CN221171085U - Pipeline positioning device for municipal gas engineering - Google Patents

Abstract

The utility model relates to a pipeline positioning device for municipal gas engineering, which comprises a base unit, two adjusting units, two placing units, two stabilizing units and a plurality of locking units, wherein the base unit is arranged on a horizontal plane and is connected with an external embedded part; the two adjusting units are symmetrically arranged at the top end of the base unit and are respectively and movably connected with the base unit; the two placing units are detachably connected with the corresponding adjusting units respectively and are used for placing the pipeline and moving along the vertical direction and moving along the horizontal direction under the action of the adjusting units. The gas pipeline fixing device has the advantages that the gas pipelines are limited and fixed by the placing unit and the stabilizing unit, so that the stability of the two adjacent gas pipelines after being butted is improved; the placement unit and the base unit are detachably connected and installed through threads, and the placement unit can be adjusted to be positioned at the relative position of the base unit, so that the longitudinal adjustment of the placement unit is realized.

Description

Pipeline positioning device for municipal gas engineering

Technical Field

The utility model relates to the technical field of positioning devices for municipal gas pipelines, in particular to a pipeline positioning device for municipal gas engineering.

Background

The gas pipe is a special pipeline for conveying combustible gas, and the metal gas pipe hose is used for replacing the traditional buckle mode rubber hose, so that the defects that the rubber hose is easy to fall off, easy to age, easy to bite by insects and short in service life can be overcome, when adjacent gas pipelines are in butt joint, the problem that the gas leakage is caused by the fact that the adjacent gas pipelines are not firm in connection and easy to shift or fall off after long-term use exists, and therefore a pipeline positioning device is needed to support the gas pipelines.

The existing gas pipeline fixing and positioning device generally adopts a plurality of screws to strengthen the gas pipeline fixing and positioning device, when the position of the gas pipeline fixing and positioning device needs to be adjusted, the screws are loosened, the adjustment can be completed, the operation of the gas pipeline fixing and positioning device is complex, and therefore the use effect of the gas pipeline fixing device is reduced.

At present, no effective solution is proposed for the problem of inconvenient position adjustment of the positioning device for the gas pipeline in the related technology.

Disclosure of utility model

The utility model aims to overcome the defects in the prior art, and provides a pipeline positioning device for municipal gas engineering, so as to solve the problem of inconvenient position adjustment of the positioning device for the gas pipeline in the related art.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

A pipe locating device for municipal gas engineering, comprising:

The base unit is arranged on the horizontal plane and is connected with the external embedded part;

The two adjusting units are symmetrically arranged at the top end of the base unit and are respectively and movably connected with the base unit;

The two placing units are detachably connected with the corresponding adjusting units respectively and are used for placing the pipeline and moving in the vertical direction and moving in the horizontal direction under the action of the adjusting units;

The two stabilizing units are respectively arranged above the corresponding placing units, are respectively detachably connected with the corresponding placing units and are used for fixing the pipeline;

The locking units are detachably connected with the corresponding stabilizing units and the placing units respectively and used for fixing the stabilizing units.

In some of these embodiments, the base unit comprises:

the base element is arranged on the horizontal plane and is connected with the external embedded part;

The two first sliding elements are symmetrically arranged at the top end of the base element and are respectively connected with the corresponding adjusting units in a sliding way;

The two first rotating elements are respectively arranged at the side parts of the base element, are respectively communicated with the corresponding first sliding elements, and are respectively connected with the corresponding adjusting units in a rotating way.

In some of these embodiments, the base unit further comprises:

The two second rotating elements are respectively arranged in the base element, are respectively communicated with the corresponding first sliding elements and are respectively connected with the corresponding adjusting units in a rotating way.

In some of these embodiments, the adjustment unit comprises:

The bottom end of the second sliding element is in sliding connection with the base unit, and the top end of the second sliding element protrudes out of the base unit and is detachably connected with the placing unit;

The first connecting element is arranged at the top end of the second sliding element and is detachably connected with the placing unit;

And the driving element is respectively and rotatably connected with the bottom end of the second sliding element and the base unit and is used for driving the second sliding element to move.

In some of these embodiments, the adjustment unit further comprises:

And the third rotating element penetrates through the bottom end of the second sliding element and is rotationally connected with the driving element.

In some of these embodiments, the placement unit includes:

The placing element is movably arranged above the adjusting unit and is used for placing the pipeline and moving along the horizontal direction under the action of the adjusting unit;

the top end of the second connecting element is rotationally connected with the placing element, and the bottom end of the second connecting element is detachably connected with the adjusting unit and is used for driving the placing element to move along the vertical direction;

The two first supporting elements are symmetrically arranged on two sides of the placing element;

the two third connecting elements penetrate through the corresponding first supporting elements respectively and are detachably connected with the corresponding locking units;

The first limiting elements are respectively arranged at the end parts of the corresponding first supporting elements and are detachably connected with the corresponding stabilizing units.

In some of these embodiments, the placement unit further comprises:

The auxiliary elements are arranged at the top ends of the second connecting elements and used for assisting in driving the second connecting elements to rotate.

In some of these embodiments, the stabilizing unit comprises:

The fixing element is detachably arranged above the placing unit and is used for fixing the pipeline;

the two second supporting elements are symmetrically arranged on two sides of the stabilizing element and are detachably connected with the corresponding locking units;

The second limiting elements are respectively arranged at the end parts of the corresponding second supporting elements and are detachably connected with the placing unit.

In some of these embodiments, the stabilization unit further comprises:

And the two fourth connecting elements penetrate through the corresponding second supporting elements and are detachably connected with the corresponding locking units.

In some of these embodiments, the locking unit comprises:

And the locking element is detachably connected with the corresponding stabilizing unit and the placing unit respectively and is used for fixing the stabilizing unit.

Compared with the prior art, the utility model has the following technical effects:

According to the pipeline positioning device for municipal gas engineering, the gas pipelines are limited and fixed by the placement unit and the stabilizing unit, so that the stability of the two adjacent gas pipelines after being butted is improved; the placement unit and the base unit are detachably connected and installed through threads, and the relative position of the placement unit on the base unit can be adjusted, so that the longitudinal adjustment of the placement unit is realized; the transverse position of the placing unit can be adjusted by the adjusting unit so as to meet the use requirement.

Drawings

FIG. 1 is a schematic perspective view of a pipe positioner according to an embodiment of the present utility model;

FIG. 2 is an exploded view of a pipe positioner according to an embodiment of the present utility model;

FIG. 3 is a schematic perspective view of a pipe positioner according to an embodiment of the present utility model with a pipe installed therein;

FIG. 4 is a pipe positioner of a base unit according to an embodiment of the present utility model;

FIG. 5a is an exploded view of an adjustment unit according to an embodiment of the present utility model;

FIG. 5b is a cross-sectional view of a portion of an adjustment unit according to an embodiment of the utility model;

fig. 6 is an exploded view of a placement unit according to an embodiment of the present utility model;

FIG. 7 is a schematic perspective view of a stabilizing unit according to an embodiment of the present utility model;

Fig. 8 is a schematic perspective view of a locking unit according to an embodiment of the present utility model;

wherein the reference numerals are as follows: 100. a base unit; 101. a base member; 102. a first sliding element; 103. a first rotating element; 104. a second rotating element;

200. An adjusting unit; 201. a second sliding element; 202. a first connecting element; 203. a driving element; 204. a third rotating element;

300. a placement unit; 301. placing the element; 302. a second connecting element; 303. a first support element; 304. a third connecting element; 305. a first limiting element; 306. an auxiliary element;

400. A stabilizing unit; 401. a stabilizing element; 402. a second support element; 403. a second limiting element; 404. a fourth connecting element;

500. a locking unit; 501. a locking element.

Detailed Description

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

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

The utility model is further described below with reference to the drawings and specific examples, which are not intended to be limiting.

An exemplary embodiment of the present utility model, as shown in fig. 1, 2 and 3, a pipe positioning apparatus for municipal gas works, includes a base unit 100, two adjusting units 200, two placing units 300, two stabilizing units 400 and a plurality of locking units 500. The base unit 100 is arranged on a horizontal plane and is connected with an external embedded part; the two adjusting units 200 are symmetrically arranged at the top end of the base unit 100 and are respectively and movably connected with the base unit 100; the two placing units 300 are detachably connected with the corresponding adjusting units 200 respectively, and are used for placing pipelines and moving in the vertical direction and moving in the horizontal direction under the action of the adjusting units 200; the two stabilizing units 400 are respectively arranged above the corresponding placing units 300, and are respectively detachably connected with the corresponding placing units 300 for fixing the pipeline; the locking units 500 are detachably connected with the corresponding fixing units 400 and the placing units 300, respectively, for fixing the fixing units 400.

Specifically, the base unit 100 is fixedly connected with an external embedded part; mounting the placing unit 300 to the adjusting unit 200, placing the pipe in the placing unit 300, adjusting the placing height using the placing unit 300, and adjusting the position of the placing unit 300 using the adjusting unit 200; the pipe is fixed to the placing unit 300 by the cooperation of the securing unit 400 and the locking unit 500.

As shown in fig. 4, the base unit 100 includes a base member 101, two first slide members 102, and two first rotation members 103. Wherein the base element 101 is arranged on the horizontal plane and is connected with an external embedded part; the two first sliding elements 102 are symmetrically arranged at the top end of the base element 101 and are respectively connected with the corresponding adjusting units 200 in a sliding manner; the two first rotating elements 103 are respectively disposed at the side portions of the base element 101, respectively communicate with the corresponding first sliding elements 102, and are respectively rotatably connected with the corresponding adjusting units 200.

The base element 101 is rectangular in cross-section.

In some of these embodiments, the base member 101 is made of steel construction.

In some of these embodiments, the base element 101 is a mounting base plate.

The first sliding element 102 has a convex cross-section. Specifically, the first slide element 102 includes an outer slide channel and an inner slide channel. Wherein the outer chute is arranged at the top end of the base element 101 and is in sliding connection with the adjusting unit 200; the inner slide groove is provided inside the base member 101, communicates with the outer slide groove, and is slidably connected with the adjusting unit 200.

The dimensions of the outer chute match those of the base member 101. Typically, the length of the outer chute is less than the length of the base member 101, the width of the outer chute is less than the width of the base member 101, and the depth of the outer chute is less than the height of the base member 101.

The dimensions of the inner chute match those of the base member 101. Typically, the length of the inner slide groove is smaller than the length of the base element 101, the width of the inner slide groove is smaller than the width of the base element 101, and the depth of the inner slide groove is smaller than the height of the base element 101.

The size of the inner chute is matched with that of the outer chute. Generally, the length of the inner chute is equal to the length of the outer chute, the width of the inner chute is greater than the width of the outer chute, and the depth of the inner chute is greater than the depth of the outer chute.

In some of these embodiments, the first sliding element 102 is a sliding channel.

The first rotating element 103 communicates with the inner slide groove.

The first rotary element 103 has a circular cross section.

The first rotating element 103 is dimensioned to match the dimensions of the base element 101. Typically, the diameter of the first rotational element 103 is smaller than the width/height of the base element 101, and the axial dimension (e.g. depth) of the first rotational element 103 is smaller than the length of the base element 101.

Wherein the axial dimension (e.g., depth) of the first rotating element 103 is equal to the thickness of the sidewall formed by the base element 101 and the first sliding element 102.

The first rotating element 103 is dimensioned to match the dimensions of the inner chute. Typically, the diameter of the first rotating element 103 is smaller than the width/depth of the inner slide groove.

In some of these embodiments, the first rotating element 103 is a first rotating bore.

Further, the base unit 100 further comprises two second rotating elements 104. The two second rotating elements 104 are respectively disposed inside the base element 101, respectively communicate with the corresponding first sliding elements 102, and are respectively rotatably connected with the corresponding adjusting units 200.

Specifically, the second rotating element 104 communicates with the inner chute.

The second rotating element 104 has a circular cross section.

The dimensions of the second rotating element 104 match those of the base element 101. Typically, the diameter of the second rotational element 104 is smaller than the width/height of the base element 101, and the axial dimension (e.g. depth) of the second rotational element 104 is smaller than the length of the base element 101.

The second rotating element 104 is sized to match the size of the inner chute. Typically, the diameter of the second rotational element 104 is smaller than the width/depth of the inner slide groove.

The dimensions of the second rotating element 104 match those of the first rotating element 103. Generally, the diameter of the second rotating element 104 is equal to the diameter of the first rotating element 103.

In some of these embodiments, the second rotating element 104 is a second rotating bore.

As shown in fig. 5a, 5b, the adjustment unit 200 comprises a second sliding element 201, a first connecting element 202 and a driving element 203. Wherein, the bottom end of the second sliding element 201 is slidably connected with the base unit 100, and the top end of the second sliding element 201 protrudes out of the base unit 100 and is detachably connected with the placement unit 300; the first connecting element 202 is disposed at the top end of the second sliding element 201 and is detachably connected with the placement unit 300; the driving element 203 is rotatably connected to the bottom end of the second sliding element 201 and the base unit 100, respectively, and is used for driving the second sliding element 201 to move.

Specifically, the bottom end of the second sliding element 201 is slidingly connected to the first sliding element 102; the tip of the second slide member 201 is provided protruding from the first slide member 102; the driving element 203 is rotatably connected to the first rotating element 103 and the second rotating element 104, respectively.

The second slide element 201 has a convex cross section. Specifically, the second slide member 201 includes an outer slide and an inner slide. Wherein, the outer slide block is connected with the outer slide groove in a sliding way; the inner slide block is arranged at the bottom of the outer slide block and is in sliding connection with the inner slide groove.

The size of the outer sliding block is matched with that of the outer sliding groove. Generally, the length of the outer slide is smaller than the length of the outer slide, the width of the outer slide is equal to the width of the outer slide, and the height of the outer slide is greater than the depth of the outer slide.

The size of the inner sliding block is matched with that of the inner sliding groove. Generally, the length of the inner slide is equal to the width of the inner slide groove, the width of the inner slide is smaller than the length of the inner slide groove, and the height of the inner slide is equal to the depth of the inner slide groove.

The size of the inner slide block is matched with that of the outer slide block. Generally, the length of the inner slide is greater than the width of the outer slide, the width of the inner slide is equal to the length of the outer slide, and the height of the inner slide is less than the height of the outer slide.

In some of these embodiments, the second sliding element 201 is made of a metal material.

In some of these embodiments, the second slide element 201 is a slider.

The first connecting element 202 is arranged at the top end of the outer slide.

The first connecting element 202 has a circular cross-section.

The first connecting element 202 is dimensioned to match the dimensions of the outer slide. Typically, the diameter of the first coupling element 202 is smaller than the length/width of the outer slider and the axial dimension (e.g., depth) of the first coupling element 202 is smaller than the height of the outer slider.

In some of these embodiments, the first connecting element 202 is a first threaded bore.

The driving element 203 is rotatably connected to the inner slide.

The driving element 203 has a circular cross section. Specifically, the driving member 203 includes a screw and a socket. The screw rod is respectively connected with the bottom end of the second sliding element 201, the first rotating element 103 and the second rotating element 104 in a rotating way and is used for driving the second sliding element 201 to move; the slot is arranged at the end part of the screw rod and is detachably connected with an external hexagonal wrench, and the slot is used for inserting the hexagonal wrench into the screw rod so as to twist the screw rod.

The size of the screw rod is matched with the size of the inner slide block. Typically, the diameter of the screw is smaller than the length/height of the inner slide and the axial dimension of the screw is larger than the width of the inner slide.

The size of the screw is matched to the size of the first rotating element 103 (the second rotating element 104). Typically, the diameter of the screw is equal to the diameter of the first rotating element 103 (second rotating element 104), and the axial dimension (e.g., depth) of the screw is greater than the axial dimension (e.g., depth) of the first rotating element 103 (second rotating element 104).

The size of the slot is matched with the size of the screw rod. Typically, the radial dimension of the socket is less than the diameter of the screw and the axial dimension (e.g., depth) of the socket is less than the axial dimension of the screw.

In some of these embodiments, the drive element 203 is not separately rotationally coupled to the second rotational element 104. For example, the driving element 203 is connected to the second rotating element 104 via a bearing housing.

In some of these embodiments, the driving element 203 is made of a metal material.

Further, the adjusting unit 200 further comprises a third rotating element 204. The third rotating element 204 is disposed through the bottom end of the second sliding element 201 and is rotatably connected to the driving element 203.

Specifically, the third rotating element 204 is disposed through the inner slide, and is disposed coaxially with the first rotating element 103 and the second rotating element 104.

More specifically, the third rotational element 204 is in rotational connection with the screw.

The third rotational element 204 has a circular cross-section.

The third rotational element 204 is sized to match the size of the inner slide. Typically, the diameter of the third rotational element 204 is smaller than the length/height of the inner slide, and the axial dimension (e.g., depth) of the third rotational element 204 is equal to the length of the inner slide.

The third rotational element 204 is sized to match the size of the lead screw. Typically, the diameter of the third rotational element 204 is equal to the diameter of the screw, and the axial dimension (e.g., depth) of the third rotational element 204 is less than the axial dimension of the screw.

The size of the third rotating element 204 matches the size of the first rotating element 103 (the second rotating element 104). Generally, the diameter of the third rotational element 204 is equal to the diameter of the first rotational element 103 (the second rotational element 104), and the axial dimension (e.g., depth) of the third rotational element 204 is greater than the axial dimension (e.g., depth) of the first rotational element 103 (the second rotational element 104).

In some of these embodiments, the third rotational element 204 is a second threaded bore.

As shown in fig. 6, the placement unit 300 includes a placement element 301, a second connection element 302, two first support elements 303, two third connection elements 304, and a plurality of first limiting elements 305. Wherein the placing element 301 is movably disposed above the adjusting unit 200, and is used for placing a pipeline and moving in a horizontal direction under the action of the adjusting unit 200; the top end of the second connecting element 302 is rotatably connected with the placing element 301, and the bottom end of the second connecting element 302 is detachably connected with the adjusting unit 200 and is used for driving the placing element 301 to move along the vertical direction; the two first supporting elements 303 are symmetrically disposed on two sides of the placing element 301; the two third connecting elements 304 are respectively arranged penetrating through the corresponding first supporting elements 303 and detachably connected with the corresponding locking units 500; the first limiting elements 305 are respectively disposed at the ends of the corresponding first supporting elements 303, and detachably connected to the corresponding fixing units 400.

Specifically, the placement member 301 is movably disposed above the second slide member 201; the bottom end of the second connecting element 302 is detachably connected to the first connecting element 202.

More specifically, the placement element 301 is movably disposed above the outer slide.

The top end of the placement element 301 is rounded for adapting the pipe.

The dimensions of the placement element 301 are matched to the dimensions of the outer slide. Typically, the length of the placement element 301 is greater than the length of the outer slider, the width of the placement element 301 is greater than the width of the outer slider, and the height of the placement element 301 is less than the height of the outer slider.

The dimensions of the placement member 301 match those of the base member 101. Typically, the length of the placement member 301 is less than the length of the base member 101, and the width of the placement member 301 is less than the width of the base member 101.

In some of these embodiments, the placement element 301 is made of a metallic material.

In some of these embodiments, the placement element 301 is a placement plate.

The second connecting element 302 has a circular cross-section.

The dimensions of the second connecting element 302 match those of the placement element 301. Typically, the diameter of the second connecting element 302 is smaller than the length/width of the placement element 301, and the axial dimension of the second connecting element 302 is larger than the height of the placement element 301.

The dimensions of the second connecting element 302 match those of the first connecting element 202. Generally, the diameter of the second connecting element 302 is equal to the diameter of the first connecting element 202, and the axial dimension (e.g., depth) of the second connecting element 302 is not less than the axial dimension (e.g., depth) of the first connecting element 202.

In some of these embodiments, the second connecting element 302 is not separately rotationally connected to the placement element 301. For example, the second connecting element 302 is connected to the placement element 301 via a bearing block.

In some embodiments, the second connecting element 302 is made of metal.

In some of these embodiments, the second connecting element 302 is a threaded rod.

The first support element 303 has a rectangular cross section.

The dimensions of the first support element 303 match the dimensions of the placement element 301. Generally, the sum length of the first support elements 303 is smaller than the length of the placement element 301, the width of the first support elements 303 is smaller than the width of the placement element 301, and the height of the first support elements 303 is smaller than the height of the placement element 301.

In some of these embodiments, the first support element 303 is fixedly coupled to the placement element 301, including but not limited to welding.

In some embodiments, the first support element 303 is made of a metal material.

In some of these embodiments, the first support element 303 is a first support plate.

The third connecting element 304 has a circular cross section.

The third connecting element 304 is dimensioned to match the dimensions of the first supporting element 303. Typically, the diameter of the third connecting element 304 is smaller than the length/width of the first supporting element 303, and the axial dimension (e.g. depth) of the third connecting element 304 is equal to the height of the first supporting element 303.

In some of these embodiments, the third connecting element 304 is a third threaded bore.

The first limiting element 305 has a rectangular cross section.

The first limiting element 305 is sized to match the size of the first supporting element 303. Generally, the length of the first limiting element 305 is smaller than the width of the first supporting element 303, the width of the first limiting element 305 is smaller than the length of the first supporting element 303, and the height of the first limiting element 305 is equal to the height of the first supporting element 303.

The number of first limiting elements 305 matches the number of first supporting elements 303. Generally, the number of first limiting elements 305 is an integer multiple of the number of first supporting elements 303. I.e. each first supporting element 303 is provided with at least one first limiting element 305.

In some of these embodiments, each first support element 303 is provided with two first stop elements 305. The two first limiting elements 305 are symmetrically disposed on two sides of the first supporting element 303.

In some of these embodiments, the first stop element 305 is a stop slot.

Further, the placement unit 300 further comprises several auxiliary elements 306. The auxiliary elements 306 are disposed at the top end of the second connecting element 302, and are used for assisting in driving the second connecting element 302 to rotate.

The auxiliary element 306 has a circular cross section.

The auxiliary element 306 is dimensioned to match the dimensions of the second connecting element 302. Typically, the diameter of the auxiliary element 306 is smaller than the diameter/axial dimension of the second connecting element 302, and the axial dimension (e.g. depth) of the auxiliary element 306 is smaller than the diameter of the second connecting element 302.

A number of auxiliary elements 306 are arranged distributed along the circumference of the second connecting element 302.

In some of these embodiments, the auxiliary elements 306 are six.

In some of these embodiments, the auxiliary element 306 is an auxiliary torsion slot.

As shown in fig. 7, the stabilizing unit 400 includes a stabilizing element 401, two second supporting elements 402, and a plurality of second limiting elements 403. Wherein, the fixing element 401 is detachably disposed above the placement unit 300 for fixing the pipe; the two second supporting elements 402 are symmetrically disposed at two sides of the fixing element 401 and detachably connected with the corresponding locking units 500; the second limiting elements 403 are respectively disposed at the ends of the corresponding second supporting elements 402, and are detachably connected to the placement unit 300.

Specifically, the stabilizing element 401 is detachably disposed above the placement element 301; the second limiting element 403 is detachably connected to the first limiting element 305.

The bottom end of the stabilizing element 401 is rounded for adapting the pipe.

The dimensions of the stabilizing element 401 match the dimensions of the placement element 301. Generally, the length of the stabilizing element 401 is equal to the length of the placement element 301, the width of the stabilizing element 401 is equal to the width of the placement element 301, and the height of the stabilizing element 401 is equal to the height of the placement element 301.

In some of these embodiments, the stabilization member 401 is made of a metallic material.

In some of these embodiments, the stabilizing element 401 is a stabilizing plate.

The second support element 402 is rectangular in cross-section.

The dimensions of the second support element 402 match the dimensions of the stabilizing element 401. Generally, the length of the second support element 402 is less than the length of the stabilizing element 401, the width of the second support element 402 is less than the width of the stabilizing element 401, and the height of the second support element 402 is less than the height of the stabilizing element 401.

The dimensions of the second support element 402 match the dimensions of the first support element 303. In general, the length of the second support element 402 is equal to the length of the first support element 303, the width of the second support element 402 is equal to the width of the first support element 303, and the height of the second support element 402 is equal to the height of the first support element 303.

In some of these embodiments, the second support element 402 is fixedly coupled to the stabilization element 401, including but not limited to welding.

In some of these embodiments, the second support element 402 is made of a metal material.

In some of these embodiments, the second support element 402 is a second support plate.

The second limiting element 403 has a rectangular cross section.

The dimensions of the second stop element 403 are matched to the dimensions of the second support element 402. Generally, the length of the second limiting element 403 is smaller than the width of the second supporting element 402, the width of the second limiting element 403 is smaller than the length of the second supporting element 402, and the height of the second limiting element 403 is larger than the height of the second supporting element 402.

The dimensions of the second stop element 403 match the dimensions of the first stop element 305. Generally, the length of the second limiting element 403 is equal to the length of the first limiting element 305, the width of the second limiting element 403 is equal to the width of the first limiting element 305, and the height of the second limiting element 403 is greater than the height of the first limiting element 305.

The number of second stop elements 403 matches the number of second support elements 402. Generally, the number of second stop elements 403 is an integer multiple of the number of second support elements 402. I.e. each second supporting element 402 is provided with at least one second limiting element 403.

In some of these embodiments, each second support element 402 is provided with two second stop elements 403. The two second limiting elements 403 are symmetrically disposed on two sides of the second supporting element 402.

The number of second stop elements 403 matches the number of first stop elements 305. Generally, the number of second spacing elements 403 is equal to the number of first spacing elements 305.

In some of these embodiments, the second stop element 403 is fixedly coupled to the second support element 402, including but not limited to welding. For example, the second limiting element 403 is integrally formed with the second supporting element 402.

In some embodiments, the second limiting element 403 is made of a metal material.

In some of these embodiments, the second stop element 403 is a stop block.

Further, the stabilizing unit 400 further comprises two fourth connecting elements 404. Wherein, two fourth connecting elements 404 are disposed through the corresponding second supporting elements 402 and detachably connected with the corresponding locking units 500.

Specifically, the fourth connecting element 404 is disposed corresponding to the third connecting element 304.

The fourth connecting element 404 has a circular cross-section.

The fourth connecting element 404 is sized to match the size of the second support element 402. Typically, the diameter of the fourth connecting element 404 is smaller than the length/width of the second support element 402, and the axial dimension (e.g., depth) of the fourth connecting element 404 is equal to the height of the second support element 402.

The fourth connecting element 404 is sized to match the size of the third connecting element 304. Generally, the diameter of the fourth connecting element 404 is equal to the diameter of the third connecting element 304, and the axial dimension (e.g., depth) of the fourth connecting element 404 is equal to the axial dimension (e.g., depth) of the third connecting element 304.

In some of these embodiments, the fourth connecting element 404 is a through hole, a fourth threaded hole.

As shown in fig. 8, the locking unit 500 includes a locking element 501. The locking element 501 is detachably connected to the corresponding fixing unit 400 and the placement unit 300, respectively, for fixing the fixing unit 400.

Specifically, the locking element 501 is detachably connected to the corresponding fourth connecting element 404 and third connecting element 304, respectively.

The locking element 501 comprises a screw and a screw head. Specifically, the screws are detachably connected with the corresponding fourth connecting element 404 and the third connecting element 304 respectively; the screw head is arranged at the top end of the screw rod.

The size of the screw matches the size of the fourth connecting element 404 (third connecting element 304). Typically, the diameter of the screw is equal to the diameter of the fourth connecting element 404 (third connecting element 304), and the axial dimension (e.g., depth) of the screw is greater than the axial dimension (e.g., depth) of the fourth connecting element 404 (third connecting element 304).

The size of the screw head matches the size of the fourth connecting element 404 (third connecting element 304). Generally, the radial dimension of the screw head is greater than the diameter of the fourth connecting element 404 (third connecting element 304) and the axial dimension of the screw head is less than the axial dimension (e.g., depth) of the fourth connecting element 404 (third connecting element 304).

The size of the screw head is matched with that of the screw rod. Typically, the radial dimension of the screw head is greater than the diameter of the screw, and the axial dimension of the screw head is less than the axial dimension of the screw.

In some of these embodiments, the locking element 501 is made of a metal material.

In some of these embodiments, locking element 501 is a bolt.

The application method of the utility model is as follows:

First) mounting base member 101

The base element 101 is placed at a corresponding position and is fixedly connected with an external embedded part.

(Two) mounting placement member 301

By means of the threaded connection of the second connecting element 302 with the first connecting element 202, so that the placement element 301 is located above the second sliding element 201;

(III) adjusting the lateral position of the placement element 301

The driving element 203 is driven to rotate on the base element 101 by an external hexagonal wrench;

The driving element 203 drives the second sliding element 201 to correspondingly move along the first sliding element 102, so that the transverse position of the placing element 301 is adjusted;

(IV) adjusting the longitudinal position of the placement element 301

Inserting an external steel column into the second connecting element 302 through the auxiliary element 306, and rotating the steel balls to drive the second connecting element 302 to correspondingly rotate along the circumferential direction of the first connecting element 202, so as to adjust the longitudinal position of the placing element 301;

(V) placing the pipeline

Placing the pipes on the corresponding placement elements 301;

After the placement of the pipes, the placement element 301 can also be adjusted to be located in a corresponding position of the base element 101.

Sixth, fix the pipeline

Placing the stabilization member 401 over the placement member 301 (i.e., over the pipe) and engaging the second stop member 403 with the first stop member 305 to facilitate alignment of the stabilization member 401 with the placement member 301;

The locking element 501 is screwed with the fourth connecting element 404 and the third connecting element 304 in sequence until the locking element 501 is tightened, thereby completing the fixation of the pipe.

The utility model has the advantages that the gas pipelines are limited and fixed by the placement unit and the stabilizing unit, so that the stability of the two adjacent gas pipelines after being butted is improved; the placement unit and the base unit are detachably connected and installed through threads, and the relative position of the placement unit on the base unit can be adjusted, so that the longitudinal adjustment of the placement unit is realized; the transverse position of the placing unit can be adjusted by the adjusting unit so as to meet the use requirement.

The foregoing description is only illustrative of the preferred embodiments of the present utility model and is not to be construed as limiting the scope of the utility model, and it will be appreciated by those skilled in the art that equivalent substitutions and obvious variations may be made using the description and illustrations of the present utility model, and are intended to be included within the scope of the present utility model.

Claims (10)

1. A pipeline positioner for municipal gas engineering, characterized by, include:

the base unit (100) is arranged on the horizontal plane and is connected with the external embedded part;

The two adjusting units (200) are symmetrically arranged at the top ends of the base unit (100) and are respectively and movably connected with the base unit (100);

The two placing units (300) are detachably connected with the corresponding adjusting units (200) respectively, and are used for placing pipelines and moving in the vertical direction and moving in the horizontal direction under the action of the adjusting units (200);

The two stabilizing units (400) are respectively arranged above the corresponding placing units (300) and are respectively detachably connected with the corresponding placing units (300) for fixing the pipeline;

The locking units (500) are detachably connected with the corresponding stabilizing units (400) and the placing units (300) respectively, and are used for fixing the stabilizing units (400).

2. The pipe positioning device according to claim 1, wherein the base unit (100) comprises:

The base element (101), the base element (101) is set up in the horizontal plane, and connect with external embedded part;

The two first sliding elements (102) are symmetrically arranged at the top end of the base element (101) and are respectively connected with the corresponding adjusting units (200) in a sliding manner;

The two first rotating elements (103) are respectively arranged at the side parts of the base element (101), are respectively communicated with the corresponding first sliding elements (102), and are respectively connected with the corresponding adjusting units (200) in a rotating mode.

3. The pipe positioning device according to claim 2, wherein the base unit (100) further comprises:

The two second rotating elements (104) are respectively arranged in the base element (101), are respectively communicated with the corresponding first sliding elements (102), and are respectively connected with the corresponding adjusting units (200) in a rotating mode.

4. The pipe positioning apparatus according to claim 1, wherein the adjusting unit (200) comprises:

The bottom end of the second sliding element (201) is in sliding connection with the base unit (100), and the top end of the second sliding element (201) protrudes out of the base unit (100) and is detachably connected with the placement unit (300);

a first connecting element (202), the first connecting element (202) being arranged at the top end of the second sliding element (201) and being detachably connected with the placement unit (300);

The driving element (203) is respectively and rotatably connected with the bottom end of the second sliding element (201) and the base unit (100) and is used for driving the second sliding element (201) to move.

5. The pipe positioner according to claim 4, wherein the adjusting unit (200) further comprises:

And the third rotating element (204) penetrates through the bottom end of the second sliding element (201) and is rotationally connected with the driving element (203).

6. The pipe positioner according to claim 1, wherein the placement unit (300) comprises:

The placing element (301) is movably arranged above the adjusting unit (200) and is used for placing a pipeline and moving in the horizontal direction under the action of the adjusting unit (200);

The top end of the second connecting element (302) is rotationally connected with the placing element (301), and the bottom end of the second connecting element (302) is detachably connected with the adjusting unit (200) and is used for driving the placing element (301) to move along the vertical direction;

Two first supporting elements (303), wherein the two first supporting elements (303) are symmetrically arranged at two sides of the placing element (301);

The two third connecting elements (304), the two third connecting elements (304) penetrate through the corresponding first supporting elements (303) respectively and are detachably connected with the corresponding locking units (500);

The first limiting elements (305) are respectively arranged at the ends of the corresponding first supporting elements (303), and are detachably connected with the corresponding stabilizing units (400).

7. The pipe positioner according to claim 6, wherein the placement unit (300) further comprises:

The auxiliary elements (306) are arranged at the top ends of the second connecting elements (302) and used for assisting in driving the second connecting elements (302) to rotate.

8. The pipe positioning apparatus as claimed in claim 1, wherein the securing unit (400) comprises:

-a securing element (401), the securing element (401) being detachably arranged above the placement unit (300) for securing a pipe;

Two second supporting elements (402), wherein the two second supporting elements (402) are symmetrically arranged at two sides of the stabilizing element (401) and are detachably connected with the corresponding locking units (500);

The second limiting elements (403) are respectively arranged at the ends of the corresponding second supporting elements (402), and are detachably connected with the placing unit (300).

9. The pipe positioner according to claim 8, wherein the securing unit (400) further comprises:

And two fourth connecting elements (404), wherein the two fourth connecting elements (404) penetrate through the corresponding second supporting elements (402) and are detachably connected with the corresponding locking units (500).

10. The pipe positioner according to claim 1, wherein the locking unit (500) comprises:

And the locking element (501) is detachably connected with the corresponding stabilizing unit (400) and the placing unit (300) respectively and is used for fixing the stabilizing unit (400).