CN219093857U - Automatic chamfering device for round tubular parts - Google Patents

Abstract

The utility model relates to the technical field of pipe machining, and discloses an automatic chamfering device for circular pipe-shaped parts, which structurally comprises a bottom plate, a servo indexing motor, a turntable, a supporting column, a chamfering assembly, a feeding chute, a discharging chute and a pressing assembly, and has the beneficial effects that: through being provided with swage subassembly and chamfer subassembly, compress tightly the pipe part of embedding on the carousel with the help of swage cylinder and leading the positive blend stop, then drive the chamfer cutter with the help of the chamfer cylinder and chamfer to the pipe part, can make the pipe part more neat, the chamfer degree of depth is more unanimous to the work that the device is repeated constantly on a circle can realize processing in batches, realizes not having artificial automatic chamfer operation, has reduced workman's working strength, has improved the efficiency of work.

Description

Automatic chamfering device for round tubular parts

Technical Field

The utility model relates to the technical field of pipe machining, in particular to an automatic chamfering device for circular pipe-shaped parts.

Background

The round tube is a steel material with two open ends and a hollow concentric circle section, the length of the steel material is larger than the length of the steel material at the periphery, the steel material can be used for pipelines, thermal equipment, mechanical industry, petroleum geological drilling, containers, chemical industry and special purposes, and in the industrial production process, as the round tube is provided with burrs after being processed and produced, the round tube is usually required to be cut and chamfered into a required round tube and then applied;

the utility model provides a steel pipe chamfering device as disclosed in patent document CN212705862U, the on-line screen storage device comprises a workbench, install a plurality of bottoms on the workstation and take the seat, install a pair of post of taking on the seat of taking, the steel pipe overlap joint is between two adjacent posts of taking, the left end position department of workstation top surface is equipped with the chamfer seat, power storehouse and chamfer storehouse have been seted up respectively to the left and right sides of chamfer seat, install the rotation motor in the power storehouse, the output shaft end of rotation motor stretches into in the chamfer storehouse and coaxial coupling has the stick of polishing, rotation motor and stick of polishing all are the slope form, the position department that chamfer storehouse top surface is located is less than the top position of steel pipe. This steel pipe chamfer device takes seat and chamfer seat through setting up the end on the workstation for overlap joint steel pipe to the chamfer seat again and promote the steel pipe and make the steel pipe support behind the side of chamfer seat, stir the steel pipe when making the steel pipe rotate on the end take the seat through the steel pipe, the interior mouth of steel pipe can be evenly chamfer work to the stick of polishing of chamfer seat internal rotation, increases the aesthetic property of steel pipe.

Based on the above, although the problem that the round pipe is uneven in chamfering can be solved in the above patent, because the device can only process one round pipe at a time when working, the chamfering can not be processed in a large scale, and the production efficiency is low, so that the labor intensity of workers is increased, and the working efficiency is reduced.

Disclosure of Invention

1. Technical problem to be solved by the utility model

Aiming at the problems in the prior art, the utility model aims to provide an automatic chamfering device for round pipe-shaped parts, which has the function of chamfering round pipes in a large batch.

2. Technical proposal

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

the utility model provides an automatic chamfer device to tubular part, its structure is including the bottom plate, installs servo graduation motor on the bottom plate, and servo graduation motor's output shaft is connected with the carousel, and the carousel passes through link and bottom plate clearance fit, and the top of bottom plate is fixed with the support column, installs the swager subassembly on the support column, and one side that servo graduation motor was kept away from to the carousel is equipped with the chamfer subassembly, and the chamfer subassembly is fixed with the bottom plate, and the both sides of bottom plate are fixed with feed chute and blown down tank through the connecting plate.

As optimization, the chamfering assembly comprises a chamfering motor, the bottom of the chamfering motor is fixed with a chamfering cylinder, a chamfering tool is movably mounted on the chamfering motor, a collecting box is arranged right below the chamfering tool, and the collecting box is fixed with a supporting column.

The chamfering motor is arranged, and the chamfering cutter can be driven to rotate by means of power of motor rotation to chamfer round pipe parts.

The chamfering cylinder can drive the chamfering motor to move forwards and backwards by means of the telescopic performance of the cylinder.

The collecting box is arranged, and scraps generated during chamfering of the round pipe parts can be collected.

As optimization, the discharging groove is provided with a stripping baffle which can be contacted with the circular pipe-shaped part on the turntable.

The setting of above-mentioned material separation blade that takes off can form spacing blocking to the pipe part of accomplishing the chamfer on the carousel for the pipe part can drop from the carousel.

As optimization, the material pressing assembly comprises a material pressing cylinder, one side of the material pressing cylinder is connected with the support column, and a guide baffle strip is arranged on the other side of the material pressing cylinder.

The setting of above-mentioned swager cylinder can compress tightly the pipe part on the carousel, and the chamfer cutter of being convenient for chamfer the part.

The setting of the guide baffle strip can enable round pipe parts embedded into the turntable to be more neat and the chamfering depth to be more consistent.

As optimization, the turntable comprises a rotating shaft, the rotating shaft is arranged at the circle center of the turntable, the rotating shaft is fixed with the output end of the servo indexing motor, and the annular array on the turntable is provided with clamping grooves.

3. Advantageous effects

Compared with the prior art, the utility model has the advantages that:

according to the automatic chamfering device for the circular pipe-shaped parts, the pressing assembly and the chamfering assembly are arranged, the circular pipe parts embedded in the turntable can be pressed by means of the pressing cylinder and the guide baffle strip, and then the chamfering tool is driven by the chamfering cylinder to chamfer the circular pipe parts, so that the circular pipe parts are tidier, the chamfering depth is more consistent, the device can work continuously and repeatedly, a large number of machining can be performed, manual automatic chamfering operation is not needed, the working intensity of workers is reduced, and the working efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of an automatic chamfering device for round tubular parts according to the present utility model;

FIG. 2 is a schematic view of the structure of the automatic chamfering device in the second state of the present utility model;

FIG. 3 is a schematic view of a stripping baffle of the automatic chamfering device;

FIG. 4 is a schematic view of the chamfer assembly of the present utility model;

FIG. 5 is a schematic view of a press assembly according to the present utility model;

FIG. 6 is a schematic diagram of a turntable according to the present utility model;

fig. 7 is a schematic structural diagram of a turntable clamping groove according to the present utility model.

Reference numerals in the drawings: the automatic chamfering machine comprises a bottom plate-1, a servo indexing motor-2, a turntable-3, a support column-4, a chamfering component-5, a feed chute-6, a discharge chute-7, a pressing component-8, a stripping baffle-71, a chamfering motor-51, a chamfering cylinder-52, a chamfering cutter-53, a collecting box-54, a pressing cylinder-81, a guide baffle strip-82, a rotating shaft-31 and a clamping groove-32.

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.

An embodiment of the present utility model is shown in fig. 1-7, and is specifically as follows:

the utility model provides an automatic chamfer device to tubular part, its structure is including bottom plate 1, servo indexing motor 2, carousel 3, the support column 4, chamfer subassembly 5, feed chute 6, blown down tank 7, swager subassembly 8, install servo indexing motor 2 on the bottom plate 1, servo indexing motor 2's output shaft is connected with carousel 3, carousel 3 passes through link and bottom plate 1 clearance fit, the top of bottom plate 1 is fixed with support column 4, install swager subassembly 8 on the support column 4, one side that servo indexing motor 2 was kept away from to carousel 3 is equipped with chamfer subassembly 5, chamfer subassembly 5 is fixed with bottom plate 1, the both sides of bottom plate 1 are fixed with feed chute 6 and blown down tank 7 through the connecting plate.

In this embodiment, the chamfering assembly 5 includes a chamfering motor 51, a chamfering cylinder 52, a chamfering tool 53, and a collecting box 54, the bottom of the chamfering motor 51 is fixed with the chamfering cylinder 52, the chamfering tool 53 is movably mounted on the chamfering motor 51, the collecting box 54 is arranged under the chamfering tool 53, the collecting box 54 is fixed with the supporting column 4, the chamfering motor 51 is arranged to drive the chamfering tool 53 to rotate by the power of the motor rotation to chamfer the round pipe part, the chamfering cylinder 52 is arranged to drive the chamfering motor 51 to move back and forth by the expansion and contraction performance of the cylinder, and the collecting box 54 is arranged to collect the scraps generated during chamfering the round pipe part.

In this embodiment, install on the blown down tank 7 and take off material separation blade 71, take off the material separation blade 71 can contact with the pipe form part on the carousel 3, above-mentioned setting that takes off material separation blade 71 can form spacing blocking to the pipe part of accomplishing the chamfer on the carousel 3 for the pipe part can drop from carousel 3.

In this embodiment, the material pressing assembly 8 is including pressing the material cylinder 81, leading the positive blend stop 82, and the one side of pressing the material cylinder 81 is connected with the support column 4, and leading the positive blend stop 82 is installed to the opposite side of pressing the material cylinder 81, and the setting of above-mentioned material pressing cylinder 81 can compress tightly the pipe part on the carousel 3, and the chamfer cutter 53 of being convenient for carries out the chamfer to the part, and the setting of above-mentioned positive blend stop 82 can make the pipe part of embedding carousel more neat, and the chamfer degree of depth is more unanimous.

In this embodiment, the turntable 3 includes a rotating shaft 31 and a clamping groove 32, the rotating shaft 31 is installed at the center of the turntable 3, the rotating shaft 31 is fixed with the output end of the servo indexing motor 2, and the clamping groove 32 is arranged on the turntable 3 in an annular array.

Working principle: when the round pipe parts are required to be chamfered, the slender round pipe parts to be chamfered are neatly placed in the feeding groove 6, then the servo indexing motor 2 is driven to rotate to drive the rotary table 3 provided with the part clamping groove 32 to rotate, the round pipe parts are automatically embedded in the rotary table 3 and gradually ascend along with the rotary table 3 driven by the servo indexing motor 2, meanwhile, the round pipe parts embedded in the rotary table 3 are neater, the chamfering depth is more consistent, part guide blocking strips 82 are arranged on the left side, the right side and the upper side of the rotary table 3, the round pipe parts can be neatly placed on the rotary table 3, when the round pipe parts are rotated to a chamfering station, the material pressing cylinder 81 works to compress the round pipe parts, then the chamfering cylinder 52 works to push the chamfering cutter 53 which always rotates, the chamfering cutter 53 is driven to rotate once by the servo indexing motor 2, then the chamfering cylinder 81 pushes the chamfering motor 51 and the chamfering cutter 53 once, after the chamfering operation is completed, the chamfering cylinder 81 is loosened, the round pipe parts continue to rotate along with the rotary table 3 until the chamfering operation is stopped at the position of the chamfering blocking strip 71, and then the round pipe parts do not need to be manually placed in the chamfering device, and the chamfering device can be stopped along the chamfering device.

The above examples merely represent a few embodiments of the present utility model, which are described in more detail and are not to be construed as limiting the scope of the present utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of the utility model should be assessed as that of the appended claims.

Claims (6)

1. Automatic chamfering device for circular pipe-shaped parts is characterized in that: the structure of the automatic feeding device comprises a bottom plate (1), a servo indexing motor (2) arranged on the bottom plate (1), a rotary table (3) arranged on an output shaft of the servo indexing motor (2), a support column (4) arranged at the top of the bottom plate (1), a pressing component (8) arranged on the support column (4), a chamfering component (5) arranged on one side, far away from the servo indexing motor (2), of the rotary table (3), and a feeding groove (6) and a discharging groove (7) which are arranged on two sides of the bottom plate (1) and fixed through connecting plates;

the chamfering assembly (5) comprises a chamfering motor (51), a chamfering cylinder (52) arranged at the bottom of the chamfering motor (51), a chamfering tool (53) movably matched with the chamfering motor (51) and a collecting box (54) arranged under the chamfering tool (53).

2. The automatic chamfering device for round tubular parts according to claim 1, wherein: and a stripping baffle (71) is arranged on the discharging chute (7).

3. The automatic chamfering device for round tubular parts according to claim 2, wherein: the stripping baffle (71) can be contacted with the circular pipe-shaped part on the turntable (3).

4. The automatic chamfering device for round tubular parts according to claim 1, wherein: the pressing assembly (8) comprises a pressing cylinder (81) and a guide baffle strip (82) arranged on one side of the pressing cylinder (81).

5. The automatic chamfering device for round tubular parts according to claim 4, wherein: the guide baffle strips (82) can enable parts embedded into the turntable (3) to be tidier, and chamfering depths are more consistent.

6. The automatic chamfering device for round tubular parts according to claim 1, wherein: the rotary table (3) comprises a rotary shaft (31) and clamping grooves (32) which are arranged on the rotary table (3) in an annular array.

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