suitably reduced.

Referring to fig. 2 and 3, when the pipe 8 is vibrated by vibration, the vibration of the pipe 8 drives the at least one positioning member 4 to move along the vibration direction. In practical application, the pipeline 8 rocks at most to drive two setting elements 4 to move along its direction of rocking once along arbitrary direction, in order to be convenient for follow-up expression, the following is described in detail to pipeline 8 rocks the process of driving one setting element 4 to move along its direction of rocking, and pipeline 8 rocks the process of driving two setting elements 4 to move along its direction of rocking and its principle are the same.

When the pipeline 8 shakes to drive one positioning piece 4 to move along the shaking direction, the distance between the positioning piece 4 which is influenced by the shaking of the pipeline 8 and the corresponding rotating piece 2 is reduced, at the moment, the space between the corresponding supporting component 3 and the positioning piece 4 and the corresponding rotating piece 2 is limited, at the moment, the supporting component 3 drives the rotating piece 2 to overcome the plurality of elastic pieces 6 to rotate along with the rotating piece 2, at the moment, the acting force of the plurality of elastic pieces 6 can inhibit the rotating piece 2 to rotate, so that the shaking of the pipeline 8 at the moment is inhibited, and a damping effect is achieved;

in addition, the other supporting component 3 corresponding to the same rotating piece 2 changes the position state between the corresponding positioning piece 4 and the rotating piece 2 due to the rotation of the rotating piece 2, at the moment, the supporting component 3 drives the corresponding positioning piece 4 to move in the direction away from the pipeline 8, at the moment, the positioning piece 4 has the trend of driving the other positioning piece 4 corresponding to the same rotating piece 2 to move in the direction close to the pipeline 8 through the connecting belt 51, so that the shaking of the pipeline 8 at the moment can be further restrained, and the damping effect is further achieved;

meanwhile, as one positioning piece 4 moves along the shaking direction of the pipeline 8 in the two positioning pieces 4 on the same rotating piece 2 at the moment, the other positioning piece 4 moves along the direction away from the pipeline 8; at this time, the two positioning pieces 4 will drive the extending connecting belt 51 to deform, and after the connecting belt 51 deforms, the two positioning pieces 4 corresponding to the other rotating piece 2 will be driven to move towards the direction close to the pipeline 8, so that the pipeline 8 can be effectively restrained from shaking along other directions, and meanwhile, the pipeline 8 can be further restrained from shaking at this time by the positioning pieces 4 being abutted against the pipeline 8, so that the damping effect is further achieved.

The implementation principle of the transportation pipeline support with the shock absorption function is as follows:

after the pipeline 8 is arranged on the pipeline support, when the pipeline 8 shakes due to vibration, the pipeline 8 drives one or two positioning pieces 4 to move along the shaking direction of the pipeline 8, the corresponding rotating piece 2 is driven to rotate after the positioning pieces 4 move along with the positioning pieces, and the rotation of the rotating piece 2 can be restrained by a plurality of elastic pieces 6 in the rotating process of the rotating piece 2, so that the shaking of the pipeline 8 is restrained, and a certain damping effect is achieved; after the rotating piece 2 rotates along with the rotating piece, the moving directions of the two positioning pieces 4 on the same rotating piece 2 are opposite, so that the shaking of the pipeline 8 is restrained, and a certain shock absorption effect can be achieved; meanwhile, the two locating pieces 4 corresponding to the other rotating piece 2 can be driven to further tightly prop against the pipeline 8 through the connecting component 5, so that the vibration of the pipeline 8 along other directions can be restrained, the vibration of the pipeline 8 at the moment can be restrained further, the effect of further shock absorption is achieved, finally the vibration of the pipeline 8 in the transportation process of the pipeline 8 can be effectively reduced, and the influence of the vibration of the pipeline 8 on the normal transportation of the pipeline 8 can be reduced.

The embodiment of the application also discloses a construction method for constructing the transportation pipeline bracket with the shock absorption function, which comprises the following steps:

s1, fixedly connecting the frame body 1 with a carrier.

After the installation position of the pipeline bracket is determined according to the construction track of the pipeline 8, the connecting part 12 of the frame body 1 is fixedly connected with surrounding carriers (such as ground, wall and the like) so that the axis of the yielding port 11 coincides with the construction track of the corresponding pipeline 8.

S2, enabling the pipeline 8 to pass through the yielding port 11, and enabling the plurality of positioning pieces 4 to encircle the pipeline 8 through the connecting assembly 5.

The rolling piece 52 is controlled to rotate so that the connecting belt 51 is excessively extended compared with the radial dimension of the pipeline 8, the pipeline 8 can easily pass through a space formed by the four positioning pieces 4 through the enclosing of the connecting assembly 5, and the axis of the pipeline 8 passing through the yielding port 11 is overlapped with the axis of the yielding port 11 through a temporary supporting structure;

then, two corresponding support assemblies 3 of the rotating piece 2 are adjusted, firstly, one support assembly 3 is adjusted, the adjusting piece 33 is controlled to rotate so that the movable piece 32 slides relative to the fixed piece 31, and the corresponding positioning piece 4 is abutted against the surface of the pipeline 8; the other support component 3 is regulated, the movable component 32 is controlled to slide relative to the fixed component 31 until the corresponding positioning component 4 is abutted against the surface of the pipeline 8, and then the position state of the support component 3 at the moment is locked through the locking component 34; the steps are repeated to adjust the two supporting components 3 corresponding to the other rotating piece 2, so that the four positioning pieces 4 can jointly encircle and position the pipeline 8;

then the rolling piece 52 is controlled to rotate, the extending length of the connecting belt 51 is reduced, the four positioning pieces 4 tightly encircle the pipeline 8, the positioning effect of the four positioning pieces 4 on the pipeline 8 is further improved, and then the rolling piece 52 is controlled to fix the position and the corresponding supporting structure is removed.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (10)

1. The transportation pipeline bracket with the shock absorption function is characterized by comprising a bracket body (1), a plurality of rotating parts (2), a plurality of supporting components (3), a plurality of positioning parts (4) and a connecting component (5);

the frame body (1) is provided with a yielding port (11) for the pipeline (8) to pass through;

the rotating piece (2) is in a circular ring structure, the rotating piece (2) is rotationally connected with the frame body (1), the rotating axis of the rotating piece (2) passes through the abdication port (11), and the rotating axes of the rotating pieces (2) are overlapped;

the positioning pieces (4) are positioned in the yielding port (11), and the connecting assembly (5) connects the positioning pieces (4) with each other, so that the positioning pieces (4) encircle the pipeline (8) passing through the yielding port (11);

the supporting components (3) are in one-to-one correspondence with the positioning pieces (4), and the corresponding positioning pieces (4) are movably connected with the rotating piece (2) by the supporting components (3);

at least two locating pieces (4) are movably connected to the rotating piece (2), when the pipeline (8) vibrates to drive one locating piece (4) to move relative to the corresponding rotating piece (2), the locating pieces (4) drive the corresponding rotating piece (2) to rotate through the supporting component (3), other locating pieces (4) movably connected with the same rotating piece (2) move along with the locating pieces, and the locating pieces (4) driven by the pipeline (8) are restrained to move through the connecting component (5).

2. A transportation pipeline bracket with shock absorbing function according to claim 1, characterized in that the number of the rotating parts (2) is two, and the number of the supporting components (3) and the number of the positioning parts (4) are four;

the rotating piece (2) is connected with two positioning pieces (4) in a co-movable mode, and the positions, connected with the rotating piece (2) through the supporting component (3), of the two positioning pieces (4) are located at two ends of the rotating piece (2) in the same radial direction.

3. A transportation pipeline bracket with shock absorbing function according to claim 2, characterized in that the rotation of the frame body (1) is limited by the rotation piece (2), and in the process that a plurality of rotation pieces (2) rotate relative to the frame body (1), a plurality of positioning pieces (4) can keep encircling the pipeline (8).

4. A transportation pipeline bracket with a shock absorbing function according to claim 3, further comprising a plurality of elastic members (6), wherein the elastic members (6) are arranged in the frame body (1), two ends of each elastic member (6) are respectively connected with the frame body (1) and the rotating member (2), and the elastic members (6) can drive the rotating member (2) to rotate to a limit position and keep the same.

5. A transportation pipeline bracket with shock absorbing function according to claim 2, characterized in that the supporting component (3) comprises a fixed part (31) and a movable part (32), the fixed part (31) and the movable part (32) are respectively movably connected with the corresponding rotating part (2) and the corresponding positioning part (4), and the movable part (32) is slidably connected with the fixed part (31).

6. The transportation pipeline bracket with the shock absorption function according to claim 5, wherein one supporting component (3) of the two supporting components (3) corresponding to the same rotating component (2) further comprises an adjusting component (33), the adjusting component (33) is rotationally connected with the fixed component (31), the rotating axis of the adjusting component (33) is parallel to the sliding direction of the movable component (32), the adjusting component (33) is sleeved outside the movable component (32) and is in threaded fit with the movable component (32), and the movable component (32) can be controlled to slide relative to the fixed component (31) by rotating the adjusting component (33);

the other supporting component (3) further comprises a plurality of locking pieces (34), the locking pieces (34) are detachably connected with the fixing pieces (31), and the locking pieces (34) can be abutted against the movable pieces (32) after being connected with the fixing pieces (31) so that the relative positions of the movable pieces (32) and the fixing pieces (31) are fixed.

7. A transportation pipeline bracket with shock absorbing function according to claim 2, characterized in that the connecting assembly (5) comprises a connecting belt (51) with elasticity, both ends of the connecting belt (51) are connected with the same positioning piece (4), and the connecting belt (51) passes through other positioning pieces (4).

8. The transportation pipeline bracket with the shock absorbing function according to claim 7, wherein the connecting assembly (5) further comprises a winding piece (52), the winding piece (52) is arranged on the positioning piece (4) connected with the end part of the connecting belt (51), the winding piece (52) is rotationally connected with the positioning piece (4), and one end of the connecting belt (51) is connected with the winding piece (52) and can wind on the winding piece (52).

9. The transportation pipeline bracket with the shock absorption function according to claim 1, further comprising a plurality of anti-slip pads (7) with elastic deformation capability, wherein the anti-slip pads (7) are in one-to-one correspondence with the positioning pieces (4), and the anti-slip pads (7) are arranged at positions where the positioning pieces (4) are contacted and abutted with the pipeline (8).

10. A construction method for constructing a transportation pipeline bracket with a shock absorbing function as set forth in any one of claims 1 to 9, comprising the steps of:

fixedly connecting the frame body (1) with a carrier;

the pipeline (8) passes through the yielding port (11), and the positioning pieces (4) encircle the pipeline (8) through the connecting assembly (5).