CN216938662U - Beveling device for pipe end - Google Patents

Abstract

The utility model discloses a beveling device for a pipe port, which comprises an installation seat, wherein a first sliding plate is connected above the installation seat in a sliding manner, a second sliding plate is connected above the first sliding plate in a sliding manner, a beveling component is arranged above the second sliding plate, and butting components for butting and supporting the end part of a pipe are respectively arranged on two sides of the first sliding plate.

Description

Beveling device for pipe end opening

Technical Field

The utility model belongs to the technical field of pipe beveling equipment, and particularly relates to a beveling device for a pipe port.

Background

In the prior art, the two ends of a pipe need to be subjected to groove treatment in the process of processing the pipe into a finished pipe product, wherein the groove treatment refers to a slope formed by processing and polishing the two ends of the pipe, a specific groove angle can be selected according to different pipe wall thicknesses, and the groove angle is 45 degrees, 30 degrees and the like.

In the prior art, equipment for grooving a pipe end port is diversified, and the equipment is as follows: CN201922267862.1 discloses a paper tube top layer groove device, including the lower carriage, the processing platform is installed to the lower carriage upside, processing platform upper end both sides are installed first upright wall and second respectively and are found the wall, the motor is installed to first upright wall upper end one side, motor one end transmission is connected with the sloping mouth head, the first inboard of groove is inserted and is equipped with the cutter, the second is found wall upper end one side and is installed the pneumatic cylinder, pneumatic cylinder one end transmission is connected with the telescopic link, paper tube peg graft pole is installed to telescopic link one end, paper tube fixture is installed at paper tube peg graft pole both ends.

Above-mentioned this type of beveling device can carry out the groove to the both ends of tubular product, but this type of current beveling device can only carry out the groove to the surface of tubular product when using, can not carry out the groove to the internal surface of tubular product, reduces and uses position and result of use to whole degree of automation is low, and the result of use is poor, and leads to groove chamfer inefficiency, and groove chamfer is uneven moreover, thereby influences the production quality of tubular product.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the main technical problem of providing a beveling device for a pipe port, which has a simple structure and is convenient to use, can be used for beveling the inner surface and the outer surface of the pipe port, can improve the chamfering precision and the production quality of pipes.

In order to solve the technical problems, the utility model provides the following technical scheme:

the utility model provides a pipe end is groove device for port, includes the mount pad, and the top sliding connection of mount pad has first sliding plate, and the top sliding connection of first sliding plate has the second sliding plate, and the groove subassembly is installed to the top of second sliding plate, and the butt joint subassembly that is used for carrying out the butt joint support to the tip of tubular product is installed respectively to the both sides of first sliding plate.

The following is a further optimization of the above technical solution of the present invention:

the groove component comprises a groove driving motor fixedly installed above the second sliding plate, and at least one groove cutter is fixedly installed on a power output shaft of the groove driving motor.

And (4) further optimizing: the mounting seat is connected with the first sliding plate in a sliding mode through a first sliding assembly, and a first driving assembly used for driving the first sliding plate to slide is mounted on the mounting seat.

Further optimization: the first sliding assembly comprises two first sliding rails which are arranged in parallel and fixedly mounted on the mounting seat, a first sliding block is connected to the upper portion of each first sliding rail in a sliding mode, and the first sliding block is fixedly connected with the lower end face of the first sliding plate.

Further optimization: the first driving assembly comprises a driving cylinder arranged between the mounting seat and the first sliding plate, the driving cylinder is fixedly mounted on the mounting seat, and the telescopic end of the driving cylinder is fixedly connected with the first sliding plate.

Further optimization: the first sliding plate is connected with the second sliding plate in a sliding mode through a second sliding assembly, and a second driving assembly used for driving the second sliding plate to slide is installed on the first sliding plate.

Further optimization: the second sliding assembly comprises two second sliding rails which are arranged in parallel and fixedly installed on the first sliding plate, a second sliding block is connected above the second sliding rails in a sliding mode, and the second sliding block is fixedly connected with the second sliding plate.

Further optimization: the second driving assembly comprises a servo driving motor fixedly mounted on the first sliding plate, and a power output end of the servo driving motor is in transmission connection with the second sliding plate through a transmission assembly.

Further optimization: the top connection component comprises support rods which are fixedly installed on the first sliding plate and are close to the positions of the two sides of the first sliding plate, and the other ends of the two support rods are respectively arranged on the two sides of the groove cutter.

Further optimization: and the positions on one side surface of the supporting rod, which are close to the upper end of the supporting rod, are respectively and rotatably provided with a top-connecting roller.

By adopting the technical scheme, the automatic beveling machine is ingenious in concept, reasonable in structure, convenient to use, stable in overall operation, simple in overall structure, convenient to use, and capable of conducting automatic beveling operation on a pipe, greatly reducing labor intensity, reducing production cost and further improving economic benefits of enterprises, and is simple in overall structure, convenient to use, capable of improving use effect and reducing use cost.

The utility model is further illustrated with reference to the following figures and examples.

Drawings

FIG. 1 is a schematic view of the overall structure of embodiment 1 of the present invention;

FIG. 2 is a schematic structural view in use in embodiment 1 of the present invention;

fig. 3 is a schematic structural view in use in embodiment 2 of the present invention.

In the figure: 1-mounting a base; 2-a first sliding bar; 3-a second sliding plate; 4-groove driving motor; 5, beveling a cutter; 6-a first slide rail; 7-a first slider; 8-driving the cylinder; 9-a second slide rail; 10-a second slide; 11-a servo drive motor; 12-a connecting seat; 13-a support bar; 14-top-connected rollers; 15-a drive roller; 16-a sliding platform assembly; 17-a sliding seat; 18-a third slide rail; 19-a third slide; 20-a threaded rod; 21-a thread block; 22-a servo motor; 23-a base; 24-a base; 25-a support frame; 26-a chuck; 27-power motor.

Detailed Description

Example 1: referring to fig. 1-3, a beveling apparatus for a pipe port includes an installation base 1, a first sliding plate 2 is slidably connected above the installation base 1, a second sliding plate 3 is slidably connected above the first sliding plate 2, a beveling assembly is installed above the second sliding plate 3, and butting assemblies for butting and supporting an end of a pipe are respectively installed on two sides of the first sliding plate 2.

The groove component comprises a groove driving motor 4 fixedly arranged above the second sliding plate 3, and at least one groove cutter 5 is fixedly arranged on a power output shaft of the groove driving motor 4.

The groove driving motor 4 works to drive the groove cutter 5 to rotate at a high speed, and the groove cutter 5 can be used for performing groove operation on a port of a pipe when rotating at the high speed.

The sliding directions of the first sliding plate 2 and the second sliding plate 3 are arranged in the same direction.

The mounting base 1 is connected with the first sliding plate 2 in a sliding mode through a first sliding assembly, and the mounting base 1 is provided with a first driving assembly used for driving the first sliding plate 2 to slide.

The first sliding assembly comprises two first sliding rails 6 which are arranged in parallel, the length of the first sliding plate 2 and the sliding direction of the first sliding plate 2 are arranged in parallel, and the first sliding rails 6 are fixedly installed on the installation base 1.

A first sliding block 7 is connected above the first sliding rail 6 in a sliding manner, and the first sliding block 7 is fixedly connected with the lower end face of the first sliding plate 2.

By the design, the first sliding plate 2 can be slidably mounted on the mounting base 1 through the sliding connection between the first sliding block 7 and the first sliding rail 6, and the assembly and the mounting are convenient.

The first driving assembly comprises a driving cylinder 8 arranged between the mounting seat 1 and the first sliding plate 2, the driving cylinder 8 is fixedly mounted on the mounting seat 1, and the telescopic end of the driving cylinder 8 is fixedly connected with the first sliding plate 2.

The driving cylinder 8 outputs power to drive the first sliding plate 2 to move, and the first sliding plate 2 can be stably moved by the cooperation of the first sliding block 7 and the first sliding rail 6.

The first sliding plate 2 and the second sliding plate 3 are slidably connected through a second sliding member, and a second driving member for driving the second sliding plate 3 to slide is installed on the first sliding plate 2.

The second sliding assembly comprises two second sliding rails 9 which are arranged in parallel, the length of the second sliding rails 9 is arranged in parallel with the sliding direction of the second sliding plate 3, and the second sliding rails 9 are fixedly arranged on the first sliding plate 2.

A second sliding block 10 is connected above the second sliding rail 9 in a sliding manner, and the second sliding block 10 is fixedly connected with the second sliding plate 3.

By means of the design, the second sliding plate 3 can be slidably mounted on the first sliding plate 2 through the sliding connection between the second sliding block 10 and the second sliding rail 9, and the assembly and the mounting are convenient.

The second driving component comprises a servo driving motor 11 fixedly arranged on the first sliding plate 2, and the power output end of the servo driving motor 11 is in transmission connection with the second sliding plate 3 through a transmission component.

The transmission assembly is prior art, and the transmission assembly includes the lead screw, and threaded connection has the movable block on the lead screw, and the one end and the 11 transmission of servo drive motor of lead screw are connected, and movable block fixed mounting is on second sliding plate 3.

By the design, the servo driving motor 11 can drive the second sliding plate 3 to slide through the transmission assembly, and the second sliding plate 3 can be stably moved through the cooperation of the second sliding block 10 and the second sliding rail 9.

A connecting seat 12 is fixedly arranged above the second sliding plate 3, and the bevel driving motor 4 is fixedly arranged on the connecting seat 12.

In this embodiment, there are two beveling cutters 5, and the two beveling cutters 5 are respectively and fixedly mounted on the power output shaft of the bevel driving motor 4.

The two beveling cutters 5 are arranged at intervals, and the interval distance of the two beveling cutters 5 is matched with the wall thickness of the pipe to be beveled.

By the design, the inner surface and the outer surface of the pipe port can be synchronously beveled by the two beveling cutters 5, so that the working speed of beveling operation can be improved, and the using effect can be improved.

In addition to this embodiment, the number of the groove cutters 5 may also be one, and one groove cutter 5 is used for performing a single groove on the inner surface or the outer surface of the pipe end.

When the beveling operation is performed on the outer surface of the pipe end opening, an outer surface beveling cutter is selected and assembled on a power output shaft of the bevel driving motor 4.

When the inner surface of the pipe end is subjected to groove operation, an inner surface groove cutter is selected and assembled on a power output shaft of the groove driving motor 4.

The top connection component comprises support rods 13 which are fixedly arranged on the first sliding plate 2 and are close to the two sides of the first sliding plate, and the other ends of the two support rods 13 are respectively arranged on the two sides of the beveling knife 5.

And abutting rollers 14 are rotatably mounted on one side surface of the support rod 13 near the upper end thereof.

When the device is used, the cylinder 8 is driven to output power to drive the first sliding plate 2 to move towards one side close to the pipe, and the first sliding plate 2 can drive the support rod 13 and the butting roller 14 to move towards one side close to the pipe.

At this time, the butting roller 14 can be butted with the end face of the pipe to be beveled, so that the axial position of the pipe to be beveled is positioned.

Then the bevel driving motor 4 works, and the bevel driving motor 4 works to drive the bevel cutter 5 to rotate at a high speed.

Then the servo driving motor 11 works, the servo driving motor 11 works to drive the second sliding plate 3 to move towards one side close to the pipe, at the moment, the second sliding plate 3 drives the beveling cutter 5 rotating at a high speed to feed, so that the beveling cutter 5 is in contact with the pipe to be beveled, and the beveling cutter 5 rotating at a high speed is used for beveling two ports of the pipe to be beveled, so that the pipe beveling machine is convenient to use.

When in use, as shown in fig. 2, two pipe port beveling devices are provided, and the two pipe port beveling devices are respectively disposed on the base 23, and the sliding platform assembly 16 is fixedly mounted on the base 23.

One of the tube ports is mounted on the sliding platform assembly 16 by a beveling device, and the other tube port is fixedly mounted on the base 23 by the beveling device.

And the driving rollers 15 are respectively rotatably installed at two sides of the bevel knife 5 above the base 23, and two ends of the driving rollers 15 are respectively supported by bearing seats to rotate.

The driving roller 15 is driven by a peripheral driving assembly (not shown in the figure), which may be composed of a chain and a driving motor, and the peripheral driving assembly is not described herein in detail for the prior art.

The design can be with treating that the tubular product of groove is installed between two drive rollers 15, drive roller 15 rotates this moment and can drive the tubular product of treating the groove and rotate, and sliding platform subassembly 16 work can drive the beveling device for the tubular product port on the sliding platform subassembly 16 and move to the one side that is close to another tubular product port and uses the beveling device, and butt joint roller 14 through two tubular product ports for the beveling device this moment can with treat the terminal surface butt joint of groove tubular product mutually, and then the realization is treated the axial position of groove tubular product and is fixed a position.

And the beveling device for the pipe end can be used for beveling the pipe to be beveled.

In this embodiment, the sliding platform assembly 16 includes a sliding seat 17 slidably mounted on the upper end surface of the base 23, the sliding direction of the sliding seat 17 is parallel to the axis of the driving roller 15, and one of the pipe ports is fixedly mounted on the sliding seat 17 by a beveling device.

Two third sliding rails 18 which are arranged in parallel are fixedly arranged on the upper end surface of the base 23, and the third sliding rails 18 and the axis of the driving roller 15 are arranged in parallel in space.

A third slide block 19 is slidably mounted on the third slide rail 18, and the slide seat 17 is fixedly mounted on the third slide block 19.

A threaded rod 20 is rotatably mounted on the base 23, and the threaded rod 20 is arranged between the two third slide rails 18.

Two ends of the threaded rod 20 are respectively rotatably mounted on bearing supports which are fixedly mounted on the base 23.

The threaded rod 20 is connected with a threaded block 21 in a threaded manner, and the threaded block 21 is fixedly arranged on the sliding seat 17.

A servo motor 22 is fixedly installed on the base 23, and the power output end of the servo motor 22 is in transmission connection with the threaded rod 20.

Design like this, servo motor 22 output power drive threaded rod 20 rotates, and threaded rod 20 rotates and drives screw block 21 and remove, and screw block 21 removes and drives sliding seat 17 and remove, and then realizes driving corresponding beveling device for the tubular product port and remove to the both sides that are close to or keep away from another beveling device for the tubular product port, facilitates the use.

Embodiment 2, in this embodiment, the beveling apparatus for a pipe port may be further installed on a base 24, a support frame 25 is further installed on the base 24, and the support frame 25 and the beveling apparatus for a pipe port are arranged at an interval.

A chuck 26 for mounting a pipe to be beveled is arranged on one side of the support frame 25 close to the beveling device for the pipe port, and a power motor 27 for driving the chuck 26 to rotate automatically is mounted on the support frame 25.

The chuck 26 is prior art and may be a three-grip chuck, which is not described in detail herein.

When the beveling device is used, one end of a pipe to be beveled can be arranged on the chuck 26, and then the butting roller 14 of the beveling device for the pipe port can be butted with the other end of the pipe to be beveled.

At this moment, the power motor 27 can drive the chuck 26 to rotate automatically, the chuck 26 rotates to drive the pipe to be beveled to rotate, and the beveling device for the pipe port can be used for beveling one end of the pipe, so that the pipe is convenient to use.

It will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in the embodiments described above without departing from the principles and spirit of the utility model, the scope of which is defined by the appended claims.

Claims (10)

1. The utility model provides a groove device for tubular product port, includes mount pad (1), its characterized in that: the top sliding connection of mount pad (1) has first sliding plate (2), and the top sliding connection of first sliding plate (2) has second sliding plate (3), and the groove subassembly is installed to the top of second sliding plate (3), and the top that is used for carrying out the top to connect the support to the tip of tubular product is installed respectively to the both sides of first sliding plate (2) and is connect the subassembly.

2. The beveling apparatus for a pipe port according to claim 1, wherein: the groove component comprises a groove driving motor (4) fixedly arranged above the second sliding plate (3), and at least one groove cutter (5) is fixedly arranged on a power output shaft of the groove driving motor (4).

3. The beveling apparatus for a pipe port according to claim 2, wherein: the mounting seat (1) is connected with the first sliding plate (2) in a sliding mode through a first sliding assembly, and a first driving assembly used for driving the first sliding plate (2) to slide is mounted on the mounting seat (1).

4. The beveling apparatus for a pipe port according to claim 3, wherein: the first sliding assembly comprises two first sliding rails (6) which are arranged in parallel and fixedly mounted on the mounting base (1), a first sliding block (7) is connected to the upper portion of each first sliding rail (6) in a sliding mode, and the first sliding block (7) is fixedly connected with the lower end face of the first sliding plate (2).

5. The beveling apparatus for a pipe port of claim 4, wherein: the first driving assembly comprises a driving cylinder (8) arranged between the mounting seat (1) and the first sliding plate (2), the driving cylinder (8) is fixedly mounted on the mounting seat (1), and the telescopic end of the driving cylinder (8) is fixedly connected with the first sliding plate (2).

6. The beveling apparatus for a pipe port of claim 5, wherein: the first sliding plate (2) is in sliding connection with the second sliding plate (3) through a second sliding assembly, and a second driving assembly for driving the second sliding plate (3) to slide is mounted on the first sliding plate (2).

7. The beveling apparatus for a pipe port according to claim 6, wherein: the second sliding assembly comprises two second sliding rails (9) which are arranged in parallel and fixedly mounted on the first sliding plate (2), a second sliding block (10) is connected above the second sliding rails (9) in a sliding mode, and the second sliding block (10) is fixedly connected with the second sliding plate (3).

8. The beveling apparatus for a pipe port according to claim 7, wherein: the second driving component comprises a servo driving motor (11) fixedly installed on the first sliding plate (2), and a power output end of the servo driving motor (11) is in transmission connection with the second sliding plate (3) through a transmission component.

9. The beveling apparatus for a pipe port according to claim 8, wherein: the top connection component comprises support rods (13) which are fixedly installed on the first sliding plate (2) and are close to the positions of the two sides of the first sliding plate, and the other ends of the two support rods (13) are respectively arranged on the two sides of the beveling knife (5).

10. The beveling apparatus for a pipe port according to claim 9, wherein: and abutting rollers (14) are respectively and rotatably arranged at the positions close to the upper ends of the supporting rods (13) on one side surface.

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