CN220286630U - Pipeline supporting device for hydraulic engineering - Google Patents

Abstract

The utility model relates to a pipeline supporting device for hydraulic engineering, which aims to solve the technical problem that excessive stress and easy wire removal of threads connected by threads can be caused by excessive rotation of a current adjusting rod, and comprises a supporting plate and a fastening structure; two fastening structures are symmetrically arranged on the supporting plate; each fastening structure comprises a connecting block, a movable block, a clamping block, a spring and a positioning assembly; the connecting block is arranged in the movable area of the supporting plate in a sliding manner; wherein the connecting block is connected with a traveling mechanism arranged in the supporting plate; the movable block is arranged in the connecting block in a penetrating way; the clamping block is fixedly arranged at the inner end of the movable block; the two springs are symmetrically arranged between the clamping block and the connecting block; the positioning assembly is arranged on the outer side of the connecting block, and the positioning assembly has the advantages that the excessive moving distance is provided for the connecting block, the thread advancing structure in the supporting plate is not damaged, and thread stripping is not caused.

Description

Pipeline supporting device for hydraulic engineering

Technical Field

The utility model relates to the technical field of water conservancy pipeline laying, in particular to a pipeline supporting device for water conservancy projects.

Background

The hydraulic engineering refers to various projects such as flood control, drainage, irrigation, hydroelectric generation, water supply, beach treatment, water and soil conservation, water resource protection and the like, including projects such as new construction, expansion, reconstruction, reinforcement, repair, demolition and the like, and matched and auxiliary projects thereof, and the hydraulic engineering is mainly used for pipelines, and the pipeline laying is of great importance.

The utility model discloses a supporting device for pipeline laying for hydraulic engineering, which comprises a supporting table, a rotating rod, a spiral drill bit, a threaded hole and a rotating groove, wherein the rotating rod penetrates through the supporting table, the spiral drill bit is arranged on the rotating rod, a limiting cylinder is arranged on the supporting table, a lifting rod is connected to the limiting cylinder, a rotating disc is arranged on the lifting rod, a supporting rod is connected to the rotating disc, a limiting rod is connected to the supporting rod, an adjusting rod penetrates through the supporting rod, and a first rotating disc is connected to the adjusting rod. The height of the supporting rod can be conveniently adjusted through the rotation of the lifting rod, and the water conservancy pipeline can be horizontally limited synchronously through the rotation of the adjusting rod, so that the water conservancy pipeline is more convenient.

Although the device has more beneficial effects, the following problems still exist: the device realizes the movement of the limiting rod by the rotation of the adjusting rod through the threads when the device clamps and positions the pipeline, when the limiting rod contacts the pipeline, the adjusting rod can excessively rotate to achieve larger abutting force in order to abut against the pipeline, and the threads in threaded connection are excessively stressed and easily take off threads, so that the movement of the limiting rod is influenced after the threads are taken off. In view of this, we propose a pipeline supporting device for hydraulic engineering.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art, adapt to the actual needs, and provide a pipeline supporting device for hydraulic engineering, so as to solve the technical problem that excessive stress and easy wire removal of threads connected by threads can be caused by excessive rotation of a current adjusting rod.

In order to achieve the purpose of the utility model, the technical scheme adopted by the utility model is as follows: the pipeline supporting device for the hydraulic engineering comprises a supporting plate and a fastening structure;

two fastening structures are symmetrically arranged on the supporting plate;

each fastening structure comprises a connecting block, a movable block, a clamping block, a spring and a positioning assembly;

the connecting block is arranged in the movable area of the supporting plate in a sliding manner; wherein the connecting block is connected with a traveling mechanism arranged in the supporting plate; the movable block is arranged in the connecting block in a penetrating way; the clamping block is fixedly arranged at the inner end of the movable block; the two springs are symmetrically arranged between the clamping block and the connecting block; the locating component is arranged outside the connecting block.

Preferably, the connecting block is provided with a through hole, and the through hole is matched with the movable block.

Preferably, a limiting block is fixedly arranged at the outer end of the movable block, and the limiting block is transversely arranged relative to the through hole.

Preferably, at least one baffle is fixedly arranged at the bottom of the clamping block, and the baffle is in contact with the supporting plate.

Preferably, the positioning component comprises a U-shaped block, a rotating wheel, a screw rod, an internal threaded pipe, a limiting rod and a limiting hole;

the U-shaped block is fixedly arranged on the connecting block; the rotating wheel is rotationally arranged in the U-shaped block; the bottom end of the rotating wheel is rotationally connected with the U-shaped block through a rotating shaft; the screw rod penetrates through the U-shaped block; wherein the inner end of the screw is fixedly connected with the top end of the rotating wheel; the internal thread pipe is sleeved on the screw rod; wherein the internally threaded pipe is in threaded connection with the screw rod; wherein the internal thread pipe is in plug-in fit with a plurality of jacks formed on the positioning side of the movable block; the four limiting rods are fixedly arranged on the U-shaped block in an annular array; the screw rods are positioned in the middle of the four limiting rods; the four limiting holes are formed in the opening end of the internal thread pipe in an annular array; wherein, the spacing hole with the gag lever post grafting cooperation.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the connecting block, the movable block, the clamping block, the spring and the positioning assembly are arranged, the connecting block is driven to move through the thread advancing structure in the supporting plate, the clamping block continuously moves after contacting the pipeline to be clamped, the clamping block props against the pipeline, the outer end of the movable block penetrates out of the connecting block, and the spring is further compressed; under the condition that the thread advancing structure in the supporting plate excessively rotates, the distance between the connecting block and the clamping block provides the distance for the excessive movement of the connecting block, the thread advancing structure in the supporting plate cannot be damaged, and the thread stripping condition cannot occur. The problem of adjust the excessive atress of screw thread that can lead to threaded connection and easily take off the silk is solved.

2. According to the utility model, the U-shaped block, the rotating wheel, the screw rod, the internal thread pipe, the limiting rod and the limiting hole are arranged, the clamping blocks are propped against the pipeline, under the condition that the thread advancing structure in the supporting plate excessively rotates, the outer end of the movable block penetrates out of the connecting block, the rotating wheel is rotated, the screw rod rotates to drive the internal thread pipe to move, and the internal thread pipe moves upwards and is inserted into the jack, so that the movable block and the connecting block are positioned, the clamping blocks are kept stable, the pipeline clamped by the two clamping blocks is kept stable, and left and right shaking of the pipeline is avoided. The setting of gag lever post and spacing hole makes the internal thread pipe only at vertical removal for the screw rod, and the internal thread pipe can not rotate along with the screw rod.

Drawings

FIG. 1 is a schematic diagram of a front view of the present utility model;

FIG. 2 is a schematic view of a fastening structure of the present utility model;

FIG. 3 is an exploded view of the fastening structure of the present utility model;

FIG. 4 is an exploded view of the positioning assembly of the present utility model;

in the figure: 1. a support plate; 2. a fastening structure;

201. a connecting block; 202. a spring; 203. clamping blocks; 204. a baffle; 205. a movable block; 206. a positioning assembly; 207. a limiting block;

2011. a through hole;

2051. a jack;

2061. a U-shaped block; 2062. a rotating shaft; 2063. a rotating wheel; 2064. a limit rod; 2065. a limiting hole; 2066. an internally threaded tube; 2067. and (3) a screw.

Detailed Description

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings:

example 1: a pipeline supporting device for hydraulic engineering, see fig. 1 to 4, comprises a supporting plate 1 and a fastening structure 2; the two fastening structures 2 are symmetrically arranged on the support plate 1; each fastening structure 2 comprises a connection block 201, a movable block 205, a clamping block 203, a spring 202 and a positioning assembly 206; the connecting block 201 is arranged in the movable area of the supporting plate 1 in a sliding manner; wherein the connecting block 201 is connected with a travel mechanism arranged in the supporting plate 1; the movable block 205 is arranged in the connecting block 201 in a penetrating way; the clamping block 203 is fixedly arranged at the inner end of the movable block 205; two springs 202 are symmetrically arranged between the clamping block 203 and the connecting block 201, two ends of each spring 202 are fixedly connected with one side opposite to the clamping block 203 and the connecting block 201 respectively, and the elastic coefficient of each spring 202 is selected by a person skilled in the art according to actual conditions; the positioning assembly 206 is disposed outside the connection block 201.

According to the utility model, through the arrangement of the connecting block 201, the movable block 205, the clamping block 203, the spring 202 and the positioning component 206, the connecting block 201 is driven to move through a thread advancing structure (not shown in the figure and disclosed in the comparison document) in the supporting plate 1, the clamping block 203 continuously moves the connecting block 201 after contacting a pipeline to be clamped, the clamping block 203 butts against the pipeline, the outer end of the movable block 205 penetrates out of the connecting block 201, the spring 202 is further compressed, and under the condition that the thread advancing structure in the supporting plate 1 excessively rotates, the distance between the connecting block 201 and the clamping block 203 provides the excessive moving distance for the connecting block 201, so that the thread advancing structure in the supporting plate 1 is not damaged, and the condition of thread stripping is avoided. The problem of adjust the excessive atress of screw thread that can lead to threaded connection and easily take off the silk is solved.

The connection block 201 is provided with a through hole 2011, and the through hole 2011 is adapted to the movable block 205. The through hole 2011 is configured to enable the connection block 201 to move relative to the movable block 205, so that an excessive distance of the length of the movable block 205 is left between the connection block 201 and the clamping block 203.

Further, a stopper 207 is fixed to the outer end of the movable block 205, and the stopper 207 is disposed transversely to the through hole 2011. The stopper 207 is provided so that the movable block 205 does not disengage from the connection block 201.

Still further, the front and rear ends of the bottom of the clamping block 203 are respectively fixedly provided with a baffle 204, and the baffle 204 is in contact with the supporting plate 1. Since the clamping blocks 203 move with the connecting blocks 201 before contacting the pipeline, the clamping blocks 203 correspond to grooves (not shown in the figure and disclosed in the comparison document) where the travelling structure of the supporting plate 1 is located, and in order to keep the clamping blocks 203 stable, the baffle 204 contacts the upper surface of the supporting plate 1 to provide supporting force for the clamping blocks 203.

Illustratively, the positioning assembly 206 includes a U-shaped block 2061, a runner 2063, a screw 2067, an internally threaded tube 2066, a stop rod 2064, and a stop bore 2065; the U-shaped block 2061 is fixedly arranged on the connecting block 201; the rotating wheel 2063 is rotatably arranged in the U-shaped block 2061; wherein, the bottom end of the rotating wheel 2063 is rotationally connected with the U-shaped block 2061 through a rotating shaft 2062; the screw 2067 is arranged in the U-shaped block 2061 in a penetrating way; wherein, the inner end of the screw 2067 is fixedly connected with the top end of the rotating wheel 2063; the internal thread tube 2066 is sleeved on the screw rod 2067; wherein the internally threaded tube 2066 is threadably coupled to a screw 2067; wherein, the internal thread tube 2066 is in plug-in fit with a plurality of jacks 2051 arranged on the positioning side of the movable block 205; the four limit rods 2064 are fixedly arranged on the U-shaped block 2061 in an annular array; wherein the screw 2067 is positioned in the middle of the four stop bars 2064; four limiting holes 2065 are arranged at the opening end of the internal thread tube 2066 in an annular array; wherein, the limit hole 2065 is inserted and matched with the limit rod 2064. According to the utility model, the U-shaped block 2061, the rotating wheel 2063, the screw 2067, the internal thread tube 2066, the limiting rod 2064 and the limiting hole 2065 are arranged, the clamping block 203 is propped against a pipeline, under the condition that the thread advancing structure in the supporting plate 1 excessively rotates, the outer end of the movable block 205 penetrates out of the connecting block 201, the rotating wheel 2063 is rotated, the screw 2067 rotates to drive the internal thread tube 2066 to move, and the internal thread tube 2066 moves upwards and is inserted into the inserting hole 2051, so that the movable block 205 and the connecting block 201 are positioned, the clamping block 203 is kept stable, and the pipeline clamped by the two clamping blocks 203 is kept stable, thereby preventing the pipeline from shaking left and right. The positioning of the stopper rod 2064 and the stopper hole 2065 is such that the internally threaded tube 2066 moves only longitudinally with respect to the screw rod 2067 and the internally threaded tube 2066 does not rotate with the screw rod 2067.

Working principle: when the device is used, after a longitudinal adjusting mechanism (not shown in the figure and the comparison document is disclosed) connected with the supporting plate 1 is used for adjusting the height, a pipeline is placed on the supporting plate 1, the connecting block 201 is driven to move through a thread advancing structure in the supporting plate 1, the clamping block 203 continuously moves the connecting block 201 after contacting the pipeline to be clamped, the clamping block 203 butts against the pipeline, the outer end of the movable block 205 penetrates out of the connecting block 201, the spring 202 is further compressed, under the condition that the thread advancing structure in the supporting plate 1 excessively rotates, the distance between the connecting block 201 and the clamping block 203 is provided for the excessive moving distance of the connecting block 201, the thread advancing structure in the supporting plate 1 is not damaged, the thread is not broken, the screw 2063 is rotated clockwise, the screw 2067 is rotated clockwise to drive the internal thread pipe 2066 to move upwards, and the internal thread pipe 2066 is correspondingly inserted into the jack 2051, so that the movable block 205 and the connecting block 201 are positioned, the clamping blocks 203 are kept stable, and the pipeline clamped by the two clamping blocks 203 is kept stable, and the pipeline is prevented from shaking left and right; after the pipeline is installed, the rotating wheel 2063 is rotated anticlockwise, the screw 2067 is rotated anticlockwise to drive the internal thread pipe 2066 to move downwards to be separated from the insertion hole 2051, the two fastening structures 2 are moved away from each other by the thread advancing structure in the supporting plate 1 to loosen the pipeline, and the supporting device is taken away.

The embodiments of the present utility model are disclosed as preferred embodiments, but not limited thereto, and those skilled in the art will readily appreciate from the foregoing description that various modifications and variations can be made without departing from the spirit of the present utility model.

Claims (5)

1. Pipeline strutting arrangement for hydraulic engineering, including backup pad (1), its characterized in that still includes:

two fastening structures (2) symmetrically arranged on the support plate (1);

each of the fastening structures (2) comprises:

the connecting block (201) is arranged in the movable area of the supporting plate (1) in a sliding manner;

wherein the connecting block (201) is connected with a travel mechanism arranged in the supporting plate (1);

the movable block (205) is arranged in the connecting block (201) in a penetrating way;

the clamping block (203) is fixedly arranged at the inner end of the movable block (205);

at least one spring (202) arranged between the clamping block (203) and the connecting block (201);

-a positioning assembly (206) arranged outside the connection block (201).

2. The pipeline supporting device for hydraulic engineering according to claim 1, wherein the connecting block (201) is provided with a through hole (2011), and the through hole (2011) is matched with the movable block (205).

3. The pipeline supporting device for hydraulic engineering according to claim 2, wherein a limiting block (207) is fixedly arranged at the outer end of the movable block (205), and the limiting block (207) is transversely arranged relative to the through hole (2011).

4. A pipeline supporting device for hydraulic engineering according to claim 1, characterized in that at least one baffle plate (204) is fixedly arranged at the bottom of the clamping block (203), and the baffle plate (204) is in contact with the supporting plate (1).

5. A hydraulic engineering pipe support device according to claim 1, wherein the positioning assembly (206) comprises:

the U-shaped block (2061) is fixedly arranged on the connecting block (201);

a rotating wheel (2063) rotatably arranged in the U-shaped block (2061);

wherein the bottom end of the rotating wheel (2063) is rotationally connected with the U-shaped block (2061) through a rotating shaft (2062);

the screw rod (2067) is arranged in the U-shaped block (2061) in a penetrating way;

wherein, the inner end of the screw (2067) is fixedly connected with the top end of the rotating wheel (2063);

an internally threaded tube (2066) which is sleeved on the screw (2067);

wherein the internally threaded tube (2066) is threadedly connected to the screw (2067);

wherein the internal thread pipe (2066) is in plug-in fit with a plurality of jacks (2051) formed on the positioning side of the movable block (205);

a plurality of limit rods (2064) which are fixedly arranged on the U-shaped blocks (2061) in an annular array;

wherein the screw (2067) is positioned in the middle of the limiting rods (2064);

a plurality of limiting holes (2065) which are arranged at the opening end of the internal thread pipe (2066) in an annular array;

wherein the limit hole (2065) is in plug-in fit with the limit rod (2064).