CN108526328B

CN108526328B - Energy-conserving high-efficient automobile engine oil pipe filter processingequipment

Info

Publication number: CN108526328B
Application number: CN201810269926.9A
Authority: CN
Inventors: 徐坤
Original assignee: Wenling Qiaobu Shoes Co Ltd
Current assignee: Wenling Qiaobu Shoes Co., Ltd
Priority date: 2018-03-29
Filing date: 2018-03-29
Publication date: 2020-09-01
Anticipated expiration: 2038-03-29
Also published as: CN108526328A

Abstract

The invention relates to an energy-saving and high-efficiency automobile engine oil pipe filter processing device which comprises a rotary table, wherein four groups of circular through grooves are formed in the rotary table, and a plurality of circular through grooves in each group are distributed in a circumferential manner; the feeding mechanism comprises a feeding groove extending along the radial direction of the rotary disc and a feeding rotary disc connected with the feeding groove and positioned above the rotary disc; the stamping mechanism comprises a stamping piston and a stamping driving mechanism which are positioned in the stamping pipe; the extrusion mechanism comprises an extrusion piston and an extrusion driving mechanism which are positioned in the extrusion pipe; the feeding mechanism, the stamping mechanism and the extruding mechanism are arranged around the rotary disc, the rotary disc can rotate to enable any group of circular through grooves to rotate to the position corresponding to the feeding mechanism, and the filter body is enabled to rotate to the positions corresponding to the stamping mechanism and the extruding mechanism respectively after material receiving. The processing device provided by the invention has the advantages of simple structure, high processing efficiency and uniform product quality.

Description

Energy-conserving high-efficient automobile engine oil pipe filter processingequipment

Technical Field

The invention relates to an energy-saving and high-efficiency machining device for an oil pipe filter of an automobile engine.

Background

In order to filter impurities in an oil pipe of an energy-saving automobile engine, a small filter needs to be arranged in the oil pipe, and the structure of the oil pipe filter commonly used at present is that a filter disc with holes is arranged in a small cylinder, oil flows through the holes in the filter disc, and meanwhile, the impurities in the oil are filtered. However, the filter of this structure is not very ideal in filtering effect. As an improvement, a mat-type net is arranged inside a small cylinder for filtering at present, but because the dense mat-type net cannot be uniformly arranged in a narrow space inside the small cylinder, even if the dense mat-type net is arranged, the phenomenon that the inner wall of the small cylinder cannot be in close contact with the mat-type net can occur, so that oil passing through a filter passes through the space between the mat-type net and the side wall of the small cylinder without being filtered (leaking), and the filtering effect is seriously influenced.

Chinese patent No. CN201410020673.3 discloses an automobile engine oil pipe filter processing device, which comprises a rotary table, wherein the rotary table is provided with at least one notch matched with a hollow cylindrical filter body of a filter; the feeding mechanism is used for accommodating the filter body and can be communicated with the notch; the punching mechanism comprises a punching piston and a punching driving mechanism which drives the punching piston to do linear reciprocating motion in the axial direction of the filter body, and the punching piston punches at least one circular part of a sheet with a hole into the filter body; the extrusion mechanism comprises an extrusion piston and an extrusion driving mechanism for driving the extrusion piston to do linear reciprocating motion in the axial direction of the filter body, and the extrusion piston extrudes a spherical filter screen into the filter body; the feeding mechanism, the stamping mechanism and the extruding mechanism are arranged around the turntable, and the turntable can rotate to enable the filter body in the gap to respectively rotate to correspond to the feeding mechanism, the stamping mechanism and the extruding mechanism. A method of manufacture using such an apparatus is also disclosed. The turntable of the patent can only finish the processing of one oil pipe filter when rotating for one circle, and the efficiency is not ideal.

Disclosure of Invention

The technical problem to be solved by the invention is to provide an efficient energy-saving and high-efficiency automobile engine oil pipe filter processing device capable of improving the filtering capacity of a filter, aiming at the problems in the prior art.

The technical scheme adopted by the invention for solving the technical problems is as follows: an energy-saving and high-efficiency automobile engine oil pipe filter processing device comprises a rotary table 4, wherein four groups of circular through grooves 41 are formed in the rotary table 4, and a plurality of circular through grooves 41 in each group are distributed in a circumferential manner; the feeding mechanism 1 comprises feeding grooves 11 extending along the radial direction of the rotary disc 4 and a feeding rotary disc 12 connected with the feeding grooves and positioned above the rotary disc 4, the feeding rotary disc 12 is provided with notches 122 corresponding to each group of circular through grooves 41, the feeding grooves 11 are used for feeding the filter bodies 61 into the notches 122 of the feeding rotary disc 12, and the feeding rotary disc 12 is driven by a first motor 121 to rotate to a position corresponding to the circular through grooves 41 so that the filter bodies 61 fall into the circular through grooves 41 right below; a punching mechanism 2, including a punching piston 21 located in a punching pipe 24 and a punching driving mechanism 22 for driving the punching piston 21 to make a linear reciprocating motion in the axial direction of the filter body 61, wherein the punching piston 21 punches at least a circular part of a sheet 62 into the filter body 61, the punching driving mechanism 22 is further provided with a suspension 7 extending to the right above the turntable 4, and the punching pipe 24 makes a circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the extrusion mechanism 3 comprises an extrusion piston 31 positioned in an extrusion pipe 34 and an extrusion driving mechanism 32 for driving the extrusion piston 31 to do linear reciprocating motion in the axial direction of the filter body 61, the extrusion piston 31 extrudes a spherical filter screen 63 into the filter body 61, the extrusion driving mechanism 32 is also provided with a suspension 7 extending to the right upper part of the turntable 4, and the extrusion pipe 34 does circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the feeding mechanism 1, the stamping mechanism 2 and the extrusion mechanism 3 are arranged around the rotary disc 4, the rotary disc 4 can rotate to enable any group of circular through grooves 41 to rotate to the position corresponding to the feeding mechanism 1, and the filter body 61 is enabled to rotate to the positions corresponding to the stamping mechanism 2 and the extrusion mechanism 3 respectively after receiving materials.

In one embodiment of the invention, four groups of circular through grooves 41 are arranged at intervals of 90 degrees symmetrically along the turntable 4, and the feeding mechanism 1, the stamping mechanism 2 and the extrusion mechanism 3 are also arranged at intervals of 90 degrees respectively; the design enables the feeding mechanism 1, the stamping mechanism 2 and the extrusion mechanism 3 to simultaneously correspond to a group of circular through grooves 41 so as to realize synchronous work, and the production efficiency is greatly improved.

The stainless steel wire is formed into a hollow cylindrical mesh tube by weaving, and then the mesh tube is extruded to form a spherical filter net 63. The rotary disc 4 is driven to rotate, so that the circular through groove 41 rotates to the position below the feeding rotary disc 12 and then stops; placing a filter body 61 in the feed chute 11; the first filter body 61 in the feed chute 11 is pushed into the first notch 441 in the corresponding feed turntable 12, the first motor 121 drives the feed turntable 12 to rotate so that the second notch 441 is aligned with the feed chute 11, the second filter body 61 in the feed chute 11 is pushed into the second notch 441 of the feed turntable 12, when the lower end of the notch 122 is communicated with the circular through groove 41, the filter bodies 61 fall into the circular through groove 41 until the filter bodies 61 are contained in the group of circular through grooves 41, and the turntable 4 is driven so that the circular through groove 41 rotates to the position below the stamping piston 21 to stop.

The punching driving mechanism 22 drives the punching piston 21 to press down, the punching piston 21 presses down at least one circular part of the sheet 62 into the corresponding filter body 61 until the circular part is pressed against the step 611 in the filter body 61, the punching pipe 24 rotates along the circular sliding groove 71 on the lower bottom surface of the suspension 7 to the upper side of the next circular through groove 41, the punching piston 21 repeats the above actions, and so on, all the filter bodies 61 are punched into the circular sheet 62, and the rotary disc 4 is driven to make the circular through groove 41 rotate to the lower side of the pressing piston 31 and then stop.

Pushing a spherical filter screen 63 to the lower part of the extrusion piston 31, driving the extrusion piston 31 to press downwards by the extrusion driving mechanism 32, extruding at least one filter screen 63 into the corresponding filter body 61 by the extrusion piston 31 until the filter screen 63 is pressed into a plunger shape with a side wall tightly attached to the inner side wall of the filter body 61 by the spherical extrusion under the blocking of the sheet 62, and finishing the filter processing; the extrusion pipe 34 rotates along the circular sliding groove 71 on the lower bottom surface of the suspension 7 to the position above the next circular through groove 41, the extrusion piston 31 repeats the actions, and so on, so that all filters are processed. Continued rotation of the drive dial 4 causes the circular channel 41 to rotate away from the squeeze piston 31 to remove the finished filter.

In one embodiment of the present invention, an isolation rotary disk 13 driven by a third motor 132 is disposed between the feeding rotary disk 12 and the rotary disk 4, and the isolation rotary disk 13 is provided with a channel 131 having the same shape as the notch 122 of the feeding rotary disk 12.

In the process that the feeding groove 11 conveys the filter body 61 to the notch 122 of the feeding rotary disc 12, the channel 131 of the isolation rotary disc 13 and the notch 122 of the feeding rotary disc 12 are staggered and rotate synchronously, so that the feeding groove 11 sequentially conveys the filter body 61 into the notch 122 and does not fall into the circular through groove 41, after all the notches 122 of the feeding rotary disc 12 are filled, the third motor 132 drives the isolation rotary disc 13 to rotate, and the notch 122 of the feeding rotary disc 12, the channel 131 of the isolation rotary disc 13 and the circular through groove 41 are communicated, so that the filter body 61 can smoothly fall into the circular through groove 41 from the notch 122.

In one embodiment of the invention, the width of the feed chute 11 is adapted to the diameter of the filter body 61. The filter bodies 61 may be arranged one after the other to ensure that only one filter body 61 enters the indentation 441 at a time.

In one embodiment of the present invention, a washer 25 is provided above the outer periphery of the circular through groove 41 of the turntable 4 and below the ram piston 21. Thereby avoiding damage to the filter body 61 by the ram piston 21 during the stamping process.

In an embodiment of the present invention, the punching mechanism 2 further includes a winding mechanism 23, the winding mechanism 23 includes a passive winding disc 231 and an active winding disc 234 respectively disposed at two sides of the punching piston 21, and a positioning member 232 having a horizontal positioning slot 233, the positioning member 232 is disposed adjacent to the punching piston 21, the sheet 62 has a wide-side strip shape and can be simultaneously punched to form a plurality of circular portions, one end of the sheet 62 is wound around the passive winding disc 231, and the other end of the sheet 62 passes through the positioning slot 233 and under the punching piston 21 and then is wound around the active winding disc 234. So that the sheet 62 can be automatically moved so that the non-punched portion is timely replenished under the punching piston 21.

In one embodiment of the present invention, the shaft of the active take-up reel 234 is drivingly connected to a second motor 235.

In one embodiment of the present invention, the squeezing mechanism 3 further comprises a feeding pipe 33 which accommodates the spherical filter screen 63 and communicates with the lower side of the squeezing piston 31. So that the spherical filter net 63 is sequentially fed below the pressing piston 31 for pressing.

In an embodiment of the invention, the feeding mechanism 1, the stamping mechanism 2, the extruding mechanism 3 and the rotary table 4 are arranged on a working table 5, a feed opening 51 is arranged at a corresponding position below the rotary table 4 between the feeding mechanism 1 and the extruding mechanism 3 on the working table 5, a feed hopper 52 is arranged below the feed opening 51, and the feed hopper 52 collects a processed filter falling from the feed opening 51, so that the discharge is convenient.

Compared with the prior art, the invention has the advantages that:

1. the processing device comprises two mechanisms of a punching sheet 62 and an extruding filter screen 63, so that under the condition that the sheet 62 is extruded into the filter body 61, the spherical filter screen 63 is extruded into the filter body 61 to form a compact and uniform plunger shape, and under the blocking action of the sheet, the side wall of the formed filter screen of the filter is tightly attached to the inner side wall of the filter body 61, thereby avoiding the phenomenon of filter leakage and greatly enhancing the filtering effect of the filter;

2. the processing device is provided with four groups of circular through grooves 41, and when the processing device enters a continuous working state, one group of circular through grooves 41 are positioned at corresponding positions of the feeding mechanism 1 to receive the filter body 61 at the same time; the second group of circular through grooves 41 are positioned at corresponding positions of the punching mechanism 2, and the punching piston 21 sequentially punches the circular parts of the sheets 62 into the filter body 61; the third group of circular through grooves 41 are positioned at corresponding positions of the extrusion mechanism 3, and the extrusion piston 31 sequentially extrudes the filter screen 63 into the filter body 61; the fourth group of circular through grooves 41 are positioned at the feed opening 51 and used for unloading the processed filter; the synchronous operation greatly improves the processing efficiency.

Drawings

FIG. 1 is a schematic view of a filter manufacturing apparatus according to the present invention;

fig. 2 is an exploded view of the structure of the feeding mechanism 1 of the present invention;

fig. 3 is a schematic structural view of the suspension 7 of the present invention;

FIG. 4 is a schematic view of the punching mechanism 2 according to the present invention in a pre-punching state;

FIG. 5 is a schematic diagram of the stamping mechanism 2 according to the present invention in a post-stamping state;

FIG. 6 is a schematic view of the pressing mechanism 3 according to the present invention in a state before pressing;

FIG. 7 is a schematic view of the pressing mechanism 3 according to the present invention;

fig. 8 is a schematic view of the pressing mechanism 3 according to the present invention in a pressed state;

FIG. 9 is a schematic view of the filter web 63 of the present invention extruding stock material;

fig. 10 is a cross-sectional view of a filter of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

Example 1

As shown in fig. 1-10, the present embodiment provides an energy-saving and high-efficiency machining device for an oil tube filter of an automobile engine, which includes a turntable 4, wherein four sets of circular through grooves 41 are disposed on the turntable 4, and a plurality of circular through grooves 41 in each set are circumferentially distributed; the feeding mechanism 1 comprises feeding grooves 11 extending along the radial direction of the rotary disc 4 and a feeding rotary disc 12 connected with the feeding grooves and positioned above the rotary disc 4, the feeding rotary disc 12 is provided with notches 122 corresponding to each group of circular through grooves 41, the feeding grooves 11 are used for feeding the filter bodies 61 into the notches 122 of the feeding rotary disc 12, and the feeding rotary disc 12 is driven by a first motor 121 to rotate to a position corresponding to the circular through grooves 41 so that the filter bodies 61 fall into the circular through grooves 41 right below; a punching mechanism 2, including a punching piston 21 located in a punching pipe 24 and a punching driving mechanism 22 for driving the punching piston 21 to make a linear reciprocating motion in the axial direction of the filter body 61, wherein the punching piston 21 punches at least a circular part of a sheet 62 into the filter body 61, the punching driving mechanism 22 is further provided with a suspension 7 extending to the right above the turntable 4, and the punching pipe 24 makes a circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the extrusion mechanism 3 comprises an extrusion piston 31 positioned in an extrusion pipe 34 and an extrusion driving mechanism 32 for driving the extrusion piston 31 to do linear reciprocating motion in the axial direction of the filter body 61, the extrusion piston 31 extrudes a spherical filter screen 63 into the filter body 61, the extrusion driving mechanism 32 is also provided with a suspension 7 extending to the right upper part of the turntable 4, and the extrusion pipe 34 does circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the feeding mechanism 1, the stamping mechanism 2 and the extrusion mechanism 3 are arranged around the rotary disc 4, the rotary disc 4 can rotate to enable any group of circular through grooves 41 to rotate to the position corresponding to the feeding mechanism 1, and the filter body 61 is enabled to rotate to the positions corresponding to the stamping mechanism 2 and the extrusion mechanism 3 respectively after receiving materials.

Example 2

As shown in fig. 1-10, the present embodiment provides an energy-saving and high-efficiency machining device for an oil tube filter of an automobile engine, which includes a turntable 4, wherein four sets of circular through grooves 41 are disposed on the turntable 4, and a plurality of circular through grooves 41 in each set are circumferentially distributed; a feeding mechanism 1, which comprises feeding grooves 11 extending along the radial direction of the rotating disc 4 and a feeding rotating disc 12 connected with the feeding grooves 11 and located above the rotating disc 4, wherein the feeding rotating disc 12 is provided with notches 122 corresponding to each group of circular through grooves 41, the feeding grooves 11 are used for feeding the filter bodies 61 into the notches 122 of the feeding rotating disc 12, the feeding rotating disc 12 is driven by a first motor 121 to rotate to a position corresponding to the circular through grooves 41 so that the filter bodies 61 fall into the circular through grooves 41 right below, the width of the feeding grooves 11 is matched with the diameter of the filter bodies 61, an isolation rotating disc 13 driven by a third motor 132 is arranged between the feeding rotating disc 12 and the rotating disc 4, and the isolation rotating disc 13 is provided with a channel 131 with the same shape as the notches 122 of the feeding rotating disc 12; a punching mechanism 2, including a punching piston 21 located in a punching pipe 24 and a punching driving mechanism 22 for driving the punching piston 21 to make a linear reciprocating motion in the axial direction of the filter body 61, wherein the punching piston 21 punches at least a circular part of a sheet 62 into the filter body 61, the punching driving mechanism 22 is further provided with a suspension 7 extending to the right above the turntable 4, and the punching pipe 24 makes a circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the extrusion mechanism 3 comprises an extrusion piston 31 positioned in an extrusion pipe 34 and an extrusion driving mechanism 32 for driving the extrusion piston 31 to do linear reciprocating motion in the axial direction of the filter body 61, the extrusion piston 31 extrudes a spherical filter screen 63 into the filter body 61, the extrusion driving mechanism 32 is also provided with a suspension 7 extending to the right upper part of the turntable 4, and the extrusion pipe 34 does circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the feeding mechanism 1, the stamping mechanism 2 and the extrusion mechanism 3 are arranged around the rotary disc 4, the rotary disc 4 can rotate to enable any group of circular through grooves 41 to rotate to the position corresponding to the feeding mechanism 1, and the filter body 61 is enabled to rotate to the positions corresponding to the stamping mechanism 2 and the extrusion mechanism 3 respectively after receiving materials. And a gasket 25 is arranged above the periphery of the circular through groove 41 of the turntable 4 and below the stamping piston 21.

Example 3

As shown in fig. 1-10, the present embodiment provides an energy-saving and high-efficiency machining device for an oil tube filter of an automobile engine, which includes a turntable 4, wherein four sets of circular through grooves 41 are disposed on the turntable 4, and a plurality of circular through grooves 41 in each set are circumferentially distributed; the feeding mechanism 1 comprises feeding grooves 11 extending along the radial direction of the rotary disc 4 and a feeding rotary disc 12 connected with the feeding grooves and positioned above the rotary disc 4, the feeding rotary disc 12 is provided with notches 122 corresponding to each group of circular through grooves 41, the feeding grooves 11 are used for feeding the filter bodies 61 into the notches 122 of the feeding rotary disc 12, and the feeding rotary disc 12 is driven by a first motor 121 to rotate to a position corresponding to the circular through grooves 41 so that the filter bodies 61 fall into the circular through grooves 41 right below; a punching mechanism 2, including the punching piston 21 that is arranged in the punching pipe 24 and the punching driving mechanism 22 that drives the punching piston 21 to do the straight reciprocating motion in the axial direction of the filter body 61, the punching piston 21 punches at least a circular part of a slice 62 into the filter body 61, the punching driving mechanism 22 is further provided with a suspension 7 that extends to the right above the turntable 4, the punching pipe 24 does the circular motion along the circular sliding groove 71 of the lower bottom surface of the suspension 7, the punching mechanism 2 further comprises a winding mechanism 23, the winding mechanism 23 comprises a passive winding disc 231 and an active winding disc 234 that are respectively arranged at the two sides of the punching piston 21 and a positioning piece 232 that is provided with a horizontal positioning groove 233, the positioning piece 232 is arranged adjacent to the punching piston 21, the slice 62 is in the shape of a wide edge strip, one end of the slice 62 is wound on the passive winding disc 231, the other end of the driving winding plate passes through the positioning groove 233 and the lower part of the stamping piston 21 and then is wound on the driving winding plate 234, and the shaft of the driving winding plate 234 is in driving connection with a second motor 235; the extrusion mechanism 3 comprises an extrusion piston 31 positioned in an extrusion pipe 34 and an extrusion driving mechanism 32 for driving the extrusion piston 31 to do linear reciprocating motion in the axial direction of the filter body 61, the extrusion piston 31 extrudes a spherical filter screen 63 into the filter body 61, the extrusion driving mechanism 32 is also provided with a suspension 7 extending to the right upper part of the turntable 4, and the extrusion pipe 34 does circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the feeding mechanism 1, the stamping mechanism 2 and the extrusion mechanism 3 are arranged around the rotary disc 4, the rotary disc 4 can rotate to enable any group of circular through grooves 41 to rotate to the position corresponding to the feeding mechanism 1, and the filter body 61 is enabled to rotate to the positions corresponding to the stamping mechanism 2 and the extrusion mechanism 3 respectively after receiving materials.

Example 4

As shown in fig. 1-10, the present embodiment provides an energy-saving and high-efficiency machining device for an oil tube filter of an automobile engine, which includes a turntable 4, wherein four sets of circular through grooves 41 are disposed on the turntable 4, and a plurality of circular through grooves 41 in each set are circumferentially distributed; the feeding mechanism 1 comprises feeding grooves 11 extending along the radial direction of the rotary disc 4 and a feeding rotary disc 12 connected with the feeding grooves and positioned above the rotary disc 4, the feeding rotary disc 12 is provided with notches 122 corresponding to each group of circular through grooves 41, the feeding grooves 11 are used for feeding the filter bodies 61 into the notches 122 of the feeding rotary disc 12, and the feeding rotary disc 12 is driven by a first motor 121 to rotate to a position corresponding to the circular through grooves 41 so that the filter bodies 61 fall into the circular through grooves 41 right below; a punching mechanism 2, including a punching piston 21 located in a punching pipe 24 and a punching driving mechanism 22 for driving the punching piston 21 to make a linear reciprocating motion in the axial direction of the filter body 61, wherein the punching piston 21 punches at least a circular part of a sheet 62 into the filter body 61, the punching driving mechanism 22 is further provided with a suspension 7 extending to the right above the turntable 4, and the punching pipe 24 makes a circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the extrusion mechanism 3 comprises an extrusion piston 31 positioned in an extrusion pipe 34 and an extrusion driving mechanism 32 for driving the extrusion piston 31 to do linear reciprocating motion in the axial direction of the filter body 61, the extrusion piston 31 extrudes a spherical filter screen 63 into the filter body 61, the extrusion driving mechanism 32 is also provided with a suspension 7 extending to the right upper part of the turntable 4, the extrusion pipe 34 does circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7, and the extrusion mechanism 3 also comprises a feeding pipe 33 which contains the filter screen 63 and is communicated with the lower part of the extrusion piston 31; the feeding mechanism 1, the stamping mechanism 2 and the extrusion mechanism 3 are arranged around the rotary disc 4, the rotary disc 4 can rotate to enable any group of circular through grooves 41 to rotate to the position corresponding to the feeding mechanism 1, and the filter body 61 is enabled to rotate to the positions corresponding to the stamping mechanism 2 and the extrusion mechanism 3 respectively after receiving materials.

Example 5

As shown in fig. 1-10, the present embodiment provides an energy-saving and high-efficiency machining device for an oil tube filter of an automobile engine, which includes a turntable 4, wherein four sets of circular through grooves 41 are disposed on the turntable 4, and a plurality of circular through grooves 41 in each set are circumferentially distributed; the feeding mechanism 1 comprises feeding grooves 11 extending along the radial direction of the rotary disc 4 and a feeding rotary disc 12 connected with the feeding grooves and positioned above the rotary disc 4, the feeding rotary disc 12 is provided with notches 122 corresponding to each group of circular through grooves 41, the feeding grooves 11 are used for feeding the filter bodies 61 into the notches 122 of the feeding rotary disc 12, and the feeding rotary disc 12 is driven by a first motor 121 to rotate to a position corresponding to the circular through grooves 41 so that the filter bodies 61 fall into the circular through grooves 41 right below; a punching mechanism 2, including a punching piston 21 located in a punching pipe 24 and a punching driving mechanism 22 for driving the punching piston 21 to make a linear reciprocating motion in the axial direction of the filter body 61, wherein the punching piston 21 punches at least a circular part of a sheet 62 into the filter body 61, the punching driving mechanism 22 is further provided with a suspension 7 extending to the right above the turntable 4, and the punching pipe 24 makes a circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the extrusion mechanism 3 comprises an extrusion piston 31 positioned in an extrusion pipe 34 and an extrusion driving mechanism 32 for driving the extrusion piston 31 to do linear reciprocating motion in the axial direction of the filter body 61, the extrusion piston 31 extrudes a spherical filter screen 63 into the filter body 61, the extrusion driving mechanism (32) is also provided with a suspension 7 extending to the right upper part of the turntable 4, and the extrusion pipe 34 does circular motion along a circular sliding groove 71 on the lower bottom surface of the suspension 7; the feeding mechanism 1, the stamping mechanism 2 and the extrusion mechanism 3 are arranged around the rotary disc 4, the rotary disc 4 can rotate to enable any group of circular through grooves 41 to rotate to the position corresponding to the feeding mechanism 1, and the filter body 61 is enabled to rotate to the positions corresponding to the stamping mechanism 2 and the extrusion mechanism 3 respectively after receiving materials. Feeding mechanism 1, punching press mechanism 2, extrusion mechanism 3 and carousel 4 set up on table surface 5, table surface 5 is last to be located carousel 4 below relevant position between feeding mechanism 1 and the extrusion mechanism 3 has seted up feed opening 51, feed opening 51 below is equipped with down hopper 52, down hopper 52 collects the follow the filter that has finished that feed opening 51 fell down.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The machining device for the oil pipe filter of the energy-saving and high-efficiency automobile engine is characterized by comprising a rotary table (4), wherein four groups of circular through grooves (41) are formed in the rotary table (4), and the circular through grooves (41) in each group are distributed in a circumferential manner;

the feeding mechanism (1) comprises feeding grooves (11) extending along the radial direction of the rotary disc (4) and feeding rotary discs (12) connected with the feeding grooves and located above the rotary disc (4), notches (122) corresponding to each group of circular through grooves (41) are formed in the feeding rotary discs (12), the feeding grooves (11) are used for feeding the filter bodies (61) into the notches (122) of the feeding rotary discs (12), and the feeding rotary discs (12) are driven by a first motor (121) to rotate to positions corresponding to the circular through grooves (41) so that the filter bodies (61) fall into the circular through grooves (41) right below;

the punching mechanism (2) comprises a punching piston (21) positioned in a punching pipe (24) and a punching driving mechanism (22) for driving the punching piston (21) to do linear reciprocating motion in the axial direction of the filter body (61), the punching piston (21) punches at least one circular part of a sheet (62) into the filter body (61), the punching driving mechanism (22) is also provided with a suspension (7) extending to the right upper part of the rotary disc (4), and the punching pipe (24) does circular motion along a circular sliding groove (71) on the lower bottom surface of the suspension (7);

the extrusion mechanism (3) comprises an extrusion piston (31) positioned in an extrusion pipe (34), and an extrusion driving mechanism (32) for driving the extrusion piston (31) to do linear reciprocating motion in the axial direction of the filter body (61), wherein the extrusion piston (31) extrudes a spherical filter screen (63) into the filter body (61), the extrusion driving mechanism (32) is also provided with a suspension (7) extending to the right upper part of the turntable (4), and the extrusion pipe (34) does circular motion along a circular sliding groove (71) on the lower bottom surface of the suspension (7);

the feeding mechanism (1), the stamping mechanism (2) and the extrusion mechanism (3) are arranged around the rotary table (4), the rotary table (4) can rotate to enable any one group of circular through grooves (41) to rotate to the position corresponding to the feeding mechanism (1), and the filter body (61) rotates to the position corresponding to the stamping mechanism (2) and the extrusion mechanism (3) respectively after material receiving;

an isolation rotary table (13) driven by a third motor (132) is arranged between the feeding rotary table (12) and the rotary table (4), and the isolation rotary table (13) is provided with a channel (131) with the same shape as the notch (122) of the feeding rotary table (12); in the process that the filter body (61) is conveyed to the notch (122) of the feeding rotary disc (12) by the feeding groove (11), the channel (131) of the isolation rotary disc (13) and the notch (122) of the feeding rotary disc (12) are staggered and rotate synchronously, so that the filter body (61) is sequentially conveyed into the notch (122) by the feeding groove (11) and does not fall into the circular through groove (41), after all the notches (122) of the feeding rotary disc (12) are filled, the isolation rotary disc (13) is driven to rotate by the third motor (132), the notch (122) of the feeding rotary disc (12), the channel (131) of the isolation rotary disc (13) and the circular through groove (41) are communicated, and the filter body (61) can smoothly fall into the circular through groove (41) from the notch (122).

2. The energy-saving and high-efficiency automobile engine oil pipe filter processing device as claimed in claim 1, wherein the width of the feed chute (11) is adapted to the diameter of the filter body (61).

3. The energy-saving and high-efficiency automobile engine oil pipe filter processing device as claimed in claim 1, characterized in that a gasket (25) is arranged above the periphery of the circular through groove (41) of the rotary disc (4) and below the stamping piston (21).

4. The energy-saving and high-efficiency automobile engine oil pipe filter processing device according to claim 1, wherein the punching mechanism (2) further comprises a winding mechanism (23), the winding mechanism (23) comprises a passive winding disc (231) and an active winding disc (234) which are respectively arranged at two sides of the punching piston (21), and a positioning member (232) provided with a horizontal positioning groove (233), the positioning member (232) is arranged adjacent to the punching piston (21), the thin sheet (62) is in a wide-side strip shape, one end of the thin sheet (62) is wound on the passive winding disc (231), and the other end of the thin sheet is wound on the active winding disc (234) after passing through the positioning groove (233) and below the punching piston (21).

5. The energy-saving and high-efficiency automobile engine oil pipe filter processing device as claimed in claim 4, characterized in that the shaft of the driving winding disc (234) is in driving connection with a second motor (235).

6. The energy-saving and high-efficiency automobile engine oil pipe filter processing device as claimed in claim 1, wherein the extrusion mechanism (3) further comprises a feed pipe (33) which accommodates the filter screen (63) and is communicated to the lower part of the extrusion piston (31).

7. The energy-saving and high-efficiency automobile engine oil pipe filter processing device as claimed in any one of claims 1-5, wherein the feeding mechanism (1), the stamping mechanism (2), the extruding mechanism (3) and the rotary table (4) are arranged on a working table (5), a blanking port (51) is arranged at a corresponding position below the rotary table (4) between the feeding mechanism (1) and the extruding mechanism (3) on the working table (5), a blanking hopper (52) is arranged below the blanking port (51), and the blanking hopper (52) collects the processed filter falling from the blanking port (51).