CN112974605A - Reciprocating type stamping device - Google Patents

Abstract

The invention discloses a reciprocating type stamping device which comprises a main hollow shell, wherein a sealed main moving space is arranged at the top end inside the main hollow shell, an object placing groove is formed in one side of the main moving space, a main first moving hole is formed in the bottom of the main moving space, a main second moving hole is formed in the bottom of the main first moving hole, and a main third moving hole communicated with the bottom surface of the main hollow shell is formed in the bottom of the main second moving hole. When the telescopic control mechanism is separated from the stamping part, the radial thrust force necessary for separation is controlled by the gentle slope, so that the change mode of the radial force is slow and movable, the telescopic control mechanism and the movable valve block can be separated more easily and quickly, the relative movement of the two parts in the separation process can not be influenced, and the abrasion to the parts and the consumption to energy in the separation process are reduced.

Description

Reciprocating type stamping device

Technical Field

The invention relates to the technical field of punching devices, in particular to a reciprocating type punching device.

Background

At present, when the existing reciprocating type punching device carries out reciprocating motion, when the reciprocating type punching device is separated from a punching control part, due to the separation mode, the larger radial force needs to be overcome during separation, and the energy consumption on the separation part is larger.

Disclosure of Invention

The present invention is directed to a reciprocating press apparatus to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme: a reciprocating stamping device comprises a main hollow shell, wherein a sealed main moving space is arranged at the top end inside the main hollow shell, an object placing groove is formed in one side of the main moving space, a main first moving hole is formed in the bottom of the main moving space, a main second moving hole is formed in the bottom of the main first moving hole, a main third moving hole communicated with the bottom surface of the main hollow shell is formed in the bottom of the main second moving hole, a downward gentle slope inclined plane is formed in one side of the bottom surface of the main hollow shell, a compressed main spiral spring is arranged inside the main moving space, a moving valve block is arranged at one end of the main spiral spring, a main groove structure is arranged at the center of the bottom of the moving valve block, an impact head structure is arranged on one side of the moving valve block, and a telescopic control mechanism is arranged at the longitudinal position of the main groove structure, the main first moving hole, the main second moving hole and the main third moving hole, the telescopic control mechanism is sleeved inside a spiral spring type power driving mechanism in a structure positioned inside the main second moving hole, and the telescopic control mechanism positioned on the bottom surface of the main hollow shell is installed inside an inclined buffer type butt joint mechanism.

Further, the telescopic control mechanism comprises a valve block for the telescopic control mechanism, an inclined plane for the telescopic control mechanism, a limit column for the telescopic control mechanism, a rod body for the telescopic control mechanism, an annular mounting groove for the telescopic control mechanism and a limit plate for the telescopic control mechanism; one side of the valve block for the telescopic control mechanism is provided with a slope for the gentle slope type telescopic control mechanism, a telescopic control mechanism is provided with a limit column for the telescopic control mechanism at the bottom of the valve block for the telescopic control mechanism, the bottom of the limit column for the telescopic control mechanism is provided with a limiting plate for the telescopic control mechanism of an integrated structure, and the intersection of the limiting plate for the telescopic control mechanism and the rod body for the telescopic control mechanism is provided with an annular mounting groove for the telescopic control mechanism.

Furthermore, the telescopic control mechanism is located in the horizontal plane of the main first moving hole through the limiting column, and the rod body of the telescopic control mechanism is sleeved inside the spiral spring type power driving mechanism.

Furthermore, the limiting plate for the telescopic control mechanism is located at the bottom of the lower surface of the main hollow shell and is installed inside the oblique buffer type docking mechanism.

Further, the coil spring type power driving mechanism comprises a first plate for the coil spring type power driving mechanism, a second plate for the coil spring type power driving mechanism, a first mounting hole for the coil spring type power driving mechanism, a second sleeving hole for the coil spring type power driving mechanism, a coil spring for the coil spring type power driving mechanism, a spherical groove structure for the coil spring type power driving mechanism and a ball for the coil spring type power driving mechanism; the inner centers of the first plate and the second plate for the coil spring type power driving mechanism are respectively provided with a first mounting hole and a second splicing hole for the coil spring type power driving mechanism, a compressed coil spring type coil spring for the power driving mechanism is arranged between the top of the coil spring type power driving mechanism at the bottom of the first plate for the coil spring type power driving mechanism and the top of the second plate for the coil spring type power driving mechanism, the inner part of the edge of the upper surface of the first plate for the helical spring type power driving mechanism and the inner part of the edge of the lower surface of the second plate for the helical spring type power driving mechanism are respectively provided with a spherical groove structure for the helical spring type power driving mechanism, and a ball for the helical spring type power driving mechanism is arranged in the spherical groove structure for the helical spring type power driving mechanism.

Furthermore, the first plate for the coil spring type power driving mechanism and the second plate for the coil spring type power driving mechanism are both located inside the main second moving hole, and the balls for the coil spring type power driving mechanism are abutted to the upper surface and the lower surface of the main second moving hole.

Further, the coil spring type power driving mechanism is sleeved on the side surface of the annular mounting groove for the telescopic control mechanism through a first mounting hole, the coil spring type power driving mechanism and the annular mounting groove are fixedly connected, the coil spring type power driving mechanism is sleeved on the rod body of the rod body for the telescopic control mechanism through a second sleeving hole, and the coil spring type power driving mechanism and the rod body are in active sleeving connection.

Further, the slant buffer type docking mechanism comprises a valve block for the slant buffer type docking mechanism, a plate mounting groove for the slant buffer type docking mechanism, a top inclined plane for the slant buffer type docking mechanism, a bottom inclined plane for the slant buffer type docking mechanism, a hollow rod for the slant buffer type docking mechanism, a moving space for the slant buffer type docking mechanism, a moving plate for the slant buffer type docking mechanism, a spiral spring for the slant buffer type docking mechanism, a telescopic rod for the slant buffer type docking mechanism, and a connecting plate for the slant buffer type docking mechanism; a top inclined plane for the slant buffering type butt joint mechanism is arranged between the upper side face and the lower side face of the valve block for the slant buffering type butt joint mechanism, a plate mounting groove for the slant buffering type butt joint mechanism is arranged in the center of the upper surface of the valve block for the slant buffering type butt joint mechanism, a bottom inclined plane for the slant buffering type butt joint mechanism is arranged at the slant symmetrical position of the top inclined plane for the slant buffering type butt joint mechanism and the valve block for the slant buffering type butt joint mechanism, a moving space for the slant buffering type butt joint mechanism is arranged in the slant buffering type butt joint mechanism, a moving plate for the slant buffering type butt joint mechanism is arranged in the moving space for the slant buffering type butt joint mechanism, and a telescopic rod for the slant buffering type butt joint mechanism is arranged in the center of one end face of the moving plate for the slant buffering type butt joint mechanism, and the telescopic rod for the slant buffer type docking mechanism is provided with a connecting plate for the slant buffer type docking mechanism at one end positioned outside.

Furthermore, the inside of plate mounting groove for slant buffering formula docking mechanism installs the limiting plate for telescopic control mechanism.

Furthermore, the first mounting hole for the spiral spring type power driving mechanism is parallel to the plane of the gentle slope inclined plane, and the two are opposite.

Compared with the prior art, the invention has the beneficial effects that: when the telescopic control mechanism is separated from the stamping part, the radial thrust force necessary for separation is controlled by the gentle slope, so that the change mode of the radial force is slow and movable, the telescopic control mechanism and the movable valve block can be separated more easily and quickly, the relative movement of the two parts in the separation process can not be influenced, and the abrasion to the parts and the consumption to energy in the separation process are reduced.

Drawings

FIG. 1 is a schematic view of a reciprocating stamping apparatus according to the present invention;

FIG. 2 is a schematic structural diagram of a telescopic control mechanism of a reciprocating punching apparatus according to the present invention;

FIG. 3 is a schematic structural diagram of a coil spring type power driving mechanism in a reciprocating punching apparatus according to the present invention;

FIG. 4 is a schematic structural diagram of an oblique buffer docking mechanism in a reciprocating punching apparatus according to the present invention;

in the figure: 1, a main hollow housing, 2, a main moving space, 3, an object placing groove, 4, a main first moving hole, 5, a main second moving hole, 6, a main third moving hole, 7, a gentle slope inclined plane, 8, a moving valve block, 9, a main coil spring, 10, an impact head structure, 11, a main groove structure, 12, a telescopic control mechanism, 121, a valve block for a telescopic control mechanism, 122, an inclined plane for a telescopic control mechanism, 123, a limit post for a telescopic control mechanism, 124, a rod body for a telescopic control mechanism, 125, an annular mounting groove for a telescopic control mechanism, 126, a limit plate for a telescopic control mechanism, 14, a coil spring type power driving mechanism, 141, a first plate for a coil spring type power driving mechanism, 142, a second plate for a coil spring type power driving mechanism, 143, a first mounting hole for a coil spring type power driving mechanism, 144, a second socket hole for coil spring type power drive mechanism, 145, a coil spring for coil spring type power drive mechanism, 146, a spherical groove structure for coil spring type power drive mechanism, 147, a ball for coil spring type power drive mechanism, 15, a slant buffer type docking mechanism, 151, a valve block for slant buffer type docking mechanism, 152, a block mounting groove for slant buffer type docking mechanism, 153, a top slope for slant buffer type docking mechanism, 154, a bottom slope for slant buffer type docking mechanism, 155, a hollow rod for slant buffer type docking mechanism, 156, a moving space for slant buffer type docking mechanism, 157, a moving plate for slant buffer type docking mechanism, 158, a coil spring for slant buffer type docking mechanism, 159, a telescopic rod for slant buffer type docking mechanism, 1510, a connecting plate for slant buffer type docking mechanism.

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.

Referring to fig. 1, an embodiment of the present invention: including main hollow shell 1, the inside top of main hollow shell 1 is equipped with a sealed main removal space 2, one side of main removal space 2 is equipped with the object and places recess 3, 2 bottoms in main removal space are equipped with a main first removal hole 4, the bottom of main first removal hole 4 is equipped with main second removal hole 5, the bottom of main second removal hole 5 is equipped with the main third removal hole 6 of the main hollow shell 1 basal surface of intercommunication, basal surface one side of main hollow shell 1 is equipped with decurrent gentle slope inclined plane 7, the internally mounted main coil spring 9 of a compression of main removal space 2, a removal valve piece 8 is installed to one end of main coil spring 9, the bottom center of removal valve piece 8 is equipped with main groove structure 11, one side of removal valve piece 8 is equipped with strikes first structure 10, main groove structure 11, main first removal hole 4, A telescopic control mechanism 12 is arranged at the longitudinal position of the main second moving hole 5 and the main third moving hole 6, the telescopic control mechanism 12 is sleeved inside a coil spring type power driving mechanism 14 in a structure positioned inside the main second moving hole 5, and the telescopic control mechanism 12 positioned on the bottom surface of the main hollow shell 1 is arranged inside an oblique buffer type butt joint mechanism 15.

Referring to fig. 2, the telescopic control mechanism 12 includes a valve block 121 for the telescopic control mechanism, an inclined plane 122 for the telescopic control mechanism, a limit post 123 for the telescopic control mechanism, a rod body 124 for the telescopic control mechanism, an annular mounting groove 125 for the telescopic control mechanism, and a limit plate 126 for the telescopic control mechanism; a gentle slope type telescopic control mechanism inclined plane 122 is arranged on one side of the telescopic control mechanism valve block 121, a telescopic control mechanism limiting post 123 is installed at the bottom of the telescopic control mechanism valve block 121, a telescopic control mechanism limiting plate 126 of an integrated structure is arranged at the bottom of the telescopic control mechanism limiting post 123, and a telescopic control mechanism annular mounting groove 125 is formed at the intersection of the telescopic control mechanism limiting plate 126 and the telescopic control mechanism rod body 124; the limit column 123 for the telescopic control mechanism is positioned in the horizontal plane of the main first moving hole 4, and the rod body 124 for the telescopic control mechanism is sleeved inside the spiral spring type power driving mechanism 14; the limiting plate 126 for the telescopic control mechanism is located at the bottom of the lower surface of the main hollow shell 1 and is installed inside the oblique buffer type docking mechanism 15.

Referring to fig. 3, the coil spring type power driving mechanism 14 includes a first plate 141 for a coil spring type power driving mechanism, a second plate 142 for a coil spring type power driving mechanism, a first mounting hole 143 for a coil spring type power driving mechanism, a second socketing hole 144 for a coil spring type power driving mechanism, a coil spring 145 for a coil spring type power driving mechanism, a spherical groove structure 146 for a coil spring type power driving mechanism, and a ball 147 for a coil spring type power driving mechanism; the coil spring type first plate 141 and the coil spring type second plate 142 for the power driving mechanism are respectively provided at the inner center thereof with a coil spring type first mounting hole 143 and a coil spring type second mating hole 144 for the power driving mechanism, a coil spring 145 for a compression coil spring type power driving mechanism is installed between the top of the second plate 142 for a bottom coil spring type power driving mechanism of the first plate 141 for a coil spring type power driving mechanism, the inside of the upper surface edge of the first plate 141 for the coil spring type power driving mechanism and the inside of the lower surface edge of the second plate 142 for the coil spring type power driving mechanism are respectively provided with a spherical groove structure 146 for the coil spring type power driving mechanism, a ball 147 for the coil spring type power driving mechanism is arranged in the spherical groove structure 146 for the coil spring type power driving mechanism; the first plate 141 and the second plate 142 for the coil spring type power driving mechanism are both positioned in the main second moving hole 5, and the ball 147 for the coil spring type power driving mechanism is abutted against the upper surface and the lower surface of the main second moving hole 5; the first mounting hole 143 for the coil spring type power driving mechanism is sleeved on the side surface of the annular mounting groove 125 for the telescopic control mechanism, and the two are fixedly connected, and the second sleeving hole 144 for the coil spring type power driving mechanism is sleeved on the rod body of the rod body 124 for the telescopic control mechanism, and the two are actively sleeved.

Referring to fig. 4, the slant buffer type docking mechanism 15 includes a valve block 151 for slant buffer type docking mechanism, a block mounting groove 152 for slant buffer type docking mechanism, a top inclined surface 153 for slant buffer type docking mechanism, a bottom inclined surface 154 for slant buffer type docking mechanism, a hollow rod 155 for slant buffer type docking mechanism, a moving space 156 for slant buffer type docking mechanism, a moving plate 157 for slant buffer type docking mechanism, a spiral spring 158 for slant buffer type docking mechanism, a telescopic rod 159 for slant buffer type docking mechanism, and a connecting plate 1510 for slant buffer type docking mechanism; a top inclined plane 153 for the slant buffer type butt joint mechanism is arranged between the upper side surface and the lower side surface of the valve block 151 for the slant buffer type butt joint mechanism, a block mounting groove 152 for the slant buffer type butt joint mechanism is arranged at the center of the upper surface of the valve block 151 for the slant buffer type butt joint mechanism, a bottom inclined plane 154 for the slant buffer type butt joint mechanism is arranged at the slant symmetrical part of the valve block 151 for the slant buffer type butt joint mechanism and the top inclined plane 153 for the slant buffer type butt joint mechanism, a moving space 156 for the slant buffer type butt joint mechanism is arranged inside a hollow rod 155 for the slant buffer type butt joint mechanism which is arranged on the surface of the bottom inclined plane 154 for the slant buffer type butt joint mechanism, a moving plate 157 for the slant buffer type butt joint mechanism is arranged inside the moving space 156 for the slant buffer type butt joint mechanism, a telescopic rod 159 for the slant buffer type butt joint mechanism is arranged at the center of one end surface, the telescopic rod 159 for the oblique buffer type docking mechanism is provided with a connecting plate 1510 for the oblique buffer type docking mechanism at one end positioned outside; a limiting plate 126 for a telescopic control mechanism is arranged in the plate mounting groove 152 for the oblique buffer type docking mechanism; the first mounting hole 143 for the coil spring type power driving mechanism is parallel to the plane of the gentle slope inclined plane 7, and the two are opposite.

The specific use mode is as follows: during the work of the invention, a reciprocating telescopic rod is fixedly connected with an oblique buffer type docking mechanism by a connecting plate 1510, then an object to be punched is placed in an object placing groove 3, at the moment, the reciprocating telescopic rod is controlled to enable the oblique buffer type docking mechanism 15 to move left and right in a reciprocating way, when the oblique buffer type docking mechanism 15 moves to the position of a gentle slope inclined plane 7, the oblique buffer type docking mechanism uses an inclined plane 153 and the gentle slope inclined plane 7 to carry out combined motion, at the moment, the telescopic control mechanism 12 can move downwards while moving leftwards, when the valve block 121 for the telescopic control mechanism is completely separated from a main groove structure 11, the movable valve block 8 moves rightwards rapidly under the action of a main spiral spring 9, so that an impact head structure 10 punches the object, at the moment, the reciprocating telescopic rod drives the oblique buffer type docking mechanism 15 to move rightwards, during the moving process, because the effect of coil spring formula power drive mechanism 14 for each part resets, when meetting removal valve piece 8, the bottom corner of removal valve piece 8 can make telescopic control mechanism use inclined plane 122 slowly compress downwards, when moving main groove structure 11 position, enters into inside main groove structure 11, so reciprocal, can carry out impact effect many times.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. A reciprocating punching device, comprising a main hollow casing (1), characterized in that: the top of the interior of the main hollow shell (1) is provided with a sealed main moving space (2), one side of the main moving space (2) is provided with an object placing groove (3), the bottom of the main moving space (2) is provided with a main first moving hole (4), the bottom of the main first moving hole (4) is provided with a main second moving hole (5), the bottom of the main second moving hole (5) is provided with a main third moving hole (6) communicated with the bottom surface of the main hollow shell (1), one side of the bottom surface of the main hollow shell (1) is provided with a downward gentle slope inclined plane (7), a compressed main spiral spring (9) is arranged in the main moving space (2), one end of the main spiral spring (9) is provided with a moving valve block (8), the center of the bottom of the moving valve block (8) is provided with a main groove structure (11), one side of the moving valve block (8) is provided with an impact head structure (10), a telescopic control mechanism (12) is placed at the longitudinal position of the main groove structure (11), the main first moving hole (4), the main second moving hole (5) and the main third moving hole (6), the telescopic control mechanism (12) is sleeved inside a spiral spring type power driving mechanism (14) in a structure positioned inside the main second moving hole (5), and the telescopic control mechanism (12) positioned on the bottom surface of the main hollow shell (1) is installed inside a slant buffering type butt joint mechanism (15).

2. A reciprocating stamping apparatus as claimed in claim 1, wherein: the telescopic control mechanism (12) comprises a valve block (121) for the telescopic control mechanism, an inclined plane (122) for the telescopic control mechanism, a limiting column (123) for the telescopic control mechanism, a rod body (124) for the telescopic control mechanism, an annular mounting groove (125) for the telescopic control mechanism and a limiting plate (126) for the telescopic control mechanism; one side of valve piece (121) for telescopic control mechanism is equipped with gentle slope formula telescopic control mechanism and uses inclined plane (122), a telescopic control mechanism of bottom installation of valve piece (121) for telescopic control mechanism uses spacing post (123), the bottom of telescopic control mechanism with spacing post (123) is equipped with telescopic control mechanism of integral type structure and uses limiting plate (126), telescopic control mechanism is equipped with annular mounting groove (125) for telescopic control mechanism with limiting plate (126) and the intersection of the telescopic control mechanism with the body of rod (124).

3. A reciprocating stamping apparatus as claimed in claim 2, wherein: the telescopic control mechanism is characterized in that the limiting column (123) for the telescopic control mechanism is located in the horizontal plane of the main first moving hole (4), and the rod body (124) for the telescopic control mechanism is sleeved inside the spiral spring type power driving mechanism (14).

4. A reciprocating stamping apparatus as claimed in claim 2, wherein: the limiting plate (126) for the telescopic control mechanism is positioned at the bottom of the lower surface of the main hollow shell (1) and is installed inside the inclined buffer type butt joint mechanism (15).

5. A reciprocating stamping apparatus as claimed in claim 1, wherein: the coil spring type power driving mechanism (14) comprises a first plate (141) for the coil spring type power driving mechanism, a second plate (142) for the coil spring type power driving mechanism, a first mounting hole (143) for the coil spring type power driving mechanism, a second sleeving hole (144) for the coil spring type power driving mechanism, a coil spring (145) for the coil spring type power driving mechanism, a spherical groove structure (146) for the coil spring type power driving mechanism and a ball (147) for the coil spring type power driving mechanism; the spring coil type power driving mechanism is characterized in that a first mounting hole (143) for the spring coil type power driving mechanism and a second sleeving hole (144) for the spring coil type power driving mechanism are respectively formed in the inner centers of a first plate (141) for the spring coil type power driving mechanism and a second plate (142) for the spring coil type power driving mechanism, a compressed spring coil (145) for the spring coil type power driving mechanism is mounted between the tops of the second plate (142) for the spring coil type power driving mechanism and the bottom of the first plate (141) for the spring coil type power driving mechanism, spherical groove structures (146) for the spring coil type power driving mechanism are respectively arranged inside the upper surface edge of the first plate (141) for the spring coil type power driving mechanism and inside the lower surface edge of the second plate (142) for the spring coil type power driving mechanism, and a roller structure (146) for the spring coil spring power driving mechanism is mounted inside the spherical groove structures (146) for the spring coil A bead (147).

6. A reciprocating stamping apparatus as claimed in claim 5, wherein: the first plate (141) and the second plate (142) for the coil spring type power driving mechanism are both positioned in the main second moving hole (5), and the balls (147) for the coil spring type power driving mechanism are abutted against the upper surface and the lower surface of the main second moving hole (5).

7. A reciprocating stamping apparatus as claimed in claim 5, wherein: the spiral spring type power driving mechanism is sleeved on the side surface of the annular mounting groove (125) for the telescopic control mechanism through a first mounting hole (143), the first mounting hole and the annular mounting groove are fixedly connected, the spiral spring type power driving mechanism is sleeved on the rod body of the rod body (124) for the telescopic control mechanism through a second sleeving hole (144), and the first mounting hole and the second sleeving hole are in active sleeving.

8. A reciprocating stamping apparatus as claimed in claim 1, wherein: the oblique buffer type butt joint mechanism (15) comprises a valve block (151) for an oblique buffer type butt joint mechanism, a block mounting groove (152) for the oblique buffer type butt joint mechanism, a top inclined surface (153) for the oblique buffer type butt joint mechanism, a bottom inclined surface (154) for the oblique buffer type butt joint mechanism, a hollow rod (155) for the oblique buffer type butt joint mechanism, a moving space (156) for the oblique buffer type butt joint mechanism, a moving plate (157) for the oblique buffer type butt joint mechanism, a spiral spring (158) for the oblique buffer type butt joint mechanism, a telescopic rod (159) for the oblique buffer type butt joint mechanism and a connecting plate (1510) for the oblique buffer type butt joint mechanism; a top inclined plane (153) for the slant buffering type butt joint mechanism is arranged between the upper side face and the lower side face of the valve block (151) for the slant buffering type butt joint mechanism, a block mounting groove (152) for the slant buffering type butt joint mechanism is arranged in the center of the upper surface of the valve block (151) for the slant buffering type butt joint mechanism, a bottom inclined plane (154) for the slant buffering type butt joint mechanism is arranged at the slant symmetrical position of the valve block (151) for the slant buffering type butt joint mechanism and the top inclined plane (153) for the slant buffering type butt joint mechanism, a moving space (156) for the slant buffering type butt joint mechanism is arranged inside a hollow rod (155) for the slant buffering type butt joint mechanism, and a slant buffering type butt joint mechanism (157) is arranged inside the moving space (156) for the slant buffering type butt joint mechanism, an expansion link (159) for the slant buffer type docking mechanism is installed in the center of one end face of the movable plate (157) for the slant buffer type docking mechanism, and a connecting plate (1510) for the slant buffer type docking mechanism is installed at one end, located outside, of the expansion link (159) for the slant buffer type docking mechanism.

9. A reciprocating stamping apparatus as claimed in claim 8, wherein: and a limiting plate (126) for a telescopic control mechanism is arranged in the plate mounting groove (152) for the oblique buffer type butt joint mechanism.

10. A reciprocating stamping apparatus as claimed in claim 8, wherein: the first mounting hole (143) for the spiral spring type power driving mechanism is parallel to the plane of the gentle slope inclined plane (7) and opposite to the plane of the gentle slope inclined plane.

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