CN218906354U - Automatic forming device for multi-structure arc-shaped conductive package - Google Patents

Abstract

The utility model discloses an automatic forming device for multi-structure arc conductive wrapping, relates to the technical field of conductive foam, and can at least partially solve the problems that the multi-structure arc conductive foam in the prior art cannot be produced automatically and has low production efficiency. The embodiment of the utility model discloses an automatic forming device for a multi-structure arc-shaped conductive package, which comprises a first discharging plate, an arc-shaped rod, a folding plate and a forming pressing block, wherein the first discharging plate is arranged on the arc-shaped rod; the top surface height of first blowing board is less than the top surface height of book flitch, and the arc pole is used for pressing the part that the material is located first blowing board top on first blowing board, and book flitch can follow the horizontal direction and move towards the arc pole and have the arc of shape adaptation in the arc pole outside and roll over the silo, and the shaping briquetting can follow vertical direction and move towards the arc pole and have the arc step with the inboard shape adaptation of arc pole, the shape after arc step and the arc are rolled over the silo combination and arc pole shape looks adaptation.

Description

Automatic forming device for multi-structure arc-shaped conductive package

Technical Field

The utility model relates to the technical field of conductive foam, in particular to an automatic forming device for multi-structure arc conductive wrapping.

Background

The conductive foam is mainly applied to electronic products and plays roles of static electricity prevention, electromagnetic shielding and the like. The conductive foam required in different application scenes is often different in structure, for example, the conductive foam is often arc-shaped when the structure of the conductive foam is round such as the chamfering part of an electronic product or a sweeping robot.

In the prior art, the multi-structure arc conductive foam is generally wrapped and molded manually at present due to the structural specificity of the conductive foam, and the conductive foam is extremely low in efficiency and low in overall yield due to the fact that the size of the conductive foam is low, so that the material waste is easy to cause. Therefore, how to design a special structural shape of the multi-structure arc conductive foam, the multi-structure arc conductive foam can realize automatic production, and further improve production efficiency and yield of products, which is a problem to be solved by the application.

In view of this, the present application is specifically proposed.

Disclosure of Invention

The utility model aims to provide an automatic forming device for multi-structure arc-shaped conductive wrapping, which is used for solving the problems that the multi-structure conductive foam in the prior art cannot be automatically produced and has low production efficiency.

In order to solve the technical problems, the utility model adopts the following scheme:

the automatic forming device for the multi-structure arc-shaped conductive package comprises a first discharging plate, an arc-shaped rod, a folding plate and a forming pressing block, wherein the first discharging plate is arranged on the arc-shaped rod;

the top surface height of first blowing board is less than the top surface height of book flitch, and the arc pole is used for pressing the part that the material is located first blowing board top on first blowing board, and book flitch can follow the horizontal direction and move towards the arc pole and have the arc of shape adaptation in the arc pole outside and roll over the silo, and the shaping briquetting can follow vertical direction and move towards the arc pole and have the arc step with the inboard shape adaptation of arc pole, the shape after arc step and the arc are rolled over the silo combination and arc pole shape looks adaptation.

In some optional embodiments, the first discharging plate is fixed on the lower base plate, and the folding plate is arranged on the lower base plate and is in sliding connection with the lower base plate.

In some optional embodiments, the folding machine further comprises a folding push-pull cylinder for driving the folding plate to be close to or far away from the first discharging plate, and the output end of the folding push-pull cylinder is fixedly connected with one end of the folding plate far away from the arc folding groove.

In some optional embodiments, the lower substrate is provided with a gate frame, and the gate frame further comprises an upper substrate positioned above the lower substrate and a material pressing cylinder for driving the upper substrate to move along the vertical direction, wherein the arc-shaped rod follows the upper substrate along the vertical direction.

In some alternative embodiments, the arc-shaped rods comprise a first arc-shaped rod and a second arc-shaped rod, and the combined first arc-shaped rod and the combined second arc-shaped rod are matched with the arc-shaped steps and the arc-shaped folding groove in shape.

In some alternative embodiments, the device further comprises a first connecting rod fixed at the end of the first arc-shaped rod along the radial direction of the arc of the first arc-shaped rod, and a second connecting rod fixed at the end of the second arc-shaped rod along the radial direction of the arc of the second arc-shaped rod; and the first connecting rod and the second connecting rod are rotationally connected with the same rotating shaft.

In some optional embodiments, the device further comprises a first rod-pulling cylinder and a second rod-pulling cylinder for driving the first arc rod and the second arc rod to pull out the formed package, the output end of the first rod-pulling cylinder is hinged with the first connecting rod, the second rod-pulling cylinder is hinged with the second connecting rod, and one ends, far away from the output end, of the first rod-pulling cylinder and the second rod-pulling cylinder are both hinged with the upper substrate.

In some alternative embodiments, the second arcuate bar includes integrally formed D-shaped sections and semi-circular sections, the semi-circular sections having the same shape as the first arcuate bar.

In some optional embodiments, the device further comprises a middle substrate arranged between the upper substrate and the lower substrate, the middle substrate is driven with the upper substrate along the vertical direction, one end of the rotating shaft is arranged on the upper substrate, the other end of the rotating shaft is arranged on the middle substrate, one end of the middle substrate, which is close to the folding plate, is arc-shaped, and an arc-shaped groove matched with one side of the arc shape of the middle substrate is formed in the bottom of the forming press block.

In some optional embodiments, the first discharging plate is provided with an arc-shaped first positioning protrusion, the folding plate is provided with a second positioning protrusion, and the first positioning protrusion and the second positioning protrusion enclose the same shape as the material after the first discharging plate and the folding plate are close to each other.

The utility model has the beneficial effects that:

the utility model discloses an automatic forming device for a multi-structure arc-shaped conductive package, which comprises a first discharging plate, an arc-shaped rod, a folding plate and a forming pressing block, wherein the first discharging plate is arranged on the arc-shaped rod; the top surface height of first blowing board is less than the top surface height of book flitch, the arc pole is used for pressing the part that the material is located first blowing board top on first blowing board, and the arc pole can follow its circular arc direction and remove, book the flitch can follow the horizontal direction and move towards the arc pole and have the arc of shape adaptation in the arc pole outside and roll over the silo, the shaping briquetting can follow vertical direction and move towards the arc pole and have the arc step with the inboard shape adaptation of arc pole, the shape after arc step and the arc are rolled over the silo combination and arc pole shape looks adaptation.

The effect is as follows:

through setting up first blowing board, book flitch, arc pole and the shaping briquetting of mutually cooperatees for the material turns over through arc pole swage, book flitch promotion material, and the shaping briquetting pushes down the general design conception that the parcel was accomplished to the material once more, can make the electrically conductive foam of multi-structure arc realize automated molding, has solved the current electrically conductive foam of multi-structure need the manual work parcel, can't automatic become to produce, problem that production efficiency is low.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of the present utility model;

fig. 2 is a schematic diagram of a three-dimensional structure of a multi-structure arc conductive foam wrapping and forming pressure maintaining process according to an embodiment of the present utility model;

fig. 3 is a schematic top view of a first blanking plate and a folding plate when they are close together in an embodiment of the present utility model;

FIG. 4 is a schematic perspective view of an embodiment of the present utility model before the arc rod is pushed down;

FIG. 5 is a schematic perspective view of an embodiment of the present utility model after the arc rod is pressed downward;

FIG. 6 is a schematic perspective view of a briquette according to an embodiment of the present utility model before being pressed down;

FIG. 7 is a schematic perspective view of an arc rod according to an embodiment of the present utility model;

FIG. 8 is a schematic perspective view of a folding plate according to an embodiment of the present utility model;

fig. 9 is a schematic perspective view of a molded compact according to an embodiment of the present utility model.

Reference numerals illustrate:

1-a lower base plate, 11-a first discharging plate, 111-a first positioning bulge, 12-a door-shaped frame, 21-a material folding plate, 211-a second positioning bulge, 212-an arc material folding groove, 22-a material folding push-pull cylinder, 31-a first arc rod, 32-a first rod drawing cylinder, 33-a first connecting rod, 34-second arc-shaped rods, 341-D-shaped sections, 342-semicircular sections, 35-second rod drawing cylinders, 36-second connecting rods, 41-middle base plates, 42-upper base plates, 43-material pressing cylinders, 44-vertical guide rails, 51-forming press blocks, 511-arc-shaped grooves, 512-arc-shaped steps and 52-forming cylinders.

Detailed Description

The present utility model will be described in further detail with reference to examples and drawings, but embodiments of the present utility model are not limited thereto.

In the description of the present utility model, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "longitudinal", "lateral", "horizontal", "inner", "outer", "front", "rear", "top", "bottom", etc., are directions or positional relationships based on those shown in the drawings, or are directions or positional relationships conventionally put in use of the inventive product, are merely for convenience of describing the present utility model and for simplifying the description, and are not indicative or implying that the apparatus or element to be referred to must have a specific direction, be constructed and operated in a specific direction, and therefore should not be construed as limiting the present utility model.

In the description of the present utility model, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "configured," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The utility model is described in detail below by reference to the attached drawings and in connection with the embodiments:

as shown in fig. 1 to 9, the automatic forming device for the multi-structure arc conductive package comprises a first discharging plate 11, an arc rod, a folding plate 21 and a forming press block 51, wherein;

the top surface height of first flitch 11 is less than the top surface height of book flitch 21, the arc pole is used for pressing the part that the material is located first flitch 11 top on first flitch 11, and the arc pole can follow its circular arc direction and remove, book flitch 21 can follow the horizontal direction and move towards the arc pole and have the arc of shape adaptation in the arc pole and roll over silo 212, shaping briquetting 51 can follow the vertical direction and move towards the arc pole and have the arc step 512 with the inboard shape adaptation of arc pole, the shape after arc step 512 and the arc are rolled over silo 212 combination and arc pole shape looks adaptation.

In this embodiment, because the shape after the combination of arc step 512 and arc roll over silo 212 and arc pole shape looks adaptation, consequently, the material is pressed behind first blowing platform through the arc pole, turn over through arc roll over silo 212 and arc step 512 in proper order, can wrap up the material on the arc pole, take out the arc pole again and can obtain fashioned product, especially, automated production's product is the arc in this embodiment, consequently, need turn over the material from the outside of arc pole to the top of arc pole earlier, reuse shaping briquetting 51 turns over the material from the top of arc pole to the inner arc one side of arc pole for the material is wrapped up on the arc pole completely.

According to the embodiment, the first discharging plate 11, the folding plate 21, the arc-shaped rods and the forming pressing block 51 are arranged in a mutually cooperative mode, so that materials are folded through the arc-shaped rods and pushed by the folding plate 21, the forming pressing block 51 presses the materials again to complete the wrapping, and the arc-shaped rods are discharged along the arc direction after the wrapping and forming of the materials are achieved, automatic forming of the multi-structure arc-shaped conductive foam can be achieved, and the problems that the conventional multi-structure conductive foam needs manual wrapping, cannot be automatically formed and is low in production efficiency are solved. According to the embodiment, the production time of single multi-structure arc-shaped conductive foam can be prolonged to be within one minute, and compared with manual package molding, the production efficiency can be greatly improved.

In some alternative embodiments, the lower substrate 1 is further included, the first discharging plate 11 is fixed on the lower substrate 1, and the folding plate 21 is disposed on the lower substrate 1 and is slidably connected with the lower substrate 1. As shown in fig. 1, the first discharging plate 11 is disposed on the lower substrate 1, and a side of the first discharging plate 11, which is close to the folding plate 21, is in a circular arc shape; the bottom of the material folding plate 21 is arranged on the sliding sleeve, a guide rail matched with the sliding sleeve is arranged at the top of the lower base plate 1, and the material folding plate 21 is in sliding connection with the guide rail on the lower base plate 1 through the sliding sleeve.

In some optional embodiments, the device further includes a folding push-pull cylinder 22 for driving the folding plate 21 to approach or depart from the first discharging plate 11, and an output end of the folding push-pull cylinder 22 is fixedly connected with an end of the folding plate 21 distant from the arc-shaped folding groove 212. As shown in fig. 4 and fig. 5, the folding push-pull cylinder 22 is horizontally arranged, the folding push-pull cylinder 22 is fixed on the lower substrate 1, and the folding push-pull cylinder 22 is used for pushing the folding plate 21 to be close to the first discharging plate 11 or far away from the first discharging plate 11, in this embodiment, the folding push-pull cylinder 22 is a common electric cylinder, and in some embodiments, the folding push-pull cylinder 22 may also be an electric telescopic rod, which is not described herein again.

In some alternative embodiments, the lower substrate 1 is provided with a gate frame 12, and further includes an upper substrate 42 above the lower substrate 1, and a pressing cylinder 43 for driving the upper substrate 42 to move in a vertical direction, where the arc rod follows the upper substrate 42 in the vertical direction. As shown in fig. 1 and 2, the pressing cylinder 43 is disposed on the gate frame 12 in an inverted state, and an output end of the pressing cylinder 43 is fixedly connected with a top of the upper substrate 42, and the pressing cylinder 43 can push the upper substrate 42 to move downward in a vertical direction or pull the upper substrate 42 to move upward in a vertical direction. The upper substrate 42 moves downwards along the vertical direction to be that the upper substrate 42 moves towards the direction close to the lower substrate 1, in this embodiment, two vertical guide rails 44 which are vertically arranged are further arranged on the upper substrate 42, a sliding sleeve which is matched with the two vertical guide rails 44 is fixed on the door-shaped frame 12, and when the upper substrate 42 is driven to move upwards or downwards along the vertical direction through arranging the two vertical guide rails 44, the material pressing cylinder 43 can utilize the two vertical guide rails 44 to further limit the moving direction of the upper substrate 42. In this embodiment, the arc rod is synchronously follow-up with the upper substrate 42 along the vertical direction, so that when the upper substrate 42 moves down, the arc rod moves down, and then the arc rod presses the portion of the material above the first discharging plate 11, in this embodiment, the material pressing cylinder 43 is a common electric cylinder, and in some embodiments, the material folding push-pull cylinder 22 may also be an electric telescopic rod, which is not described herein again.

In some alternative embodiments, the arcuate bars include a first arcuate bar 31 and a second arcuate bar 34, the combined first arcuate bar 31 and second arcuate bar 34 and the combined arcuate step 512 are shaped to fit the arcuate folding trough 212. As shown in fig. 6 to 9, the first arc-shaped lever 31 and the second arc-shaped lever 34 may be combined, and the combined shape of the first arc-shaped lever 31 and the second arc-shaped lever 34 is a circular arc-shaped lever; in this embodiment, the arc rod matched with the shape of the combined arc step 512 and the arc folding groove 212 is formed by combining the first arc rod 31 and the second arc rod 34, so that the first arc rod 31 and the second arc rod 34 are arranged, so that after the material is completely wrapped on the first arc rod 31 and the second arc rod 34 to be molded, the first arc rod 31 and the second arc rod 34 can be respectively pulled out from two sides of a molded product, and the overlong pulling distance and overlarge radian caused by pulling out of the whole arc rod from one side of the molded product are avoided.

In some alternative embodiments, the device further comprises a first connecting rod 33 fixed to the end of the first arc-shaped rod 31 along the radial direction of the arc where the first arc-shaped rod 31 is located, and a second connecting rod 36 fixed to the end of the second arc-shaped rod 34 along the radial direction of the arc where the second arc-shaped rod 34 is located; and the first link 33 and the second link 36 are rotatably connected with the same rotation shaft. As shown in fig. 4 and 5, in this embodiment, the first connecting rod 33 is disposed at an end of the first arc rod 31 away from the second arc rod 34, the second connecting rod 36 is disposed at an end of the second arc rod 34 away from the first arc rod 31, in this embodiment, an end of the first connecting rod 33 away from the first arc rod 31 and an end of the second connecting rod 36 away from the second arc rod 34 are rotatably connected on the same rotating shaft, and the axis of the rotating shaft coincides with the center of the arc where the first arc rod 31 and the second arc rod 34 are located, in this embodiment, the first arc rod 31 and the second arc rod 34 can be moved along the arc where they are located by driving the first connecting rod 33 and the second connecting rod 36 to rotate along the rotating shaft, when the ends of the first connecting rod 33 and the second connecting rod 36 away from the rotating shaft are away from each other, the first arc rod 31 and the second arc rod 34 are away from each other, and when the ends of the first connecting rod 33 and the second connecting rod 36 away from the rotating shaft are close to each other.

In some alternative embodiments, the device further comprises a first rod-pulling cylinder 32 and a second rod-pulling cylinder 35 for driving the first arc rod 31 and the second arc rod 34 to pull out the molded package, the output end of the first rod-pulling cylinder 32 is hinged with the first connecting rod 33, the second rod-pulling cylinder 35 is hinged with the second connecting rod 36, and one end, away from the output end, of the first rod-pulling cylinder 32 and the second rod-pulling cylinder 35 is hinged with the upper base plate 42. As shown in fig. 4 and 5, the output end of the first rod pumping cylinder 32 is hinged to one end of the first connecting rod 33 away from the second connecting rod 36, the output end of the second rod pumping cylinder 35 is hinged to one end of the second connecting rod 36 away from the first connecting rod 33, the first arc rod 31 is fixed between two ends of the first connecting rod 33 and is arranged close to the output end of the first rod pumping cylinder 32, and the second arc rod 34 is fixed in front of two ends of the second two rods and is arranged close to the output end of the second rod pumping cylinder 35. The first pumping rod cylinder 32 and the second pumping rod cylinder 35 may be electric cylinders or electric telescopic rods, and will not be described herein. As shown in fig. 2, the device further comprises a first hinge rod and a second hinge rod, wherein one end of the first hinge rod is hinged with the upper substrate 42, the other end of the first hinge rod is hinged with one end of the first rod drawing cylinder 32 away from the output end of the first rod drawing cylinder, one end of the second hinge rod is hinged with the upper substrate 42, and the other end of the second hinge rod is hinged with one end of the second rod drawing cylinder 35 away from the output end of the second rod drawing cylinder. When the first rod-pulling cylinder 32 and the second rod-pulling cylinder 35 push the first connecting rod 33 and the second connecting rod 36 respectively, the included angle formed by the first connecting rod 33 and the second connecting rod 36 becomes larger, the first arc rod 31 fixed on the first connecting rod 33 and the second arc rod 34 fixed on the second connecting rod 36 are far away from each other, so that the first arc rod 31 and the second arc rod 34 can be pulled out from the wrapped molded product, and the first rod-pulling cylinder 32 and the second rod-pulling cylinder 35 can be electric cylinders or electric telescopic rods and are not described herein again.

In some alternative embodiments, the second arc-shaped rod 34 includes an integrally formed D-shaped section 341 and a semicircular section 342, and the semicircular section 342 has the same shape as the first arc-shaped rod 31. In this embodiment, as shown in fig. 7, the second arc-shaped rod 34 includes a D-shaped section 341 and a semicircular section 342, and the sectional area of the D-shaped section 341 is larger than that of the semicircular section 342, and the shape of the first arc-shaped rod 31 and the second arc-shaped rod 34 after being combined is the same as that of the molded product.

In some alternative embodiments, the device further comprises a middle base plate 41 arranged between the upper base plate 42 and the lower base plate 1, the middle base plate 41 is driven with the upper base plate 42 along the vertical direction, one end of the rotating shaft is arranged on the upper base plate 42, one end of the rotating shaft is arranged on the middle base plate 41, one end of the middle base plate 41, which is close to the material folding plate 21, is in a circular arc shape, and the bottom of the forming press block 51 is provided with an arc-shaped groove 511 matched with one side of the circular arc shape of the middle base plate 41. In this embodiment, as shown in fig. 1 and 2, the middle substrate 41 is disposed below the upper substrate 42, the bottom surface of the arc-shaped rod is flush with the bottom surface of the middle substrate 41, one end of the middle substrate 41, which is close to the folding plate 21, is in a circular arc shape, and the circle center of the circular arc corresponding to the circular arc side of the middle substrate 41 coincides with the circle center of the circular arc corresponding to the arc-shaped rod.

In some alternative embodiments, the first discharging plate 11 is provided with an arc-shaped first positioning protrusion 111, the folding plate 21 is provided with a second positioning protrusion 211, and the area enclosed by the first positioning protrusion 111 and the second positioning protrusion 211 after the first discharging plate 11 and the folding plate 21 approach is the same as the material shape. As shown in fig. 3, the first positioning protrusions 111 are two, the two first positioning protrusions 111 are all in arc shape, the circle centers of the arcs where the two first positioning protrusions 111 are located are coincident, the second positioning protrusions 211 are at least five, two of the second positioning protrusions 211 are distributed on two sides of the area surrounded by the first positioning protrusions 111 and the second positioning protrusions 211, and the other three second positioning protrusions 211 are distributed on the outer sides of the area surrounded by the first positioning protrusions 111 and the second positioning protrusions 211.

When in use, the utility model is characterized in that: placing the cut material on the area surrounded by the first positioning protrusion 111 and the second positioning protrusion 211, then starting the material pressing cylinder 43, driving the upper substrate 42 to move along the vertical direction towards the first discharging plate 11 by the material pressing cylinder 43, at this time, the first arc rod 31 and the second arc rod 34 move downwards along with the upper substrate 42 until the first arc rod 31 and the second arc rod 34 press the part of the material above the first discharging plate 11 onto the first discharging plate 11, and since the top surface of the material folding plate 21 is higher than the top surface of the first discharging plate 11, the part of the material above the material folding plate 21 is in a vertical state, then starting the material folding push-pull cylinder 22 to push the material folding plate 21 to move towards the first discharging plate 11, and since the arc folding groove 212 matched with the shape outside the arc rod is arranged on the material folding plate 21, therefore, the vertical portion will be pushed by the arc folding groove 212 to wrap the outer side of the arc rod, at this time, the material does not wrap the arc rod completely, then the forming cylinder 52 is started, the forming cylinder 52 pushes the forming press block 51 to move downwards until the arc step 512 arranged at the bottom of the forming press block 51 wraps the material on the arc rod completely, then the first rod drawing cylinder 32 and the second rod drawing cylinder 35 are restarted, the first rod drawing cylinder 32 and the second rod drawing cylinder 35 push the first connecting rod 33 and the second connecting rod 36 to turn over, and further the first connecting rod 33 and the second connecting rod 36 respectively drive the first arc rod 31 and the second arc rod 34 to be away from each other, so that a formed product can be obtained, and then reset is performed, and automatic forming of the next product can be performed.

In summary, through setting up the first blowing board 11, book flitch 21, arc pole and the shaping briquetting 51 that mutually support and use for the material turns over through arc pole swage, book flitch 21 promotion material, and shaping briquetting 51 pushes down the material again and accomplishes the parcel, and the general design conception of arc pole along its circular arc direction discharge after the parcel shaping of material can realize the automatic shaping of multi-structure arc conductive foam.

It is to be understood that the above embodiments are merely illustrative of the application of the principles of the present utility model, but not in limitation thereof. Various modifications and improvements may be made by those skilled in the art without departing from the spirit and substance of the utility model, and are also considered to be within the scope of the utility model.

Claims (10)

1. The automatic forming device for the multi-structure arc-shaped conductive package is characterized by comprising a first discharging plate (11), an arc rod, a folding plate (21) and a forming pressing block (51), wherein the first discharging plate is provided with a plurality of arc-shaped grooves;

the top surface height of first blowing board (11) is less than the top surface height of book flitch (21), the arc pole is used for pressing the part that the material is located first blowing board (11) top on first blowing board (11), book flitch (21) can follow the horizontal direction and move towards the arc pole and have arc book silo (212) with the outside shape adaptation of arc pole, shaping briquetting (51) can follow the vertical direction and move towards the arc pole and have arc step (512) with the inboard shape adaptation of arc pole, shape and the arc pole shape looks adaptation after arc step (512) and the combination of arc book silo (212).

2. The automatic forming device of the multi-structure arc-shaped conductive package according to claim 1, further comprising a lower substrate (1), wherein the first discharging plate (11) is fixed on the lower substrate (1), and the folding plate (21) is arranged on the lower substrate (1) and is in sliding connection with the lower substrate.

3. The automatic forming device for the multi-structure arc-shaped conductive package according to claim 2, further comprising a folding push-pull cylinder (22) for driving the folding plate (21) to be close to or far away from the first discharging plate (11), wherein the output end of the folding push-pull cylinder (22) is fixedly connected with one end of the folding plate (21) far away from the arc-shaped folding groove (212).

4. The automatic forming device of the multi-structure arc-shaped conductive package according to claim 2, wherein the door-shaped frame (12) is arranged on the lower substrate (1), and the automatic forming device further comprises an upper substrate (42) positioned above the lower substrate (1) and a material pressing cylinder (43) for driving the upper substrate (42) to move along the vertical direction, wherein the arc-shaped rod is driven with the upper substrate (42) along the vertical direction.

5. The automatic forming device for the multi-structure arc conductive package according to claim 4, wherein the arc rods comprise a first arc rod (31) and a second arc rod (34), and the combined first arc rod (31) and second arc rod (34) are matched with the combined arc step (512) in shape with the arc folding groove (212).

6. The automatic forming device of the multi-structure arc conductive package according to claim 5, further comprising a first connecting rod (33) fixed to an end of the first arc-shaped rod (31) along a radial direction of an arc where the first arc-shaped rod (31) is located, and a second connecting rod (36) fixed to an end of the second arc-shaped rod (34) along a radial direction of an arc where the second arc-shaped rod (34) is located; and the first connecting rod (33) and the second connecting rod (36) are rotatably connected with the same rotating shaft.

7. The automatic forming device for the multi-structure arc-shaped conductive package according to claim 6, further comprising a first rod drawing cylinder (32) and a second rod drawing cylinder (35) for driving the first arc rod (31) and the second arc rod (34) to draw out the formed package, wherein an output end of the first rod drawing cylinder (32) is hinged with the first connecting rod (33), the second rod drawing cylinder (35) is hinged with the second connecting rod (36), and one ends of the first rod drawing cylinder (32) and the second rod drawing cylinder (35) far away from the output end are both hinged with the upper substrate (42).

8. The automatic forming device of a multi-structure arc conductive wrap according to claim 6, wherein the second arc-shaped rod (34) comprises an integrally formed D-shaped section (341) and a semicircular section (342), the semicircular section (342) having the same shape as the first arc-shaped rod (31).

9. The automatic forming device for the multi-structure arc-shaped conductive package according to claim 6, further comprising a middle substrate (41) arranged between the upper substrate (42) and the lower substrate (1), wherein the middle substrate (41) is driven with the upper substrate (42) along the vertical direction, one end of the rotating shaft is arranged on the upper substrate (42), the other end of the rotating shaft is arranged on the middle substrate (41), one end of the middle substrate (41) close to the folding plate (21) is arc-shaped, and an arc-shaped groove (511) matched with one arc-shaped side of the middle substrate (41) is arranged at the bottom of the forming press block (51).

10. The automatic forming device for the multi-structure arc-shaped conductive package according to claim 1, wherein an arc-shaped first positioning protrusion (111) is arranged on the first discharging plate (11), a second positioning protrusion (211) is arranged on the folding plate (21), and the area, which is formed by the first positioning protrusion (111) and the second positioning protrusion (211) and is formed by surrounding the first discharging plate (11) and the folding plate (21) after the first positioning protrusion and the folding plate (21) are close to each other, is identical to the shape of a material.

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