CN108110968B

CN108110968B - All-in-one core punching machine

Info

Publication number: CN108110968B
Application number: CN201710830607.6A
Authority: CN
Inventors: 陈洁明
Original assignee: Jieyang Mingjiada Hardware & Plastic Industry Co ltd
Current assignee: Jieyang Mingjiada Hardware & Plastic Industry Co ltd
Priority date: 2017-09-15
Filing date: 2017-09-15
Publication date: 2023-06-27
Anticipated expiration: 2037-09-15
Also published as: CN108110968A

Abstract

The invention relates to the field of motor rotor machining machinery, in particular to an all-in-one core punching machine. The invention adopts the following technical scheme: the invention relates to an all-in-one core punching machine, which comprises a core punching machine main body, wherein the core punching machine main body is provided with a core feeding device, a shaft core punching device, a chip set guiding device, a chip staggered sheet rotating device and a chip set sheet feeding device, and has the advantages that: the automatic punching device comprises a shaft core punching device, a core punching device and a chip staggered piece rotating device, is high in automatic efficiency, greatly improves production efficiency, reduces manual investment, reduces production cost and improves market competitiveness of products.

Description

All-in-one core punching machine

Technical Field

The invention relates to the field of motor rotor machining machinery, in particular to an all-in-one core punching machine.

Background

The motor is a small motor with wide application, various processing modes, manual processing and semi-automatic processing in small processing and full-automatic production line processing in large processing. In small-size processing, manual working efficiency is low, semi-automatic processing's equipment is rather than lacking, and degree of automation is low, especially dashes core machine part, very influences machining efficiency, and then improves the manufacturing cost of enterprise.

Disclosure of Invention

The invention aims to provide an all-in-one core punching machine, and particularly provides the all-in-one core punching machine which is simple in structure and high in efficiency.

In order to achieve the above purpose, the invention adopts the following technical scheme: the utility model provides an all-in-one core punching machine, including the core punching machine main part, the core punching machine main part is provided with and send core device, axle core stamping device, towards core device, chipset send the piece device, send core device including the axle core silo that is used for holding axle core, its bottom of axle core silo extends to the longitudinal axis core guide slot parallel with axle core silo discharge port, set up axle core stamping device between being located axle core silo and vertical axle core guide slot at being close longitudinal axis core guide slot, the terminal adjacent core device that sets up of longitudinal axis core guide slot, the opposite side that dashes core device sets up chipset send the piece device.

A first cylinder is arranged at one end of the longitudinal axial core guide groove, an axial core arranged in the longitudinal axial core guide groove is driven by a pushing rod to push towards the direction of the vertical axial core guide groove, and an axial core arc guide hole connected with the longitudinal axial core guide groove is arranged in the vertical axial core guide groove.

The shaft core stamping device is arranged between the vertical shaft core guide groove and the shaft core trough and comprises a first hydraulic cylinder, a core pressing rod, a core punching upper die and a core punching lower die which are arranged at the top of the shaft core stamping frame, the first hydraulic cylinder drives the core punching upper die to output towards the direction of the core punching lower die through the core pressing rod, and the vertical shaft core guide groove penetrates through the core punching lower die to extend to a core inlet of the vertical shaft core guide groove.

Preferably, the butt joint positions of the upper die and the bottom die are respectively provided with embossments which are matched with each other.

Further, the chip set sheet feeding device comprises a second cylinder positioned at one side of the core punching device, and drives the chip supporting tray to reciprocate between the chip set guiding device and the core punching device through the sheet feeding rod.

Further, a chip set guiding device is arranged between the core punching device and the chip set sheet feeding device, the chip set guiding device comprises a chip set guiding rack and at least one group of first chip guiding shafts arranged on the upper part of the chip set guiding rack, and a chip set discharge port corresponding to the chip set guiding shafts when the chip carrier is pulled back is arranged at the bottom of the chip set guiding rack.

Further, the core feeding device further comprises a third cylinder, an intermediate transmission rod and a core bracket, wherein the third cylinder is positioned at one side of the vertical core guide groove, and the third cylinder moves back and forth between the vertical core guide groove and the core punching device through the intermediate transmission rod and the core bracket.

Further, a fourth cylinder is arranged at the bottom of the third cylinder, the fourth cylinder drives the third cylinder to ascend or descend through a lifting rod, and the lifting height of the fourth cylinder is slightly larger than the depth of the fixed shaft hole of the punching rod.

Further, the chip misplacement rotating device comprises a chip group adjusting rack arranged at the top of the chip group guiding device, a chip group rotating misplacement pipeline is arranged at the bottom of the chip group adjusting rack, one end of the top of the chip group rotating misplacement pipeline extends to the corresponding position of a chip inlet at the top of the chip group adjusting rack, one end of the bottom of the chip group rotating misplacement pipeline is connected with the chip group guiding device, the misplacement servo motor drives the chip group rotating misplacement pipeline to rotate, and a third chip guiding shaft is arranged on the inner edge of the chip group rotating misplacement pipeline in a surrounding mode.

A fifth cylinder is arranged on one side of the chip set adjusting rack, the fifth cylinder drives a chip feeding ruler through a pull-back rod, a first feed back opening and a second feed back opening which are slightly larger than the chip set in diameter are formed in the chip feeding ruler, second chip guide shafts are arranged on two sides of the chip feeding opening, the feed back opening, the chip guide grooves and the chip feeding opening are in the same axial direction when the chip feeding rod is pulled back, the first feed back opening is located at the bottom of the second chip guide shaft close to one side of the fifth cylinder, and the second feed back opening and the chip feeding opening are correspondingly arranged.

The invention has the advantages that: simple structure, degree of automation is high, and rotor machining efficiency is high and further has kept its uniformity and holistic result of use of product, still specifically includes axle core stamping device, towards core device, chip dislocation rotary device, and automatic efficiency is high, very big improvement the efficiency of production, reduction artificial input, reduction in production cost improves the market competition of its product.

Drawings

Fig. 1 is a perspective view of an all-in-one core punching machine according to embodiment 1;

FIG. 2 is an isometric view of an embodiment 1 of an all-in-one core press;

FIG. 3 is a front view of the structure of the multi-in-one core punching machine of embodiment 1;

reference numerals: 1-core feeding device, 10-longitudinal core guiding groove, 11-first cylinder, 12-core pushing rod, 13-core feeding groove, 14-sixth cylinder, 15-core pushing rod, 16-vertical core guiding groove, 17-cylinder bracket, 170-fourth cylinder, 18-third cylinder, 19-middle driving rod and 190-core bracket;

2-shaft core stamping device, 21-first hydraulic cylinder, 22-core pressing rod, 23-core upper die and 24-core lower die;

4-a core punching machine main body;

3-core punching device, 31-core punching rack, 32-core punching bar and 33-fixed shaft hole;

5-chip set sheet feeding device, 51-sheet feeding rod and 52-chip tray; 6-chip set guiding device, 61-first chip guiding shaft, 62-ninth cylinder and 63-baffle rod; the device comprises a 7-chip misplacement rotating device, a 70-chip set adjusting rack, a 71-misplacement servo motor, a 72-chip set rotating misplacement pipeline, a 73-third chip guide shaft, a 74-chip feeding ruler, a 740-fifth cylinder, a 75-second feed back opening, a 76-first feed back opening, a 77-second chip guide shaft, a 78-chip inlet opening and a 79-second chip guide shaft bracket; 8-eighth cylinder, 81-pushing plate compression bar.

Detailed Description

Example 1: referring to fig. 1-3, an all-in-one core punching machine comprises a core punching machine main body 4, wherein a core conveying device 1, a core punching device 2, a core punching device 3 and a chip group sheet conveying device 5 are arranged on the core punching machine main body, the core conveying device 1 comprises a core shaft groove 13 for accommodating a core, a longitudinal core shaft groove 10 which is parallel to the discharge outlet of the core shaft groove 13 extends to the bottom of the core shaft groove 13, the core punching device 2 is arranged between the core shaft groove 13 and the vertical core shaft groove 16 near the longitudinal core shaft groove 10, the core punching device 3 is arranged adjacent to the tail end of the longitudinal core shaft groove 10, and the chip group sheet conveying device 5 is arranged on the other side of the core punching device 3.

The first cylinder 11 is arranged at one end of the longitudinal axis core guide groove 10, the first cylinder 11 drives the axis core arranged in the longitudinal axis core guide groove 10 to push towards the direction of the vertical axis core guide groove 16 through the core pushing rod 12, the vertical axis core guide groove 16 is internally provided with an axis core arc-shaped guide hole connected with the longitudinal axis core guide groove, the height of the vertical axis core guide groove 16 is correspondingly configured according to the height of the axis core to be suitable for guiding the axis core to a discharge hole of the axis core naturally, and particularly, the center-moving arc-shaped guide hole of the vertical axis core guide groove 16 extends downwards to a position corresponding to a subsequent axis core bracket from one side close to the longitudinal axis core guide groove 10 in an arc shape.

The shaft core stamping device 2 is arranged between the vertical shaft core guide groove 16 and the shaft core trough 13, the shaft core stamping device 2 comprises a first hydraulic cylinder 21, a core pressing rod 22, a core upper die 23 and a core lower die 24 which are arranged at the top of the shaft core stamping frame, the first hydraulic cylinder 21 drives the core upper die 23 to output towards the core lower die 24 through the core pressing rod 22, and the longitudinal shaft core guide groove 10 penetrates through the core lower die 24 to extend to a core inlet of the vertical shaft core guide groove 10.

In this embodiment, an elastic device for limiting the pressing down of the upper die 23 to the lower die 24 is provided between the upper die 23 and the lower die 24, and may be a compression spring in a spring sleeve therebetween.

When the axial direction to be embossed moves between the upper die 23 and the lower die 24, the first hydraulic cylinder 21 drives the core pressing rod to press downwards so that the upper die 23 presses downwards towards the lower die 24 to press the shaft core to form the expected embossing, and after the embossing is completed, the core pressing rod 22 is lifted, and the upper die is lifted due to the existence of the compression spring so as to continue the next process.

In this embodiment, the shaft core to be punched is disposed in the shaft core trough 13 and is discharged downward into the longitudinal shaft core guide trough 10 through the shaft core trough 13, specifically, the longitudinal shaft core guide trough 10 is provided with a corresponding shaft core notch corresponding to the bottom discharge port of the shaft core trough 13, preferably, the shaft core trough 13 may be designed into a V-shape, the bottom of the shaft core trough 13 is in a hollow structure, and a sixth cylinder 14 is disposed on one side of the shaft core trough 13 to obliquely drive the pushing chip 15 to drive the shaft core to push into the longitudinal shaft core guide trough 10 toward the shaft core notch direction.

When the shaft core enters the longitudinal shaft core guide groove 10, the first cylinder 11 drives the shaft core to push towards the vertical shaft core guide groove 16 through the pushing core bar 12, and in general, the moving distance of the first cylinder 11 pushed by the pushing core bar 12 is at least one shaft core length.

The core feeding device 1 further comprises a third air cylinder 18, an intermediate transmission rod 19 and a core bracket 190 which are positioned on one side of the vertical core guide groove 16, wherein the third air cylinder 18 transmits the core bracket 190 to reciprocate between the vertical core guide groove 16 and the core punching device 3 through the intermediate transmission rod 19, the third air cylinder 18 is arranged on the air cylinder bracket 17, preferably, a fourth air cylinder 170 is arranged at the bottom of the air cylinder bracket 17, the fourth air cylinder 170 is lifted or lowered through the lifting rod to transmit the air cylinder bracket 17, and the lifting height of the fourth air cylinder 170 is slightly larger than the depth of the fixed shaft hole 33 of the core punching rod 32.

In the present embodiment, when the spindle bracket 190 is located at the bottom of the vertical spindle guide 16, coaxially with the axial direction of the discharge port of the above-described vertical spindle guide 16, it is preferable that the vertical spindle guide 16 is provided with a seventh cylinder that outputs with respect to the discharge port direction of the vertical spindle guide 16, and the seventh cylinder may discharge the drive spindle core, which is placed in the vertical spindle guide direction, to its discharge port as needed, and this portion may be required to be disposed, without being necessarily provided.

In the above embodiment, the fourth cylinder 170 may drive the cylinder bracket 190 to lift and cause the mandrel bracket 190 to lift and take the mandrel discharged from the vertical mandrel guide groove 16 or to lift and press the mandrel into the above-described fixed shaft hole 33.

In use, first, the spindle carrier 190 is moved to the discharge port of the vertical spindle guide slot 16 to receive the spindle, the spindle carrier 190 is moved to the bottom of the spindle device 3, and the spindle carrier 190 is lifted to press the spindle into the fixed shaft hole 33 of the spindle bar 32.

Preferably, the cylinder bracket 17 is provided with a limit rail which is in form-fit with the intermediate transmission rod 19 to maintain its output axial direction.

The core punching device 3 arranged on the core punching machine main body 1 comprises a pressing transmission mechanism arranged on the core punching rack 31 for transmitting a core punching rod to punch a chip group on a chip supporting tray 52 at the bottom of the core punching rod, the pressing transmission mechanism can be a second hydraulic cylinder 30 or a pressing cylinder, a fixed shaft hole 33 matched with a shaft core is formed at the bottom of the core punching rod 32, and a ring-arranged rubber layer is arranged in the fixed shaft hole 33.

In the present embodiment, after the stacked chip sets to be punched are placed on the chip carrier plate 52, the axial core is placed on the core rod 32 as described above, and then the core rod 32 is pressed down and punched onto the central axis of the stacked chip sets to complete the axial core mounting of the chip sets.

The chip set feeding device 5 comprises a second cylinder 50 at one side of the core punching device 3, which drives a chip carrier tray 52 via a feeding rod 51 and drives it back and forth between the chip set guiding device 6 and the core punching device 3.

In this embodiment, the chip set is discharged from the chip set guiding device 6 and falls onto the chip carrier plate 52, and is output by the second cylinder 50 to be driven to the bottom of the core punching device 3, after the finished product is separated from the chip carrier plate 52 after the core punching is completed, the second cylinder 50 retracts and drives the chip carrier plate 52 to move to the bottom of the chip set guiding device 6, the specific chip set guiding device 6 is correspondingly arranged with the opening of the chip carrier plate 52, and the chip limiting shaft 73 matched with the chip set abdicating opening can also be arranged on the chip carrier plate 52 according to the requirement.

A chipset guide device 6 is disposed between the core punching device 3 and the chipset feeding device 5, where the chipset guide device 6 includes a chipset guide frame and at least one set of first chip guide shafts 61 disposed on an upper portion of the chipset guide frame, and a chipset discharge port corresponding to the chipset guide frame when the chip tray 52 is pulled back is disposed at a bottom of the chipset guide frame, and in this embodiment, the chipset is serially disposed on the first chip guide shafts 61.

The chip misplacement rotating device 7 comprises a chip group adjusting rack 70 arranged at the top of the chip group guiding device 6, a chip group rotating misplacement pipeline 72 arranged at the bottom of the chip group adjusting rack 70, a chip group rotating misplacement inlet 78 extending to the top of the chip group adjusting rack 7 from one end of the chip group rotating misplacement pipeline 72 is correspondingly arranged, one end of the bottom of the chip group rotating misplacement pipeline 72 is connected with the chip group guiding device 6, the misplacement servo motor 71 drives the chip group rotating misplacement pipeline 72 to rotate, and a third chip guiding shaft protruding is annularly arranged at the inner edge of the chip group rotating misplacement pipeline 72.

A fifth cylinder 740 is arranged on one side of the chip set adjusting rack 70, the fifth cylinder 740 drives a chip feeding ruler 74 through a pull rod, the chip feeding ruler 74 is provided with a first feed back opening 76 and a second feed back opening 75 which are slightly larger than the diameter of the chip set, second chip guide shafts 77 are arranged on two sides of the chip feeding opening 78, when the chip feeding ruler 74 is pulled back, the first feed back opening 76, the second feed back opening 75 and the chip feeding opening 78 are in the same axial direction, the first feed back opening 76 is positioned at the bottom of the second chip guide shaft 77 close to one side of the fifth cylinder 740, and the second feed back opening 75 and the chip feeding opening 78 are correspondingly arranged.

Preferably, the second chip guiding shafts 77 are respectively installed on the second chip guiding shaft frames 79, the chip feeding ruler 74 is slidably installed in the two second chip guiding shaft frames 79, and the eighth air cylinder 8 is arranged at the chip inlet 78 to drive the chip pushing rod 81 to output towards the chip inlet, so that the purpose is to further feed the chip groups without misplately into the chip inlet.

In the above embodiment, the chips without chip missing are respectively mounted on the second chip guiding shafts 77 on the two sides, the chips will drop onto the first feed back opening 76 of the chip feeding ruler 74, the depth of the first feed back opening 76 is generally consistent with the number of chips with chip missing expected, the fifth cylinder 740 drives the chip feeding ruler 74, pushes the first feed back opening 76 with chips toward the chip inlet 78, and makes the chips move forward and drop into the chip inlet to be subjected to rotary chip missing by the chip rotating chip missing pipeline 72, and the chip groups after chip missing are dropped to the chip guiding device 6 from the bottom of the chip rotating chip missing pipeline.

The second feed back port 75 is simultaneously moved to the bottom of another second chip guide shaft 77 and loaded into the chip set during pushing of the first feed back port 76 toward the chip inlet port.

The fifth cylinder 740 drives the feeding ruler 74 to pull back, and makes the second feed back hole 75 coaxial with the feeding hole 78, so that the chip set is fed into the feeding hole 78 for rotating and staggering.

It can be seen from the above that, each time the chip feeding rule is driven, a certain number of chips are brought into the chip set rotating and staggered chip pipeline, the action sequence is controlled by the control device to drive the chip feeding rule to feed chips and drive the chip set rotating and staggered chip pipeline to rotate by a preset angle, then the chip feeding rule drives the chip set rotating and staggered chip pipeline to rotate again, and the continuous reciprocation is realized to staggered chips, and the number of chips placed in the chip set rotating and staggered chip pipeline can be controlled by the transmission of the baffle rod 63 in cooperation with the following ninth air cylinder 62.

In the above embodiment, the rotation angle of the chipset rotating misplacement pipeline may be configured correspondingly according to the number of the chip yielding ports.

The staggered sheet process ensures that the balance of the finished product is higher after the multi-group chip sets are punched, so as to improve the quality of the finished product.

Preferably, a ninth cylinder 62 is arranged at the position, close to the chip set rotating misplacement pipeline 72, of the chip set misplacement rotating device, and the ninth cylinder 62 drives a blocking rod 63 to block the falling direction of the chip set guiding device 6.

Of course, the above embodiments are only preferred embodiments of the present invention, and the scope of the present invention is not limited thereto, so that all equivalent modifications made in the principles of the present invention are included in the scope of the present invention.

Claims

1. The utility model provides an all-in-one core punching machine, including the core punching machine main part, the core punching machine main part is provided with and send the core device, the axle core stamping device, core punching device, chip group send the piece device, chip dislocation piece rotary device, send the core device to include the axle core silo that is used for holding axle core, the axle core silo its bottom extends to the vertical axle core guide slot parallel with axle core silo discharge port, set up axle core stamping device between axle core silo and vertical axle core guide slot, the end adjacent arrangement of vertical axle core guide slot is towards the piece device, the opposite side of core punching device sets up chip group send the piece device, chip group send the piece device to be located the below of chip dislocation piece rotary device, it is located the one side that chip dislocation piece rotary device kept away from chip group send the piece device to send the piece rotary device, be located the one end of vertical axle core guide slot and set up first cylinder, first cylinder makes the axle core of placing in the vertical axle core guide slot push towards vertical axle core guide slot direction through the transmission core bar, the vertical axial core guide groove is internally provided with an axial core arc-shaped guide hole connected with the vertical axial core guide groove, the axial core stamping device comprises a first hydraulic cylinder, a core pressing rod, a core upper die and a core lower die which are arranged at the top of an axial core stamping frame, the first hydraulic cylinder drives the core upper die to output towards the core lower die through the core pressing rod, the vertical axial core guide groove penetrates through the core lower die to extend to a core inlet of the vertical axial core guide groove, a chip group guide device is arranged between the core stamping device and a chip group sheet feeding device, the chip group misplacement rotating device comprises a chip group adjusting frame arranged at the top of the chip group guide device, a chip group rotating misplacement pipeline is arranged at the bottom of the chip group adjusting frame, one end of the top of the chip group rotating misplacement pipeline extends to the top of the chip group adjusting frame and is correspondingly arranged, one end of the bottom of the chip group rotating misplacement pipeline is connected with the chip group guide device, the staggered piece servo motor drives the chip group to rotate and the staggered piece pipeline to rotate, and a third chip guide shaft is arranged on the inner edge of the chip group rotating staggered piece pipeline in a surrounding mode.

2. An all-in-one core punching machine according to claim 1, wherein: the core punching device comprises a pressing transmission mechanism arranged on the core punching frame, the pressing transmission mechanism transmits the core punching rod to punch the chip group on the chip bearing tray, and a fixed shaft hole matched with the shaft core is formed at the bottom of the core punching rod.

3. An all-in-one core punch according to claim 2, wherein: the chip set sheet feeding device comprises a second air cylinder positioned at one side of the core punching device, and the second air cylinder drives the chip tray through a sheet feeding rod and drives the chip tray to reciprocate between the chip set guiding device and the core punching device.

4. An all-in-one core punch as claimed in claim 3, wherein: the chip set guiding device comprises a chip set guiding rack and at least one group of first chip guiding shafts arranged on the upper part of the chip set guiding rack, and a chip set discharging port corresponding to the chip supporting disc is arranged at the bottom of the chip set guiding rack.

5. An all-in-one core punching machine according to claim 4, wherein: the core feeding device further comprises a third cylinder, an intermediate transmission rod and a core bracket, wherein the third cylinder, the intermediate transmission rod and the core bracket are positioned on one side of the vertical core guide groove, and the third cylinder moves back and forth between the vertical core guide groove and the core punching device through the intermediate transmission rod and the core bracket.

6. An all-in-one core punch as defined in claim 5, wherein: and a fourth cylinder is arranged at the bottom of the third cylinder and is driven by the lifting rod to lift or descend, and the lifting height of the fourth cylinder is slightly larger than the depth of the fixed shaft hole of the punching rod.

7. An all-in-one core punching machine according to claim 1, wherein: a fifth cylinder is arranged on one side of the chip set adjusting rack, the fifth cylinder drives a chip feeding ruler through a pull-back rod, a first feed back opening and a second feed back opening which are slightly larger than the diameter of the chip set are formed in the chip feeding ruler, second chip guide shafts are arranged on two sides of the chip feeding opening, when the chip feeding rod is pulled back, the first feed back opening, the second feed back opening and the chip feeding opening are in the same axial direction, the first feed back opening is located at the bottom of the second chip guide shaft close to one side of the fifth cylinder, and the second feed back opening and the chip feeding opening are correspondingly arranged.