CN117816801A - Pipeline sample rod auxiliary bending equipment - Google Patents

Abstract

The invention provides auxiliary bending equipment for a pipeline sample rod, which comprises a box body, wherein a through groove and a through hole are formed in the box body, a pushing assembly provided with a corner device is arranged in the box body, and a corner assembly consisting of a clamping mould, a clamping shoe and a corner measurer is arranged on one side of the upper end of the box body; the pipeline sample rod is pushed to advance through the pushing component, the pipeline sample rod is clamped on the clamping fixture by using the clamping shoe when reaching the bending starting point position, the pipeline sample rod is bent by rotating the clamping fixture, the steering gear is adjusted to drive the pipeline sample rod to rotate along the central axis, and the steps of pushing, bending, rotating and the like are repeated on the pipeline sample rod until the simulation bending of all the bending starting point positions is completed. According to the method, equipment is used for accurately adjusting the sample rod in the process of simulating the bending of the sample rod, the rationality of the pipeline design is directly judged, if the phenomenon that the sample rod cannot be bent occurs, bending information is timely modified, an original manual bending simulating method is replaced, the bending simulating result is more reliable and efficient, material loss is reduced, and construction efficiency is improved.

Description

Pipeline sample rod auxiliary bending equipment

Technical Field

The invention relates to the field of pipeline bending operation in the ship manufacturing industry, in particular to pipeline sample rod auxiliary bending equipment.

Background

When a ship is built, pipelines in the ship are often required to be bent at different angles, and in order to reduce the waste of materials, workers usually simulate bending of pipeline sample rods before bending pipeline operation.

At present, manual simulation bending methods are basically used in various factories, and part of pipelines are in accordance with construction conditions in the simulation process due to incapability of performing accurate bending, but a series of problems such as interference and the like can occur in the actual production process, so that the material loss is increased, and the construction efficiency is reduced.

Disclosure of Invention

The invention provides auxiliary bending equipment for a pipeline sample rod, which aims to solve the problem that the construction efficiency is reduced due to the fact that the material loss is increased caused by poor reliability of a manual simulation bending method. The device is matched with a plurality of mechanisms, and the pipeline sample rod is subjected to simulated bending by adjusting accurate data to form a set of novel simulated bending method, so that the existing manual simulated bending method is replaced, the simulated bending result is more reliable, and the technical problem of construction efficiency reduction caused by material loss increase is solved.

The invention solves the technical problems by adopting the scheme that:

the auxiliary bending equipment for the pipeline sample rod comprises a box body, wherein the box body is arranged on a horizontal plane, and an accommodating space is formed in the box body and communicated with the outside and used for providing installation and support; the propelling component is arranged in the box body and used for controlling the feeding length of the pipeline sample rod; the corner assembly is fixedly arranged at the upper end of the box body and is used for realizing the bending of the pipeline sample rod; and the corner device is assembled at the upper end of the propulsion component and is used for controlling the rotation angle of the pipeline sample rod around the central axis of the pipeline sample rod.

The embodiment discloses that the box body comprises a through groove, the through groove is arranged in the box body, and the side view cross section of the through groove can be T-shaped or L-shaped, preferably L-shaped; and the through hole is formed in the side wall of the box body and is used for providing installation.

The pushing assembly comprises a screw rod, and is assembled in the box body through the through hole; the L-shaped sliding arm consists of a sliding arm rod and a nut, the sliding arm rod is assembled on the screw rod through the nut, and the sliding arm rod extends outwards along the through groove respectively; the position indicator is assembled at the front end of the outer side of the sliding arm rod of the L-shaped sliding arm, and a length scale is arranged at the position where the upper end of the position is contacted with the box body and is used for determining the feeding length of the pipeline sample rod; and the sliding block is assembled at the upper end of the outer side of the sliding arm rod of the L-shaped sliding arm and is used for driving the pipeline sample rod to move in the horizontal direction.

The embodiment discloses that the corner module comprises a mould, the upper end of the box body is fixedly arranged near the through groove, the upper surface of the corner module is provided with an angle scale, and the side wall of the corner module is provided with a circle of groove for placing a pipeline sample rod; one end of the clamping tile is arranged on the side wall of the clamping mould, a groove is formed in the side wall of the clamping tile, the size of the clamping tile is matched with that of the groove of the clamping mould, and the other end of the clamping tile extends towards the direction of the through groove and is used for bending the pipeline sample rod in cooperation with the rotation of the clamping mould; the angle measurer is fixedly arranged at the center of the angle scale at the upper end of the clamping fixture and is used for determining a bending angle; wherein, the clamping mould and the through groove of the clamping tile form a hole-shaped structure for installing a pipeline sample rod after being matched, the central axis of the central axis coincides with the central axis of the pipeline sample rod and is parallel to the central axis of the through groove in the vertical direction.

The embodiment discloses that the sliding block is provided with an assembly hole along the feeding direction of the pipeline sample rod, and the corner device is assembled in the assembly hole; one end of the corner device is provided with an angle scale for determining the rotation angle of the pipeline sample rod, and the other end of the corner device is provided with an assembly clamping groove for enabling the pipeline sample rod to be in fastening connection with the corner device.

In order to further solve the technical problem to be solved, the application method of the auxiliary bending equipment for the pipeline sample rod provided by the invention comprises the following steps:

step 1, all positions of the sliding block, the clamping fixture and the corner device are zeroed;

step 2, a pipeline sample rod to be simulated passes through a hole-shaped structure between the clamping mould and the clamping tile and is inserted into an assembly clamping groove of the corner device;

step 3, calculating bending data of simulated bending of the sample rod according to lofting and sampling data provided on site through calculation in a certain proportion, wherein the bending data comprises information such as feeding length, bending starting point position, straight pipe section length, corner angle, bent angle and the like;

step 4, rotating the screw rod according to the length of the straight pipe section and the starting and bending point position, so that the L-shaped sliding arm moves and drives the sliding block to push the pipeline sample rod to advance, and determining the position of the sliding block and calculating the moving distance by observing the position indicator;

step 5, after the starting point position reaches the corner assembly, clamping the pipeline sample rod on the clamping fixture through the clamping shoe, rotating the clamping fixture according to the corner angle, and determining the bending angle of the pipeline sample rod by observing the corner measurer;

step 6, after primary bending is completed, loosening the clamping shoe, resetting the clamping mould to zero, and adjusting the rotation angle of the corner device according to the corner angle to enable the pipeline sample rod to rotate according to data;

and 7, repeating the steps 4, 5 and 6 until the simulated bending of all the starting bending point positions of the pipeline sample rod is completed.

The positive effects are as follows:

the invention is characterized in that a through groove and a through hole are formed in a box body, a pushing component provided with a corner device is arranged in the through groove, and a corner component consisting of a clamping mould, a clamping tile and a corner measurer is arranged at one side of the upper end of the box body. The pipeline sample rod is pushed to advance through the pushing component, the pipeline sample rod is clamped on the clamping fixture by using the clamping shoe when reaching the bending starting point position, the pipeline sample rod is bent by rotating the clamping fixture, the steering gear is adjusted to drive the pipeline sample rod to rotate along the central axis, and the steps of pushing, bending, rotating and the like are repeated on the pipeline sample rod until the simulation bending of all the bending starting point positions is completed. According to the method, equipment is used for accurately adjusting the sample rod in the process of simulating the bending of the sample rod, the rationality of the pipeline design is directly judged, if the phenomenon that the sample rod cannot be bent occurs, bending information is timely modified, an original manual bending simulating method is replaced, the bending simulating result is more reliable and efficient, material loss is reduced, and construction efficiency is improved. The auxiliary bending device is suitable for being used as auxiliary bending equipment of a pipeline sample rod.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of the present application;

FIG. 2 is a front view of an embodiment of the present application;

FIG. 3 is a top view of an embodiment of the present application;

fig. 4 is a cross-sectional view of example A-A of the present application.

In the drawing the view of the figure,

10. the box body is provided with a through groove 11 and a through hole 12;

20. the device comprises a pushing assembly, a screw, a 22L-shaped sliding arm, a 23 position indicator and a 24 sliding block, wherein the pushing assembly is used for pushing the screw;

30. the bending angle assembly, 31, the mould, 32, the clamping tile and 33, the bending angle measurer;

40. a corner device.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown, a tubing-like wand assisted bending apparatus comprising:

the box body 10 is arranged on a horizontal plane, and is internally provided with a containing space which is communicated with the outside and is used for providing installation and support; the propulsion component 20 is arranged in the box body 10 and is used for controlling the feeding length of the pipeline sample rod; the corner assembly 30 is fixedly arranged at the upper end of the box body 10 and is used for realizing the bending of the pipeline sample rod; and the corner device 40 is assembled at the upper end of the propulsion component 20 and is used for controlling the rotation angle of the pipeline sample rod around the central axis of the pipeline sample rod.

Specifically, the box 10 is disposed on a horizontal plane, and has an accommodating space therein, and communicates the spaces above, in front of, and behind with the outside for providing installation and support; the propulsion component 20 is assembled and arranged in the box body 10 and is used for controlling the feeding length of the pipeline sample rod; the corner component 30 is fixedly arranged at one side of the upper end of the box body 10 in a bolt connection mode and is used for realizing the bending of the pipeline sample rod; the corner device 40 is assembled and arranged at the upper end of the propulsion component 20, and is used for controlling the rotation angle of the pipeline sample rod around the central axis of the pipeline sample rod.

The box body 10 comprises a through groove 11 which is arranged in the box body 10, and the side view cross section of the box body 10 can be T-shaped or L-shaped, preferably L-shaped; and the through hole 12 is formed in the side wall of the box body 10 and is used for providing installation.

Specifically, the through groove 11 is formed in the box 10, the cross section of the through groove in side view may be T-shaped or L-shaped, in this embodiment, the through groove is preferably L-shaped, and the propulsion assembly 20 is assembled and disposed in the through groove; the through hole 12 is formed on the side wall of the case 10, and the through hole 12 communicates with the through groove 11 inside the through hole 12 to provide mounting for the propulsion unit 20.

The propulsion component 20 comprises a screw 21 which is assembled inside the through groove 11 through the through hole 12; an L-shaped slide arm 22 composed of a slide arm rod and a nut, the slide arm rod is assembled on the screw 21 through the nut, and the slide arm rod extends outwards along the through groove 11; a position indicator 23 mounted on the front end of the outer side of the slide arm rod of the L-shaped slide arm 22, and provided with a length scale at the upper end thereof in contact with the box 10 for determining the feeding length of the pipeline sample rod; and the sliding block 24 is assembled at the upper end of the outer side of the sliding arm rod of the L-shaped sliding arm 22 and is used for driving the pipeline sample rod to move in the horizontal direction.

Specifically, the screw 21 is assembled inside the through groove 11 through the through hole 12, and can freely rotate in the through groove 11; the L-shaped sliding arm 22 consists of a sliding arm rod and a nut, the nut is assembled on the screw 21 in a threaded connection mode, so that the L-shaped sliding arm 22 moves on the screw 21 through the nut when the screw 21 is rotated, and the L-shaped sliding arm 22 is provided with two sliding arm rods which respectively extend outwards along the through groove 11 until contacting with the space above and in front of the box body 10; the position indicator 23 is assembled at the front end of the sliding arm rod of the L-shaped sliding arm 22 in a threaded connection mode, and is positioned in front of the outer side of the box body 10, a length scale is arranged at the position where the upper end of the position indicator 23 contacts with the box body 10, the end far away from the corner assembly 30 is a starting point of a numerical value 0, and the position indicator 23 is used for determining the feeding length of the pipeline sample rod; the sliding block 24 is assembled at the upper end of the sliding arm rod of the L-shaped sliding arm 22 in a threaded connection manner, and is located above the outer side of the box 10, and is used for driving the pipeline sample rod to move in the horizontal direction.

The corner assembly 30 comprises a clamping fixture 31, is fixedly arranged at the upper end of the box body 10 near the through groove 11, is provided with an angle scale on the upper surface, and is provided with a circle of grooves on the side wall for placing a pipeline sample rod; a clamping shoe 32, one end of which is arranged on the side wall of the mould 31, a groove is arranged on the side wall of the clamping shoe, the size of which is matched with that of the groove of the mould 31, and the other end of which extends towards the direction of the through groove 11 and is used for bending the pipeline sample rod in cooperation with the rotation of the mould 31; the angle measurer 33 is fixedly arranged at the center of the angle scale at the upper end of the clamping fixture 31 and is used for determining a bending angle; wherein, the clamping fixture 31 and the groove of the clamping shoe 32 form a hole structure for installing the pipeline sample rod after being matched, and the central axis of the hole structure coincides with the central axis of the pipeline sample rod and is parallel to the central axis of the through groove 11 in the vertical direction.

Specifically, the clamping fixture 31 is disposed near the through groove 11 and is fixed on one side of the upper end of the box body 10, the upper surface thereof is provided with an angle scale, and the side wall thereof is provided with a circle of grooves for placing the pipeline sample rod; one end of the clamping shoe 32 is clamped and arranged on the side wall of the clamping mould 31, a groove is formed in the side wall of the clamping shoe, and the size of the clamping shoe is matched with that of the groove of the clamping mould 31 and is used for clamping a pipeline sample rod; the other end of the clamping shoe 32 extends towards the direction of the through groove 11 and is used for bending the pipeline sample rod in cooperation with the rotation of the clamping mould 31; the clamping fixture 31 and the grooves of the clamping shoe 32 form a hole-shaped structure for installing a pipeline sample rod after being matched, the central axis of the hole-shaped structure coincides with the central axis of the pipeline sample rod and is parallel to the central axis of the through groove 11 in the vertical direction, so that the pipeline sample rod does not deviate along the linear motion when the sliding block 24 moves in the through groove 11; the angle measurer 33 is fixedly arranged at the center of an angle scale at the upper end of the clamping fixture 31 in a bolt connection mode, so that the angle measurer 33 does not rotate along with the clamping fixture 31 when the clamping fixture 31 rotates, and is used for measuring the rotation angle of the clamping fixture 31 and further determining the bending angle of the pipeline sample rod; when the clamping shoe 32 and the pipeline sample rod are perpendicular to each other, the pointing angle of the angle measurer 33 is an angle datum point.

The sliding block 24 is provided with an assembly hole along the feeding direction of the pipeline sample rod, and the corner device 40 is assembled in the assembly hole; one end of the corner device 40 is provided with an angle scale for determining the rotation angle of the pipeline sample rod, and the other end of the corner device is provided with an assembly clamping groove for enabling the pipeline sample rod to be in fastening connection with the corner device 40.

Specifically, the sliding block 24 is provided with an assembly hole along the feeding direction of the pipeline sample rod, one end of the corner device 40 is assembled in the sliding block 24 in a rotating connection manner, and an angle scale is arranged on the side wall of the sliding block 24 and used for determining the rotation angle of the pipeline sample rod; the other end of the corner device 40 extends to the opposite side and passes through the sliding block 24, and the tail end is provided with an assembly clamping groove for enabling the pipeline sample rod to be fixedly connected with the corner device 40, so that the pipeline sample rod rotates along with the corner device 40.

The working procedure of this embodiment is:

the application method of the auxiliary bending equipment for the pipeline sample rod comprises the following steps:

step 1, all positions of the sliding block 24, the clamping fixture 31 and the corner device 40 are zeroed;

step 2, inserting a pipeline sample rod to be simulated into an assembly clamping groove of the corner device 40 through a hole-shaped structure between the clamping mould 31 and the clamping tile 32;

step 3, calculating bending data of simulated bending of the sample rod according to lofting and sampling data provided on site through calculation in a certain proportion, wherein the bending data comprises information such as feeding length, bending starting point position, straight pipe section length, corner angle, bent angle and the like;

step 4, rotating the screw 21 according to the length of the straight pipe section and the starting point position, so that the L-shaped sliding arm 22 moves and drives the sliding block 24 to push the pipeline sample rod to advance, and determining the position of the sliding block 24 and calculating the moving distance by observing the position indicator 23;

step 5, after the starting point position reaches the corner assembly 30, clamping the pipeline sample rod on the clamping fixture 31 through the clamping shoe 32, rotating the clamping fixture 31 according to the corner angle, and determining the bending angle of the pipeline sample rod by observing the corner measurer 33;

step 6, after primary bending is completed, loosening the clamping shoe 32, resetting the clamping fixture 31 to zero, and adjusting the rotation angle of the corner device 40 according to the rotation angle so that the pipeline sample rod rotates according to data;

and 7, repeating the steps 4, 5 and 6 until the simulated bending of all the starting bending point positions of the pipeline sample rod is completed.

The invention is characterized in that:

the invention is characterized in that a through groove 11 and a through hole 12 are formed in a box body 10, a pushing assembly 20 consisting of a screw 21, an L-shaped sliding arm 22, a position indicator 23 and a sliding block 24 is arranged in the box body 10, a corner assembly 30 consisting of a clamping shoe 32, a clamping shoe 31 and a corner measurer 33 is arranged on one side of the upper end of the box body 10, and a corner measurer 40 is assembled on the sliding block 24. In the actual use process, the pipeline sample rod is pushed to advance through the pushing component 20, the clamping shoe 32 is used for clamping the pipeline sample rod on the clamping fixture 31 when the pipeline sample rod reaches the bending starting point position, the clamping fixture 31 is rotated to bend the pipeline sample rod, the steering gear 40 is adjusted to drive the pipeline sample rod to rotate along the central axis, and the steps of pushing, bending, rotating and the like are repeated on the pipeline sample rod until the simulated bending of all the bending starting point positions is completed. Through the technical scheme, equipment is used for accurately adjusting the sample rod in the process of simulating the bending of the sample rod, the rationality of the pipeline design is directly judged, if the phenomenon that the sample rod cannot be bent occurs, bending information is timely modified, an original manual bending simulating method is replaced, the bending simulating result is more reliable and efficient, material loss is reduced, and construction efficiency is improved.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present invention, and although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present invention.

Claims (6)

1. The utility model provides a pipeline appearance pole auxiliary bending equipment which characterized in that:

the box body (10) is arranged on the horizontal plane, and the inside of the box body is provided with a containing space which is communicated with the outside and is used for providing installation and support;

the propelling component (20) is arranged in the box body (10) and used for controlling the feeding length of the pipeline sample rod;

the corner assembly (30) is fixedly arranged at the upper end of the box body (10) and is used for realizing the bending of the pipeline sample rod;

and the corner device (40) is assembled at the upper end of the propulsion component (20) and is used for controlling the rotation angle of the pipeline sample rod around the central axis of the pipeline sample rod.

2. The pipe-line sample rod auxiliary bending apparatus according to claim 1, wherein: the box body (10) comprises a box body,

the through groove (11) is formed in the box body (10), and the side view cross section of the through groove can be T-shaped or L-shaped, preferably L-shaped;

and the through hole (12) is arranged on the side wall of the box body (10) and is used for providing installation.

3. The pipe-line sample rod auxiliary bending apparatus according to claim 2, wherein: the propulsion assembly (20) comprises a housing,

a screw (21) which is fitted into the through-groove (11) through the through-hole (12);

the L-shaped sliding arm (22) consists of a sliding arm rod and a nut, the sliding arm rod is assembled on the screw rod (21) through the nut, and the sliding arm rod extends outwards along the through groove (11) respectively;

the position indicator (23) is assembled at the front end of the outer side of the sliding arm rod of the L-shaped sliding arm (22), and a length scale is arranged at the position where the upper end of the sliding arm rod contacts the box body (10) and is used for determining the feeding length of the pipeline sample rod;

and the sliding block (24) is assembled at the upper end of the outer side of the sliding arm rod of the L-shaped sliding arm (22) and is used for driving the pipeline sample rod to move in the horizontal direction.

4. A tubing wand auxiliary bending apparatus according to claim 3, wherein: the corner assembly (30) includes,

the clamping fixture (31) is fixedly arranged at the upper end of the box body (10) close to the through groove (11), an angle scale is arranged on the upper surface of the clamping fixture, and a circle of groove is formed in the side wall of the clamping fixture and used for placing a pipeline sample rod;

one end of the clamping tile (32) is arranged on the side wall of the clamping mould (31), a groove is formed in the side wall of the clamping tile, the size of the clamping tile is matched with that of the groove of the clamping mould (31), and the other end of the clamping tile extends towards the direction of the through groove (11) and is used for bending a pipeline sample rod in cooperation with the rotation of the clamping mould (31);

the bending angle measurer (33) is fixedly arranged at the center of the angle scale at the upper end of the clamping fixture (31) and is used for determining the bending angle;

the clamping shoe (32) is provided with a clamping shoe (31) and a clamping shoe (11), wherein the clamping shoe is provided with a groove, the groove is provided with a hole-shaped structure for installing a pipeline sample rod, and the central axis of the hole-shaped structure is coincident with the central axis of the pipeline sample rod and is parallel to the central axis of the through groove (11) in the vertical direction.

5. The pipe-line sample rod auxiliary bending apparatus according to claim 4, wherein:

the sliding block (24) is provided with an assembly hole along the feeding direction of the pipeline sample rod, and the corner device (40) is assembled in the assembly hole;

one end of the corner device (40) is provided with an angle scale for determining the rotation angle of the pipeline sample rod, and the other end of the corner device is provided with an assembly clamping groove for enabling the pipeline sample rod to be in fastening connection with the corner device (40).

6. The application method of the auxiliary bending equipment for the pipeline sample rod is characterized by comprising the following steps of: the pipe-line sample rod auxiliary bending apparatus according to claim 5, comprising the steps of:

step 1, all positions of the sliding block (24), the clamping fixture (31) and the corner device (40) are zeroed;

step 2, a pipeline sample rod to be simulated passes through a hole-shaped structure between the clamping mould (31) and the clamping tile (32) and is inserted into an assembly clamping groove of the corner device (40);

step 3, calculating bending data of simulated bending of the sample rod according to lofting and sampling data provided on site through calculation in a certain proportion, wherein the bending data comprises information such as feeding length, bending starting point position, straight pipe section length, corner angle, bent angle and the like;

step 4, rotating the screw rod (21) according to the length of the straight pipe section and the starting point position, enabling the L-shaped sliding arm (22) to move and driving the sliding block (24) to push the pipeline sample rod to advance, determining the position of the sliding block (24) by observing the position indicator (23), and calculating the moving distance;

step 5, after the starting point position reaches the corner assembly (30), clamping the pipeline sample rod on the clamping fixture (31) through the clamping shoe (32), rotating the clamping fixture (31) according to the corner angle, and determining the bending angle of the pipeline sample rod by observing the corner measurer (33);

step 6, after primary bending is completed, loosening the clamping shoe (32) and returning the clamping fixture (31) to zero, and adjusting the rotation angle of the corner device (40) according to the rotation angle so that the pipeline sample rod rotates according to data;

and 7, repeating the steps 4, 5 and 6 until the simulated bending of all the starting bending point positions of the pipeline sample rod is completed.