CN114713687A

CN114713687A - Full-automatic copper sheathing turn-ups stamping equipment

Info

Publication number: CN114713687A
Application number: CN202210444959.9A
Authority: CN
Inventors: 俞文兴; 何敏浩; 吴玉林
Original assignee: Zhejiang Zhixuan Bearing Technology Co ltd
Current assignee: Zhejiang Zhixuan Bearing Technology Co ltd
Priority date: 2022-04-26
Filing date: 2022-04-26
Publication date: 2022-07-08

Abstract

The invention discloses full-automatic copper bush flanging stamping equipment which comprises a base, wherein a mounting frame is fixed on the left side surface of the base, the top end of the mounting frame extends to a position right above the base, a hydraulic telescopic rod is vertically arranged on the bottom surface of the top end of the mounting frame, a stamping head assembly is installed at the bottom end of the hydraulic telescopic rod, a first groove is formed in the left end of the top surface of the base, a formed part is arranged in the first groove, the formed part is of an annular structure, and a distance is reserved between the top end of the formed part and the top surface of the base. The invention can avoid the workpiece from toppling in the conveying process, and ensure the smooth conveying treatment; the condition that the workpiece falls off in the transferring process is avoided, and the smooth transferring work is ensured; only one workpiece is ensured to appear at the left end position of the first guide plate each time, the workpieces are operated in sequence, and the operation disorder of the workpieces is avoided.

Description

Full-automatic copper sheathing turn-ups stamping equipment

Technical Field

The invention relates to the technical field of copper bush flanging stamping, in particular to full-automatic copper bush flanging stamping equipment.

Background

The copper sleeve is divided into a plurality of types, including a machine copper roller, a copper bearing and the like. Oil-lubricated bearings are used in various large and heavy machines and are important components of the machines. The copper bush, also called copper bush, is divided into various types, including machine copper roller, copper bearing, etc. The composite material is used for various light, large and heavy machines and is an important component on the machine. The product has the function of the traditional tin bronze bearing, takes electrolytic copper as a raw material and is matched with a plurality of trace metal elements, and is formed by high-temperature sintering and air pressure centrifugal casting processing.

In the processing process of the copper bush, the workpiece needs to be subjected to flanging stamping treatment, and special flanging stamping equipment needs to be used. However, the flanging and stamping equipment in the prior art has the following disadvantages: 1. the automatic feeding device has no automatic operation function, needs manual conveying and feeding, and has high operation strength; 2. the workpieces cannot be conveyed smoothly, and the workpieces occasionally topple in the conveying process, so that the working efficiency is reduced; 3. the clamping effect of the workpiece is poor, the workpiece is separated, and certain risks exist.

Disclosure of Invention

The invention aims to provide full-automatic copper bush flanging stamping equipment, which has the advantages that the problem that the equipment does not have the function of automatic operation, needs manual conveying and feeding and has high operation strength is solved; the workpieces cannot be conveyed smoothly, and the workpieces occasionally topple in the conveying process, so that the working efficiency is reduced; the clamping effect of the workpiece is poor, the workpiece is fallen off, and certain risks exist.

In order to realize the purpose of the invention, the invention adopts the following technical scheme: a full-automatic copper bush flanging stamping device comprises a base, wherein a mounting frame is fixed on the left side face of the base, the top end of the mounting frame extends to a position right above the base, a hydraulic telescopic rod is vertically arranged on the bottom face of the top end of the mounting frame, a stamping head assembly is mounted at the bottom end of the hydraulic telescopic rod, a first groove is formed in the left end of the top face of the base, a formed part is arranged in the first groove, the formed part is of an annular structure, and a distance is reserved from the top end of the formed part to the top face of the base;

a second groove is formed in the middle of the top surface of the base, a motor is installed in the second groove, a cross arm is fixed to an output shaft of the motor and located above the top surface of the base, and a clamping piece is fixed to the free end of the cross arm;

the workpiece conveying device is characterized in that a third groove is formed in the right end of the top surface of the base, a conveying belt is arranged in the third groove in a rotating mode, the left end of the conveying belt faces the right end of the clamping piece, a guide piece is arranged on the right end of the top surface of the base, and workpieces on the conveying belt are guided into the clamping piece by the guide piece in sequence.

Preferably, a plurality of inserted bars are vertically fixed at the bottom end of the forming part, a plurality of jacks are vertically formed in the bottom surface of the first groove, the inserted bars are detachably inserted into the jacks, and the cross sections of the inserted bars and the jacks are of circular structures.

Preferably, the holder is the semicircular structure, the right-hand member of holder has open structure, open structure's both ends all are equipped with the arc and lead in the board, be tangent transition between the inner of arc leading in board, the right-hand member of holder.

Preferably, a negative pressure pump is installed on the outer side of the clamping piece, an arc-shaped channel is formed in the clamping piece, a plurality of negative pressure suction ports are formed in the inner side wall of the clamping piece, an air suction port of the negative pressure pump is communicated with the negative pressure suction ports through the arc-shaped channel, and the negative pressure suction ports are evenly distributed along the circumferential direction of the inner wall of the clamping piece.

Preferably, the guide part comprises two first guide plates and two second guide plates, the two first guide plates are distributed in parallel, the two second guide plates are distributed in an included angle, the distance between the left ends of the two second guide plates is smaller than that between the right ends of the two second guide plates, and the distance between the two first guide plates can just accommodate one workpiece to pass through transversely.

Preferably, the punching head assembly comprises a first punching plate, a second punching plate and a third punching plate, the first punching plate is fixedly arranged at the bottom end of the hydraulic telescopic rod, the first punching plate, the second punching plate and the third punching plate are detachably combined together, and the first punching plate, the second punching plate and the third punching plate are sequentially distributed from top to bottom.

Preferably, the first punching plate, the second punching plate and the third punching plate are connected through a threaded rod, a containing groove is formed in the bottom end of the third punching plate, and the containing groove is used for containing the head of the threaded rod.

Preferably, the bottom surface of the cross arm is provided with a supporting ball, the top surface of the base is provided with an annular groove, and the supporting ball is arranged in the annular groove in a rolling manner.

Compared with the prior art, the full-automatic copper bush flanging stamping equipment adopting the technical scheme has the following beneficial effects:

when the stamping head assembly continues to press downwards, the workpiece is stamped and deformed and is filled in the inner space of the formed part and a gap between the top end of the formed part and the top surface of the base, so that the workpiece is stamped to form a copper sleeve flanging structure, and the flanging processing operation of a copper sleeve is completed;

in the device, the second groove is used for accommodating and fixing the motor, when the clamping piece clamps a workpiece in use, the motor is started, the output shaft of the motor rotates to drive the cross arm to swing, the cross arm drives the clamping piece to swing, the clamping piece drives the workpiece in the clamping piece to swing, when the workpiece is operated right above the formed piece, the clamping piece is loosened to enable the workpiece in the clamping piece to fall downwards, and the workpiece enters the formed piece to be used for subsequent punching and flanging operation;

in the device, two arc-shaped guide-in plates are fixed at the right end of the clamping piece, when a workpiece is conveyed into the left end inside the guide piece and a conveying belt continuously moves leftwards, the workpiece is conveyed into the clamping piece, specifically, the workpiece is firstly guided into an open structure by the arc-shaped guide-in plates and then enters into a semi-annular structure of the clamping piece, wherein the workpiece smoothly moves leftwards due to the tangent transition design, so that the workpiece is prevented from toppling over in the conveying process, and the smooth conveying treatment is ensured;

in the device, the clamping piece fixedly supports the negative pressure pump, and simultaneously accommodates the arc-shaped channel and the plurality of negative pressure suction ports; in the use process, the negative pressure pump is started to generate negative pressure, so that negative pressure is generated in the arc-shaped channel, then negative pressure is generated in the negative pressure suction ports, the negative pressure suction ports are in common contact with the left side wall of the workpiece, the workpiece is adsorbed, the workpiece can be stably clamped by the clamping piece, the workpiece is prevented from falling off in the transfer process, and the smooth transfer work is ensured;

and in use, when the conveying belt moves leftwards continuously, the workpieces on the top surface of the conveying belt are conveyed leftwards continuously, wherein the workpieces firstly enter between the two second guide plates, then the workpieces are gradually guided to be distributed in a triangular arrangement, the workpiece at the leftmost end is guided into between the two first guide plates, the workpieces enter between the two first guide plates and then are arranged in a straight line shape, only one workpiece is arranged at the left end position of each first guide plate, the workpieces are operated in sequence, and the operation disorder of the workpieces is avoided.

Drawings

Fig. 1 is a main sectional view of an embodiment of the full-automatic copper bush flanging and stamping device.

Fig. 2 is a sectional view of the position of the molding member in the embodiment.

FIG. 3 is an enlarged view of the embodiment at A in FIG. 1.

FIG. 4 is a schematic top view of the embodiment at the position of the clamping member and the guiding member.

Fig. 5 is a top sectional view of the position of the holder in the embodiment.

FIG. 6 is a schematic view of a punch head assembly according to an embodiment.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

As shown in fig. 1-2 full-automatic copper sheathing turn-ups stamping equipment, including base 1, be fixed with mounting bracket 21 on the left surface of base 1, the top of mounting bracket 21 extends to position department directly over base 1, the vertical hydraulic telescoping rod 22 that is provided with on the top bottom surface of mounting bracket 21, stamping head subassembly 23 is installed to hydraulic telescoping rod 22's bottom, first recess 11 has been seted up to the top surface left end of base 1, be provided with formed part 3 in the first recess 11, formed part 3 is the loop configuration, a section distance is left to the top surface of base 1 on the top of formed part 3.

In the device, the base 1 fixedly supports the mounting frame 21, the top end of the mounting frame 21 fixedly supports the hydraulic telescopic rod 22, the hydraulic telescopic rod 22 fixes the stamping head assembly 23, and the first groove 11 accommodates and limits the forming part 3.

During use, a workpiece 5 is firstly placed into the formed part 3, then the extension hydraulic telescopic rod 22 is started, the bottom end of the hydraulic telescopic rod 22 drives the stamping head assembly 23 to move downwards, the bottom surface of the stamping head assembly 23 presses the top end of the workpiece 5 downwards, when the stamping head assembly 23 continues to press downwards, the workpiece 5 is deformed by stamping and is filled with the inner space of the formed part 3 and the gap between the top end of the formed part 3 and the top surface of the base 1, so that the workpiece 5 is stamped to form a copper bush flanging structure, and the flanging processing operation of a copper bush is completed.

As shown in fig. 3 and 4, a second groove 12 is opened at a middle position of the top surface of the base 1, the motor 4 is installed in the second groove 12, a cross arm 41 is fixed on an output shaft of the motor 4, the cross arm 41 is positioned at a position above the top surface of the base 1, and a clamping piece 43 is fixed on a free end of the cross arm 41.

In the device, the second groove 12 is used for accommodating and fixing the motor 4, when the clamping piece 43 clamps the workpiece 5 in use, the motor 4 is started, the output shaft of the motor 4 rotates to drive the cross arm 41 to swing, the cross arm 41 drives the clamping piece 43 to swing, the clamping piece 43 drives the workpiece 5 inside the clamping piece to swing, after the workpiece 5 is operated right above the formed part 3, the clamping piece 43 is loosened to enable the workpiece 5 inside the clamping piece to drop downwards, and after the workpiece 5 enters the formed part 3, the subsequent punching flanging operation is performed.

As shown in fig. 3 and 4, a third groove 13 is formed in the right end of the top surface of the base 1, a conveying belt 6 is rotatably arranged in the third groove 13, the left end of the conveying belt 6 faces the right end of the clamping member 43, a guide member 7 is arranged on the right end of the top surface of the base 1, and the workpieces 5 on the conveying belt 6 are sequentially guided into the clamping member 43 by the guide member 7.

In the device, the cross section of the third groove 13 is a rectangular structure, and the conveying belt 6 is distributed along the length direction of the rectangular structure; in use, place a plurality of work pieces 5 on the top surface of conveyer belt 6 earlier, start conveyer belt 6, conveyer belt 6 swivelling movement left, conveyer belt 6 drives a plurality of work pieces 5 and moves left, a plurality of work pieces 5 move left under the guide effect of guide 7, and simultaneously, work piece 5 forms a style of calligraphy in the inside left end of guide 7 and arranges, then conveyer belt 6 carries the inside of holder 43 to work piece 5, for holder 43 centre gripping work piece 5, thereby carry out subsequent transportation material loading processing to work piece 5.

As shown in fig. 2, a plurality of insertion rods 31 are vertically fixed at the bottom end of the forming member 3, a plurality of insertion holes 14 are vertically formed in the bottom surface of the first groove 11, the insertion rods 31 are detachably inserted into the insertion holes 14, and the cross sections of the insertion rods 31 and the insertion holes 14 are circular structures.

Before using, place formed part 3 in first recess 11 earlier, simultaneously, insert a plurality of inserted bars 31 respectively in a plurality of jacks 14, wherein, jack 14 holds the design of spacing inserted bar 31, can spacing formed part 3 to avoid formed part 3 to rock in 11 internal rotations of first recess, in order to ensure that formed part 3 can carry out accurate punching press operation to work piece 5, improve the operation precision.

As shown in fig. 4 and 5, the clamping member 43 is a semi-annular structure, the right end of the clamping member 43 has an open structure, the two ends of the open structure are both provided with arc-shaped guide plates 431, and the inner ends of the arc-shaped guide plates 431 and the right end of the clamping member 43 are in tangential transition.

In the device, two arc guide plates 431 are fixed at the right end of a clamping piece 43, in use, when a workpiece 5 is conveyed into the left end of the interior of a guide piece 7, when a conveying belt 6 moves leftwards continuously, the workpiece 5 is conveyed into the interior of the clamping piece 43, specifically, the workpiece 5 is firstly guided into an open structure by the arc guide plates 431, then the workpiece 5 enters into a semi-annular structure of the clamping piece 43, wherein the workpiece 5 moves leftwards smoothly and smoothly due to the tangent transition design, the workpiece 5 is prevented from falling down in the conveying process, and smooth conveying processing is ensured.

As shown in fig. 4 and 5, a negative pressure pump 432 is installed outside the clamping member 43, an arc-shaped channel 433 is opened inside the clamping member 43, a plurality of negative pressure suction ports 434 are opened on the inner side wall of the clamping member 43, suction ports of the negative pressure pump 432 are communicated with each other through the arc-shaped channel 433 and the plurality of negative pressure suction ports 434, and the plurality of negative pressure suction ports 434 are uniformly distributed along the circumferential direction of the inner wall of the clamping member 43.

In the device, a negative pressure pump 432 is fixedly supported by a clamping piece 43, and the clamping piece 43 contains an arc-shaped channel 433 and a plurality of negative pressure suction ports 434; in the use process, start negative pressure pump 432, negative pressure pump 432 produces the negative pressure for produce the negative pressure in the arc passageway 433, then produce the negative pressure simultaneously in a plurality of negative pressure suction ports 434, a plurality of negative pressure suction ports 434 contact the left side wall of work piece 5 jointly, thereby adsorb work piece 5, make the centre gripping work piece 5 that holder 43 can be stable, avoid work piece 5 to take place the condition that drops at the in-process of transporting, ensure the smooth going on of transfer work.

As shown in fig. 3 and 4, the guide member 7 includes two first guide plates 71 and two second guide plates 72, the two first guide plates 71 are disposed in parallel, the two second guide plates 72 are disposed at an included angle, the distance between the left ends of the two second guide plates 72 is smaller than the distance between the right ends of the two second guide plates 72, and the distance between the two first guide plates 71 is just enough to accommodate one workpiece 5 to pass through in the transverse direction.

In use, when the conveying belt 6 moves leftwards continuously, the workpieces 5 on the top surface of the conveying belt are conveyed leftwards continuously, wherein the workpieces 5 firstly enter between the two second guide plates 72, then the workpieces 5 are gradually guided to be distributed in a triangular arrangement, the workpiece 5 at the leftmost end is guided into between the two first guide plates 71, wherein the workpieces 5 enter between the two first guide plates 71 and then are arranged in a straight line shape, only one workpiece 5 is ensured to appear at the position of the left end of each first guide plate 71, the workpieces 5 are operated in sequence, and the operation disorder of the workpieces 5 is avoided.

As shown in fig. 6, the punching head assembly 23 includes a first punching plate 231, a second punching plate 232 and a third punching plate 233, the first punching plate 231 is fixedly disposed on the bottom end of the hydraulic telescopic rod 22, the first punching plate 231, the second punching plate 232 and the third punching plate 233 are detachably combined together, and the first punching plate 231, the second punching plate 232 and the third punching plate 233 are sequentially distributed from top to bottom. The first punching plate 231, the second punching plate 232 and the third punching plate 233 are connected by a threaded rod 234, a receiving groove 235 is formed in the bottom end of the third punching plate 233, and the receiving groove 235 is used for receiving the head of the threaded rod 234.

In use, when the thickness of the punch head assembly 23 needs to be adjusted, the threaded rod 234 can be rotatably removed to remove the second punch plate 232 or the third punch plate 233, thereby changing the thickness of the punch head assembly 23 to meet different process requirements, and in addition, when the lower punch plate is damaged or worn, the threaded rod 234 can be removed first, and then the damaged third punch plate 233 can be replaced, so that the maintenance and the replacement can be facilitated.

As shown in fig. 3, the bottom surface of the cross arm 41 is provided with a supporting ball 42, the top surface of the base 1 is provided with an annular groove, and the supporting ball 42 is arranged in the annular groove in a rolling manner. When the cross arm 41 swings, the cross arm 41 drives the supporting ball 42 at the bottom end thereof to roll, and the supporting ball 42 is used for supporting the cross arm 41 upwards so as to improve the strength of the cross arm 41, wherein the supporting ball 42 rolls in the annular groove, has a guiding function and is beneficial to smooth rolling of the supporting ball 42.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims

1. The full-automatic copper bush flanging stamping equipment comprises a base (1) and is characterized in that a mounting frame (21) is fixed on the left side face of the base (1), the top end of the mounting frame (21) extends to a position right above the base (1), a hydraulic telescopic rod (22) is vertically arranged on the bottom face of the top end of the mounting frame (21), a stamping head assembly (23) is mounted at the bottom end of the hydraulic telescopic rod (22), a first groove (11) is formed in the left end of the top face of the base (1), a formed part (3) is arranged in the first groove (11), the formed part (3) is of an annular structure, and a distance is reserved from the top end of the formed part (3) to the top face of the base (1);

a second groove (12) is formed in the middle of the top surface of the base (1), a motor (4) is installed in the second groove (12), a cross arm (41) is fixed to an output shaft of the motor (4), the cross arm (41) is located above the top surface of the base (1), and a clamping piece (43) is fixed to the free end of the cross arm (41);

the utility model discloses a clamping piece's structure, including base (1), third recess (13) have been seted up on the top surface right-hand member of base (1), third recess (13) internal rotation is equipped with conveyer belt (6), the left end of conveyer belt (6) is just facing to the right-hand member of holder (43), be equipped with guide (7) on the top surface right-hand member of base (1), work piece (5) on conveyer belt (6) are by guide (7) leading-in the inside of holder (43) in proper order.

2. The full-automatic copper bush flanging stamping equipment of claim 1, characterized in that: the bottom of formed part (3) is vertical to be fixed with a plurality of inserted bars (31), a plurality of jacks (14) have vertically been seted up to the bottom surface of first recess (11), inserted bar (31) detachable inserts and establishes in jack (14), the cross section of inserted bar (31), jack (14) is circular structure.

3. The full-automatic copper bush flanging stamping equipment of claim 1, characterized in that: the clamping piece (43) is of a semi-annular structure, the right end of the clamping piece (43) is provided with an open structure, the two ends of the open structure are both provided with arc-shaped guide-in plates (431), and the inner ends of the arc-shaped guide-in plates (431) and the right end of the clamping piece (43) are in tangent transition.

4. The full-automatic copper bush flanging stamping equipment of claim 3, characterized in that: negative pressure pump (432) are installed to the outside of holder (43), arc passageway (433) have been seted up to the inside of holder (43), a plurality of negative pressure suction ports (434) have been seted up on the inside wall of holder (43), the induction port of negative pressure pump (432) communicates with each other through arc passageway (433) and a plurality of negative pressure suction ports (434), and is a plurality of negative pressure suction ports (434) are along the circumferencial direction evenly distributed of the inner wall of holder (43).

5. The full-automatic copper bush flanging stamping equipment of claim 1, characterized in that: the guide piece (7) comprises two first guide plates (71) and two second guide plates (72), the two first guide plates (71) are distributed in parallel, the two second guide plates (72) are distributed in an included angle, the distance between the left ends of the two second guide plates (72) is smaller than that between the right ends of the two second guide plates, and the distance between the two first guide plates (71) can just accommodate one workpiece (5) to pass through in the transverse direction.

6. The full-automatic copper bush flanging stamping equipment of claim 1, characterized in that: the stamping head assembly (23) comprises a first stamping plate (231), a second stamping plate (232) and a third stamping plate (233), wherein the first stamping plate (231) is fixedly arranged at the bottom end of the hydraulic telescopic rod (22), the first stamping plate (231), the second stamping plate (232) and the third stamping plate (233) are detachably combined together, and the first stamping plate (231), the second stamping plate (232) and the third stamping plate (233) are sequentially distributed from top to bottom.

7. The full-automatic copper bush flanging stamping equipment of claim 6, characterized in that: the first punching plate (231), the second punching plate (232) and the third punching plate (233) are connected through a threaded rod (234), a containing groove (235) is formed in the bottom end of the third punching plate (233), and the containing groove (235) is used for containing the head of the threaded rod (234).

8. The full-automatic copper sheathing turn-ups stamping equipment of claim 1, characterized in that: the bottom surface of the cross arm (41) is provided with a supporting ball (42), the top surface of the base (1) is provided with an annular groove, and the supporting ball (42) is arranged in the annular groove in a rolling mode.