CN115740244A - Stamping part processing die capable of being positioned in multiple directions and implementation method thereof - Google Patents

Abstract

A stamping part processing die capable of being positioned in multiple directions and an implementation method thereof belong to the technical field of stamping part processing die positioning, and aim to solve the problems that when a traditional stamping part processing die is used for stamping a strip material, the strip material can deviate, and a defective stamping part is easy to cause, and when the traditional stamping part processing die is used for positioning the strip material, the force formed by stamping can drive the strip material to move downwards, so that the positioning effect of a positioning structure on the strip material is damaged, and the positioning function is poor in flexibility; this application passes through banded material and transports in punching press inslot portion, drive through double-end motor, just pivot and reversal axle simultaneous antiport, the both sides of grasping banded material, two sets of relative extrusion mechanisms extrude banded material both sides, carry out multidirectional location to banded material, through the punching press of punching press subassembly and lower punching press subassembly cooperation completion impact piece, go up the punching press subassembly in the decline punching press, the linkage subassembly drives many places locating component and banded material and descends together.

Description

Stamping part processing die capable of being positioned in multiple directions and implementation method thereof

Technical Field

The invention relates to the technical field of stamping part processing die positioning, in particular to a stamping part processing die capable of realizing multidirectional positioning and an implementation method thereof.

Background

The stamping is a forming processing method for applying external force to plates, strips, pipes, profiles and the like by a press and a die to cause plastic deformation or separation, so as to obtain workpieces (stamping parts) with required shapes and sizes.

Traditional stamping workpiece mold processing is when transporting to the band material, because of being not convenient for through the inside splint that set up antiport at the mold processing, and set up the structure that plays the squeezing action and come multidirectional location band material, lead to in the punching press band material, the condition of band material skew can appear, easily lead to the condition that the defective products appears in the stamping workpiece, and traditional stamping workpiece mold processing is when fixing a position to the band material, the dynamics that the punching press formed can drive the band material and move down, and then the positioning effect of location structure to the band material has been destroyed, its locate function flexibility is relatively poor.

In order to solve the problems, a stamping part processing die capable of positioning in multiple directions and an implementation method thereof are provided.

Disclosure of Invention

The invention aims to provide a stamping part processing die capable of positioning in multiple directions and an implementation method thereof, and solves the problems that in the background art, when a strip is transported, a traditional stamping part processing die is inconvenient to position the strip in multiple directions by arranging a clamping plate rotating in the reverse direction in the processing die and arranging a structure with an extrusion effect, the strip can deviate when the strip is stamped, and the stamping part is prone to be defective, and when the strip is positioned, the force formed by stamping can drive the strip to move downwards, so that the positioning effect of the positioning structure on the strip is damaged, and the positioning function is poor in flexibility.

In order to achieve the purpose, the invention provides the following technical scheme: the stamping part processing die capable of being positioned in multiple directions comprises an upper stamping assembly and a lower stamping assembly arranged at the position right below the upper stamping assembly, wherein a strip-shaped material is arranged inside the lower stamping assembly, the lower stamping assembly comprises a U-shaped strip and a stamping groove formed inside the U-shaped strip, a fixing strip is arranged at the lower end of the U-shaped strip, a conveying rolling shaft is arranged at one end of the fixing strip, two groups of compression rollers are arranged at the other end of the fixing strip, one end of the strip-shaped material is positioned inside the two groups of compression rollers, the other end of the strip-shaped material is positioned at the upper end of the conveying rolling shaft, the strip-shaped material is conveyed inside the lower stamping assembly under the action of external mechanical tension, lifting grooves are formed in the connecting positions of the inner walls of two sides of the U-shaped strip and the upper end of the fixing strip, the lifting grooves are arranged in two groups, multiple positioning assemblies are movably arranged inside the two groups of lifting grooves, a linkage groove is formed in one side of the lifting groove, and two groups of linkage assemblies are arranged inside the linkage grooves;

the multi-direction positioning assembly comprises a double-end motor arranged inside a lifting groove, one end of the double-end motor is provided with an extrusion mechanism through a shaft connection, the extrusion mechanism is provided with two groups, the other end of the double-end motor is provided with a forward rotating shaft through a shaft connection, one end of the forward rotating shaft is provided with a first transmission barrel through a shaft connection, one end of the first transmission barrel is provided with a reverse rotating shaft through a shaft connection, one side of the first transmission barrel is provided with a first connection shaft, one end of the reverse rotating shaft is provided with a second transmission barrel through a shaft connection, one end of the second transmission barrel is provided with another group of extrusion mechanism through a shaft connection, a belt-shaped material is transported inside the lifting groove and driven by the double-end motor, the forward rotating shaft and the reverse rotating shaft rotate simultaneously in a reverse direction, the two opposite groups of extrusion mechanisms extrude the two sides of the belt-shaped material, the belt-shaped material is positioned in multiple directions, the punching of an impact piece is completed through the cooperation of an upper punching assembly and a lower punching assembly, and the linkage assembly drives the multi-direction positioning assembly and the belt-shaped material to descend together.

Furthermore, the inside of the U-shaped strip penetrates through the U-shaped strip to be provided with a plurality of through grooves, one side of each through groove is provided with a matching strip groove, the inside of the fixing strip penetrates through the U-shaped strip to be provided with a falling groove, the falling grooves are provided with a plurality of groups, and the falling groove positions of the groups are located under the corresponding through grooves of the groups.

Further, go up the stamping assembly and include hydraulic lifting block and set up the punching press post in hydraulic lifting block downside, and the punching press post sets up the multiunit, and the punching press post position of multiunit is in under the corresponding multiunit runs through the groove, and a set of punching press post one side is provided with the rack, and rack one end is connected with hydraulic lifting block downside, and the rack setting is directly over the cooperation strip groove.

Furthermore, an L-shaped clamping plate is arranged on the outer side of the forward rotating shaft, the L-shaped clamping plate is not in contact with the outer side of the reverse rotating shaft, clamping rollers are movably arranged in the L-shaped clamping plate and are arranged in multiple groups, an L-shaped clamping plate and a clamping roller are also arranged on the outer side of the reverse rotating shaft, and the second transmission cylinder and the first transmission cylinder are members made of the same structure.

Furthermore, the first transmission drum comprises a first conical gear connected with the positive rotation shaft through a shaft, a second conical gear is arranged on one side of the first conical gear in a meshed mode, one side of the second conical gear is connected with the first connecting shaft, a third conical gear is arranged on one side of the second conical gear in a meshed mode, and one side of the third conical gear is connected with the negative rotation shaft through a shaft.

Further, extrusion mechanism includes fixed shell and the second connecting axle of setting in fixed shell one side, and fixed shell side is provided with the jogged column, and the inside gomphosis of fixed shell is provided with the meshing post, and the inside spring guide pillar that is provided with of meshing post one end, spring guide pillar one end are provided with the bar post, and bar post one end is provided with the extrusion strip, and the inside activity of extrusion strip is provided with the extrusion loose axle, and the extrusion loose axle sets up the multiunit.

Furthermore, a driving wheel is movably arranged in the fixed shell, the lower end of the driving wheel is meshed with the meshing column, and the jogged column is jogged in the lower punching component.

Furthermore, the linkage assembly comprises a fixed motor fixedly arranged inside the U-shaped strip, rotating wheels are arranged at two ends of the fixed motor through shaft connection, the rotating wheels are provided with four groups, linkage plates are embedded inside the linkage grooves, tooth sockets are formed in one sides of the linkage plates, the tooth sockets are provided with four groups, the tooth sockets of the four groups are meshed with the rotating wheels of the four groups, and the linkage plates are fixedly connected with the first connecting shaft and the second connecting shaft.

Further, the inside activity of cooperation strip inslot is provided with the semi-gear, and the outside that the semi-gear has the tooth and rack phase-match, and the non-tooth outside of semi-gear is provided with the arc head post, and cooperation strip inslot wall is provided with the electrical property button, and electrical property button and fixed motor electric connection.

The invention provides another technical scheme that: the implementation method for providing the stamping part processing die capable of being positioned in multiple directions comprises the following steps:

s1: when the strip-shaped material is in the lower stamping assembly and needs to be stamped, the distance between the two groups of L-shaped clamping plates on the outer sides of the forward rotating shaft and the reverse rotating shaft is gradually reduced until the upper side and the lower side of the strip-shaped material are clamped, the movable extrusion shafts always extrude the side edges of the strip-shaped material, and the two groups of multi-directional positioning assemblies are oppositely arranged, so that the strip-shaped material is positioned in multiple directions;

s2: after the strip-shaped material is positioned, the hydraulic lifting block and the punching column are driven to descend through external hydraulic pressure, the positioned strip-shaped material descends simultaneously while the punching column descends for punching until the strip-shaped material descends to the position of the falling groove, and the punching column punches the strip-shaped material;

s3: after the punching is finished, the punching column rises, so that the linkage plate drives the multi-directional positioning assembly and the strip-shaped material to rise, and the strip-shaped material is still in a horizontal position transportation state, so that all implementation steps are completed.

Compared with the prior art, the invention has the following beneficial effects:

1. the invention provides a stamping part processing die capable of being positioned in multiple directions and an implementation method thereof.

2. According to the stamping part processing die capable of being positioned in multiple directions and the implementation method thereof, the stamping column descends to stamp the strip-shaped material at the same time, the positioned strip-shaped material descends at the same time until the stamping column descends to the position of the falling groove, and the stamping column stamps the strip-shaped material, so that the positioning effect of the positioning structure on the strip-shaped material is still kept while stamping is realized, after stamping is finished, the stamping column ascends, the linkage plate drives the multiple positioning assemblies and the strip-shaped material to ascend, the strip-shaped material is still in a horizontal position transportation state, and the problems that when the strip-shaped material is positioned by the traditional stamping part processing die, the strip-shaped material is driven to move downwards by the force formed by stamping, the positioning effect of the positioning structure on the strip-shaped material is damaged, and the positioning function is poor in flexibility are solved.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the upper punch assembly of the present invention;

FIG. 3 is a schematic perspective view of a lower punch assembly according to the present invention;

FIG. 4 is a schematic plan view of a lower punch assembly of the present invention;

FIG. 5 is a schematic view of a multi-directional positioning assembly according to the present invention;

FIG. 6 is a schematic structural view of a second transmission cylinder according to the present invention;

FIG. 7 is a schematic view of the pressing mechanism of the present invention;

FIG. 8 is a schematic plan view of a driving wheel according to the present invention;

fig. 9 is an enlarged schematic view of a portion a in fig. 4 according to the present invention.

In the figure: 1. an upper punch assembly; 11. a hydraulic lifting block; 12. punching the column; 13. a rack; 2. a lower punch assembly; 21. u-shaped strips; 211. a through groove; 212. matching the strip groove; 2121. a half gear; 2122. an arc head column; 2123. an electrical button; 22. a fixing strip; 221. a dropping groove is formed; 23. punching a groove; 24. a transport roller; 25. a compression roller; 26. a lifting groove; 27. a multi-directional positioning assembly; 271. a double-headed motor; 2711. an L-shaped splint; 2712. clamping the roller; 272. a forward rotation shaft; 273. a reverse rotation shaft; 274. a first transmission drum; 2741. a first conical gear; 2742. a second conical gear; 2743. a third bevel gear; 275. a first connecting shaft; 276. an extrusion mechanism; 27611. a driving wheel; 2761. fixing the housing; 2762. a second connecting shaft; 2763. an embedded column; 2764. an engagement post; 2765. a bar-shaped column; 2766. a spring guide post; 2767. extruding the strip; 2768. extruding the movable shaft; 277. a second transmission cylinder; 28. a linkage groove; 29. a linkage assembly; 291. a linkage plate; 292. a tooth socket; 293. fixing the motor; 294. a rotating wheel; 3. a strip of material.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In order to solve the technical problems that when a strip is transported by a traditional stamping part processing die, the strip is not convenient to position in multiple directions by arranging a clamping plate rotating in the reverse direction in the processing die and arranging a structure with an extrusion function, so that the strip can deviate when the strip is stamped, and defective products can easily occur on a stamping part, as shown in fig. 1 to 8, the following preferred technical scheme is provided:

a stamping part processing die capable of being positioned in multiple directions comprises an upper stamping component 1 and a lower stamping component 2 arranged at the position right below the upper stamping component 1, wherein a strip-shaped material 3 is arranged inside the lower stamping component 2, the lower stamping component 2 comprises a U-shaped strip 21 and a stamping groove 23 arranged inside the U-shaped strip 21, a fixing strip 22 is arranged at the lower end of the U-shaped strip 21, a conveying roller 24 is arranged at one end of the fixing strip 22, a pressing roller 25 is arranged at the other end of the fixing strip, two groups of pressing rollers 25 are arranged, one end of the strip-shaped material 3 is arranged inside the two groups of pressing rollers 25, the other end of the strip-shaped material 3 is arranged at the upper end of the conveying roller 24, the strip-shaped material 3 is conveyed inside the lower stamping component 2 under the action of external mechanical tension, lifting grooves 26 are formed in the connecting positions of the inner walls at the two sides of the U-shaped strip 21 and the upper end of the fixing strip 22, the lifting grooves 26 are arranged in two groups, a multi-direction positioning component 27 is movably arranged inside the two groups of lifting grooves 26, a linkage groove 28 is formed in one side of the lifting groove 26, two groups of linkage grooves 28 are arranged, linkage assemblies 29 are arranged in the two groups of linkage grooves 28, the multi-directional positioning assembly 27 comprises a double-head motor 271 arranged in a lifting groove 26, one end of the double-head motor 271 is provided with an extrusion mechanism 276 through a shaft connection, two groups of extrusion mechanisms 276 are arranged, the other end of the double-head motor 271 is provided with a forward rotating shaft 272 through a shaft connection, one end of the forward rotating shaft 272 is provided with a first transmission cylinder 274 through a shaft connection, one end of the first transmission cylinder 274 is provided with a reverse rotating shaft 273 through a shaft connection, one end of the reverse rotating shaft 273 is provided with a second transmission cylinder 277 through a shaft connection, one end of the second transmission cylinder 277 is provided with another group of extrusion mechanisms 276 through a shaft connection, the belt-shaped materials 3 are transported in the punching groove 23, the forward rotating shaft 272 and the reverse rotating shaft 273 are driven by the double-head motor 271 to rotate in opposite directions simultaneously, the two sides of a strip-shaped material 3 are clamped, two sets of opposite extrusion mechanisms 276 extrude the two sides of the strip-shaped material 3, the strip-shaped material 3 is positioned in multiple directions, the stamping of an impact piece is completed through the cooperation of the upper stamping assembly 1 and the lower stamping assembly 2, the upper stamping assembly 1 is used for descending and stamping, the linkage assembly 29 drives the multiple-direction positioning assembly 27 and the strip-shaped material 3 to descend together, the through grooves 211 are formed in the U-shaped strip 21 in a penetrating mode, multiple sets of through grooves 211 are formed in the through grooves 211, one side of one set of through grooves 211 is provided with a matching strip groove 212, the fixing strip 22 is used for penetrating through the inside and is provided with a falling groove 221, the falling grooves 221 are provided with multiple sets, the positions of the multiple sets of the falling grooves 221 are located under the corresponding multiple sets of through grooves 211, the upper stamping assembly 1 comprises a hydraulic lifting block 11 and stamping columns 12 arranged on the lower side of the hydraulic lifting block 11, the stamping columns 12 are provided with multiple sets, racks 13 are located under the corresponding multiple sets of the corresponding sets of through grooves 211, one side of the stamping columns 12, one set above the hydraulic lifting block 11, and the racks 13 are arranged above the matching strip grooves 212.

The outer side of the rotating shaft 272 is provided with an L-shaped clamping plate 2711, the L-shaped clamping plate 2711 is not in contact with the outer side of the inversion shaft 273, the inner part of the L-shaped clamping plate 2711 is movably provided with a clamping roller 2712, the clamping roller 2712 is provided with a plurality of groups, the outer side of the inversion shaft 273 is also provided with the L-shaped clamping plate 2711 and the clamping roller 2712, the second transmission cylinder 277 and the first transmission cylinder 274 are members made of the same structure, the first transmission cylinder 274 comprises a first conical gear 2741 connected with the rotating shaft 272 through a shaft, one side of the first conical gear 2741 is meshed with a second conical gear 2742, one side of the second conical gear 2742 is connected with a first connecting shaft 275, one side of the second conical gear 2742 is meshed with a third conical gear 2743, one side of the third conical gear 2743 is connected with the inversion shaft 273 through a shaft, the extrusion mechanism 276 comprises a fixed shell 2761 and a second connecting shaft 2762 arranged on one side of the fixed shell 2761, the side of the fixed shell 2761 and one end of the movable bar 2764 arranged on the fixed shell 2767, one end of the movable bar 2766 is provided with a plurality of the bar 2765, one end of the bar 2765 is provided with a plurality of movable bar 2765, and a bar 2764 is arranged on the bar 2767, and a bar 2765 bar 2767 is arranged on the bar 2767, and a movable bar 2765 arranged on the bar 2767, and a plurality of the bar 2765 is arranged on the bar 2767, and a movable bar 2767, and a bar 2765 are arranged on the bar 2767, and a bar 2765.

Specifically, when the strip-shaped material 3 is inside the lower punching component 2 and needs to be punched, the double-head motor 271 is firstly used for driving the forward rotating shaft 272 to rotate, at this time, the L-shaped clamping plates 2711 rotate upwards, the rotation of the forward rotating shaft 272 drives the first conical gear 2741, the second conical gear 2742 and the third conical gear 2743 to rotate, and the third conical gear 2743 drives the reverse rotating shaft 273 to rotate, namely, the L-shaped clamping plates 2711 arranged on the outer side of the reverse rotating shaft 273 rotate downwards, namely, the distance between the two groups of L-shaped clamping plates 2711 on the outer sides of the forward rotating shaft 272 and the reverse rotating shaft 273 is gradually reduced until the upper side and the lower side of the strip-shaped material 3 are clamped, the arrangement of the plurality of groups of clamping rollers 2712 does not influence the transportation of the strip-shaped material 3, and when the forward rotating shaft 272 and the reverse rotating shaft 273 rotate, the fixed housing 2761 can be driven to rotate, namely, the engaging column 2764 can be pushed to move to the position of the belt-shaped material 3, when the two sets of L-shaped clamping plates 2711 do not clamp the upper and lower sides of the belt-shaped material 3, the extrusion movable shaft 2768 is in contact with the side surface of the belt-shaped material 3, when the distance between the two sets of L-shaped clamping plates 2711 gradually decreases, due to the arrangement of the spring guide post 2766, the extrusion movable shaft 2768 is always in contact with the side surface of the belt-shaped material 3 until the last two sets of L-shaped clamping plates 2711 clamp the belt-shaped material 3, the extrusion movable shaft 2768 always extrudes the side edge of the belt-shaped material 3, because of the two sets of multi-direction positioning components 27 are arranged oppositely, namely, the belt-direction positioning of the belt-shaped material 3 is realized, the transportation of the belt-shaped material 3 after being positioned is in the stamping fixed position, and the deviation can not occur during the transportation.

In order to solve the technical problems that when a strip material is positioned by a traditional stamping part processing die, the force formed by stamping can drive the strip material to move downwards, so that the positioning effect of a positioning structure on the strip material is damaged, and the flexibility of the positioning function is poor, as shown in fig. 5 and 9, the following preferred technical scheme is provided:

the linkage assembly 29 comprises a fixed motor 293 fixedly arranged inside the U-shaped strip 21, two ends of the fixed motor 293 are provided with rotating wheels 294 through shaft connection, the rotating wheels 294 are provided with four groups, a linkage plate 291 is embedded inside the linkage groove 28, one side of the linkage plate 291 is provided with tooth grooves 292, the tooth grooves 292 are provided with four groups, the tooth grooves 292 of the four groups are meshed with the rotating wheels 294 of the four groups, the linkage plate 291 is fixedly connected with a first connecting shaft 275 and a second connecting shaft 2762, a half gear 2121 is movably arranged inside the matching strip groove 212, the toothed outer side of the half gear 2121 is matched with the rack 13, the toothless outer side of the half gear 2121 is provided with an arc head column 2122, the inner wall of the matching strip groove 212 is provided with an electric button 2123, and the electric button 2123 is electrically connected with the fixed motor 293.

Specifically, after the belt-shaped material 3 is positioned, the hydraulic lifting block 11 and the punching column 12 are driven to descend by external hydraulic pressure until the punching column 12 punches the belt-shaped material 3 through the corresponding through groove 211, and at the same time, the rack 13 descends along with the punching column 12 and is embedded inside the matching strip groove 212, the rack 13 and the half gear 2121 can be meshed, the descending of the rack 13 can drive the half gear 2121 and the arc column 2122 to rotate in the forward direction, when the arc column 2122 contacts with the electric button 2123, the fixed motor 293 is driven by an electric signal to enable a plurality of groups 294 to rotate, at the moment, the linkage plate 291 drives the multi-direction positioning assembly 27 to descend, namely, the belt-shaped material 3 is driven to descend integrally, the positioned belt-shaped material 3 descends simultaneously when the punching column 12 descends and punches, until the positioned belt-shaped material 3 descends to the lower falling groove 221, the punching column 12 punches the belt-shaped material 3, that while punching is realized, the positioning structure still maintains the positioning effect on the belt-shaped material 3 after punching is completed, the punching column 12, the raised convex gear 13 and the rack 13 drive the arc column 2122 to drive the multi-direction positioning assembly to rotate, so that the belt-shaped material 27 and the belt-shaped material is in the reverse direction, and the linkage plate 291 and the linkage plate 27 is prevented from being in the state that the belt-shaped material is in the state that the belt-shaped linkage assembly is still transported when the belt-shaped material is transported in the conveying mechanism 291 and the belt-shaped linkage assembly.

In order to further better explain the above examples, the present invention also provides an implementation method of the stamping part processing die capable of being oriented in multiple directions, which comprises the following steps:

the method comprises the following steps: when the belt-shaped material 3 is in the lower punching component 2 and needs to be punched, the distance between the two groups of L-shaped clamping plates 2711 on the outer sides of the forward rotating shaft 272 and the reverse rotating shaft 273 is gradually reduced until the upper side and the lower side of the belt-shaped material 3 are clamped, the extrusion movable shaft 2768 always extrudes the side edge of the belt-shaped material 3, and the two groups of multi-direction positioning components 27 are arranged oppositely, namely the belt-shaped material 3 is positioned in multiple directions;

step two: after the strip-shaped material 3 is positioned, the hydraulic lifting block 11 and the punching column 12 are driven to descend through external hydraulic pressure, the positioned strip-shaped material 3 descends simultaneously while the punching column 12 descends for punching until the strip-shaped material 3 descends to the position of the falling groove 221, and the punching column 12 punches the strip-shaped material 3;

step three: after the stamping is completed, the stamping column 12 is lifted, so that the linkage plate 291 drives the multi-directional positioning assembly 27 and the strip-shaped material 3 to rise, and the strip-shaped material 3 is still in a horizontal position for transportation, so that all implementation steps are completed.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. Stamping workpiece mold processing that can multidirectionally fix a position, including last stamping component (1) and setting stamping component (2) down under last stamping component (1) position, stamping component (2) inside is provided with banded material (3) down, its characterized in that: the lower punching assembly (2) comprises a U-shaped strip (21) and punching grooves (23) formed in the U-shaped strip (21), a fixing strip (22) is arranged at the lower end of the U-shaped strip (21), a conveying roller (24) is arranged at one end of the fixing strip (22), a pressing roller (25) is arranged at the other end of the fixing strip, two groups of pressing rollers (25) are arranged, one end of a strip-shaped material (3) is located in the two groups of pressing rollers (25), the other end of the strip-shaped material is located at the upper end of the conveying roller (24), the strip-shaped material (3) is conveyed in the lower punching assembly (2) under the action of external mechanical tension, lifting grooves (26) are formed in the connecting positions of the inner walls of two sides of the U-shaped strip (21) and the upper ends of the fixing strips (22), two groups of lifting grooves (26) are formed, a multi-side positioning assembly (27) is movably arranged in the two groups of lifting grooves (26), a linkage groove (28) is formed in one side of the lifting groove (26), two groups of linkage grooves (28) are formed, and linkage assemblies (29) are arranged in the two groups of linkage grooves (28);

the multi-direction positioning assembly (27) comprises a double-end motor (271) arranged in the lifting groove (26), one end of the double-end motor (271) is connected with an extrusion mechanism (276) through a shaft, and the extrusion mechanisms (276) are arranged in two groups.

2. A multidirectional positionable stamping die as in claim 1 wherein: the punching press is characterized in that through grooves (211) penetrate through the U-shaped strip (21), a plurality of groups of through grooves (211) are formed in the U-shaped strip (21), a matching strip groove (212) is formed in one side of one group of through grooves (211), a falling groove (221) penetrates through the inside of a fixed strip (22), a plurality of groups of falling grooves (221) are formed in the falling groove(s), the falling grooves (221) are located under the corresponding groups of through grooves (211), a positive rotating shaft (272) is arranged at the other end of a double-head motor (271) through a shaft connection, a first transmission cylinder (274) is arranged at one end of the positive rotating shaft (272) through a shaft connection, a reverse rotating shaft (273) is arranged at one end of the first transmission cylinder (274) through a shaft connection, a second transmission cylinder (276) is arranged at one end of the second transmission cylinder (277) through a shaft connection, another group of extruding mechanisms (273) are arranged at one end of the second transmission cylinder (277) through a shaft connection, the belt-shaped material (3) is transported to the inside the punching groove (23), the double-head motor (274) is driven, the positive rotating shaft (272) and the second transmission cylinder (271) and the reverse rotating simultaneously, the pressing mechanism (276) clamps the belt-shaped material (3), two groups of the pressing press the pressing assembly (3) to press the punching press the two sides of the pressing assembly (3) and punch press the multiple parts (3) to complete the punching press the multiple parts (2), when the upper stamping assembly (1) descends and stamps, the linkage assembly (29) drives the multi-direction positioning assembly (27) and the strip-shaped material (3) to descend together.

3. A multidirectional positionable stamping die as in claim 2 wherein: go up punching press subassembly (1) including hydraulic pressure elevator (11) and set up punching press post (12) in hydraulic pressure elevator (11) downside, and punching press post (12) set up the multiunit, multiunit punching press post (12) position is in under corresponding multiunit runs through groove (211), a set of punching press post (12) one side is provided with rack (13), and rack (13) one end is connected with hydraulic pressure elevator (11) downside, rack (13) set up directly over cooperation strip groove (212).

4. A multidirectional positionable stamping die as in claim 1 wherein: the outer side of the forward rotating shaft (272) is provided with an L-shaped clamping plate (2711), the L-shaped clamping plate (2711) is not in contact with the outer side of the reverse rotating shaft (273), the inner part of the L-shaped clamping plate (2711) is movably provided with a clamping roller (2712), the clamping roller (2712) is provided with a plurality of groups, the outer side of the reverse rotating shaft (273) is also provided with the L-shaped clamping plate (2711) and the clamping roller (2712), and the second transmission cylinder (277) and the first transmission cylinder (274) are members made of the same structure.

5. A multidirectional positionable stamping forming die according to claim 1 and further including: first transmission section of thick bamboo (274) include with positive pivot (272) through the first conical gear (2741) of axle coupling, first conical gear (2741) one side meshing is provided with second conical gear (2742), and second conical gear (2742) one side is connected with first connecting axle (275), second conical gear (2742) one side meshing is provided with third conical gear (2743), third conical gear (2743) one side is connected with reversal shaft (273) through the axle.

6. A multidirectional positionable stamping workpiece processing die as in claim 5, wherein: the extrusion mechanism (276) comprises a fixed shell (2761) and a second connecting shaft (2762) arranged on one side of the fixed shell (2761), an embedded column (2763) is arranged on the side face of the fixed shell (2761), an engaged column (2764) is embedded in the fixed shell (2761), a spring guide column (2766) is arranged in one end of the engaged column (2764), a strip-shaped column (2765) is arranged at one end of the spring guide column (2766), an extrusion strip (2767) is arranged at one end of the strip-shaped column (2765), an extrusion movable shaft (2768) is movably arranged in the extrusion strip (2767), and multiple groups of extrusion movable shafts (2768) are arranged.

7. A multidirectional positionable stamping workpiece processing die as in claim 6, wherein: a driving wheel (27611) is movably arranged in the fixed shell (2761), the lower end of the driving wheel (27611) is meshed with a meshing column (2764), and the embedded column (2763) is embedded in the lower punching component (2).

8. A multidirectional positionable stamping die as in claim 2 wherein: the linkage assembly (29) comprises a fixed motor (293) fixedly arranged in the U-shaped strip (21), rotating wheels (294) are arranged at two ends of the fixed motor (293) through shaft connection, four groups of rotating wheels (294) are arranged, a linkage plate (291) is embedded in the linkage groove (28), a tooth groove (292) is formed in one side of the linkage plate (291), the tooth grooves (292) are arranged in the four groups, the tooth grooves (292) in the four groups are meshed with the rotating wheels (294) in the four groups, and the linkage plate (291) is fixedly connected with a first connecting shaft (275) and a second connecting shaft (2762).

9. A multidirectional positionable stamping part processing die as defined in claim 8, wherein: a half gear (2121) is movably arranged in the matching strip groove (212), the toothed outer side of the half gear (2121) is matched with the rack (13), the non-toothed outer side of the half gear (2121) is provided with an arc head column (2122), the inner wall of the matching strip groove (212) is provided with an electric button (2123), and the electric button (2123) is electrically connected with the fixed motor (293).

10. A method for implementing a multidirectional positionable stamping forming tool according to any of claims 1 to 9, wherein: the method comprises the following steps:

s1: when the strip-shaped material (3) is in the lower stamping component (2) and needs to be stamped, the distance between two groups of L-shaped clamping plates (2711) on the outer sides of the forward rotating shaft (272) and the reverse rotating shaft (273) is gradually reduced until the upper side and the lower side of the strip-shaped material (3) are clamped, the extrusion movable shaft (2768) always extrudes the side edge of the strip-shaped material (3), and the two groups of multi-direction positioning components (27) are oppositely arranged, namely the strip-shaped material (3) is positioned in multiple directions;

s2: after the strip-shaped material (3) is positioned, the hydraulic lifting block (11) and the stamping column (12) are driven to descend through external hydraulic pressure, the positioned strip-shaped material (3) descends simultaneously when the stamping column (12) descends for stamping until the strip-shaped material descends to the position of the falling groove (221), and the stamping column (12) stamps the strip-shaped material (3);

s3: after the punching is finished, the punching column (12) ascends, so that the linkage plate (291) drives the multi-direction positioning assembly (27) and the strip-shaped material (3) to ascend, and the strip-shaped material (3) is still in a horizontal position for transportation, and all implementation steps are finished.

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