CN212418938U - High efficiency sweeps clean-up equipment - Google Patents

Abstract

The utility model relates to a high efficiency sweeps clean-up equipment, it includes the support, is fixed with the straight line module on the support, installs the slide on the straight line module, is fixed with the electric jar on the slide, and the piston rod of electric jar is fixed with the fixed pipe, and the fixed intraductal rotation is inlayed and is equipped with the connecting pipe, and the bottom of connecting pipe is connected with through first hose and inhales the bits pipe; the fixed pipe is provided with a driving assembly and is connected with an external chip suction machine through a second hose; the connecting pipe is provided with a driving assembly, and the outer wall of the chip suction pipe is provided with a first chip suction port. In the process of cleaning the waste scraps, the electric cylinder drives the fixed pipe to descend, and the driving assembly drives the scrap suction pipe to rotate to an inclined state, so that the scrap suction pipe can penetrate through the through groove and enter the inner side of the workpiece; then, the driving assembly drives the chip suction pipe to rotate to the horizontal state, and the driving assembly drives the connecting pipe and the chip suction pipe to rotate, so that the waste chips on the inner side of the workpiece are sucked. The utility model provides the high clearance efficiency of sweeps.

Description

High efficiency sweeps clean-up equipment

Technical Field

The utility model belongs to the technical field of the technique of sweeps clearance and specifically relates to a high efficiency sweeps clean-up equipment is related to.

Background

Drilling and tapping on existing workpieces is typically done by workers holding drills and tappers.

As shown in fig. 1, a large steel workpiece 1 is hollow, and has a plurality of through grooves 11 milled on its side and surface. In the process of processing the workpiece 1, a drilling machine is required to drill a plurality of blind holes 12 which are sequentially arranged along the length direction of the workpiece 1 on both sides of the workpiece, and then tapping is carried out on the basis of the blind holes 12 through a tapping machine.

However, there is a possibility that the waste chips generated during milling, drilling and tapping of the workpiece may enter the inside of the workpiece through the through groove, and if a worker holds the chip suction pipe of the chip suction machine to suck the waste chips on the inside of the workpiece, the cleaning efficiency is low, so that improvement is required.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims at providing a high efficiency sweeps clean-up equipment has improved the cleaning efficiency of sweeps.

The above object of the present invention can be achieved by the following technical solutions: a high-efficiency scrap cleaning device comprises a support, wherein a linear module extending along the length direction of a workpiece is fixed on the support, a sliding plate is mounted on the linear module, an electric cylinder is fixed on the sliding plate, a piston rod of the electric cylinder extends along the vertical direction and is fixed with a fixed pipe, a connecting pipe is embedded in the fixed pipe in a rotating mode, and the bottom end of the connecting pipe is connected with a scrap sucking pipe through a first hose; the fixed pipe is provided with a driving assembly for driving the connecting pipe to rotate, and the fixed pipe is connected with an external chip suction machine through a second hose; the connecting pipe is provided with a driving assembly for driving the chip suction pipe to rotate, the rotating plane of the chip suction pipe is parallel to the vertical surface, and the outer wall of the chip suction pipe is provided with a first chip suction port facing the inner wall of the bottom of the workpiece.

By adopting the technical scheme, in the process of cleaning the waste scraps, the sliding plate is driven to slide by the linear module, so that the scrap suction pipe is positioned right above the through groove; then the fixing pipe is driven to descend by the electric cylinder, and the chip suction pipe is driven to rotate to an inclined state by the driving assembly, so that the chip suction pipe can penetrate through the through groove to enter the inner side of the workpiece; then, the chip suction pipe is driven to rotate to a horizontal state through the driving assembly, and the first chip suction port and the bottom of the inner side of the workpiece are arranged at intervals; then the driving assembly drives the connecting pipe and the scrap sucking pipe to rotate, and scraps on the inner side of the workpiece enter the external scrap sucking machine through the scrap sucking pipe, the connecting pipe, the fixing pipe and the second hose, so that the cleaning efficiency of the scraps is improved.

The chip suction pipe can penetrate through any penetrating groove right below the linear module through the matching of the linear module and the electric cylinder, so that the operation is convenient; all the through grooves under the linear module are penetrated by the scrap suction pipe to suck the scraps, and then the workpiece is moved to enable the area which is not sucked with the scraps to move to the position under the linear module.

The present invention may be further configured in a preferred embodiment as: the driving assembly comprises a driven bevel gear fixedly sleeved outside the connecting pipe, a driving bevel gear meshed with the driven bevel gear and a motor fixed on the outer wall of the fixed pipe, and an output shaft of the motor is fixedly embedded in the driving bevel gear.

Through adopting above-mentioned technical scheme, when the motor drove the rotation of initiative bevel gear, driven bevel gear, connecting pipe and inhale the bits pipe and will synchronous revolution for inhale the bits pipe and can rotate and absorb the sweeps of the inboard bottom of work piece.

The present invention may be further configured in a preferred embodiment as: and a second chip suction port is formed in the end part of the chip suction pipe.

By adopting the technical scheme, the bottom of the inner side of the workpiece is rectangular, and the covering area of the chip suction pipe during rotation is circular, so that the scraps at the corners of the inner side of the workpiece are sucked into the chip suction pipe through the second chip suction port.

The present invention may be further configured in a preferred embodiment as: and a wear-resistant block is fixed on the outer wall of the bottom of the scrap suction pipe.

Through adopting above-mentioned technical scheme, when inhaling the rotatory horizontal state of bits pipe, wear-resisting piece will be contradicted in the inboard bottom of work piece for first chip-absorbing mouth is the interval setting with the inboard bottom of work piece, and has improved the stability of inhaling the bits pipe in rotatory in-process.

The present invention may be further configured in a preferred embodiment as: the driving assembly comprises a rotating block which is rotatably connected to the bottom of the connecting pipe, and the chip suction pipe is arranged on the rotating block; an upper baffle and a lower baffle which are respectively arranged at the upper side and the lower side of the scrap suction pipe are fixed on the connecting pipe, the upper baffle is arranged horizontally, and the lower baffle is arranged obliquely.

By adopting the technical scheme, when the electric cylinder drives the fixing pipe to descend, the chip suction pipe abuts against the lower baffle plate, and the chip suction pipe is in an inclined state, so that the chip suction pipe can penetrate through the through groove to enter the inner side of the workpiece; when inhaling the decline of bits pipe and contradict in the inboard bottom of work piece, inhale the bits pipe and will take place to rotate until wear-resisting piece contradicts in the inboard bottom of work piece, inhale the upside of bits pipe this moment and will contradict in last baffle, inhale the wear-resisting piece of bits pipe downside and will contradict in the inboard bottom of work piece for inhale the bits pipe and be difficult for rocking and can rotate the sweeps of inhaling the inboard bottom of work piece.

The present invention may be further configured in a preferred embodiment as: a dovetail block is fixed on the rotating block, a dovetail groove extending along the axial direction of the dovetail block is formed in the outer wall of the chip suction pipe, and the dovetail block is embedded in the dovetail groove in a sliding mode; the rotating block is also provided with a locking piece for locking and fixing the scrap suction pipe.

Through adopting above-mentioned technical scheme, the cooperation of forked tail piece and dovetail for inhale the bits pipe and can follow self axial slip, and can fix on the turning block by locking piece, so inhale the rotation range of bits pipe and can be adjusted, thereby make and inhale the bits pipe and be applicable to the work piece of equidimension not.

The present invention may be further configured in a preferred embodiment as: the dovetail block is provided with a threaded through groove, and the locking piece is a bolt which is in threaded fit with the threaded through groove and tightly supported on the wall of the dovetail groove.

By adopting the technical scheme, after the position of the chip suction pipe is adjusted, the bolt is in threaded fit with the threaded through groove and abuts against the wall of the dovetail groove, and the chip suction pipe can be locked and fixed on the rotating block.

The present invention may be further configured in a preferred embodiment as: the straight line module is equipped with the multiunit in proper order along the length direction of work piece.

Through adopting above-mentioned technical scheme for dust absorption pipe on the multiunit sharp module can be simultaneously to the inboard sweeps of work piece absorb, thereby has further improved the cleaning efficiency of sweeps, and need not to remove the work piece.

To sum up, the utility model discloses a following beneficial technological effect:

1. the linear module, the sliding plate, the electric cylinder, the fixed pipe, the connecting pipe, the scrap sucking pipe, the driving assembly and the driving assembly are arranged, so that the scrap sucking pipe can penetrate through the through groove to enter the inner side of a workpiece, the driving assembly drives the connecting pipe and the scrap sucking pipe to rotate, and scraps on the inner side of the workpiece enter an external scrap sucking machine through the scrap sucking pipe, the connecting pipe, the fixed pipe and the second hose, so that the cleaning efficiency of the scraps is improved;

2. the second chip suction port is arranged, so that the chips at the inner side corner of the workpiece are sucked into the chip suction pipe through the second chip suction port;

3. the arrangement of the wear-resistant block, the rotating block, the upper baffle and the lower baffle ensures that the scrap suction pipe is not easy to shake and can rotationally suck the scraps at the bottom of the inner side of the workpiece;

4. the arrangement of the dovetail block, the dovetail groove and the bolt enables the rotation range of the chip suction pipe to be adjusted, and therefore the chip suction pipe is suitable for workpieces of different sizes.

Drawings

FIG. 1 is a schematic structural view of a conventional large steel workpiece;

FIG. 2 is a schematic diagram of the overall structure in the embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view illustrating a workpiece according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram illustrating a driving assembly according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram illustrating a driving assembly in an embodiment of the present invention;

fig. 6 is a schematic structural view showing a dovetail block and a dovetail groove in the embodiment of the present invention.

Reference numerals: 1. a workpiece; 11. a through groove; 12. blind holes; 2. a support; 3. a linear module; 31. a slide plate; 32. an electric cylinder; 33. a fixed tube; 34. a connecting pipe; 35. a first hose; 36. a scrap suction pipe; 361. a first chip absorbing port; 362. a second chip suction port; 37. a wear-resistant block; 38. a second hose; 4. a driving component; 41. rotating the block; 42. an upper baffle plate; 43. a lower baffle plate; 44. a dovetail block; 45. a dovetail groove; 46. a bolt; 5. a drive assembly; 51. a driven bevel gear; 52. a drive bevel gear; 53. an electric motor.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in FIG. 2, a high efficiency sweeps clean-up equipment, includes support 2, is fixed with a plurality of sharp modules 3 that arrange in proper order along the length direction of work piece 1 on the support 2, and sharp module 3 extends along work piece 1 length direction.

As shown in fig. 3, a sliding plate 31 is installed on the linear module 3, an electric cylinder 32 is fixed on the sliding plate 31, a piston rod of the electric cylinder 32 extends in the vertical direction and is fixed with a fixed pipe 33, a connecting pipe 34 is embedded in the fixed pipe 33 in a rotating manner, and the bottom end of the connecting pipe 34 is connected with a scrap suction pipe 36 through a first hose 35.

As shown in fig. 5 and 6, the connecting pipe 34 is provided with the driving assembly 4, the driving assembly 4 includes a rotating block 41 rotatably connected to the bottom of the connecting pipe 34, a rotating plane of the rotating block 41 is parallel to a vertical plane, and the scrap suction pipe 36 is arranged on the rotating block 41; an upper baffle 42 and a lower baffle 43 which are respectively arranged at the upper side and the lower side of the scrap suction pipe 36 are fixed on the connecting pipe 34, the upper baffle 42 is horizontally arranged, and the lower baffle 43 is obliquely arranged.

In the process of cleaning the waste scraps, the sliding plate 31 is driven to slide by the linear module 3, so that the scrap suction pipe 36 is positioned right above the through groove 11; then the electric cylinder 32 drives the fixing pipe 33 to descend, and at the moment, the chip suction pipe 36 abuts against the lower baffle 43 and is in an inclined state, so that the chip suction pipe 36 can penetrate through the through groove 11 to enter the inner side of the workpiece 1.

As shown in fig. 5, a wear-resistant block 37 is fixed on the outer wall of the bottom of the chip suction pipe 36, when the chip suction pipe 36 descends to abut against the inner bottom of the workpiece 1, the chip suction pipe 36 rotates until the wear-resistant block 37 abuts against the inner bottom of the workpiece 1, at this time, the upper side of the chip suction pipe 36 abuts against the upper baffle 42, and the wear-resistant block 37 on the lower side of the chip suction pipe 36 abuts against the inner bottom of the workpiece 1, so that the chip suction pipe 36 is not prone to shake.

As shown in fig. 5, a first chip suction port 361 facing the inner wall of the bottom of the workpiece 1 is arranged on the outer wall of the chip suction pipe 36, and a second chip suction port 362 is arranged at the end of the chip suction pipe 36; the fixed pipe 33 is connected with an external chip suction machine through a second hose 38, and the driving assembly 5 is arranged on the fixed pipe 33.

As shown in fig. 4, the driving assembly 5 includes a driven bevel gear 51 fixedly sleeved outside the connecting pipe 34, a drive bevel gear 52 meshed with the driven bevel gear 51, and a motor 53 fixed on the outer wall of the fixed pipe 33, wherein an output shaft of the motor 53 is fixedly embedded in the drive bevel gear 52.

When the chip suction pipe 36 rotates to the horizontal state, the motor 53 drives the driving bevel gear 52 to rotate, and the driven bevel gear 51, the connecting pipe 34 and the chip suction pipe 36 synchronously rotate; the scraps at the bottom of the inner side of the workpiece 1 enter the scrap suction pipe 36 through the first scrap suction port 361, the scraps at the corner of the inner side of the workpiece 1 enter the scrap suction pipe 36 through the second scrap suction port 362, and the scraps in the scrap suction pipe 36 enter the external scrap suction machine through the connecting pipe 34, the fixed pipe 33 and the second hose 38.

As shown in fig. 6, a dovetail block 44 is fixed on the rotating block 41, a dovetail groove 45 extending along the self axial direction is formed on the outer wall of the chip suction pipe 36, and the dovetail block 44 is slidably embedded in the dovetail groove 45; the dovetail block 44 is provided with a threaded through groove, a locking member is arranged in the threaded through groove, and the locking member is a bolt 46. The dovetail block 44 slides in the dovetail groove 45, so that the rotation range of the chip suction pipe 36 can be adjusted, and the chip suction pipe 36 is suitable for workpieces 1 with different sizes; the bolt 46 is matched with the thread through groove in a threaded manner and tightly propped against the groove wall of the dovetail groove 45, so that the chip suction pipe 36 can be locked and fixed on the rotating block 41.

The implementation principle of the embodiment is as follows: in the process of cleaning the waste scraps, the sliding plate 31 is driven to slide by the linear module 3, so that the scrap suction pipe 36 is positioned right above the through groove 11; then the electric cylinder 32 drives the fixing pipe 33 to descend, and at the moment, the chip suction pipe 36 abuts against the lower baffle 43 and is in an inclined state, so that the chip suction pipe 36 can penetrate through the through groove 11 to enter the inner side of the workpiece 1.

When the chip suction pipe 36 descends to abut against the bottom of the inner side of the workpiece 1, the chip suction pipe 36 rotates until the wear-resistant block 37 abuts against the bottom of the inner side of the workpiece 1, at the moment, the upper side of the chip suction pipe 36 abuts against the upper baffle 42, and the wear-resistant block 37 on the lower side of the chip suction pipe 36 abuts against the bottom of the inner side of the workpiece 1, so that the chip suction pipe 36 is not prone to shaking.

Then the motor 53 drives the driving bevel gear 52 to rotate, and the driven bevel gear 51, the connecting pipe 34 and the chip suction pipe 36 synchronously rotate; the scraps at the bottom of the inner side of the workpiece 1 enter the scrap suction pipe 36 through the first scrap suction port 361, the scraps at the corner of the inner side of the workpiece 1 enter the scrap suction pipe 36 through the second scrap suction port 362, and the scraps in the scrap suction pipe 36 enter the external scrap suction machine through the connecting pipe 34, the fixed pipe 33 and the second hose 38, so that the scrap cleaning efficiency is improved.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (8)

1. The utility model provides a high efficiency sweeps clean-up equipment which characterized in that: the device comprises a support (2), wherein a linear module (3) extending along the length direction of a workpiece (1) is fixed on the support (2), a sliding plate (31) is installed on the linear module (3), an electric cylinder (32) is fixed on the sliding plate (31), a piston rod of the electric cylinder (32) extends along the vertical direction and is fixed with a fixed pipe (33), a connecting pipe (34) is embedded in the fixed pipe (33) in a rotating manner, and the bottom end of the connecting pipe (34) is connected with a scrap sucking pipe (36) through a first hose (35); the fixed pipe (33) is provided with a driving assembly (5) for driving the connecting pipe (34) to rotate, and the fixed pipe (33) is connected with an external chip suction machine through a second hose (38); the connecting pipe (34) is provided with a driving assembly (4) for driving the chip suction pipe (36) to rotate, the rotating plane of the chip suction pipe (36) is parallel to the vertical surface, and the outer wall of the chip suction pipe (36) is provided with a first chip suction port (361) facing the inner wall of the bottom of the workpiece (1).

2. A high efficiency shavings removal device as claimed in claim 1, wherein: the driving assembly (5) comprises a driven bevel gear (51) fixedly sleeved outside the connecting pipe (34), a driving bevel gear (52) meshed with the driven bevel gear (51) and a motor (53) fixed on the outer wall of the fixed pipe (33), and an output shaft of the motor (53) is fixedly embedded in the driving bevel gear (52).

3. A high efficiency shavings removal device as claimed in claim 1, wherein: the end part of the chip suction pipe (36) is provided with a second chip suction port (362).

4. A high efficiency shavings removal device as claimed in claim 1, wherein: and a wear-resistant block (37) is fixed on the outer wall of the bottom of the scrap suction pipe (36).

5. A high efficiency shavings removal device as claimed in claim 4, wherein: the driving assembly (4) comprises a rotating block (41) which is rotatably connected to the bottom of the connecting pipe (34), and the scrap suction pipe (36) is arranged on the rotating block (41); an upper baffle (42) and a lower baffle (43) which are respectively arranged at the upper side and the lower side of the scrap suction pipe (36) are fixed on the connecting pipe (34), the upper baffle (42) is arranged horizontally, and the lower baffle (43) is arranged obliquely.

6. A high efficiency shavings removal device as claimed in claim 5, wherein: a dovetail block (44) is fixed on the rotating block (41), a dovetail groove (45) extending along the self axial direction is formed in the outer wall of the chip suction pipe (36), and the dovetail block (44) is embedded in the dovetail groove (45) in a sliding mode; the rotating block (41) is also provided with a locking piece for locking and fixing the scrap suction pipe (36).

7. A high efficiency shavings removal device as claimed in claim 6, wherein: the dovetail block (44) is provided with a threaded through groove, and the locking piece is a bolt (46) which is in threaded fit with the threaded through groove and tightly abuts against the wall of the dovetail groove (45).

8. A high efficiency shavings removal device as claimed in claim 1, wherein: the linear modules (3) are sequentially provided with a plurality of groups along the length direction of the workpiece (1).

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