CN112547901A - High-efficiency copper strip forming compression mould - Google Patents
High-efficiency copper strip forming compression mould Download PDFInfo
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- CN112547901A CN112547901A CN202011433892.6A CN202011433892A CN112547901A CN 112547901 A CN112547901 A CN 112547901A CN 202011433892 A CN202011433892 A CN 202011433892A CN 112547901 A CN112547901 A CN 112547901A
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- feeding
- block
- copper strip
- stamping
- rack
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D28/00—Shaping by press-cutting; Perforating
- B21D28/02—Punching blanks or articles with or without obtaining scrap; Notching
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D43/00—Feeding, positioning or storing devices combined with, or arranged in, or specially adapted for use in connection with, apparatus for working or processing sheet metal, metal tubes or metal profiles; Associations therewith of cutting devices
- B21D43/02—Advancing work in relation to the stroke of the die or tool
- B21D43/04—Advancing work in relation to the stroke of the die or tool by means in mechanical engagement with the work
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- Press Drives And Press Lines (AREA)
Abstract
The invention discloses a high-efficiency copper strip forming compression mould which comprises a rack, a feeding mechanism, a feeding block and a stamping mechanism, wherein the feeding mechanism, the feeding block and the stamping mechanism are arranged on the inner side surface of the rack, the stamping mechanism is positioned above the discharging side of the feeding block, and the forming mechanism is arranged below the stamping mechanism. The frame is also provided with a mechanical valve for switching on or off the power source of the feeding mechanism, a crank arm arranged in an L shape and a locking block arranged on the frame in a sliding way along the feeding direction. The invention can effectively avoid that the feeding mechanism starts feeding when the stamping mechanism does not reset, so that the copper strip is pressed on the cutter to cause the copper strip to bend and cannot be fed normally; meanwhile, the problem that punching consistency is affected due to inconsistent feeding length caused by feeding when the feeding mechanism is not completely reset is avoided. From this, guarantee that punching press mechanism and feeding mechanism all accomplish just to carry out the pay-off under the condition that resets, effectively adapt to punching press production rhythm at a high speed, improve stamping efficiency, and guarantee the stability of the operation of copper strips shaping crimping mould.
Description
Technical Field
The invention relates to the technical field of copper strip forming crimping dies, in particular to a high-efficiency copper strip forming crimping die.
Background
In the stamping process of the existing copper strip forming and crimping die, a feeding mechanism and a stamping mechanism are controlled by a PLC (programmable logic controller), the feeding mechanism feeds materials to the lower side of the stamping mechanism after the stamping mechanism rises, and then the stamping mechanism punches the copper strip and is matched with a forming mechanism to bend and form the copper strip.
The copper strip forming and crimping die usually works continuously, so that the running speeds of the stamping mechanism and the feeding mechanism are high, the feeding mechanism and the stamping mechanism are driven by different mechanisms, and the actions of the feeding mechanism and the stamping mechanism are difficult to keep absolutely consistent. Therefore, the stamping mechanism and the feeding mechanism of the general stamping die keep a time difference to ensure that the material strip is stamped after being fed into the stamping position.
Based on the above reasons, the punching efficiency of the existing copper strip forming crimping die cannot work efficiently, and needs to be further improved.
Disclosure of Invention
Aiming at the problems in the prior art, the invention mainly aims to provide a high-efficiency copper strip forming compression mould, aiming at driving a feeding mechanism to feed after a feeding port of a stamping mechanism is completely reserved.
In order to achieve the purpose, the high-efficiency copper strip forming compression mould provided by the invention comprises a rack, and a feeding mechanism, a feeding block and a stamping mechanism which are sequentially arranged on the inner side surface of the rack along a feeding direction, wherein the stamping mechanism is positioned above the discharging side of the feeding block, and a forming mechanism is arranged below the stamping mechanism. Further comprising:
the mechanical valve is used for switching on or switching off a power source of the feeding mechanism and is arranged on the rack;
the crank arm is arranged in an L shape and is movably arranged on the rack; the free end of the crank arm extends towards the outer side surface of the rack, and a first connecting rod and a second connecting rod which are arranged in parallel are arranged on the free end of the crank arm; the starting end of the crank arm extends towards the tool holder of the stamping mechanism, the end part of the starting end is provided with a crank part, and the crank arm body, the crank part and the first connecting rod are orthogonal in pairs;
the cutter die holder is provided with a collision block arranged along the stamping direction, and the lower end part of the collision block is arranged opposite to the crank part;
the locking block is arranged on the rack in a sliding mode along the feeding direction, a spring is arranged between the first end of the locking block and a side plate on the feeding side of the rack, and the second end of the locking block extends towards the second connecting rod;
the first end of the locking block is provided with a hook part extending to the feeding mechanism, and when the feeding mechanism resets, the feeding mechanism drives the locking block to move along one side opposite to the feeding direction.
Optionally, the feeding mechanism comprises a feeding cylinder and a clamping assembly which are sequentially arranged along a feeding direction, and the feeding cylinder is fixed on the side plate and is communicated with the mechanical valve;
the output end of the feeding cylinder is provided with a push rod, the end part of the push rod is provided with a connector, the clamping assembly is fixedly connected with the connector, and the copper strip penetrates through the clamping assembly and is clamped by the clamping assembly; the hook part of the locking block extends towards the connector, and one surface of the locking block, which is close to the side plate, is opposite to the connector;
when the mechanical valve is communicated with a power source of the feeding air cylinder, the feeding air cylinder pushes the clamping assembly to feed;
when the mechanical valve cuts off the power source of the feeding cylinder, the feeding cylinder drives the clamping assembly to automatically reset and drives the locking block to move in the same direction.
Optionally, the clamping assembly comprises a first retaining device and a second retaining device which are sequentially arranged along the feeding direction, and the first retaining device is slidably arranged on the rack and connected with the connector; the second retaining device is fixedly arranged on the rack.
Optionally, the first and second backstop devices each comprise:
the horizontal part of the L-shaped fixed block is provided with a material passing groove arranged along the feeding direction, and the copper strip passes through the material passing groove;
the swinging block is obliquely arranged towards the feeding direction and is rotatably arranged at the vertical part of the L-shaped fixed block, and the upper end of the swinging block extends towards the material passing groove and is abutted against the lower surface of the copper strip which transversely penetrates through the material passing groove;
the cover plate is covered on the L-shaped fixed block and is provided with a protruding part inserted into the material passing groove, and a material passing gap is formed between the upper end surface of the protruding part and the bottom of the material passing groove;
a guide post, the first end of which crosses the lower end of the swing block and is fixed on the cover plate through a lock pin; the second end of the guide post extends to one side of the lower end part far away from the swinging block, and the end part of the second end of the guide post is provided with an adjustable nut;
and the spring is sleeved on the guide pillar, and two ends of the spring are respectively abutted between the lower end part of the swinging block and the adjustable nut.
Optionally, a movable area is concavely arranged on one surface of the cover plate opposite to the L-shaped fixed block, and the swinging block is located in the movable area.
Optionally, the stamping mechanism includes a housing fixed to the frame, the die holder is slidably disposed in the housing along a stamping direction, and a cutter opposite to the forming mechanism is disposed on the die holder.
Optionally, a clamping groove arranged along the stamping direction is formed in one side, close to the rack, of the cutter die holder, and the collision block is arranged in the clamping groove;
when the stamping mechanism stamps along the stamping direction, the striking block impacts the crank part to enable the crank arm to rotate along the axis of the crank arm, so that the crank part is clamped between the side wall of the clamping groove and the side wall of the striking block.
Optionally, a sliding groove is formed in the inner side surface of the rack, and the locking block is slidably arranged in the sliding groove;
the inner side surface of the rack is provided with an avoidance area communicated with the sliding groove, and the second connecting rod is located in the avoidance area.
Optionally, a limiting block is arranged on the locking block, and the limiting block is close to the punching mechanism.
The invention adds a mechanical valve, a crank arm and a locking block on a copper strip forming compression mould. Wherein, the mechanical valve is used for connecting or cutting off the feeding mechanism for feeding. The crank arm is movably arranged on the rack, the free end of the crank arm extends to the outer side surface of the rack, and a first connecting rod and a second connecting rod which are arranged in parallel are arranged on the crank arm; the initiating terminal of crank arm extends to the die holder of punching press mechanism, and the initiating terminal tip has the bent handle portion, and crank arm body, bent handle portion and first connecting rod are two liang of orthogonalizations. The cutter die holder is provided with a collision block arranged along the stamping direction, and the lower end part of the collision block is arranged opposite to the crank part. The locking block is arranged on the rack in a sliding mode along the feeding direction, a spring is arranged between the first end of the locking block and the side plate on the feeding side of the rack, and the second end of the locking block extends towards the second connecting rod. The first end of the locking block is also provided with a hook part extending to the feeding mechanism, and when the feeding mechanism resets, the feeding mechanism drives the locking block to move along one side opposite to the feeding direction.
When the stamping mechanism stamps along the stamping direction, the collision block can collide the crank part of the crank arm to enable the crank arm to rotate, the first connecting rod on the crank arm is driven to apply pressure to the mechanical valve, so that the mechanical valve immediately cuts off the feeding mechanism, and the state of applying pressure to the mechanical valve is kept under the interference of the collision block, so that the feeding mechanism is ensured not to feed materials in the stamping process; meanwhile, the feeding mechanism starts to automatically reset after being cut off, and drives the second end of the locking block to be drawn out from the lower part of the second connecting rod, so that space is provided for the crank arm to swing.
When punching press mechanism punching press resets, separate until hitting the piece and the bent handle portion of cranking arm, ensure that punching press mechanism vacates the feed block discharge gate completely, crank arm can just be under the action of gravity of first connecting rod and second connecting rod naturally the lower hem for the inductive head of mechanical valve can relax, restarts the feeding mechanism pay-off.
If the feeding mechanism cannot be reset after the stamping mechanism is stamped and reset, the locking block is clamped below the second connecting rod under the action of the spring, so that the first connecting rod is kept in a state of pressing the mechanical valve, and the resetting action is continued until the locking block is pulled out from the lower part of the second connecting rod. Therefore, feeding can be ensured when the feeding mechanism is completely reset, and the consistency of the feeding length is ensured.
By the copper strip forming compression mould, the problem that the copper strip cannot be normally fed due to bending of the copper strip caused by pressing the copper strip against the cutter because the feeding mechanism starts feeding when the stamping mechanism does not reset can be effectively avoided; meanwhile, the problem that punching consistency is affected due to inconsistent feeding length caused by feeding when the feeding mechanism is not completely reset is avoided. From this, guarantee that punching press mechanism and feeding mechanism all accomplish just to carry out the pay-off under the condition that resets, effectively adapt to punching press production rhythm at a high speed, improve stamping efficiency, and guarantee the stability of the operation of copper strips shaping crimping mould.
Drawings
FIG. 1 is a schematic perspective view of one embodiment of a copper strip forming and crimping die of the present invention;
FIG. 2 is a schematic perspective view of an embodiment of a copper strip forming and crimping die of the present invention with the housing removed;
FIG. 3 is a schematic perspective view of a clamping assembly in an embodiment of a copper tape forming and crimping die of the present invention;
FIG. 4 is a schematic structural view of a clamping assembly in a feeding state in an embodiment of a copper strip forming and crimping die of the present invention;
FIG. 5 is a schematic structural view of a feeding state in an embodiment of the copper tape forming crimping die of the present invention;
FIG. 6 is a schematic structural view of a copper strip forming and crimping die according to an embodiment of the present invention in a stamping state;
fig. 7 is a schematic structural view of a locking block in an early stage of a stamping state in an embodiment of a copper strip forming and crimping die of the present invention.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to the attached drawings 1 and 5-7 in the specification, the embodiment of the invention provides a copper strip forming and crimping die, which comprises a frame 1, a feeding mechanism 2, a feeding block 3 and a stamping mechanism 4, wherein the feeding mechanism 2, the feeding block 3 and the stamping mechanism are sequentially arranged on the inner side surface of the frame 1 along a feeding direction. The stamping mechanism 4 is positioned above the discharging side of the feeding block 3, and the forming mechanism 5 is arranged below the stamping mechanism 4.
In this embodiment, the copper strip forming crimping die further comprises a mechanical valve 6, a crank arm 7 and a locking block 8.
Wherein, the mechanical valve 6 is arranged on the outer side surface of the frame 1, the input end of the mechanical valve is connected with an external power source, and the output end of the mechanical valve is communicated with the feeding mechanism 2. When the induction head of the mechanical valve 6 is extruded by external force, the mechanical valve 6 is closed, and the space between the feeding mechanism 2 and an external power source is cut off, so that the feeding mechanism 2 stops feeding, and the feeding mechanism 2 automatically resets after stopping feeding. When the induction head of the mechanical valve 6 is not extruded by external force, the mechanical valve 6 is communicated with the feeding mechanism 2 and an external power source, so that the feeding mechanism 2 feeds materials.
The crank arm 7 is movably inserted on the frame 1, the free end of the crank arm extends to the outer side surface of the frame 1, the free end is provided with a first connecting rod 71 and a second connecting rod 72 which are arranged in parallel, and the first connecting rod 71 is positioned below the induction head of the mechanical valve 6. The start end of the crank arm 7 extends towards the tool holder 42 of the stamping mechanism 4, and the end of the start end has a crank portion 7a, and the crank arm 7 body, the crank portion 7a and the first connecting rod 71 are orthogonal in pairs. The die holder 42 is provided with a striking block 421 arranged along the punching direction, and the lower end of the striking block 421 is arranged opposite to the crank portion 7 a.
When the punching mechanism 4 punches along the punching direction, the striking block 421 strikes the crank portion 7a of the crank arm 7, so that the crank arm 7 rotates along the axis thereof, and the first connecting rod 71 is driven to apply pressure to the mechanical valve 6, so that the mechanical valve 6 cuts off the connection between the feeding mechanism 2 and an external power source.
The striking block 421 has a certain length, and the crank arm 7 will keep the state of pressing the mechanical valve 6 under the interference of the striking block 421 during the punching process, so as to ensure that the feeding mechanism 2 will not feed during the punching process. And when punching press mechanism 4 resets, until hitting piece 421 along with punching press mechanism 4 and separating with the crank portion 7a of crank arm 7 completely, crank arm 7 can just freely swing, can just carry out the pay-off after guaranteeing that punching press mechanism 4 vacates the feed block 3 discharge gate completely from this, avoids punching press mechanism 4 not vacating the feed block 3 discharge gate, and feed mechanism 2 just begins the pay-off and makes copper strips 9 support and press on cutter 43, and then leads to the crooked condition that can not normally pay-off of copper strips 9.
The locking block 8 is arranged on the frame 1 in a sliding manner along the feeding direction, a first spring 81 is arranged between the first end of the locking block and the side plate 11 at the feeding side of the frame 1, the second end of the locking block extends towards the second connecting rod 72, and the first end of the locking block 8 is also provided with a hook part 8a extending towards the feeding mechanism 2.
When the feeding mechanism 2 is cut off, the automatic reset is started, and the second end of the locking block 8 is simultaneously driven to be drawn out from the lower part of the second connecting rod 72, so that a space is provided for the crank arm 7 to swing.
If the feeding mechanism 2 fails to complete the reset after the punching reset of the punching mechanism 4, the lock 8 is engaged under the second link 72 by the first spring 81, so that the first link 71 maintains the state of pressing the mechanical valve 6, and the reset operation is continued until the lock 8 is pulled out from under the second link 72. Thus, feeding can be ensured when the feeding mechanism 2 is completely reset, and the consistency of the feeding length is ensured.
By the copper strip 9 forming compression mould, the problem that the copper strip 9 cannot be normally fed due to bending of the copper strip 9 caused by pressing the copper strip 9 against the cutter 43 because the feeding mechanism 2 starts feeding when the stamping mechanism 4 does not reset is effectively avoided; meanwhile, the problem that punching consistency is affected due to inconsistent feeding length caused by feeding when the feeding mechanism 2 is not completely reset is avoided. From this, guarantee that stamping mechanism 4 and feeding mechanism 2 all accomplish just pay-off under the circumstances that resets, effectively adapt to the production rhythm of punching press at a high speed, improve stamping efficiency, and guarantee the stability of the operation of copper strips 9 shaping crimping mould.
With continued reference to fig. 1 and 2, in the present embodiment, the feeding mechanism 2 includes a feeding cylinder 21 and a clamping assembly, which are sequentially arranged along the feeding direction, and the feeding cylinder 21 is fixed on the side plate 11 and is communicated with the mechanical valve 6.
The output end of the feeding cylinder 21 is provided with a push rod, the end part of the push rod is provided with a connector 211, the clamping component is fixedly connected with the connector 211, and the copper strip 9 penetrates through the clamping component and is clamped by the clamping component. Thus, when the feed cylinder 21 pushes the clamp assembly to move toward the press mechanism 4, feeding can be performed. When the feeding cylinder 21 is cut off from the power source by the mechanical valve 6, the feeding cylinder 21 drives the clamping assembly to automatically reset.
With continued reference to fig. 7, hook portion 8a of lock block 8 extends toward connection head 211, and its side near side plate 11 is opposite to connection head 211. When the feeding cylinder 21 drives the clamping assembly to automatically reset, the connector 211 contacts with the hook portion 8a of the locking block 8, and drives the second end of the locking block 8 to be drawn out from the lower portion of the second connecting rod 72.
With continuing reference to fig. 1-2 and fig. 3-4, in this embodiment, the clamping assembly includes a first retaining device 22 and a second retaining device 23 sequentially disposed along the feeding direction, the first retaining device 22 is slidably disposed on the frame 1 and connected to the connecting joint 211; the second retaining device 23 is fixedly arranged on the frame 1.
During feeding, the feeding cylinder 21 drives the first stopping device 22 to move along the feeding direction, and the copper strip 9 and the first stopping device generate a friction force opposite to the feeding direction, so that the first stopping device 22 clamps the copper strip 9 and drives the copper strip 9 to feed.
After feeding is completed, the feeding cylinder 21 drives the first retaining device 22 to reset, the second retaining device 23 clamps the copper strip 9 under the action of the reverse tension of the copper strip 9, and the first retaining device moves in the reverse direction (the reverse direction is the same as the reverse tension of the copper strip 9) relative to the copper strip 9 along the feeding direction, so that the copper strip 9 cannot be clamped, and the first retaining device and the second retaining device reset together with the feeding cylinder 21 to perform feeding next time.
The copper strip 9 can be clamped, fed and stopped by adopting the two stopping devices, and the structure is simple and convenient to popularize and apply.
In the embodiment, the first retaining device 22 and the second retaining device 23 are the same retaining device, so that the complexity of the feeding mechanism 2 is simplified and the manufacturing cost of the feeding mechanism 2 is reduced.
Taking the first anti-backup device 22 as an example, in the present embodiment, the first anti-backup device 22 includes an L-shaped fixed block 221, a swinging block 222, a cover plate 223, a guide post 224 and a second spring 225. The horizontal part of the L-shaped fixing block 221 has a passing groove 221a arranged along the feeding direction, and the copper belt 9 passes through the passing groove 221 a. The swing block 222 is rotatably disposed at a vertical portion of the L-shaped fixing block 221 and is inclined toward one side of the feeding direction. The upper end of the swing block 222 extends into the material passing groove 221a and presses the copper strip 9 into the material passing groove 221 a.
The cover plate 223 covers the L-shaped fixing block 221 and has a protrusion 223a inserted into the material passing groove 221a, and a material passing gap is formed between the upper end surface of the protrusion 223a and the bottom of the material passing groove 221a, so as to limit the vertical deformation range of the copper strip 9 in the material passing groove 221a, so that the copper strip 9 is fed in a straight form, and the situation that the copper strip 9 cannot be normally fed due to bending in the process of pushing the copper strip 9 is avoided.
A first end of the guide post 224 traverses the lower end of the swing block 222 and is fixed to the cover plate 223 by a lock pin. The second end of the guide post 224 extends away from the lower end of the swing block 222, and the second end thereof is provided with an adjustable nut 2241. The second spring 225 is sleeved on the guide post 224, and two ends of the second spring 225 are respectively abutted between the lower end of the swing block 222 and the adjustable nut 2241. Thus, the compression amount of the second spring 225 can be changed by rotating the adjustable nut 2241, so that the acting force exerted on the swinging block 222 by the second spring 225 is adjusted, the pressure exerted on the copper strip 9 by the swinging block 222 is further changed, and the feeding resistance of the copper strip 9 is adjusted.
In addition, a movable region 223b is concavely formed on the surface of the cover plate 223 opposite to the L-shaped fixed block 221, and the swing block 222 is positioned in the movable region 223 b. Therefore, the swinging amplitude of the swinging block 222 is limited, and the situation that the swinging block 222 jumps due to overlarge swinging amplitude and cannot timely clamp the copper belt 9 is avoided.
In the present embodiment, the stamping mechanism 4 includes a housing 41 fixed to the frame 1, a tool holder 42 is slidably disposed in the housing 41 along the stamping direction, and a cutting blade 43 is disposed on the tool holder 42 and faces the forming mechanism 5. During stamping, the cutting knife 43 cuts off the copper strip 9 from the discharge side of the feeding block 3
A clamping groove (not shown) arranged along the stamping direction is arranged at one side of the cutter die holder 42 close to the rack 1, and the collision block 421 is arranged in the clamping groove. When the punching mechanism 4 punches along the punching direction, the striking block 421 strikes the crank portion 7a of the crank arm 7, so that the crank arm 7 rotates along its own axis, and the crank portion 7a is clamped between the side wall of the card slot and the side wall of the striking block 421. Thus, it is possible to avoid the situation where the crank arm 7 is rotated too much and the first link 71 violently hits the mechanical valve 6 when the striking block 421 strikes the crank portion 7a of the crank arm 7 during the high-speed punching.
In this embodiment, a sliding groove 1a is provided on the inner side surface of the frame 1, and the lock block 8 is slidably provided in the sliding groove 1 a. The sliding groove 1a can guide the sliding of the locking piece 8 and keep the stability of the sliding of the locking piece 8.
Correspondingly, an avoiding area communicated with the chute 1a is arranged on the inner side surface of the frame 1, and the second connecting rod 72 is positioned in the avoiding area. Thus, the lock block 8 can be smoothly inserted under the second link 72 and smoothly withdrawn from under the second link 72 in the rapid press process.
In this embodiment, the lock block 8 is provided with a limit block 8b, and the limit block 8b is close to the punching mechanism 4. Thereby, the movement of the locking block 8 is limited.
The above description is only a preferred embodiment of the present invention and should not be taken as limiting the invention, and any minor modifications, equivalents and improvements made to the above embodiment according to the technical spirit of the present invention should be included in the protection scope of the technical solution of the present invention.
Claims (9)
1. The utility model provides a high efficiency copper strips shaping crimping die, its includes the frame, sets gradually in feeding mechanism, pay-off piece and the punching press mechanism of frame medial surface along the pay-off direction, just punching press mechanism is located the ejection of compact side top of pay-off piece, the below of punching press mechanism sets up forming mechanism, its characterized in that still includes:
the mechanical valve is used for switching on or switching off a power source of the feeding mechanism and is arranged on the rack;
the crank arm is arranged in an L shape and is movably arranged on the rack; the free end of the crank arm extends towards the outer side surface of the rack, and a first connecting rod and a second connecting rod which are arranged in parallel are arranged on the free end of the crank arm; the starting end of the crank arm extends towards the tool holder of the stamping mechanism, the end part of the starting end is provided with a crank part, and the crank arm body, the crank part and the first connecting rod are orthogonal in pairs;
the cutter die holder is provided with a collision block arranged along the stamping direction, and the lower end part of the collision block is arranged opposite to the crank part;
the locking block is arranged on the rack in a sliding mode along the feeding direction, a spring is arranged between the first end of the locking block and a side plate on the feeding side of the rack, and the second end of the locking block extends towards the second connecting rod;
the first end of the locking block is provided with a hook part extending to the feeding mechanism, and when the feeding mechanism resets, the feeding mechanism drives the locking block to move along one side opposite to the feeding direction.
2. The high efficiency copper strip forming crimping die of claim 1, wherein said feed mechanism includes a feed cylinder and a clamping assembly disposed in sequence along a feed direction, said feed cylinder being secured to said side plate and in communication with said mechanical valve;
the output end of the feeding cylinder is provided with a push rod, the end part of the push rod is provided with a connector, the clamping assembly is fixedly connected with the connector, and the copper strip penetrates through the clamping assembly and is clamped by the clamping assembly; the hook part of the locking block extends towards the connector, and one surface of the locking block, which is close to the side plate, is opposite to the connector;
when the mechanical valve is communicated with a power source of the feeding air cylinder, the feeding air cylinder pushes the clamping assembly to feed;
when the mechanical valve cuts off the power source of the feeding cylinder, the feeding cylinder drives the clamping assembly to automatically reset and drives the locking block to move in the same direction.
3. The high-efficiency copper strip forming crimping die as claimed in claim 2, wherein the clamping assembly comprises a first retaining device and a second retaining device which are sequentially arranged along the feeding direction, and the first retaining device is slidably arranged on the frame and connected with the connector; the second retaining device is fixedly arranged on the rack.
4. The high efficiency copper strip forming crimping die of claim 3, wherein said first and second backstop devices each comprise:
the horizontal part of the L-shaped fixed block is provided with a material passing groove arranged along the feeding direction, and the copper strip passes through the material passing groove;
the swinging block is obliquely arranged towards the feeding direction and is rotatably arranged at the vertical part of the L-shaped fixed block, and the upper end of the swinging block extends towards the material passing groove and is abutted against the lower surface of the copper strip which transversely penetrates through the material passing groove;
the cover plate is covered on the L-shaped fixed block and is provided with a protruding part inserted into the material passing groove, and a material passing gap is formed between the upper end surface of the protruding part and the bottom of the material passing groove;
a guide post, the first end of which crosses the lower end of the swing block and is fixed on the cover plate through a lock pin; the second end of the guide post extends to one side of the lower end part far away from the swinging block, and the end part of the second end of the guide post is provided with an adjustable nut;
and the spring is sleeved on the guide pillar, and two ends of the spring are respectively abutted between the lower end part of the swinging block and the adjustable nut.
5. The feeding mechanism of a copper strip forming and crimping die as claimed in claim 4, wherein a movable area is concavely provided on a surface of the cover plate opposite to the L-shaped fixed block, and the swinging block is located in the movable area.
6. The high efficiency copper strip forming and crimping die of claim 1, wherein said stamping mechanism includes a housing secured to said frame, said die holder slidably disposed within said housing in a stamping direction, said die holder having a cutting blade disposed thereon opposite said forming mechanism.
7. The high-efficiency copper strip forming and crimping die as claimed in claim 6, wherein a clamping groove arranged along a stamping direction is arranged on one side of the cutter die holder close to the frame, and the collision block is arranged in the clamping groove;
when the stamping mechanism stamps along the stamping direction, the striking block impacts the crank part to enable the crank arm to rotate along the axis of the crank arm, so that the crank part is clamped between the side wall of the clamping groove and the side wall of the striking block.
8. The high efficiency copper strip forming and crimping die of claim 6, wherein a sliding slot is provided on an inner side of said frame, said locking piece is slidably disposed in said sliding slot;
the inner side surface of the rack is provided with an avoidance area communicated with the sliding groove, and the second connecting rod is located in the avoidance area.
9. The high efficiency copper strip forming crimping die of claim 8, wherein a stop block is provided on said lock, said stop block being proximate to said stamping mechanism.
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CN202011433892.6A CN112547901B (en) | 2020-12-10 | 2020-12-10 | High-efficiency copper strip forming compression mould |
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CN202011433892.6A CN112547901B (en) | 2020-12-10 | 2020-12-10 | High-efficiency copper strip forming compression mould |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113182740A (en) * | 2021-05-13 | 2021-07-30 | 宁波亚大自动化科技有限公司 | Built-in soldering lug assembling equipment for bi-pass connector |
CN114653817A (en) * | 2022-04-23 | 2022-06-24 | 乐清市通达有线电厂 | Mould is used in conductive contact piece production |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
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CN113182740A (en) * | 2021-05-13 | 2021-07-30 | 宁波亚大自动化科技有限公司 | Built-in soldering lug assembling equipment for bi-pass connector |
CN113182740B (en) * | 2021-05-13 | 2023-06-06 | 宁波亚大自动化科技有限公司 | Double-pass joint built-in soldering lug assembling equipment |
CN114653817A (en) * | 2022-04-23 | 2022-06-24 | 乐清市通达有线电厂 | Mould is used in conductive contact piece production |
CN114653817B (en) * | 2022-04-23 | 2024-05-14 | 乐清市通达有线电厂 | Die for producing conductive contact |
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