CN219703295U - Push-out type discharging structure of continuous stamping die - Google Patents

Abstract

The utility model discloses a push-out type discharging structure of a continuous stamping die, wherein a material belt cutting punch on an upper die is matched with a material belt cutting female die on a lower die to cut off a product and a material belt connecting point, a material belt floating and lifting mechanism on the lower die elastically floats and holds a material belt in the vertical direction to enable the material belt to reciprocate in the vertical direction, a material lifting block in the lower die can synchronously lift and move with the upper die, the material lifting block can upwards hold the product cut off by the material belt cutting female die by a set height, the product is separated from the material belt cutting female die and stopped in front of the product which is about to enter the material belt cutting female die on the material belt, one end of a material guiding chute is opposite to the conveying direction of the product in the lower die along the material belt conveying direction, and one end of the material guiding chute is higher than the other end of the material guiding chute.

Description

Push-out type discharging structure of continuous stamping die

Technical Field

The utility model relates to the field of hardware dies, in particular to a push-out type discharging structure of a continuous stamping die.

Background

When the continuous hardware die is used for product forming production, a material belt cutting punch is used for separating a product from the material belt after the product is formed, the separated product is discharged out of the die, the existing product discharging die is in a mode of falling out of a vertical channel under the action of dead weight, or a blowing pin hole 10 communicated with high-pressure air is arranged on a lower die, and the product is blown out of the die by adopting the high-pressure air.

After the product is processed and formed, the product is generally required to be detected and packaged, and at present, a plurality of enterprises adopt automatic equipment to detect and package the product, so that the stamping die is required to be in butt joint with the automatic equipment, and the product can be required to be uniformly discharged from the die, and the discharge position is accurate, so that the mechanical arm can accurately grasp the product.

However, the current discharging mode is difficult to ensure uniform direction and accurate blanking position after the product is discharged out of the stamping die, and is difficult to realize direct grabbing by a mechanical arm, so that the product discharged out of the stamping die can be manually placed at present, then is grabbed by the mechanical arm and sent to a detection process and a packaging process, or is manually placed into the detection process and the packaging process for manual detection and manual packaging after the product is directly collected by manual operation.

Above-mentioned technical problem leads to product stamping forming, detects and packs and is difficult to realize full automated production, needs artifical the participation, leads to the cost of labor high, and production efficiency is low, and above-mentioned ejection of compact mode still damages the product easily, causes the product defective rate high.

Disclosure of Invention

In order to overcome the defects, the utility model provides a continuous stamping die push-out type discharging structure, which can realize orderly discharging of products formed by continuous dies to a designated position, and is convenient for realizing product production, detection and packaging automatic production.

The utility model adopts the technical scheme for solving the technical problems: the utility model provides a continuous stamping die release formula ejection of compact structure, includes mould and lower mould, locates the lower mould top that last mould can elevating movement, is equipped with the material area on the mould and cuts off the drift, is equipped with the material area on the lower mould and cuts off the die, the material area cuts off the drift and can insert and locate in the material area cuts off the die with the product and take tie point to cut off, still be equipped with material area buoyancy lift mechanism on the lower mould, material area buoyancy lift mechanism is in vertical direction elasticity floating support and is held the material area and make the material area reciprocate the action in vertical direction, still be equipped with on the lower mould and lift material piece and guide chute, lift material piece can with last mould synchronous elevating movement's installation in the lower mould, lift material piece upward movement can be with the material area cut off the die and hold the settlement height upwards, make the product deviate from the material area cut off the die and stop in the material area about to get into the material area cut off the place ahead of the product of die, guide chute fixed mounting is on the lateral wall of lower mould along the material area delivery the place ahead, guide chute one end is just right with lower mould product delivery direction, guide chute one end height is higher than one end height and height is higher than the height of lower mould surface height.

As a further improvement of the utility model, a guide hole is arranged in the lower die, a material lifting block can be inserted into the guide hole in a way of sliding up and down for a set distance, and a material lifting elastic piece is also arranged in the guide hole of the lower die and provides an upward elastic holding force for the material lifting block.

As a further improvement of the utility model, the lower side of the upper die is also provided with a pressing rod, and the pressing rod can press the upper side surface of the lifting block along with the die clamping of the upper die.

As a further improvement of the utility model, the upper side surface of the lower die in front of the conveying of the material belt is also provided with a guide notch, one end of the guide notch is communicated with the material belt cutting female die, and the other end of the guide notch is directly communicated with a feed inlet at one end of the material guiding chute.

As a further improvement of the utility model, a material lifting tray for supporting the product is formed at the upper end of the material lifting block, and the material lifting tray is covered on the bottom surfaces of the material belt cutting female die and the guide notch.

As a further improvement of the utility model, the two sides of the inner side part of the material lifting tray, which is positioned at the guide notch and is vertical to the conveying direction of the products, are respectively provided with the side walls of the L-shaped structure, and the products can only slide forwards along the channels formed by the bottom surface of the tray and the two side walls.

As a further improvement of the utility model, two material lifting pipe position blocks are fixedly arranged in the lower die, the two material lifting pipe position blocks are arranged at intervals on two sides of the material lifting tray perpendicular to the product conveying direction, a limit groove with a T-shaped cross section is formed between the opposite side walls of the two material lifting pipe position blocks, the part of the material lifting tray positioned in the material belt cutting female die can be inserted into the limit groove in a vertical sliding manner, the lower side surface of the material lifting tray is stopped on the bottom surface of the limit groove, and the two side walls of the part of the material lifting tray positioned in the material belt cutting female die perpendicular to the product conveying direction are stopped on the two side walls of the limit groove.

As a further improvement of the utility model, two groups of mounting holes are arranged on the bottom surface of the lifting tray at intervals, each group of mounting holes are opposite to the material belt cutting female die and the avoidance notch respectively, each group of mounting holes comprises at least one positioning jack and at least one threaded hole, each lifting block is provided with at least one positioning bulge at the upper end, each lifting block is also provided with at least one step perforation with the inner diameter of the lower end being larger than that of the upper end, the positioning bulges on the lifting blocks are inserted into the positioning jacks on the lifting tray in the circumferential direction, the connecting bolts are inserted into the step perforations on the lifting blocks, the upper ends of the connecting bolts are in threaded connection with the threaded holes on the lifting tray, and the lower end parts of the connecting bolts are stopped on the step surfaces of the step perforations.

As a further improvement of the utility model, the side wall of the material lifting block is provided with an inward concave limit groove extending along the up-down direction, a limit pressing plate is fixedly arranged in the lower die and extends out of the inner side of the guide hole, the limit pressing plate is inserted into the inward concave limit groove on the side wall of the material lifting block, and the upper side wall and the lower side wall of the limit pressing plate are respectively stopped on the upper side surface and the lower side surface of the inward concave limit groove.

As a further improvement of the utility model, a conveyor belt mechanism is also provided, the conveyor belt mechanism can horizontally convey products forward, and the other end of the guide chute is positioned right above the conveying starting end of the conveyor belt.

The beneficial effects of the utility model are as follows: according to the utility model, the material lifting blocks and the material guiding sliding grooves are designed on the lower die, so that products separated from a material belt in the continuous stamping die are orderly pushed out of the die and are orderly discharged to a designated position along the material guiding sliding grooves, the direction of the products sent to the designated position is uniform due to the horizontal pushing mode of the products in the discharging process, and the product conveying position is accurate due to the guiding of the material guiding sliding grooves in the product conveying process.

Drawings

FIG. 1 is a schematic diagram of a stamping die employing conventional blow discharge;

FIG. 2 is a flow chart of production, inspection and packaging of a product using a conventional discharge method;

FIG. 3 is a front view of a stamping die of the present utility model;

FIG. 4 is a top view of the stamping die of the present utility model;

FIG. 5 is a right side view of the stamping die of the present utility model;

FIG. 6 is a flow chart of the production, inspection and packaging of a product employing the present utility model;

FIG. 7 is a schematic diagram of the discharge of the present utility model;

FIG. 8 is a schematic view of the present utility model in a closed mode;

FIG. 9 is a schematic view showing the utility model in an initial state of mold opening;

FIG. 10 is a schematic view showing the step feeding of a material belt according to the present utility model;

FIG. 11 is a front view of an integrated structure of a lifter block and lifter tray of the present utility model;

FIG. 12 is a top view of an integrated lifter block and lifter tray of the present utility model;

FIG. 13 is a right side view of the integrated structure of the lifter block and lifter tray of the present utility model;

FIG. 14 is a front view of a split structure of a lifter block and a lifter tray of the present utility model;

FIG. 15 is a top view of a split material lifting block and tray of the present utility model;

fig. 16 is a right side view of the split structure of the lifter block and the lifter tray of the present utility model.

Detailed Description

Examples: the utility model provides a continuous stamping die release formula ejection of compact structure, includes mould 1 and lower mould 2, and mould 1 can lifting motion locates lower mould 2 top, is equipped with material area on the mould 1 and cuts off drift 11, is equipped with the material area on the lower mould 2 and cuts off the die, the material area cuts off drift 11 and can insert and locate in the material area cuts off the die with product 8 and the place ahead of product 8 of material area 9 tie point, still be equipped with material area buoyancy lift mechanism on the lower mould 2, material area buoyancy lift mechanism is in the vertical direction elasticity and is held material area 9 and make material area 9 in the reciprocal lift action of vertical direction, still be equipped with on the lower mould 2 and lift material piece 3 and guide chute 4, lift material piece 3 can with the installation of mould 1 synchronous lifting motion in lower mould 2, lift material piece 3 upwards to move the product 8 that the material area cuts off the die and hold the settlement height, make product 8 take off the die and stop in the material area and be about to get into the product 8 place ahead of material area cut off the die, guide chute 4 is fixed mounting in the lower mould 2 along the outside of material area delivery place in the direction of material area height outside the guide chute 4, just is higher than the one end height of the side of the lower mould 4 height is higher than the side of the lower mould 4.

When the continuous die is adopted to carry out progressive stamping forming on the material belt which is conveyed forward in a straight line, after the product 8 is formed, the product 8 is cut and separated from the material belt by matching the material belt cutting punch 11 and the material belt cutting die, the product 8 is separated from the material belt after being cut and separated, after the upper die 1 is opened, the material belt is lifted up by a certain height by a material belt lifting mechanism, so that the unfinished product 8 on the material belt is separated from the lower die 2, then the material belt is conveyed forward for a step distance, the product 8 on the material belt enters the next forming station, simultaneously, the material lifting block 3 synchronously lifts up the formed product 8 separated from the material belt in the die opening process of the upper die 1, so that the product 8 is separated from the material belt cutting die on one hand, and is aligned with the front of the product 8 which is to be conveyed into the material belt cutting die on the other hand, when the material belt is conveyed forward for a step distance, the product 8 to be fed into the material belt cutting die moves forwards by one step distance against the product 8 separated from the material belt, so that the formed product 8 is pushed out of the die by the forward conveyed non-formed product 8, the product 8 pushed out of the die enters the material guiding chute 4, the formed product 8 slides downwards obliquely along the material guiding chute 4 due to the fact that one end of the material guiding chute 4 is higher than the other end of the material guiding chute 4, ordered automatic discharging is achieved, high-pressure air blowing is avoided, the discharging mode can ensure that the products 8 are discharged sequentially, disorder discharging is avoided, the product can be directly abutted with automatic equipment after discharging to achieve subsequent detection and packaging, and the discharging mode does not need extra energy consumption, so that energy is saved.

The material belt lifting mechanism on the lower die 2 generally comprises a material belt lifting elastic piece 5 which is provided with a lifting pin capable of lifting and moving and provides upward elastic holding force for the lifting pin, and the material belt is supported by the lifting pin to lift.

The lower die 2 is internally provided with a guide hole, the material lifting block 3 can be inserted into the guide hole by a set distance in a vertical sliding manner, the guide hole of the lower die 2 is internally provided with a material lifting elastic piece 5, and the material lifting elastic piece 5 provides an upward elastic holding force for the material lifting block 3. When the upper die 1 moves upwards, the material lifting block 3 and the product 8 on the material lifting block lose the lower pressure of the upper die 1, and the material lifting block 3 supports the product 8 to move upwards under the action of the elasticity of the material lifting elastic piece 5. In addition, the lifting block 3 can also realize synchronous lifting movement with the upper die 1 through an inclined sliding block mechanism matched with the upper die 1 or a pull rod mechanism connected with the upper die 1, which is an equivalent alternative structure easily thinkable by a person skilled in the art according to the utility model and belongs to the protection scope of the utility model.

The lower side of the upper die 1 is also provided with a pressing rod 12, and the pressing rod 12 can press the upper side surface of the material lifting block 3 along with the die assembly of the upper die 1. When the upper die 1 is closed, the pressing rod 12 compresses and positions the material lifting block 3, so that the product 8 is positioned in the material belt cutting female die when being separated from the material belt, the product 8 and the material belt cutting position are accurate, and meanwhile, when the upper die 1 is opened, the pressure is separated from the material lifting block 3, so that the material lifting block 3 can be automatically lifted under the action of the material lifting elastic piece 5.

The lower die 2 is further provided with a guide notch along the upper side face of the front conveying direction of the material belt, one end of the guide notch is communicated with the material belt cutting female die, and the other end of the guide notch is directly opposite to and communicated with a feed inlet at one end of the material guiding chute 4. The guide notch is arranged on the lower die 2, so that the avoidance of a formed product 8 which is not discharged from the die can be realized, the product 8 is prevented from being crushed when the lower die 2 is closed next time, besides the guide notch is arranged on the lower die 2 and used for avoiding the product 8, the notch is also arranged on the upper die 1 and used for avoiding, the length dimension of the material belt cutting female die, which is designed to be smaller than half of the length dimension of the product 8 along the discharging direction, of the lower die 2 can be designed, the product 8 is pushed out of the outer side of the stamping die and enters the material guiding chute 4 when being pushed out of the material belt cutting female die, and the mode is an equivalent replacement structure which can be easily thought by a person in the field according to the utility model, and the utility model belongs to the protection scope of the utility model.

The upper end of the material lifting block 3 is provided with a material lifting tray 6 for supporting a product 8, and the material lifting tray 6 is covered on the bottom surfaces of the material belt cutting female die and the guide notch. The product 8 is held and guided in a sliding manner through the lifting tray 6, so that the formed product 8 is discharged in a sliding manner on a smooth horizontal plane, and the product 8 is prevented from being scratched by steps.

The material lifting tray 6 is provided with L-shaped side walls 61 respectively at two sides of the inner side part of the guide notch along the conveying direction of the vertical products 8, and the products 8 can only slide forwards along the channels formed by the bottom surface of the tray and the two side walls. The side wall 61 of the L-shaped structure is arranged at the guide notch part of the material lifting tray 6, so that the product 8 slides forwards along a straight line to discharge, the product 8 is prevented from being skewed in the forward movement process of being pushed on the material lifting tray 6, ordered discharge is ensured, and further the product 8 can be smoothly docked with automatic equipment outside the stamping die.

Two material lifting pipe position blocks 22 are fixedly installed in the lower die 2, two material lifting pipe position blocks 22 are arranged on two sides of the material lifting tray 6 perpendicular to the conveying direction of the product 8 at intervals, a limiting groove with a T-shaped cross section is formed between the opposite side walls of the two material lifting pipe position blocks 22, the part of the material lifting tray 6 positioned in the material belt cutting die can be inserted into the limiting groove in a vertical sliding mode, the lower side surface of the material lifting tray 6 is stopped on the bottom surface of the limiting groove, and the two side walls of the part of the material lifting tray 6 positioned in the material belt cutting die perpendicular to the conveying direction of the product 8 are stopped on the two side walls of the limiting groove. The lifting tray 6 moves up and down to realize lifting and avoiding of the product 8, and meanwhile, the lifting tray 6 is guided and limited by two lifting pipe position blocks 22.

Two groups of mounting holes are formed in the bottom surface of the material lifting tray 6 at intervals, each group of mounting holes are opposite to the material belt cutting female die and the avoidance notch respectively, each group of mounting holes comprises at least one positioning jack 62 and at least one threaded hole 63, each material lifting block 3 is two, at least one positioning bulge 31 is arranged at the upper end of each material lifting block 3, at least one step perforation 32 with the inner diameter of the lower end being larger than that of the upper end is further arranged on each material lifting block 3 respectively, the positioning bulge 31 on the material lifting block 3 is inserted into the positioning jack 62 on the material lifting tray 6 in a circumferential direction stopping manner, a connecting bolt 33 is inserted into the step perforation 32 on the material lifting block 3, the upper end of the connecting bolt 33 is in threaded connection with the threaded hole 63 on the material lifting tray 6, and the lower end part of the connecting bolt 33 is stopped on the step surface of the step perforation 32. The material lifting block 3 and the material lifting tray 6 are formed into an integral structure in a split assembly mode, so that the material lifting tray is convenient to process and manufacture, is convenient to adapt to material lifting of products 8 with different specifications and models, and in addition, the material lifting block 3 and the material lifting tray 6 can be of an integral structure.

The side wall of the material lifting block 3 is provided with an inward concave limit groove 34 extending along the up-down direction, a limit pressing plate 21 is fixedly arranged in the lower die 2, the limit pressing plate 21 extends out of the inner side of the guide hole, the limit pressing plate 21 is inserted into the inward concave limit groove 34 on the side wall of the material lifting block 3, and the upper side wall and the lower side wall of the limit pressing plate 21 are respectively stopped on the upper side surface and the lower side surface of the inward concave limit groove 34. The limiting pressing plate 21 can be installed in the lower die 2 through screws, and the lifting distance of the material lifting block 3 is limited by the limiting pressing plate 21.

A conveyor belt mechanism 7 is further arranged, the conveyor belt mechanism 7 can horizontally convey products 8 forwards, and the other end of the guide chute 4 is positioned right above the conveying starting end of the conveyor belt. Products 8 sequentially discharged from the material guide chute 4 can be directly conveyed to a designated position through the conveying belt mechanism 7 for automatic equipment to grasp, detect and package, so that automatic intelligent production is realized, labor is saved, and production efficiency is improved.

Claims (10)

1. The utility model provides a continuous stamping die release formula ejection of compact structure, includes mould (1) and lower mould (2), locates the lower mould top that last mould can elevating movement, is equipped with material area on the last mould and cuts off drift (11), is equipped with the material area on the lower mould and cuts off the die, the material area cuts off the drift and can insert and locate in the material area cuts off the die with product (8) and material area (9) tie point cut off, still be equipped with material area climbing mechanism on the lower mould, material area climbing mechanism makes the material area in the reciprocal elevating movement of vertical direction at the floating support of vertical direction elasticity, its characterized in that: the lower die is further provided with a material lifting block (3) and a material guiding chute (4), the material lifting block can be installed in the lower die in a synchronous lifting mode with the upper die, the material lifting block can upwards move to upwards support a product cut off by the material belt cutting die to a set height, the product is separated from the material belt cutting die and stops in front of the product which is to enter the material belt cutting die on the material belt, the material guiding chute is fixedly installed on the outer side wall of the lower die in front of conveying the material belt, one end of the material guiding chute is opposite to the conveying direction of the product in the lower die, one end of the material guiding chute is higher than the other end of the material guiding chute, and one end of the material guiding chute is not higher than the upper side surface of the lower die.

2. The continuous stamping die push-out type discharging structure according to claim 1, wherein: the lower die is internally provided with a guide hole, the material lifting block can be inserted into the guide hole by a set distance in a vertical sliding manner, the guide hole of the lower die is internally provided with a material lifting elastic piece (5), and the material lifting elastic piece provides an upward elastic holding force for the material lifting block.

3. The continuous stamping die push-out type discharging structure according to claim 2, wherein: the lower side of the upper die is also provided with a pressing rod (12), and the pressing rod can press the upper side surface of the lifting block along with the die clamping of the upper die.

4. A continuous stamping die push-out type discharging structure according to claim 2 or 3, characterized in that: the lower die is further provided with a guide notch along the upper side face of the front conveying direction of the material belt, one end of the guide notch is communicated with the material belt cutting female die, and the other end of the guide notch is directly communicated with a feed inlet at one end of the material guiding chute.

5. The continuous stamping die push-out type discharging structure according to claim 4, wherein: the upper end of the lifting block is provided with a lifting tray (6) for holding products, and the lifting tray is covered on the bottom surfaces of the material belt cutting female die and the guide notch.

6. The continuous stamping die push-out type discharging structure according to claim 5, wherein: the material lifting tray is provided with side walls (61) with L-shaped structures at two sides of the inner side part of the guide notch along the direction vertical to the conveying direction of the products, and the products can only slide forwards along the channels formed by the bottom surface of the tray and the two side walls.

7. The continuous stamping die push-out type discharging structure according to claim 5, wherein: two material lifting pipe position blocks (22) are fixedly installed in the lower die, the two material lifting pipe position blocks are arranged on two sides of the material lifting tray, perpendicular to the product conveying direction, a limiting groove with a T-shaped cross section is formed between the opposite side walls of the two material lifting pipe position blocks, the part of the material lifting tray, which is positioned in the material belt cutting die, can be inserted in the limiting groove in a vertical sliding mode, the lower side surface of the material lifting tray is stopped on the bottom surface of the limiting groove, and the two side walls of the part of the material lifting tray, which is positioned in the material belt cutting die, perpendicular to the product conveying direction are stopped on the two side walls of the limiting groove.

8. The continuous stamping die push-out type discharging structure according to claim 4, wherein: two groups of mounting holes are formed in the bottom surface of the lifting tray at intervals, each group of mounting holes are opposite to the material belt cutting female die and the avoidance notch respectively, each group of mounting holes comprises at least one positioning jack (62) and at least one threaded hole (63), each lifting block is two, at least one positioning bulge (31) is arranged at the upper end of each lifting block, at least one step perforation (32) with the inner diameter of the lower end being larger than that of the upper end is further arranged on each lifting block, the positioning bulges on the lifting blocks are inserted into the positioning jacks on the lifting tray in the circumferential direction, connecting bolts (33) are inserted into the step perforation on the lifting blocks, the upper ends of the connecting bolts are in threaded connection with the threaded holes on the lifting tray, and the lower end parts of the connecting bolts are stopped on the step surfaces of the step perforation.

9. The continuous stamping die push-out type discharging structure according to claim 2, wherein: the material lifting block is characterized in that the side wall of the material lifting block is provided with an inward concave limiting groove (34) extending along the up-down direction, a limiting pressing plate (21) is fixedly arranged in the lower die, the limiting pressing plate stretches out of the inner side of the guide hole, the limiting pressing plate is inserted into the inward concave limiting groove on the side wall of the material lifting block, and the upper side wall and the lower side wall of the limiting pressing plate are respectively stopped on the upper side surface and the lower side surface of the inward concave limiting groove.

10. The continuous stamping die push-out type discharging structure according to claim 1, wherein: the conveyor belt mechanism (7) is further arranged, the conveyor belt mechanism can horizontally convey products forwards, and the other end of the guide chute is located right above the conveying starting end of the conveyor belt.