CN220187578U - Double-pipe assembly checking fixture - Google Patents

Abstract

The utility model discloses a double-pipe assembly checking fixture, which relates to the technical field of positioning checking fixtures and comprises a bottom plate, wherein an inspection seat is arranged on the bottom plate, the top surface of the inspection seat is downwards sunken to form an imitation groove for placing a double-pipe assembly, quick slots, a binding belt opening, a pipe clamp opening and a mark notch are arranged on the inspection seat and the imitation groove according to the structural profiling of the double-pipe assembly, and a plurality of comparison steps are arranged on the inspection seat and the imitation groove to realize comparison detection. Therefore, the double-tube assembly is conveniently placed in the profiling groove by utilizing the profiling structure by utilizing the dead weight, so that the inspection is convenient, the labor intensity is lightened, the labor cost is reduced, and the inspection efficiency and quality of the pipeline workpiece are improved.

Description

Double-pipe assembly checking fixture

Technical Field

The utility model relates to the technical field of positioning detection tools, in particular to a double-pipe assembly detection tool.

Background

As shown in FIG. 10, a more common pipeline workpiece (i.e., a double-pipe assembly) comprises two pipelines, a pipe clamp and a binding belt, wherein the two pipelines are bound together through the binding belt, the two pipelines are fastened through the pipe clamp when in use, one end of each pipeline is connected and provided with a quick insert, and each pipeline is further provided with a mark.

Before the pipeline workpiece is used, the pipeline workpiece needs to be checked to see whether the pipeline workpiece is qualified or not, and if the pipeline workpiece is unqualified, the use quality is affected. Most of the existing inspection modes are manual inspection by means of auxiliary measurement of workpieces and the like, but the manual inspection efficiency is low, the labor cost is high, the error is uncontrollable, and the inspection quality is affected.

Disclosure of Invention

In order to solve the problem of inspection of pipeline workpieces, the utility model provides a double-pipe assembly gauge which reduces the cost and improves the inspection quality.

The utility model provides a double-tube assembly gauge which adopts the following technical scheme.

The utility model provides a utensil is examined to double-barrelled collection assembly, includes the bottom plate, be provided with on the bottom plate:

the top surface of the inspection seat is recessed downwards to form an imitation groove for placing the double-pipe collection assembly;

the end face of the imitation groove is provided with a comparison step A for detecting the position size of the end face of the double-pipe assembly;

the end part of the profiling groove is provided with a quick slot for placing quick insertion of the end part of the pipeline;

the simulated groove is provided with a plurality of comparison steps B for detecting the position size of the simulated groove corresponding to the jacket on the double-pipe assembly;

the profiling groove is provided with a plurality of ribbon openings and is used for detecting the installation angle and the axial position size of the ribbon on the profiling groove corresponding double-tube collecting assembly;

the profiling groove is provided with a plurality of pipe clamp openings and is used for detecting the installation angle and the axial position size of the pipe clamp on the profiling groove corresponding double-pipe assembly;

the inspection seat is provided with a plurality of mark scores for detecting the position sizes of marks on the double-pipe assembly.

By adopting the technical scheme, the bottom plate is a base of the distance between the holes of the support, so that the stability of the gauge is improved, and the detection efficiency and quality of the gauge are improved; the imitation groove is formed by downwards sinking the top surface of the inspection seat, so that the pipeline is conveniently placed in the imitation groove by utilizing the dead weight, and the inspection is convenient; the comparison step A arranged on the end face of the profiling groove realizes the position and size detection of the end face of the double-pipe assembly and the length detection of the assembly; the quick inserting groove is arranged at the end part of the imitation groove, and quick inserting of the end part of the pipeline is placed by utilizing the profiling structure, so that the position detection of the quick inserting is realized; the comparison step B is arranged on the imitation groove, so that the position and the size of the sheath on the double-pipe assembly are detected; the ribbon openings arranged on the imitation grooves realize the detection of the installation angle and the axial position size of the ribbon on the double-tube collection assembly; the pipe clamp opening is arranged on the imitation groove, and the installation angle and the axial position size of the pipe clamp on the double-pipe assembly are detected; checking the mark nicks arranged on the base and detecting whether the marks are aligned realizes the detection of the position size of the marks on the double-pipe assembly.

Optionally, the bottom plate is divided into a plurality of sub-bottom plates, and the sub-bottom plates are connected side by side.

Through adopting above-mentioned technical scheme, the bottom plate divide into a plurality of sub-bottom plates, and the size of bottom plate is for according to the size of double-barrelled collection assembly and inspection seat size and decide, stores and shifts inconveniently when the size is great, so the bottom plate comprises a plurality of pieces of connection, and the storage and the shift of bottom plate of being convenient for to do not influence result of use.

Optionally, the inspection seat is divided into a plurality of sub-inspection seats, and the sub-inspection seats are connected side by side.

Through adopting above-mentioned technical scheme, the size of inspection seat is according to pipeline size and decides, stores and shifts inconveniently when the size is great, so the inspection seat comprises a plurality of pieces of connection, and the storage and the shift of inspection seat of being convenient for to do not influence result of use.

Optionally, the end face of one end of the pipe clamp opening is provided with a comparison step C for detecting the position and the size of the pipe clamp on the double-pipe set and the assembly.

Through adopting above-mentioned technical scheme, set up contrast step C at pipe strap open-ended terminal surface, the pipe strap not only uses the pipe strap opening as the detection basis, and the pipe strap can also use contrast step C as the detection reference basis, realizes the more accurate detection of position size to the pipe strap on the double-barrelled assembly.

Optionally, be provided with the baffle on the inspection seat, recess A is seted up at the baffle top, recess A is used for detecting the circumference position size of mark on a pipeline of double-barrelled collection assembly.

Through adopting above-mentioned technical scheme, the baffle that sets up on the inspection seat is located the one end of the sign on a pipeline on double-barrelled collection and the assembly, and recess A is still seted up moreover, can realize the circumference position detection to the sign on a pipeline on double-barrelled collection and the assembly.

Optionally, the inspection seat (provided with a semicircular ring, a groove B is formed in the semicircular ring, and the groove B is used for detecting the axial position size of the mark on the other pipeline of the double-pipe assembly.

By adopting the technical scheme, the position of the groove B on the semicircular ring is compared with the position of the other pipeline mark on the double-pipe set and the assembly, so that the circumferential position detection of the representation is realized.

In summary, the utility model has the following beneficial effects:

1. the bottom plate and the inspection seat are formed by splicing a plurality of blocks, the size is reduced after the disassembly, the space occupation is small, the storage and the transportation are convenient, and the splicing is practical and convenient.

2. The imitation groove is downwards concave on the top surface of the inspection seat, so that the pipeline is conveniently placed in the imitation groove by utilizing the dead weight, and the inspection is convenient.

3. The comparison step A, the comparison step B and the comparison step C are in a step structure form, so that the end faces of two pipelines can be conveniently compared with the steps for inspection, the length of the end of the pipeline can be measured, and the inspection mode is simple and visual.

4. The pipe clamps and the binding tapes on the double-pipe assembly adopt a profiling mode to detect the installation angle and the axial position, and the detection is more convenient and efficient.

5. Labor intensity is reduced, labor cost is reduced, and inspection efficiency and quality are improved.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a dual tube assembly gauge (including a dual tube assembly).

Fig. 2 is an enlarged schematic view of a portion a in fig. 1.

Fig. 3 is an enlarged schematic view of a part B in fig. 1.

Fig. 4 is an enlarged schematic view of the part C in fig. 1.

Fig. 5 is a schematic view of a partial D enlarged structure in fig. 1.

Fig. 6 is an enlarged schematic view of a portion E of fig. 1.

FIG. 7 is a schematic view of another view of a dual manifold assembly gauge (including a dual manifold assembly).

Fig. 8 is an enlarged schematic view of the part F in fig. 7.

Fig. 9 is an enlarged schematic view of a part G in fig. 7.

Fig. 10 is a schematic diagram of a dual tube manifold assembly.

Reference numerals illustrate: 1. a bottom plate; 2. checking a seat; 3. a simulated groove; 4. comparing the steps A; 5. a fast slot; 6. comparing the steps B; 7. a strap opening; 8. a pipe clamp opening; 9. comparing the steps C; 10. identifying the nicks; 11. a baffle; 12. a pin hole; 13. a groove A; 14. a semicircular ring; 15. a groove B; 16. a double-tube assembly; 17. fast inserting; 18. a sheath; 19. a tie; 20. a pipe clamp; 21. and (5) identification.

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.

The utility model is described in further detail below with reference to fig. 1 to 10.

The embodiment of the utility model discloses a double-tube assembly gauge.

Example 1

Referring to fig. 1 to 10, a dual-tube assembly gauge includes a base plate 1, wherein the base plate 1 is a rectangular thin plate, the base plate 1 is a base of the dual-tube assembly gauge, so that the stability of the gauge is improved, and the detection efficiency and quality of the gauge are improved; the bottom plate 1 is divided into six sub-bottom plates, the six sub-bottom plates are connected side by side, the bottom plate 1 can be assembled by rapid splicing, the bottom plate 1 is divided into six sub-bottom plates, the size of the bottom plate 1 is determined according to the size of the double-pipe collection assembly 16 and the size of the inspection seat 2, and the bottom plate 1 is inconvenient to store and transfer when the size is large, so that the bottom plate 1 is formed by connecting six sub-bottom plates, the storage and the transfer of the bottom plate 1 are convenient, and the using effect is not influenced.

The bottom plate 1 is fixedly provided with a checking seat 2, the checking seat 2 is a bulge formed along the structural shape of the double-pipe assembly 16 on the bottom plate 1, and the top surface of the checking seat 2 is downwards recessed to form an imitation groove 3 for placing the double-pipe assembly 16. The imitation groove 3 is formed by downwards sinking the top surface of the inspection seat 2, so that the double-pipe collection assembly 16 is conveniently placed in the imitation groove 3 by utilizing the dead weight, and the inspection is convenient.

The inspection seat 2 is the same as the bottom plate 1, and is also divided into six sub-inspection seats, the six sub-inspection seats are connected side by side, the six sub-inspection seats can be assembled in a rapid splicing way, the size of the inspection seat 2 is determined according to the size of a pipeline, and the inspection seat 2 is inconvenient to store and transfer when the size is large, so that the inspection seat 2 is formed by connecting six pieces, the storage and the transfer of the inspection seat 2 are convenient, and the using effect is not influenced.

The end surfaces at the two ends of the imitation groove 3 are respectively provided with a comparison step A4, and the comparison steps A4 are three steps with end surfaces uniformly distributed along the axial direction and are used for detecting the position size of the end surface of the double-pipe assembly 16. And after the double-pipe assembly 16 is placed, the end face of the assembly is opposite to the comparison step A4, the position and the size of the end face of the double-pipe assembly 16 and the end face of the profiling groove 3 are detected, and the length detection of the assembly is realized.

A quick slot 5 is arranged at one end of the imitation groove 3 and is used for placing a quick plug 17 at the end of the double-pipe assembly 16; the quick slot 5 arranged at the end part of the imitation groove 3 is of a quick-inserting 17 profiling structure, and the quick-inserting 17 at the end part of the pipeline is placed by utilizing the profiling structure, so that the position detection of the quick-inserting 17 is realized; and the end part of one end of the imitation groove 3 is also provided with a comparison step A4, so that the comparison detection can be realized.

The comparison step B6 is arranged on the imitation groove 3, and the comparison step B6 is three steps with end faces uniformly distributed along the axial direction, so that the position and the size of the jacket 18 on the double-pipe assembly 16 are detected; the profiling groove 3 is provided with a comparison step B6, and after the double-pipe assembly 16 is placed in the profiling groove 3, the axial position size of the jacket 18 on the double-pipe assembly 16 is compared and detected.

The simulated groove 3 is provided with ribbon openings 7 with the same number as the ribbon 19 on the double-tube collection assembly 16, and the ribbon openings are used for detecting the installation angle and the axial position size of the ribbon 19 on the double-tube collection assembly 16 corresponding to the simulated groove 3; after the double-tube assembly 16 is placed in the profiling groove 3, the binding tape 19 on the double-tube assembly 16 falls into the binding tape opening 7 formed in the profiling groove 3, and the detection of the installation angle and the axial position size of the binding tape 19 on the double-tube assembly 16 is realized.

The simulated groove 3 is provided with pipe clamp openings 8 with the same number as the pipe clamps 20 on the double-pipe assembly 16, and the pipe clamp openings are used for detecting the installation angle and the axial position size of the pipe clamps 20 on the double-pipe assembly 16 corresponding to the simulated groove 3; after the double-pipe assembly 16 is placed in the profiling groove 3, the pipe clamps 20 on the double-pipe assembly 16 fall into the pipe clamp openings 8 formed in the profiling groove 3, and detection of the installation angle and the axial position size of the pipe clamps 20 on the double-pipe assembly 16 is achieved.

The end face of one end of the pipe clamp opening 8 is provided with a comparison step C9, and the comparison step C9 is three steps with end faces uniformly distributed along the axial direction and is used for comparing and detecting the position and the size of the double-pipe set and the pipe clamp 20 on the assembly. The pipe clamp 20 not only takes whether the pipe clamp falls into the pipe clamp opening 8 normally or not as a detection basis, but also takes the comparison step C9 as a detection reference basis, so that the position and the size of the pipe clamp 20 on the double-pipe assembly 16 can be detected more accurately.

The inspection seat 2 is provided with two mark scores 10, and the mark scores 10 are strip grooves with the top surface recessed downwards and are used for detecting the position sizes of marks 21 at one ends of two pipelines of the double-pipe assembly 16; after the double tube assembly 16 is placed in the profiling groove 3, whether the marks 21 on the two pipelines are aligned with the two mark scores 10 is detected, namely, the detection of the position size of the marks 21 on the double tube assembly 16 is realized.

One end of the double profiling grooves 3 on the inspection seat 2 is provided with a baffle plate 11 at the end part of the profiling groove 3 at one side, the baffle plate 11 is a rectangular plate, the baffle plate 11 is provided with a pin hole 12, the corresponding profiling groove 3 is also provided with a pin hole 12, and the baffle plate 11 is fixedly arranged at the end part of the profiling groove 3 through a bolt. A groove A13 is formed in the middle position of the top of the baffle plate 11, and the groove A13 is aligned with the mark 21 on one pipeline in the profiling groove 3 along the axial direction, so that the size detection of the circumferential position of the mark 21 on one pipeline in the double-pipeline assembly 16 can be realized.

One end of the double profiling grooves 3 on the inspection seat 2, the end part of the profiling groove 3 on the other side is fixedly provided with a semicircular ring 14, the radius of the semicircular ring 14 is larger than that of the other pipeline, the top of the semicircular ring 14 is provided with a groove B15, and the groove B15 is aligned with a mark 21 on the pipeline in the profiling groove 3 along the axial direction, so that the size detection of the circumferential position of the mark 21 on the other pipeline in the double-pipe collecting assembly 16 can be realized.

Referring to fig. 1 to 10, the detection using method:

firstly, the bottom plate 1 and the checking seat 2 are spliced and placed stably, the double-pipe assembly 16 is placed in the profiling groove 3, whether the trend of the assembly is consistent with that of the profiling groove 3 or not is checked, whether interference exists or not is checked, and if the assembly is placed smoothly, the assembly is qualified, and otherwise, the assembly is unqualified. And comparing the end part of the pipeline with the position of the comparison step A4, detecting the length and the error of the pipeline, and judging that the end face is qualified within the range of the comparison step A4, otherwise, judging that the end face is unqualified. And detecting the conditions of the quick insertion 17 at the end part of the pipeline, the quick insertion slot 5 in the profiling groove 3, and the stable conditions, wherein the conditions are successfully qualified, and otherwise, the conditions are unqualified. And comparing the positions of the sheath 18 and the comparison step B6, and comparing the axial position sizes of the sheath 18, wherein both ends of the sheath 18 are qualified inside the step range, and are unqualified otherwise. The positions of the comparison pipe clamp 20 and the comparison step C9 are compared, the step positions of one end of the comparison detection pipe clamp 20 and the comparison step C9 are qualified in the step range, and otherwise, the comparison detection pipe clamp is unqualified. And comparing and detecting the positions of the marks 21 and the mark scores 10 at one ends of the two pipelines of the double-pipe assembly 16, wherein the alignment of the marks and the marks is qualified, and otherwise, the mark is unqualified. The alignment is detected by the grooves A13 on the baffle plate 11 and the grooves B15 on the semicircular rings 14, and the alignment condition of the two marks 21 is detected, and the alignment is qualified, otherwise, the alignment is unqualified.

In the description of the present utility model, it should be understood that the terms "one end," "another side," "top," "both ends," "middle," "end," "top," "down," "circumferential," "inside," "axial," "inner," "both ends," "end face," etc. indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model. In the description of the present utility model, unless otherwise specified and defined, it should be noted that the term "connected" should be interpreted broadly, and for example, it may be a mechanical connection or an electrical connection, or may be a connection between two elements, or may be a direct connection or may be an indirect connection through an intermediary, and it will be understood to those skilled in the art that the specific meaning of the term may be interpreted according to the specific circumstances.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (6)

1. The utility model provides a utensil is examined to double-barrelled collection assembly which characterized in that, includes bottom plate (1), be provided with on bottom plate (1):

the top surface of the inspection seat (2) is recessed downwards to form an imitation groove (3) for placing the double-tube collection assembly (16);

the end face of the profiling groove (3) is provided with a comparison step A (4) for detecting the position size of the end face of the double-pipe assembly (16);

the end part of the profiling groove (3) is provided with a quick inserting groove (5) for placing a quick inserting (17) at the end part of the pipeline;

the profiling groove (3) is provided with a comparison step B (6) for detecting the position size of a jacket (18) on the profiling groove (3) corresponding to the double-tube assembly (16);

a plurality of ribbon openings (7) are formed in the profiling groove (3) and are used for detecting the installation angle and the axial position size of the ribbon (19) on the profiling groove (3) corresponding to the double-tube collecting assembly (16);

a plurality of pipe clamp openings (8) are formed in the profiling groove (3) and are used for detecting the installation angle and the axial position size of a pipe clamp (20) on the profiling groove (3) corresponding to the double-pipe assembly (16);

the inspection seat (2) is provided with a plurality of mark scores (10) for detecting the position and the size of marks (21) on the double-tube assembly (16).

2. The double-pipe assembly gauge according to claim 1, wherein the bottom plate (1) is divided into a plurality of sub-bottom plates, and the sub-bottom plates are connected side by side.

3. The double-pipe assembly gauge according to claim 1, wherein the gauge seat (2) is divided into a plurality of sub gauge seats, and the sub gauge seats are connected and arranged side by side.

4. The double-tube assembly gauge according to claim 1, wherein a contrasting step C (9) is arranged on an end face of the tube clamp opening (8) for detecting the position and the size of the tube clamp (20) on the double-tube assembly.

5. The double-pipe assembly gauge according to claim 1, wherein a baffle (11) is arranged on the checking seat (2), a groove A (13) is formed in the top of the baffle (11), and the groove A (13) is used for detecting the circumferential position size of a mark (21) on a pipeline of the double-pipe assembly (16).

6. The double-pipe assembly gauge according to claim 1, wherein the checking seat (2) is provided with a semicircular ring (14), the semicircular ring (14) is provided with a groove B (15), and the groove B (15) is used for detecting the circumferential position size of a mark (21) on another pipeline of the double-pipe assembly (16).