CN114309210B - Stamping equipment for new energy automobile production - Google Patents

Abstract

The invention belongs to the technical field of automobile manufacturing, and particularly relates to improvement and application of stamping equipment for new energy automobile production; through above-mentioned scheme, set up the power spare on the frame to set up a selective drive subassembly that has first output and second output on the power take off of power spare, let first output and last mould place the portion and dismantle and be connected, the second output is placed the portion with the bed die and can dismantle and be connected, utilize the first output of power spare drive selective connection subassembly and go up mould place portion or bed die and place the portion and carry out selective connection, and then make that mould that is connected to the mould direction motion that is not connected, realized placing the portion to last mould or bed die and placed the portion and carry out selective drive's purpose. When the first output end and the second output end are respectively connected with the upper die placing part and the lower die placing part, the invention achieves the aim of simultaneously carrying out relative movement on the upper die placing part and the lower die placing part.

Description

Stamping equipment for new energy automobile production

Technical Field

The invention belongs to the technical field of automobile manufacturing, and particularly relates to improvement and application of stamping equipment for new energy automobile production.

Background

The new energy automobile is an automobile which adopts unconventional automobile fuel as a power source (or adopts conventional automobile fuel and an automobile-mounted power device) and integrates the advanced technology in the aspects of power control and driving of the automobile, and the formed technical principle is advanced, and the automobile has a new technology and a new structure. In the production process of the new energy automobile, various parts are required to be used, and a punch is required to punch the semi-finished parts of the new energy automobile. The punch press is a stamping press. In national production, the stamping process has the advantages of saving materials and energy sources, being high in efficiency, not high in technical requirements for operators and being capable of making products which cannot be achieved by mechanical processing through various die applications compared with the traditional mechanical processing, so that the stamping process is increasingly widely used. The stamping production is mainly aimed at the plate material. Through the mould, blanking, punching, forming, deep drawing, trimming, fine blanking, shaping, riveting, extrusion and the like can be performed, and the die is widely applied to various fields.

In the process of manufacturing the stamping part by using the stamping equipment, the power source is required to drive the upper die placing part to move in the direction of the lower die or drive the lower die to move in the direction of the upper die. Such a single die moving structure has been widely used in stamping equipment. In the prior art, in the process of stamping and manufacturing blanks, one die is fixed, the other die is movable, and then the movable die is driven by a power source to move towards the fixed die, so that the upper die and the lower die cannot be selectively driven. In the actual production process, the purpose of selectively driving the upper die or the lower die is to enable the upper die to move or enable the lower die to move according to the stamping type required by the stamping part to be determined by the selective driving when the upper die or the lower die is used, so that the purpose of controlling the movement modes of the upper die and the lower die is achieved at the same time.

Disclosure of Invention

The invention aims to provide stamping equipment for new energy automobile production.

In order to achieve the aim of the invention, the invention adopts the following technical scheme:

The utility model provides a stamping equipment for new energy automobile production, includes the frame, be provided with the power spare on the frame, the power take off end of power spare is provided with selective drive subassembly, selective drive subassembly include with power take off end fixed connection's of power spare telescopic member, be provided with on the telescopic member with coaxial and equidirectional first output and the second output of power spare, first output drive goes up mould placement part or lower mould placement part, or, second output drive lower mould placement part or last mould placement part, go up mould placement part and lower mould placement part relative up-down.

In order to better realize the invention, as a further optimization of the scheme, two sides of the telescopic component are respectively provided with a linear walking component in a staggered way, the two linear walking components are respectively connected with the upper die placing part and the lower die placing part, and the first output end and/or the second output end drive the linear walking components to move up and down.

As a further optimization of the scheme, the telescopic component comprises an outer sleeve body, one end of the outer sleeve body is fixedly connected with the power output end of the power piece, a power part is arranged in the inner cavity of the outer sleeve body, the output end of the power part is in contact with the telescopic rod, the telescopic rod slides along the inner cavity of the outer sleeve body, and the first output end and the second output end are coaxially and fixedly arranged on the rod body of the telescopic rod outside the outer sleeve body.

As a further optimization of the scheme, at least one guide groove parallel to the telescopic rod is circumferentially arranged on the inner wall of the outer sleeve body, guide blocks corresponding to the guide grooves in shape and number are arranged on the telescopic rod, and the guide blocks slide in the guide grooves.

As a further optimization of the scheme, the telescopic component further comprises a supporting piece, one end of the supporting piece is fixedly connected with the frame, a bearing with a seat is arranged at the other end of the supporting piece, and the bearing with the seat is rotationally connected with the outer sleeve body.

As a further optimization of the above scheme, the telescopic component further comprises a supporting piece with one end in sliding connection with the frame, a bearing with a seat is arranged at the other end of the supporting piece, the bearing with a seat is coaxially arranged with the telescopic rod, pin grooves are formed in the rod bodies of the telescopic rod of the first output end and the second output end, and pin blocks axially sliding along the pin grooves are arranged on the bearing with a seat.

As a further refinement of the above solution, a drive gear is fixedly arranged on each of the first output and the second output.

As a further optimization of the above scheme, the straight-line walking component comprises straight racks meshed with the driving gear, the straight racks are fixedly connected with the upper die placing part or the lower die placing part respectively and only, and the straight racks are vertically arranged on the frame in a sliding manner.

As a further optimization of the scheme, the upper die placing part and the lower die placing part are respectively provided with a limiting groove, a group of limiting assemblies are respectively and adaptively arranged in the limiting grooves, and the two limiting assemblies are respectively fixed on the frame.

As a further optimization of the scheme, the limiting assembly comprises a supporting frame fixedly connected with the frame, a telescopic device is arranged on the supporting frame, and a limiting block matched with the limiting groove is arranged at the output end of the telescopic device.

The invention has the following beneficial effects:

According to the stamping equipment for the production of the new energy automobile, the power piece is arranged on the frame, the selective driving assembly with the first output end and the second output end is arranged on the power output end of the power piece, the first output end is detachably connected with the upper die placing part, the second output end is detachably connected with the lower die placing part, the first output end of the selective connecting assembly is driven by the power piece to be selectively connected with the upper die placing part or the lower die placing part, and then the connected die moves towards the direction of the unconnected die, so that the purpose of selectively driving the upper die placing part or the lower die placing part is achieved. Meanwhile, when the first output end and the second output end are respectively connected with the upper die placing part and the lower die placing part, the invention achieves the purpose of simultaneously carrying out relative movement on the upper die placing part and the lower die placing part.

Drawings

FIG. 1 is a schematic three-dimensional structure of the present invention;

FIG. 2 is a schematic view of a three-dimensional structure of the upper mold placement unit of the present invention;

FIG. 3 is a schematic view of a three-dimensional structure of the lower mold placement unit according to the present invention;

FIG. 4 is a schematic view of a three-dimensional structure when the upper and lower mold placement sections are driven simultaneously;

FIG. 5 is a schematic three-dimensional view of the selective drive assembly depicted in FIG. 1;

FIG. 6 is a schematic view of the three-dimensional structure of the telescoping member shown in FIG. 5;

FIG. 7 is a schematic three-dimensional view of another embodiment of the telescoping member shown in FIG. 5;

FIG. 8 is an enlarged three-dimensional schematic view of the portion A of FIG. 1;

FIG. 9 is an enlarged three-dimensional schematic view of portion B of FIG. 7;

FIG. 10 is an enlarged three-dimensional schematic view of portion C of FIG. 2;

Description of the drawings: the device comprises a frame, a 2-power part, a 3-selective driving assembly, a 4-first output end, a 5-second output end, a 6-upper die placing part, a 7-lower die placing part, an 8-telescopic part, a 9-linear walking part, a 10-outer sleeve, a 11-telescopic rod, a 12-guide groove, a 13-guide block, a 14-supporting part, a 15-seat bearing, a 16-pin groove, a 17-pin block, a 18-limit groove, a 19-supporting frame, a 20-telescopic device and a 21-limit block.

Detailed Description

The present invention will be described in further detail with reference to preferred examples of the present invention, but the embodiments of the present invention are not limited thereto.

Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present invention, it should be noted that the terms "first," "second," "third," and the like are used merely to distinguish between descriptions and are not to be construed as indicating or implying relative importance.

The terms "upper," "lower," "left," "right," "inner," "outer," and the like refer to an orientation or positional relationship based on that shown in the drawings, or that is conventionally put in place when the inventive product is used, merely to facilitate description of the invention and simplify description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the invention.

Furthermore, the terms "vertical" and the like do not denote absolute perpendicularity between the required components, but may be slightly inclined. As "vertical" simply means that its direction is relatively more vertical, and does not mean that the structure must be perfectly vertical, but may be slightly tilted.

In the description of the present invention, it should also be noted that the terms "disposed," "mounted," "connected," and the like are to be construed broadly, unless otherwise specifically defined and limited. For example, the connection can be fixed connection, detachable connection or integrated connection; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Examples

As shown in fig. 1-9, a stamping device for new energy automobile production, which comprises a frame 1, wherein a power piece 2 is arranged on the frame 1, a selective driving component 3 is arranged at the power output end of the power piece 2, the selective driving component 3 comprises a telescopic component 8 fixedly connected with the power output end of the power piece 2, a first output end 4 and a second output end 5 which are coaxial and in the same direction with the output end of the power piece 2 are arranged on the telescopic component 8, the first output end 4 drives an upper die placing part 6 or a lower die placing part 7, or the second output end 5 drives the lower die placing part 7 or the upper die placing part 6, and the upper die placing part 6 and the lower die placing part 7 are arranged up and down oppositely.

As shown in fig. 1, in the present embodiment, a power member 2 is provided on a frame 1, and a selective driving unit 3 having a first output end 4 and a second output end 5 is provided on a power output end of the power member 2, and the first output end 4 is detachably connected to an upper die placing portion 6, and the second output end 5 is detachably connected to a lower die placing portion 7, and the first output end 4 of the selective connecting unit is driven by the power member 2 to selectively connect to the upper die placing portion 6 or the lower die placing portion 7, so that the connected die moves in a direction of the unconnected die, so that the present invention achieves the purpose of selectively driving the upper die placing portion 6 or the lower die placing portion 7. Meanwhile, when the first output end 4 and the second output end 5 are respectively connected with the upper die placing part 6 and the lower die placing part 7, the invention achieves the aim of simultaneously carrying out relative movement on the upper die placing part 6 and the lower die placing part 7.

It can be further stated that, as shown in fig. 2 to 4, in the present invention, when the stamping manufacturing of the automobile parts is performed, the selective driving assembly 3 has three driving modes as follows:

The first way is that the first output end 4 is connected with the upper die placing part 6, the second output end 5 is not connected with the lower die placing part 7, and referring to fig. 2, when the first output end is in the connected state, the purpose that the power piece 2 drives the upper die placing part 6 to move towards the lower die placing part 7 is achieved.

Second, the second output end 5 is connected to the lower mold placing part 7, the first output end 4 is not connected to the upper mold placing part 6, and referring to fig. 3, when the second output end is in this connected state, the power member 2 drives the lower mold placing part 7 to move upwards.

Third, the first output end 4 is connected with the upper die placing part 6, and the second output end 5 is connected with the lower die placing part 7, referring to fig. 4, when the power piece 2 is in the connected state, the purpose that the power piece 2 drives the upper die placing part 7 and the lower die placing part 7 to move relatively is achieved.

Through the three connection modes, the purpose of selectively driving the upper die placing part 7 and the lower die placing part 7 is achieved in the using process, so that the invention can selectively control according to the die movement mode required by the type of the processed stamping part, the autonomous selectivity of technicians is effectively improved, and more importantly, the method can be used for enriching the processed products.

It is particularly clear and stated that in the present embodiment, the power member 2 is a device or apparatus capable of driving the selective driving assembly 3 in a rotational motion. The apparatus or device may be used directly with conventional apparatus or devices known in the art, to which the present invention is applied only, and does not involve improvement in the specific structure of the apparatus or device. As an example, the power element 2 may include, but is not limited to, the following types: a power device such as a servo motor having a rotation shaft and capable of performing forward and reverse rotation. The linear walking component 9 has a structure capable of performing linear walking under the drive of the first output end 4 or the second output end 5, and the first output end 4 and the second output end 5 are matched with the linear walking component 9 and can drive the linear walking component to perform linear walking. As an example, the straight walking member may include, but is not limited to, the following types: a straight rack, a linear guide rail structure, a worm structure and the like.

In order to better implement the present invention, as a further optimization of the above scheme, two sides of the telescopic member 8 are respectively provided with a linear walking member 9 in a staggered manner, two linear walking members 9 are respectively connected with the upper die placing portion 6 and the lower die placing portion 7, and the first output end 4 and/or the second output end 5 drive the linear walking members 9 to move up and down.

For example: when the straight-line walking component is a straight rack, the straight rack is meshed with the driving gear, each straight rack is connected with the upper die placing part 6 and the lower die placing part 7 through connecting rods respectively, and meanwhile, a sliding groove for the vertical sliding of the straight rack is formed in the frame. The connecting rods are respectively fixed at the top and the bottom of the two straight racks, the other ends of the connecting rods connected with the tops of the straight racks are connected with the top of the upper die placing part 6, and the other ends of the connecting rods connected with the bottoms of the straight racks are connected with the bottom of the lower die placing part 7.

As shown in fig. 5, in this embodiment, the selective driving assembly 3 is provided with the telescopic members 8, so that the first output end 4 and the second output end 5 are both arranged on two sides of the telescopic members 8 in a staggered manner, and meanwhile, a linear traveling member 9 is respectively arranged on the first output end 4 and the second output end 5, and the first output end 4 and the second output end 5 can be selectively contacted with the linear traveling member 9 respectively connected with the upper mold placement portion 6 through the telescopic function of the telescopic members 8, so as to achieve the purpose of selective driving.

As further described, in this embodiment, as shown in fig. 1 to 4, the specific method for disposing the linear traveling members 9 on both sides of the telescopic member 8 in a staggered manner is to take the telescopic member 8 as a hydraulically driven telescopic device 20 as an example, vertically dispose one linear traveling member 9 on both sides of the telescopic shaft of the hydraulic telescopic device 20, and define the ends of the two linear traveling members 9 closer to the power element 2 as the proximal ends and the ends farther from the power element 2 as the distal ends, wherein at least a certain gap is provided between the distal ends of the linear traveling members 9 connected to the upper mold placement portion 6 and the proximal ends of the linear traveling members 9 connected to the lower mold placement portion 7, and the purpose of disposing the gap is that, when selectively driving the upper mold placement portion 6 or the lower mold placement portion 7 by using the present invention, the first output end 4 or the second output end 5 is connected to only the traveling member of the mold to be driven, thereby achieving the purpose of individual driving.

As a further optimization of the above scheme, the telescopic component 8 comprises an outer sleeve 10 with one end fixedly connected with the power output end of the power piece 2, a power part is arranged in the inner cavity of the outer sleeve 10, the output end of the power part is in contact with a telescopic rod 11, the telescopic rod slides along the inner cavity of the outer sleeve 10, and the first output end 4 and the second output end 5 are coaxially and fixedly arranged on the rod body of the telescopic rod outside the outer sleeve 10.

As shown in fig. 6, in this embodiment, the telescopic member 8 is provided with the outer casing 10, and the power unit is disposed in the outer casing 10, so that the power output end of the power unit is connected to the telescopic rod, and the first output end 4 and the second output end 5 are both disposed on the rod body of the telescopic rod, so that the positions of the first output end 4 and the second output end 5 can be adjusted during use, and further, the invention achieves the purpose of selective driving.

As a further optimization of the above scheme, at least one guide groove 12 parallel to the telescopic rod is circumferentially arrayed on the inner wall of the outer sleeve body 10, guide blocks 13 corresponding to the shape and the number of the guide grooves 12 are arranged on the telescopic rod, and the guide blocks 13 slide in the guide grooves 12.

In this embodiment, by providing a guide slot 12 parallel to the telescopic rod on the inner wall of the outer casing 10 and simultaneously providing a guide block 13 sliding in the guide slot 12 on the telescopic rod, the invention effectively ensures that the telescopic rod and the first output end 4 and the second output end 5 provided on the telescopic rod do not rotate relatively under the drive of the power element 2 on the basis of realizing the adjustment of the positions of the first output end 4 and the second output end 5, and ensures that the rotation force output by the power element 2 is not consumed.

As a further optimization of the above scheme, the telescopic component 8 further comprises a supporting piece 14 with one end fixedly connected with the frame 1, the other end of the supporting piece 14 is provided with a bearing 15 with a seat, and the bearing 15 with a seat is rotatably connected with the outer sleeve 10.

As shown in fig. 6, in this embodiment, the bearing is fixed on the frame 1 by the supporting member 14, and meanwhile, the bearing with a seat 15 is sleeved on the outer wall of the outer sleeve 10, so that the whole telescopic component 8 has stronger stability and no potential safety hazard due to unstable center of gravity when the telescopic component is used.

As a further optimization of the above scheme, the telescopic component 8 further comprises a supporting piece 14 with one end slidably connected with the frame 1, a seat bearing 15 is arranged at the other end of the supporting piece 14, the seat bearing 15 is coaxially arranged with the telescopic rod, pin grooves 16 are arranged on the rod bodies of the telescopic rod of the first output end and the telescopic rod of the second output end, and a pin block 17 axially sliding along the pin grooves 16 is arranged on the seat bearing 15.

As a preferred embodiment, as shown in fig. 7, in this embodiment, the bearing is fixed on the frame 1 through the supporting member 14, meanwhile, the telescopic rod is connected with the bearing with seat 15, the pin groove 16 is arranged on the telescopic rod, and the pin block 17 is arranged on the bearing with seat 15, so that the telescopic rod can slide relative to the bearing with seat 15 when the telescopic rod is used, and further, the supporting effect of the whole telescopic member 8 is stronger and the stability is higher when the telescopic member is used.

It should be specifically noted and described that in the present embodiment, when the telescopic member connects the linear traveling members of the first output end and the second output end, which are required to be connected, the supporting member 14 will travel along with the telescopic rod, so as to achieve the purpose of selectively driving the upper die placement portion or the lower die placement portion.

As a further refinement of the above solution, a drive gear is fixedly arranged on each of the first output 4 and the second output 5.

As a further optimization of the above solution, the straight running member 9 includes a straight rack engaged with the driving gear, and the straight rack is fixedly connected with the upper mold placing portion 6 or the lower mold placing portion 7, respectively, and is vertically slidably disposed on the frame 1.

As a further optimization of the above scheme, the upper die placing part 6 and the lower die placing part 7 are further provided with a limiting groove 18 respectively, a group of limiting components are respectively adapted to the two limiting grooves 18, and the two limiting components are respectively fixed on the frame 1.

In this embodiment, the limiting means is provided, so that the lower die placing part 7 or the upper die placing part 6 which is not driven can be fixedly limited by the limiting means when only the upper die placing part 6 or the lower die placing part 7 is driven, and further, the novel energy automobile part has stronger stability when being manufactured by punching.

As a further optimization of the above scheme, the limiting component comprises a supporting frame 19 fixedly connected with the frame 1, a telescopic device 20 is arranged on the supporting frame 19, and a limiting block 21 matched with the limiting groove 18 is arranged at the output end of the telescopic device 20.

As shown in fig. 1 to 10, the installation process of the stamping device of the present invention is as follows: first, it is determined whether to drive the upper die placing portion 6 or the lower die placing portion 7 alone or to drive the upper and lower die placing portions 7 simultaneously, depending on the type of the part to be processed. Assuming that the upper die placing portion 6 needs to be driven to move towards the lower die placing portion 7 at this time, for example, the telescopic device 20 of the upper die placing portion 6 is opened, the telescopic device 20 retracts the limiting block 21, the limiting of the upper die placing portion 6 is released, the power portion is opened and the telescopic rod is driven to extend, the driving gear arranged on the first output end 4 is meshed with the straight rack connected with the upper die placing portion 6, the power piece 2 is started, the power piece 2 drives the driving gear to rotate, the straight rack vertically slides along the frame 1 and drives the upper die placing portion 6 to move towards the lower die placing portion 7, meanwhile, the blank placed on the lower die placing portion 7 is subjected to stamping forming, after the part manufacturing is completed, the power piece 2 is reversed, the straight rack drives the upper die placing portion 6 to move upwards, the forming workpiece is taken out, and the process is repeated.

Through the scheme, the power piece 2 is arranged on the frame 1, the selective driving assembly 3 with the first output end 4 and the second output end 5 is arranged on the power output end of the power piece 2, the first output end 4 is detachably connected with the upper die placing part 6, the second output end 5 is detachably connected with the lower die placing part 7, the first output end 4 of the selective connecting assembly is driven by the power piece 2 to be selectively connected with the upper die placing part 6 or the lower die placing part 7, and then the connected die moves towards the direction of the unconnected die, so that the purpose of selectively driving the upper die placing part 6 or the lower die placing part 7 is achieved. Meanwhile, when the first output end 4 and the second output end 5 are respectively connected with the upper die placing part 6 and the lower die placing part 7, the invention achieves the aim of simultaneously carrying out relative movement on the upper die placing part 6 and the lower die placing part 7.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (2)

1. A stamping equipment for new energy automobile production, its characterized in that: the automatic feeding device comprises a frame (1), wherein a power piece (2) is arranged on the frame (1), a selective driving assembly (3) is arranged at the power output end of the power piece (2), the selective driving assembly (3) comprises a telescopic component (8) fixedly connected with the power output end of the power piece (2), a first output end (4) and a second output end (5) which are coaxial and in the same direction with the output end of the power piece (2) are arranged on the telescopic component (8), the first output end (4) drives an upper die placing part (6) or a lower die placing part (7), the second output end (5) drives the lower die placing part (7) or the upper die placing part (6), and the upper die placing part (6) and the lower die placing part (7) are arranged in an up-down opposite mode;

The selective drive assembly (3) comprises three drive modes:

First kind: the first output end (4) is not connected with the lower die placing part (7), the second output end (5) is connected with the upper die placing part (6), and when the first output end is in the connected state, the power piece (2) drives the upper die placing part (6) to move towards the lower die placing part (7);

The second is that the first output end (4) is connected with the lower die placing part (7), the second output end (5) is not connected with the upper die placing part (6), and when the first output end is in the connected state, the power piece (2) drives the lower die placing part (7) to move upwards;

The third is that the first output end (4) is connected with the upper die placing part (6), the second output end (5) is connected with the lower die placing part (7), when the power piece (2) is in the connection state, the power piece drives the upper die placing part and the lower die placing part to move relatively;

Two sides of the telescopic component (8) are respectively provided with a linear walking component (9) in a staggered manner, the two linear walking components (9) are respectively connected with the upper die placing part (6) and the lower die placing part (7), and the first output end (4) and/or the second output end (5) drive the linear walking components (9) to move up and down;

The telescopic component (8) comprises an outer sleeve body (10) with one end fixedly connected with the power output end of the power piece (2), a power part is arranged in the inner cavity of the outer sleeve body (10), the output end of the power part is in contact with a telescopic rod (11), the telescopic rod (11) slides along the inner cavity of the outer sleeve body (10), and the first output end (4) and the second output end (5) are coaxially and fixedly arranged on the outer wall of the telescopic rod (11);

the telescopic component (8) further comprises a supporting piece (14) with one end in sliding connection with the frame (1), a seat bearing (15) is arranged at the other end of the supporting piece (14), the seat bearing (15) and the telescopic rod are coaxially arranged, a pin groove (16) is formed in the rod body of the telescopic rod, which is provided with the first output end and the second output end, and a pin block (17) which axially slides along the pin groove (16) is arranged on the seat bearing (15);

The first output end (4) and the second output end (5) are respectively driving gears;

Each straight-line walking component (9) comprises straight racks meshed with the driving gear, each straight rack is connected with the upper die placing part (6) and the lower die placing part (7) through connecting rods respectively, and a sliding groove for the straight racks to vertically slide is formed in the frame;

Limiting grooves (18) are respectively formed in the side walls of the upper die placing part (6) and the lower die placing part (7), limiting components are respectively adapted to the two limiting grooves (18), and the limiting components are respectively fixed on the frame (1);

The limiting assembly comprises a supporting frame (19) fixedly connected with the frame (1), a telescopic device (20) is arranged on the supporting frame (19), and a limiting block (21) matched with the limiting groove (18) is arranged at the output end of the telescopic device (20).

2. The stamping device for new energy automobile production of claim 1, wherein: the telescopic device is characterized in that at least one guide groove (12) parallel to the telescopic rod is circumferentially arranged on the inner wall of the outer sleeve body (10), guide blocks (13) corresponding to the guide grooves (12) in shape and number are arranged on the telescopic rod, and the guide blocks (13) slide in the guide grooves (12).