CN214978429U - Deslagging device of intersecting line cutting machine - Google Patents

Abstract

The utility model discloses an intersecting line cutting machine dross removal mechanism, include: a first guide rail disposed at one side; the slag receiving system is arranged on the first guide rail and comprises a slag receiving pipe extending to one side, and the slag receiving system moves along the first guide rail; the rotary supporting seat and the slag receiving hopper are arranged on the slag receiving pipe, the slag receiving hopper is arranged at the end part of the slag receiving pipe, and the rotary supporting seat is arranged on the inner side of the slag receiving hopper; the dust removal system is arranged on one side of the slag receiving system and is connected with the slag receiving system through a pipeline; the cutting system is arranged on the other side of the slag receiving system and comprises a plurality of bracket groups and a cutting head, and the plurality of bracket groups are arranged below the cutting head; the slag receiving pipe extends to the position between the plurality of bracket groups and the cutting head. Through setting up dust pelletizing system and receiving the sediment system, can also reduce the purpose of workshop production pollution when using plasma cutting technology.

Description

Deslagging device of intersecting line cutting machine

Technical Field

The utility model relates to an intersecting line cutting machine field, in particular to intersecting line cutting machine dross removal mechanism.

Background

At present, the requirement of customers on the surface quality of the inner wall of the pipe cut by the intersecting line is gradually improved, so that certain materials can be delivered only by the procedures of acid washing, fine polishing and the like after being cut.

The surface treatment process of the cut pipe is roughly divided into the following two types. The method comprises the following steps: and carrying out cold machining on the inner wall of the pipe. However, the traditional cold machining has special requirements on the notch gradient of the thick-wall pipe, and meanwhile, the cold machining time is long, and the equipment cost is high. Although the surface quality of the inner wall of the pipe can be ensured, the method does not meet the actual requirement of large-scale mass production of enterprises. The second method comprises the following steps: after the inner wall of the pipe is coated with the insulating material, the inner wall of the pipe is cut by using a plasma process, so that slag can be prevented from splashing to the inner wall of the pipe during cutting. But often the condition that the insulating material is unevenly brushed exists, and the cutting quality is directly influenced. And certain harmful substances usually exist in the insulating material, when the harmful substances meet plasma, a large amount of dust is generated and is mixed with the cut metal powder, the body of an operator is seriously harmed, and the production environment of a workshop is polluted.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects in the prior art, the utility model aims to provide an intersecting line cutting machine dross removal mechanism, which achieves the purpose of reducing operation pollution.

In order to realize the purpose, the utility model discloses the technical scheme who adopts is:

the utility model provides an intersection line cutting machine dross removal mechanism, includes:

a first guide rail disposed at one side;

the slag receiving system is arranged on the first guide rail and comprises a slag receiving pipe extending to one side, and the slag receiving system is driven by a motor to move along the first guide rail;

the rotary supporting seat and the slag receiving hopper are arranged on the slag receiving pipe, the slag receiving hopper is arranged at the end part of the slag receiving pipe, and the rotary supporting seat is arranged on the inner side of the slag receiving hopper;

the dust removal system is arranged on one side of the slag receiving system and is connected with the slag receiving system through a pipeline;

the cutting system is arranged on the other side of the slag receiving system and comprises a plurality of bracket groups and a cutting head, the plurality of bracket groups are arranged below the cutting head, and the plurality of bracket groups are used for bearing a working workpiece;

the slag receiving pipe extends to the position between the plurality of bracket groups and the cutting head.

In a preferred embodiment of the present invention, the slag receiving system further comprises a slag receiving pipe installation box directly disposed on the first guide rail, one side of the slag receiving pipe installation box is connected to the dust removing system through a pipeline, and the other side of the slag receiving pipe installation box is connected to one end of the slag receiving pipe.

In a preferred embodiment of the utility model, the dust pelletizing system includes slip air outlet, slip air suction channel and dust removal host computer, the slip air outlet install slip air suction channel top, slip air outlet one end pass through the pipeline with connect the sediment pipe install bin to connect, the parallel setting in first guide rail in slip air suction channel is in one side of first guide rail, the dust removal host computer links to each other with slip air suction channel one end.

In a preferred embodiment of the present invention, the cutting system further includes a spindle headstock, a second guide rail, a third guide rail and a moving cart, the bracket set is disposed on the second guide rail, the spindle headstock is disposed between the first guide rail and the second guide rail, the third guide rail is disposed on one side of the second guide rail in parallel, the moving cart is disposed on the third guide rail, and the cutting head is disposed on the moving cart.

In a preferred embodiment of the present invention, a chuck spindle inner bushing is disposed in the spindle headstock, and the slag receiving pipe passes through the chuck spindle inner bushing.

In a preferred embodiment of the present invention, the bracket set includes a support wall, a guide wheel, a roller, a support tube and a bracket connection frame, the guide wheel is disposed on the lower portion of the bracket connection frame, and the second guide rail contacts the support wall, the support wall is an "x" type cross structure, the lower end is fixed on the bracket connection frame, the roller is laterally disposed above the support wall, and the support tube is disposed between the rollers through a ball axle.

In a preferred embodiment of the present invention, a ball axle gland is further disposed on the ball axle.

In a preferred embodiment of the present invention, the rotary support base includes a support that is attached to an inner wall of the work piece.

In a preferred embodiment of the present invention, a slag receiving hopper connecting pipe is further disposed above the slag receiving hopper and close to the inner wall of the work piece.

The beneficial effects of the utility model reside in that:

the utility model provides an intersecting line cutting machine dross removal mechanism through setting up dust pelletizing system and connecing the sediment system, can also reduce workshop production pollution's purpose when reaching the use plasma cutting technology.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a top view of the structure of the present invention.

Fig. 2 is a front view of the product structure of the present invention.

Fig. 3 is an enlarged front view of the bracket assembly of the present invention.

Fig. 4 is an enlarged side view of the bracket assembly of the present invention.

Fig. 5 is a side view enlarged view of the headstock body of the utility model.

FIG. 6 is an enlarged sectional view of the slag receiving pipe of the present invention.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "left", "right", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

The detailed structure of the present invention will be further described with reference to the accompanying drawings and the detailed description.

Referring to fig. 1 and 2, the deslagging device of the intersecting line cutting machine comprises a pair of first guide rails 4 arranged on the left side, wherein a slag receiving pipe installation box 5 is arranged on the first guide rails 4, and the slag receiving pipe installation box 5 can reciprocate along the first guide rails 4 under the driving of a motor. The inner side of the slag receiving pipe installation box 5 is provided with a sliding air suction opening 2 which is connected with the slag receiving pipe installation box through a pipeline. A sliding air suction channel 3 is arranged below the sliding air suction opening 2, and when the slag receiving pipe installation box 5 moves along the first track 4, the sliding air suction opening 2 is synchronously driven to move on the sliding air suction channel 3. The left end of the sliding air suction duct 3 is connected with the dust removal host 1. A slag receiving pipe 6 parallel to the first rail 4 is arranged on the right side of the slag receiving pipe installation box 5. The rightmost end of the first rail 4 is provided with a main shaft head box body 8, and the main shaft head box body 8 is a rectangular box body and is used for clamping and driving a workpiece 13 to rotate. A second track 14b is provided on the right side of the spindle case 8, and a plurality of carrier groups 12 are provided on the second track 14 b. The other end of the slag receiving pipe 6 passes through the main shaft box body 8 and is connected with a slag receiving hopper 10. A third rail 14a is arranged above the second rail 14b in parallel, the moving trolley 11 is arranged on the third guide rail 14a, and the cutting head 15 is arranged on the moving trolley 11 and used for cutting the workpiece 13.

Referring to fig. 3 and 4 in combination, the bracket assembly 12 is used to hold the workpiece 13, and in particular, to hold the workpiece 13 from falling off and interfering with the slag receiving hopper 10 and the slag receiving pipe 6 after the cutting operation is completed. The bracket 12 mainly includes a guide wheel 24, a roller 18, a bracket link 22, and a support pipe 21. The carriage assembly 12 is in contact with the second guide rail 14b through a plurality of guide wheels 24 provided at the bottom of the carriage connecting frame 22 and is reciprocally movable along the second guide rail 14 b. Supporting walls 25 in an X-shaped crossed structure are arranged above the guide wheels 24, the rollers 18 are laterally arranged above the supporting walls 25, a supporting pipe 21 connected through a ball shaft 19 is arranged between each pair of rollers 18, and a ball shaft gland 20 is further arranged on the ball shaft 19. Before the workpiece 13 is cut, the workpiece 13 is placed on the bracket set 12, the support wall 25 is clamped by adjusting the rotary screw 23 below the support wall 25, and the roller 18 is tightly attached to the outer surface of the workpiece 13; when the work piece 13 is cut, the blocked work piece 13 is lifted up by the support pipe 21 to be prevented from falling.

With combined reference to fig. 5 and 6, the slag receiving pipe 6 passes through the spindle headstock 8, specifically, the chuck spindle inner bushing 7 provided in the spindle headstock 8. The rotary supporting seat 9 is arranged on the slag receiving pipe 6, specifically located between the slag receiving hopper 10 and the main shaft headstock 8, and a support 16 is further arranged on the rotary supporting seat 9. A slag receiving hopper connecting pipe 17 is also arranged above the slag receiving hopper 10.

The working principle of the utility model is as follows: after the placement of the workpiece 13 on the carriage assembly 12 is complete, the apparatus is started. The workpiece 13 moves leftwards under the support of the bracket group 12 and is locked by the spindle headstock 8; the movable trolley 11 moves leftwards to enter a working area, and drives the cutting head 15 to enter the upper part of a cutting area; the synchronous slag receiving pipe installation box 5 drives the slag receiving pipe 6 to move rightwards, so that the slag receiving head 10 penetrates into the workpiece 13 and is positioned below the cutting head 15. Before the equipment is started, the supports 16 and the slag receiving hopper connecting pipes 17 with different lengths on the rotary supporting seat 9 are replaced, so that the slag receiving hopper connecting pipes 17 are close to the inner wall of the workpiece 13 as much as possible. When the cutting head 15 begins to cut the workpiece 13, the dust removal host 1 is started, negative pressure is formed at the tail end of the slag receiving hopper connecting pipe 17 through the sliding air suction duct 3 and the sliding air suction opening 2, slag jet flow and metal smoke dust generated by cutting enter the slag receiving hopper connecting pipe 17 under atmospheric pressure, waste materials with large particles fall into the slag receiving hopper 10, and waste materials with small particles are directly sucked out by the dust removal host 1.

Claims (9)

1. The utility model provides an intersection line cutting machine dross removal mechanism which characterized in that includes:

a first guide rail disposed at one side;

the slag receiving system is arranged on the first guide rail and comprises a slag receiving pipe extending to one side, and the slag receiving system moves along the first guide rail;

the rotary supporting seat and the slag receiving hopper are arranged on the slag receiving pipe, the slag receiving hopper is arranged at the end part of the slag receiving pipe, and the rotary supporting seat is arranged on the inner side of the slag receiving hopper;

the dust removal system is arranged on one side of the slag receiving system and is connected with the slag receiving system through a pipeline;

the cutting system is arranged on the other side of the slag receiving system and comprises a plurality of bracket groups and a cutting head, the plurality of bracket groups are arranged below the cutting head, and the plurality of bracket groups are used for bearing a working workpiece;

the slag receiving pipe extends to the position between the plurality of bracket groups and the cutting head.

2. The deslagging device of the intersecting line cutting machine according to claim 1, wherein the slag receiving system further comprises a slag receiving pipe installation box directly arranged on the first guide rail, one side of the slag receiving pipe installation box is connected with the dedusting system through a pipeline, and the other side of the slag receiving pipe installation box is connected with one end of the slag receiving pipe.

3. The deslagging device of the intersecting line cutting machine according to claim 1, wherein the dedusting system comprises a sliding air outlet, a sliding air suction channel and a dedusting main machine, the sliding air outlet is installed above the sliding air suction channel, one end of the sliding air outlet is connected with the slag receiving pipe installation box through a pipeline, the sliding air suction channel is arranged on one side of the first guide rail in parallel, and the dedusting main machine is connected with one end of the sliding air suction channel.

4. The apparatus of claim 1, wherein the cutting system further comprises a spindle headstock, a second guide rail, a third guide rail, and a traveling carriage, the bracket set is disposed on the second guide rail, the spindle headstock is disposed between the first guide rail and the second guide rail, the third guide rail is disposed in parallel on one side of the second guide rail, the traveling carriage is disposed on the third guide rail, and the cutting head is disposed on the traveling carriage.

5. The deslagging device of the intersecting line cutting machine as recited in claim 4, wherein a chuck main shaft inner bushing is arranged in the main shaft headstock, and the slag receiving pipe passes through the chuck main shaft inner bushing.

6. The deslagging apparatus of the intersecting line cutting machine according to claim 5, wherein said bracket set includes a support wall, a guide wheel, a roller, a support tube and a bracket connecting frame, said guide wheel is disposed at a lower portion of said bracket connecting frame and contacts with said second guide rail, said support wall has an "x" cross structure, a lower end of said support wall is fixed to said bracket connecting frame, said roller is laterally disposed above said support wall, and said support tube is disposed between said rollers through a ball axle.

7. The apparatus of claim 6, wherein a ball shaft cover is further provided on the ball shaft.

8. The apparatus of claim 1, wherein said rotary support comprises a support for engaging an inner wall of said work piece.

9. The deslagging device of the intersecting line cutting machine as claimed in claim 1, wherein a slag receiving hopper connecting pipe close to the inner wall of the work piece is further arranged above the slag receiving hopper.

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