阅读说明：本技术 一种电容器铝壳制造加工设备 (Capacitor aluminum shell manufacturing and processing equipment ) 是由 刘坤 于 2021-09-01 设计创作，主要内容包括：本发明涉及电容器铝壳冲压加工技术领域,具体涉及一种电容器铝壳制造加工设备,包括底板、成型机构和下料机构,所述的底板的上端面安装有成型机构,成型机构上设置有下料机构；本发明采用的成型机构在铝壳成型之后,通过气泵向凹模腔吹气以及凸模的带动作用,使得成型之后的铝壳能够从凹模腔内取出,然后再通过取料板的阻挡作用,使得铝壳直接从凸模的外壁脱离并向下掉落,避免了人工脱模时因脱模力度难以把握导致铝壳变形的状况,同时通过下料机构带动原料板自动向下掉落至推动板的右侧,通过气泵穿过吸孔吸气以对原料板进行吸附,避免了原料板放置位置不准确的问题。(The invention relates to the technical field of capacitor aluminum shell stamping, in particular to a capacitor aluminum shell manufacturing and processing device, which comprises a bottom plate, a forming mechanism and a blanking mechanism, wherein the upper end surface of the bottom plate is provided with the forming mechanism, and the forming mechanism is provided with the blanking mechanism; according to the forming mechanism, after the aluminum shell is formed, the air pump blows air to the female die cavity and the male die is driven to enable the formed aluminum shell to be taken out of the female die cavity, then the aluminum shell is directly separated from the outer wall of the male die and falls downwards under the blocking effect of the material taking plate, the situation that the aluminum shell is deformed due to difficulty in mastering of demolding force during manual demolding is avoided, meanwhile, the blanking mechanism drives the raw material plate to automatically fall downwards to the right side of the pushing plate, and the air pump penetrates through the suction hole to suck air to adsorb the raw material plate, so that the problem that the placing position of the raw material plate is inaccurate is avoided.)

1. The utility model provides a processing equipment is made to condenser aluminum hull, includes bottom plate (1), forming mechanism (2) and unloading mechanism (3), its characterized in that: the upper end surface of the bottom plate (1) is provided with a forming mechanism (2), and the forming mechanism (2) is provided with a blanking mechanism (3);

the forming mechanism (2) comprises a support table (20), a rectangular table (21), a circular hole (22), an electric telescopic rod (23), a push plate (24), a raw material plate (25), a female die cavity (26), a support plate (27), a frame plate (28), a material taking plate (29), a material receiving plate (201), a material taking hole (202), a support hole (203), balls (204), a hydraulic cylinder (205) and a male die (206), wherein the support table (20) is installed on the upper end face of the bottom plate (1) close to the left end, the rectangular table (21) is arranged on the support table (20), the circular hole (22) is formed in the right end face of the rectangular table (21), the electric telescopic rod (23) is installed on the left end face of the inner wall of the circular hole (22), the push plate (24) is installed on a moving rod of the electric telescopic rod (23), and the female die cavity (26) is formed between the right end face of the push plate (24) and the circular hole (22), raw material plates (25) are placed on the right end face of a push plate (24), a supporting plate (27) is installed at the position, close to the right end, of the upper end face of a bottom plate (1), a frame plate (28) is installed on the left end face of the supporting plate (27), a material taking plate (29) is installed at the position, close to the left end face, of the upper end face of the frame plate (28), a bearing plate (201) is installed on the upper end face of the frame plate (28), a material taking hole (202) is formed in the left end face of the material taking plate (29), a supporting hole (203) is formed in the left end face of the bearing plate (201), balls (204) are connected to the supporting hole (203) in a rotating mode along the circumferential direction in an equidistance mode from left to right, a hydraulic cylinder (205) is installed on the left end face of the supporting plate (27), a male die (206) matched with a female die cavity (26) is installed on a moving rod of the hydraulic cylinder (205), the left end of the male die (206) penetrates through the supporting hole (203) and then is connected with the material taking hole (202) in a sliding mode, and the male die (206) is connected with the balls (204) in a sliding mode.

2. The manufacturing and processing equipment for the aluminum shell of the capacitor as claimed in claim 1, wherein: the blanking mechanism (3) comprises a blanking box (30), a blanking through groove (31), a pushing spring (32), an extrusion plate (33), sliding beads (34), a door plate (35), a lifting knob (36), a rectangular handle (36), wherein the blanking box (30) is installed on the upper end face of the rectangular table (21), the blanking box (30) is of a rectangular box-shaped structure with an upward opening, the blanking through groove (31) is formed in the lower end face of the inner wall of the blanking box (30), the blanking through groove (31) is of a rectangular structure, the circular center of the circular hole (22) is formed in the blanking through groove (31), the front end face and the rear end face of the blanking through groove (31) are tangent to the circular hole (22), the blanking through groove (31) is located above the pushing plate (24), the extrusion plate (33) is installed on the left end face of the inner wall of the blanking box (30) through the pushing spring (32), the sliding beads (34) are installed on the lower end face of the extrusion plate (33) in a rotating mode from front to back at equal intervals, the upper end surface of the material placing box (30) is hinged with a door panel (35) near the left end, and a v-21274and a shape handle (36) are arranged on the door panel (35).

3. The manufacturing and processing equipment for the aluminum shell of the capacitor as claimed in claim 1, wherein: the improved air supply device is characterized in that the push plate (24) is composed of a left circular plate and a right circular plate, an air suction hole (240) is formed in the right circular plate of the push plate (24), the air suction hole (240) is annularly arranged, an air groove (241) communicated with the air suction hole (240) is formed in the right end face of the left circular plate of the push plate (24), an air inlet hole (24a) is formed in the air groove (241), an air supply hole (243) is formed in the left end face of the inner wall of the circular hole (22), the air supply hole (243) is connected with the air inlet hole (24a) through a telescopic pipe (242), an air pump (244) is installed on the left end face of the rectangular table (21) through the base, and an air outlet of the air pump (244) is communicated with the air supply hole (243) through a connecting pipe.

4. The manufacturing and processing equipment for the aluminum shell of the capacitor as claimed in claim 2, wherein: arc limiting plates (301) are mounted on the front end face and the rear end face of the inner wall of the material discharging box (30), and the arc limiting plates (301) are located on the front side and the rear side of the extrusion plate (33).

5. The manufacturing and processing equipment for the aluminum shell of the capacitor as claimed in claim 2, wherein: the unloading on rectangle platform (21) lead to groove (31) left and right sides inner wall and all seted up the mounting groove, install rubber gasket (210) in the mounting groove.

6. The manufacturing and processing equipment for the aluminum shell of the capacitor as claimed in claim 1, wherein: the material guide plate (11) is installed on the upper end face of the bottom plate (1) through a support column (10), the material guide plate (11) is located between the rectangular table (21) and the material taking plate (29), and the front end of the material guide plate (11) is downward inclined.

7. The manufacturing and processing equipment for the aluminum shell of the capacitor as claimed in claim 6, wherein: the upper end surface of the material guide plate (11) is provided with a spongy cushion (110).

8. The manufacturing and processing equipment for the aluminum shell of the capacitor as claimed in claim 6, wherein: a collecting box (13) is arranged on the upper end face of the bottom plate (1), and the collecting box (13) is positioned below the front side of the material guide plate (11).

Technical Field

The invention relates to the technical field of capacitor aluminum shell stamping, in particular to manufacturing and processing equipment for a capacitor aluminum shell.

Background

The shell of the capacitor generally selects aluminum as a manufacturing material, the shape of the main stream is cylindrical, the cylindrical aluminum shell has the advantages of corrosion resistance, good heat-conducting property, difficulty in expansion and deformation and the like, and the shell is easy to process and can be processed and formed through cold stamping.

However, the following problems may be encountered during the manufacturing process of the aluminum capacitor case: 1. because the aluminum shell is formed by pressing and is tightly contacted with the male die and the female die, and friction exists between the aluminum shell and the male die and between the aluminum shell and the female die, certain difficulty exists in demoulding, and the manual demoulding force is difficult to master, so that the aluminum shell can be deformed by carelessness; 2. traditional mode relies on the staff to place raw materials board in the die cavity more, is difficult to the accurate position of placing of accuse raw materials board when artifical the placing, easily causes raw materials board to place unsafe problem.

Disclosure of Invention

In order to make up the defects of the prior art, the invention provides a capacitor aluminum shell manufacturing and processing device.

The invention is realized by adopting the following technical scheme: the utility model provides a processing equipment is made to condenser aluminum hull, includes bottom plate, forming mechanism and unloading mechanism, the up end of bottom plate install forming mechanism, the last unloading mechanism that is provided with of forming mechanism.

The forming mechanism comprises a supporting table, a rectangular table, a circular hole, an electric telescopic rod, a pushing plate, a raw material plate, a concave die cavity, a supporting plate, a frame plate, a material taking plate, a bearing plate, a material taking hole, a supporting hole, a ball, a hydraulic cylinder and a convex die, wherein the supporting table is arranged at the position, close to the left end, of the upper end surface of the bottom plate, the rectangular table is arranged on the supporting table, the circular hole is formed in the right end surface of the rectangular table, the electric telescopic rod is arranged at the left end surface of the inner wall of the circular hole, the pushing plate is arranged on a moving rod of the electric telescopic rod, the concave die cavity is formed between the right end surface of the pushing plate and the circular hole, the raw material plate is arranged at the position, close to the right end surface, of the upper end surface of the bottom plate, the frame plate is arranged at the left end surface of the supporting plate, the material taking plate is arranged at the position, close to the left end surface, the material taking plate is arranged at the upper end surface, the bearing plate is arranged at the upper end surface of the frame plate, the material taking hole is arranged at the left end surface, the left end face of the bearing plate is provided with a supporting hole, balls are connected in the supporting hole in a rotating mode along the circumferential direction from left to right in the supporting hole, a hydraulic cylinder is installed on the left end face of the supporting plate, a male die matched with a female die cavity is installed on a moving rod of the hydraulic cylinder, the left end of the male die penetrates through the supporting hole and is connected with a material taking hole in a sliding mode, the male die is connected with the balls in a sliding mode, the male die drives an aluminum shell to move to the left end face of the material taking plate, the male die continues to move rightwards, the aluminum shell is separated from the male die under the limiting condition of the material taking plate and drops downwards, and the problem that the aluminum shell is difficult to take down from the male die in a manual mode is avoided.

Wherein, the blanking mechanism comprises a blanking box, a blanking through groove, a pushing spring, a squeezing plate, a sliding bead, a door plate and a v-21274, the feeding box is arranged on the upper end surface of the rectangular table and is of a rectangular box-shaped structure with an upward opening, the blanking through groove is arranged on the lower end surface of the inner wall of the blanking box and is of a rectangular structure, the blanking through groove is arranged at the circle center of a circular hole, the front end surface and the rear end surface of the blanking through groove are tangent to the circular hole, the blanking through groove is positioned above the pushing plate, the left end surface of the inner wall of the blanking box is provided with the squeezing plate through the pushing spring, the sliding bead is arranged on the lower end surface of the squeezing plate at equal distance from the front to the back, the door plate is hinged on the upper end surface of the blanking box close to the left end, the v-21274is arranged on the door plate, the upper end of the blanking box is sealed through the door plate, the situation that dust or impurities fall into the blanking box is avoided, when the hydraulic cylinder drives the formed aluminum shell through a convex die to move rightwards, the electric telescopic handle shrink drives the catch bar and removes left for next raw material plate gets into the circular port, carries out the stamping forming of next aluminum hull, has avoided putting into the unsafe situation in position behind the die cavity through the manual work with raw material plate and has taken place, has improved aluminum hull contour machining's efficiency simultaneously.

Wherein, the slurcam constitute by controlling two circular slabs, seted up on the right side circular slab of slurcam and inhaled the hole, it arranges to inhale the hole to be the annular, the wind groove with inhaling the hole intercommunication is seted up to the left side circular slab right-hand member face of slurcam, the inlet port has been seted up on the wind groove, the hole of supplying gas has been seted up to the inner wall left end face of circular port, be connected through flexible pipe between hole of supplying gas and the inlet port, the air pump is installed through the frame to the left end face of rectangle platform, the gas outlet of air pump passes through the connecting pipe and feeds through with the hole of supplying gas, adsorb raw material plate on the slurcam through the air pump, the condition that the upper end of raw material plate overturned right when having avoided the slurcam to promote raw material plate right.

The material placing box comprises a material placing box body, wherein arc limiting plates are arranged on the front end face and the rear end face of the inner wall of the material placing box body, the arc limiting plates are located on the front side and the rear side of an extrusion plate, the arc limiting plates support a raw material plate in the material placing box body, and the situation that the raw material plate placing position is inaccurate is avoided.

Wherein, the inner walls of the left and right sides of the blanking through groove on the rectangular platform are provided with mounting grooves, rubber gaskets are mounted in the mounting grooves and are used for increasing the friction force in the falling process of the raw material plate, slowing down the falling speed of the raw material plate and avoiding the problem of deformation caused by large falling impact force of the raw material plate,

the material guide plate is arranged on the upper end face of the bottom plate through the support columns and located between the rectangular platform and the material taking plate, and the front end of the material guide plate is downward inclined.

The material guide plate guides the aluminum shell taken down from the male die, and meanwhile, the spongy cushion is used for reducing the impact force when the aluminum shell drops, so that the situation that the impact force generated when the aluminum shell drops is large and deformation is caused is avoided.

The collecting box is arranged on the upper end face of the bottom plate and located below the front side of the material guide plate, and the collecting box collects the formed aluminum shell.

Compared with the prior art, the invention has the beneficial effects that: 1. according to the manufacturing and processing equipment for the aluminum shell of the capacitor, provided by the invention, after the aluminum shell is formed, the formed aluminum shell can be taken out of the cavity of the female die through the air blowing of the air pump and the driving action of the male die by the forming mechanism, and then the aluminum shell is directly separated from the outer wall of the male die and falls downwards through the blocking action of the material taking plate, so that the condition that the aluminum shell is deformed due to difficulty in grasping of demolding force during manual demolding is avoided, meanwhile, the raw material plate is driven by the blanking mechanism to automatically fall downwards to the right side of the pushing plate, and the raw material plate is adsorbed by the air pump after passing through the suction hole, so that the problem that the placement position of the raw material plate is inaccurate is avoided.

2. The rubber gasket provided by the invention is used for increasing the friction force of the raw material plate in the falling process, slowing down the falling speed of the raw material plate and avoiding the problem of deformation caused by large falling impact force of the raw material plate.

3. The material guide plate provided by the invention guides the aluminum shell taken down from the male die, and the spongy cushion is used for reducing the impact force when the aluminum shell falls, so that the deformation of the aluminum shell caused by large impact force when the aluminum shell falls is avoided.

Drawings

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic view of a first three-dimensional structure of the present invention.

Fig. 2 is a second perspective view of the present invention.

Fig. 3 is a third perspective view of the present invention.

Fig. 4 is an enlarged view of fig. 3 a of the present invention.

Fig. 5 is a schematic perspective view of the circular hole, the blanking through groove and the rectangular table of the invention.

Fig. 6 is a front sectional view of the present invention.

Fig. 7 is an enlarged view of the invention at B of fig. 6.

Fig. 8 is an enlarged view of the invention at C of fig. 6.

Fig. 9 is a schematic perspective view of the aluminum case of the present invention.

In the figure, 1: a base plate; 2: a molding mechanism; 3: a blanking mechanism; 20: a support table; 21: a rectangular table; 22: a circular hole; 23: an electric telescopic rod; 24: a push plate; 25: a raw material plate; 26: a cavity; 27: a support plate; 28: a frame plate; 29: taking a material plate; 201: a bearing plate; 202: a material taking hole; 203: a support hole; 204: a ball bearing; 205: a hydraulic cylinder; 206: a male die; 30: placing a material box; 31: a blanking through groove; 32: a push spring; 33: a pressing plate; 34: a sliding bead; 35: a door panel; 36: \ 21274and a paper handle; 240: sucking holes; 241: an air duct; 242: a telescopic pipe; 243: an air supply hole; 244: an air pump; 24 a: an air inlet; 210: a rubber gasket; 301: an arc limiting plate; 11: a material guide plate; 110: a spongy cushion.

Detailed Description

Embodiments of the present invention will be described below with reference to the accompanying drawings; in this process, the width of the lines or the size of the components in the drawings may be exaggerated for clarity and convenience of description.

In addition, the following terms are defined based on the functions of the present invention, and may be different depending on the intention of the user or the operator or the convention; therefore, these terms are defined based on the entire contents of the present specification.

Referring to fig. 1, the manufacturing and processing equipment for the capacitor aluminum shell comprises a bottom plate 1, a forming mechanism 2 and a blanking mechanism 3, wherein the forming mechanism 2 is installed on the upper end face of the bottom plate 1, and the blanking mechanism 3 is arranged on the forming mechanism 2.

Referring to fig. 2, 3, 5, 6 and 7, the forming mechanism 2 includes a support table 20, a rectangular table 21, a circular hole 22, an electric telescopic rod 23, a push plate 24, a raw material plate 25, a concave cavity 26, a support plate 27, a frame plate 28, a material taking plate 29, a receiving plate 201, a material taking hole 202, a support hole 203, a ball 204, a hydraulic cylinder 205 and a convex die 206, the support table 20 is installed near the left end of the upper end surface of the bottom plate 1, the rectangular table 21 is arranged on the support table 20, the circular hole 22 is opened on the right end surface of the rectangular table 21, the electric telescopic rod 23 is installed on the left end surface of the inner wall of the circular hole 22, the push plate 24 is installed on the moving rod of the electric telescopic rod 23, the concave cavity 26 is formed between the right end surface of the push plate 24 and the circular hole 22, the raw material plate 25 is placed on the right end surface of the push plate 24, the support plate 27 is installed near the right end surface of the upper end surface of the bottom plate 1, the frame plate 28 is installed on the left end surface of the support plate 27, the upper end surface of the frame plate 28 is provided with a material taking plate 29 close to the left end surface, the upper end surface of the frame plate 28 is provided with a bearing plate 201, the left end surface of the material taking plate 29 is provided with a material taking hole 202, the left end surface of the bearing plate 201 is provided with a supporting hole 203, balls 204 are connected in the supporting hole 203 in a rotating mode from left to right along the circumferential direction at equal intervals, the left end surface of the supporting plate 27 is provided with a hydraulic cylinder 205, a moving rod of the hydraulic cylinder 205 is provided with a male die 206 matched with the female die cavity 26, the left end of the male die 206 penetrates through the supporting hole 203 and then is in sliding connection with the material taking hole 202, the male die 206 is in sliding connection with the balls 204, during work, the pushing plate 24 is pushed by the electric telescopic rod 23 to drive the raw material plate 25 to move rightwards, after the electric telescopic rod 23 pushes rightwards to the maximum length, the hydraulic cylinder 205 is started, the hydraulic cylinder 205 pushes the male die 206 to move leftwards, the balls 204 are used for reducing the friction force when the male die 206 moves, the hydraulic cylinder 205 pushes the male die 206 to enter the female die cavity 26 to manufacture the raw material plate 25 into an aluminum shell through stamping, the inner surface of the aluminum shell is formed through the male die 206 in the forming process, the outer surface of the aluminum shell is formed through the female die cavity 26, after the aluminum shell is formed, the hydraulic cylinder 205 drives the male die 206 to move rightwards, the male die 206 drives the formed aluminum shell to be taken out of the female die cavity 26, the male die 206 drives the aluminum shell to move to the left end face of the material taking plate 29, the male die 206 continues to move rightwards, the aluminum shell is separated from the male die 206 under the limiting effect of the material taking plate 29 and drops downwards, and the problem that the aluminum shell is difficult to take down from the male die 206 manually is solved.

Referring to fig. 6 and 7, the push plate 24 is composed of a left circular plate and a right circular plate, the right circular plate of the push plate 24 is provided with suction holes 240, the suction holes 240 are annularly arranged, the right end surface of the left circular plate of the push plate 24 is provided with an air groove 241 communicated with the suction holes 240, the air groove 241 is provided with an air inlet 24a, the left end surface of the inner wall of the circular hole 22 is provided with an air supply hole 243, the air supply hole 243 is connected with the air inlet 24a through an extension tube 242, the left end surface of the rectangular table 21 is provided with an air pump 244 through a base, an air outlet of the air pump 244 is communicated with the air supply hole 243 through a connecting tube, when the raw material plate 25 enters the circular hole 22, the air pump 244 starts to pump air, the air pump 244 adsorbs the raw material plate 25 on the push plate 24 through the connecting tube, the air supply hole 243, the extension tube 242, the air groove 241 and the suction hole 240, thereby preventing the situation that the upper end of the raw material plate 25 is turned right when the push plate 24 pushes the raw material plate 25 rightwards, after the raw material plate 25 is punched and formed into the aluminum shell, the male die 206 drives the aluminum shell to move rightwards, the air pump 244 starts to blow air, and the air pushes the aluminum shell to move rightwards through the connecting pipe, the air supply hole 243, the telescopic pipe 242, the air groove 241 and the suction hole 240, so that the situation that the aluminum shell is clamped in the cavity 26 after being formed and cannot be taken out is avoided, and meanwhile, the taking-out efficiency of the aluminum shell is improved.

Referring to fig. 2, 5, 6, 7 and 8, the discharging mechanism 3 includes a discharging box 30, a discharging channel 31, a pushing spring 32, a pressing plate 33, a sliding ball 34, a door panel 35 and a v-shaped handle 36, the upper end surface of the rectangular platform 21 is provided with a material placing box 30, the material placing box 30 is of a rectangular box-shaped structure with an upward opening, the lower end surface of the inner wall of the material placing box 30 is provided with a material discharging through groove 31, the material discharging through groove 31 is of a rectangular structure, the material discharging through groove 31 is arranged at the circle center position of the circular hole 22, the front end face and the rear end face of the blanking through groove 31 are tangent to the circular hole 22, the blanking through groove 31 is positioned above the push plate 24, the left end face of the inner wall of the discharging box 30 is provided with an extrusion plate 33 through a push spring 32, the lower end face of the extrusion plate 33 is rotatably provided with sliding beads 34 at equal intervals from front to back, the upper end face of the discharging box 30 close to the left end is hinged with a door plate 35, and the door plate 35 is provided with a v-21274or a shape handle 36.

When the feeding box is in operation, when the cavity 26 is formed between the push plate 24 and the circular hole 22, the electric telescopic rod 23 is in the maximum extension state, the door plate 35 on the feeding box 30 is opened through the shape handle 36, the push spring 32 is extruded and contracted through the extrusion plate 33, then the raw material plate 25 is placed between the extrusion plate 33 and the right end face of the feeding box 30, the raw material plate 25 above the feeding through groove 31 enters the feeding through groove 31 under the action of self gravity, and the upper end of the raw material plate 25 on the left side is blocked, so that the raw material plate 25 on the left side stops moving rightwards, then the upper end of the feeding box 30 is sealed through the door plate 35, thereby avoiding the problem that dust or impurities fall into the feeding box 30, and then the push plate 24 is driven to move leftwards through the electric telescopic rod 23, when the right end face of the push plate 24 moves to the right end face of the inner wall of the feeding through groove 31, lower extreme and circular port 22 intercommunication that the unloading led to groove 31, at this moment, the interior raw material plate 25 of unloading logical groove 31 drops downwards, get into circular port 22, and simultaneously, stripper plate 33 promotes next raw material plate 25 and falls into unloading logical groove 31 under the effect that promotes spring 32, two upper and lower raw material plates 25 offset tightly, at this moment, the raw material plate 25 that is located circular port 22 is vertical placing, when pneumatic cylinder 205 drives fashioned aluminum hull through terrace die 206 and moves right, electric telescopic handle 23 shrink drives slurcam 24 and moves left, make next raw material plate 25 get into circular port 22, carry out the stamping forming of next aluminum hull, avoided putting into the unsafe situation in position behind the die cavity 26 through the manual work with raw material plate 25, the efficiency of aluminum hull forming and processing has been improved simultaneously.

Referring to fig. 7, the blanking through groove 31 on the rectangular table 21 has mounting grooves on the inner walls of the left and right sides, and rubber gaskets 210 are mounted in the mounting grooves and used for increasing the friction force of the raw material plate 25 in the falling process, so that the falling speed of the raw material plate 25 is reduced, and the problem of deformation caused by the large falling impact force of the raw material plate 25 is avoided.

Referring to fig. 4, arc-shaped limiting plates 301 are respectively installed on the front end surface and the rear end surface of the inner wall of the discharging box 30, the arc-shaped limiting plates 301 are located on the front side and the rear side of the extrusion plate 33, the arc-shaped limiting plates 301 support the raw material plates 25 in the discharging box 30, and the situation that the placing positions of the raw material plates 25 are inaccurate is avoided.

Referring to fig. 1, a material guide plate 11 is installed on the upper end surface of the bottom plate 1 through a support pillar 10, the material guide plate 11 is located between the rectangular table 21 and the material taking plate 29, and the front end of the material guide plate 11 is inclined downward.

Referring to fig. 1, the sponge pad 110 is installed on the upper end surface of the material guiding plate 11, the material guiding plate 11 guides the aluminum shell falling off from the male die 206, and meanwhile, the sponge pad 110 is used for reducing the impact force when the aluminum shell falls, so that the deformation of the aluminum shell due to the large impact force is avoided.

With reference to fig. 1, a collecting box 13 is disposed on the upper end surface of the bottom plate 1, the collecting box 13 is located below the front side of the material guiding plate 11, and the collecting box 13 collects the formed aluminum shell.

In addition, the invention also provides a manufacturing and processing method of the capacitor aluminum shell, which comprises the following steps: s1, placing a raw material plate: through the v-21274, the door plate 35 on the material placing box 30 is opened by the shape handle 36, the pushing spring 32 is extruded and contracted by the extrusion plate 33, then the raw material plate 25 is placed between the extrusion plate 33 and the right end face of the material placing box 30, the raw material plate 25 above the discharging through groove 31 enters the discharging through groove 31 under the action of self gravity, and the upper end of the raw material plate 25 on the left side stops blocking the raw material plate 25 on the left side, so that the raw material plate 25 on the left side stops moving rightwards, and then the upper end of the material placing box 30 is closed by the door plate 35, thereby avoiding the problem that dust or impurities fall into the material placing box 30.

S2, adsorption and fixation: drive slurcam 24 through electric telescopic handle 23 and remove left, when the right-hand member face of slurcam 24 removes the inner wall right-hand member face that the unloading led to groove 31, the lower extreme and the circular port 22 intercommunication that the unloading led to the groove 31, at this moment, the former feed plate 25 that the unloading led to the inslot 31 drops downwards and gets into circular port 22, stripper plate 33 promotes next former feed plate 25 under the effect of propelling spring 32 and falls into unloading and leads to the groove 31 simultaneously, two former feed plate 25 about offset tightly, then air pump 244 begins to bleed, air pump 244 passes through the connecting pipe, air feed hole 243, flexible pipe 242, wind groove 241, inhale hole 240 and adsorb former feed plate 25 on slurcam 24.

S3, punch forming: the electric telescopic rod 23 pushes the push plate 24 to drive the raw material plate 25 to move rightwards, when the electric telescopic rod 23 pushes the raw material plate to the maximum rightwards, the hydraulic cylinder 205 is started, the hydraulic cylinder 205 pushes the punch 206 to move leftwards, the ball 204 is used for reducing the friction force when the punch 206 moves, the hydraulic cylinder 205 pushes the punch 206 to enter the die cavity 26 to manufacture the raw material plate 25 into an aluminum shell through stamping, the inner surface of the aluminum shell is formed through the punch 206 in the forming process, the outer surface of the aluminum shell is formed through the die cavity 26, after the aluminum shell is formed, the hydraulic cylinder 205 drives the punch 206 to move rightwards, the punch 206 drives the formed aluminum shell to move out of the die cavity 26, the punch 206 drives the aluminum shell to move to the left end face of the material taking plate 29, the punch 206 continues to move rightwards, and the aluminum shell is separated from the punch 206 and falls downwards under the limiting effect of the material taking plate 29.

S4, collecting the aluminum shell: the material guide plate 11 guides the aluminum shell taken down from the male die 206, and meanwhile, the spongy cushion 110 is used for reducing the impact force when the aluminum shell falls, so that the situation that the aluminum shell is deformed due to the large impact force generated when the aluminum shell falls is avoided, and the collection box 13 collects the formed aluminum shell.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.