A processing apparatus

By integrating stamping and riveting devices into the same processing equipment, the problem of low processing efficiency of metal products is solved, realizing automated processing of metal products and improving processing efficiency and user experience.

CN224333854UActive Publication Date: 2026-06-09SHENZHEN TATFOOK QUAINTFAB CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN TATFOOK QUAINTFAB CO LTD
Filing Date
2025-04-21
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing technologies involve cumbersome metal product processing steps, requiring manual transfer of metal parts between different devices, resulting in low processing efficiency.

Method used

The stamping and riveting devices are integrated into the same processing equipment. The stamping and riveting are synchronized through the mold frame control, and the steel strip is directly stamped into metal parts and riveted in the mold to form metal products.

Benefits of technology

It has improved the efficiency of metal product processing, realized automated processing of metal products, reduced manual intervention, and enhanced the user experience.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a processing equipment, and provides a stamping device, a riveting device and a die holder of the processing equipment. The stamping device and the riveting device are arranged on the die holder and are spaced apart. The stamping device is used for stamping a steel strip to form a metal piece. The riveting device is used for riveting a buckle of the metal piece into a clamping groove of another metal piece to rivet the metal pieces to each other and form a metal product. The stamping device and the riveting device are integrated in the same processing equipment, so that the problem of low processing efficiency caused by different processing steps and the transfer of the metal piece in the prior art is solved. The steel strip can be directly stamped into the metal piece by the processing equipment, and the metal piece can be riveted in the die to form the metal product, so that the automation of the metal product processing is realized, the processing efficiency of the metal product is improved, and the use experience of the user for the processing equipment is improved.
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Description

Technical Field

[0001] This application relates to the field of metal processing technology, and in particular to a processing equipment. Background Technology

[0002] In existing technologies, the process for assembling metal products typically involves first stamping the required metal parts from raw materials using a stamping device, then transferring the stamped parts to an assembly device for assembly to form the final metal product. Alternatively, after stamping, the metal parts are manually connected using connectors to rivet multiple parts together to form the desired product. This cumbersome processing procedure requires manual transfer of metal parts between different devices, resulting in high manual intervention and consequently low processing efficiency. Utility Model Content

[0003] To solve the above-mentioned technical problems, this application provides a processing equipment for processing steel strips into metal products, the metal products comprising a plurality of riveted metal parts, each of the metal parts having at least one buckle and at least one slot; the processing equipment includes a stamping device, a riveting device, and a mold frame;

[0004] The stamping device and the riveting device are spaced apart on the mold frame. The stamping device is used to stamp the steel strip to form the metal part. The riveting device is used to rivet the buckle of the metal part to the slot of another metal part, so that multiple metal parts are riveted together to form the metal product.

[0005] The riveting device includes:

[0006] A clamping assembly has a clamping position and a receiving cavity, wherein the clamping position and the receiving cavity are arranged sequentially along the height direction of the clamping assembly; the clamping position is used to place the metal part to be riveted, and the receiving cavity is used to place the riveted metal part.

[0007] A pressing member, positioned above the clamping assembly, is used to push the metal part to be riveted into the clamping position;

[0008] A riveting assembly, partially inserted into the clamping assembly, is used to rivet the buckle of the riveted metal part to the slot of the metal part to be riveted, so as to rivet the metal part to be riveted to the riveted metal part.

[0009] The mold frame includes an upper mold frame and a corresponding lower mold frame, and the stamping device includes an upper mold core and a corresponding lower mold core. The upper mold core is disposed on the upper mold frame, and the lower mold core is disposed on the lower mold frame.

[0010] The clamping assembly is disposed within the lower mold frame and spaced apart from the lower mold core;

[0011] The lower pressing component is installed on the upper mold frame and is spaced apart from the upper mold core;

[0012] The upper die frame is used to move toward the lower die frame to move the upper die core closer to the lower die core, to stamp the steel strip to form the metal part, and to move the lower pressing member closer to the clamping assembly to push the metal part onto the clamping assembly.

[0013] The riveting assembly includes at least one riveting pin, which is inserted into the clamping assembly and slidably disposed with respect to the clamping assembly. The riveting pin is used to move close to the clamping position and press the buckle of the riveted metal part to rivet the buckle of the riveted metal part to the slot of the metal part to be riveted, thereby riveting the metal part to be riveted to the riveted metal part.

[0014] The riveting pin is provided with a first guide surface;

[0015] The riveting assembly further includes at least one driving member, the first end of which is disposed on the upper mold frame, and the second end of which is provided with a second guide surface;

[0016] The first guide surface and the second guide surface are arranged in parallel;

[0017] The driving component is used to drive the riveting pin to move closer to the clamping position through the cooperation of the first guide surface and the second guide surface.

[0018] The riveting assembly further includes a first elastic element, the first end of which abuts against the riveting pin, and the second end of which abuts against the clamping assembly. When the riveting pin moves closer to the clamping position, the first elastic element is compressed.

[0019] The processing equipment further includes a plurality of floating pins, which are spaced apart on the surface of the lower mold frame near the upper mold frame along the extending direction of the steel strip, and the plurality of floating pins are located on both sides of the steel strip.

[0020] The floating pin has a support groove on its side, the edge of the steel strip is located in the support groove, and the height of the support groove is greater than the thickness of the steel strip.

[0021] The processing equipment further includes a plurality of second elastic elements, one end of which is connected to the corresponding floating pin, and the other end of which is connected to the lower mold frame;

[0022] The upper mold frame is used to move closer to the lower mold frame, thereby moving the floating pin closer to the lower mold frame, compressing the second elastic element, and moving the steel strip closer to the lower mold frame.

[0023] The clamping assembly includes a first clamping block, a second clamping block, a third clamping block, and a fourth clamping block. The first clamping block and the second clamping block are spaced apart along the extension direction of the steel strip, and the third clamping block and the fourth clamping block are spaced apart along the width direction of the steel strip. The first clamping block, the second clamping block, the third clamping block, and the fourth clamping block surround and form the clamping position.

[0024] The metal part is provided with buckles and slots on both sides opposite to each other. The riveting assembly includes a first riveting pin and a second riveting pin. The first riveting pin passes through the first clamping block, and the second riveting pin passes through the second clamping block.

[0025] The first riveting pin and the second riveting pin are symmetrically arranged along the central axis of the clamping assembly, and the first riveting pin and the second riveting pin are used to simultaneously rivet the opposite sides of the metal part.

[0026] The beneficial effects of this application are as follows: Unlike existing technologies, the processing equipment provided in this application is used to process steel strips into metal products. The metal products include multiple riveted metal parts, each with at least one snap fastener and slot. The processing equipment includes a stamping device, a riveting device, and a die frame. The stamping device and the riveting device are spaced apart on the die frame. The stamping device is used to stamp the steel strip to form metal parts; the riveting device is used to rivet the snap fasteners of the metal parts to the slots of another metal part, thereby riveting multiple metal parts together to form the metal product. The die frame provides synchronous control of the stamping device and the riveting device, enabling synchronous operation of the stamping device and the riveting device and improving the processing efficiency of the metal products. This application solves the problem of low processing efficiency caused by the need to transfer metal parts during different processing steps in the prior art by integrating the stamping device and the riveting device into the same processing equipment. The processing equipment can directly stamp steel strips into metal parts and rivet the metal parts in the mold to form metal products, realizing the automation of metal product processing, improving the efficiency of metal product processing, and enhancing the user's experience of processing equipment. Attached Figure Description

[0027] To more clearly illustrate the technical solutions in the embodiments of this application, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the accompanying drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0028] in:

[0029] Figure 1 This is a schematic diagram of the structure of one embodiment of the processing equipment of this application;

[0030] Figure 2 This is a schematic diagram of the structure of an embodiment of the riveting device of this application;

[0031] Figure 3 yes Figure 2 Schematic diagram of the structure of area B of the riveting device;

[0032] Figure 4 This is a schematic diagram of another embodiment of the riveting device of this application;

[0033] Figure 5 yes Figure 4 A schematic diagram of the structure of area B' of the intermediate riveting device;

[0034] Figure 6 This is a schematic diagram of the structure of an embodiment of the floating material pin of this application.

[0035] Reference numerals: Processing equipment A; Riveting device 1; Clamping assembly 11; Clamping position 11a; Receiving cavity 11b; First clamping block 111; Second clamping block 112; Lower pressing component 12; Riveting assembly 13; Riveting striker 131; First riveting striker 131a; Second riveting striker 131b; First guide surface 1311; Driving component 132; Second guide surface 1321; First elastic component 133; Stamping device 2; Upper die core 21; Lower die core 22; Die frame 3; Upper die frame 31; Lower die frame 32; Floating pin 4. Detailed Implementation

[0036] The embodiments of this application will now be described in detail with reference to the accompanying drawings.

[0037] In the following description, specific details such as particular system architectures, interfaces, and technologies are presented for illustrative purposes rather than for limiting purposes, in order to provide a thorough understanding of this application.

[0038] In this application, the reference to "embodiment" means that a specific feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of this application. The appearance of this phrase in various places throughout the specification does not necessarily refer to the same embodiment, nor is it a separate or alternative embodiment mutually exclusive with other embodiments. It will be explicitly and implicitly understood by those skilled in the art that the embodiments described herein can be combined with other embodiments.

[0039] In this application, the term "and / or" is merely a description of the relationship between related objects, indicating that three relationships can exist. For example, A and / or B can represent three cases: A alone, A and B simultaneously, and B alone. Additionally, the character " / " generally indicates that the preceding and following related objects are in an "or" relationship. Furthermore, "many" in this application means two or more. Moreover, the term "at least one" in this application means any combination of at least two of any one or more of a plurality of objects. For example, including at least one of A, B, and C can mean including any one or more elements selected from the set consisting of A, B, and C. Furthermore, the terms "first," "second," and "third" in this application are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of indicated technical features.

[0040] To improve the efficiency of metal riveting, this application provides a metal riveting device for riveting multiple metal parts together, each metal part having at least one snap-fit ​​and at least one slot. Please refer to... Figure 1 , Figure 1 This is a schematic diagram of the structure of an embodiment of the processing equipment of this application. The processing equipment A includes a riveting device 1, a stamping device 2, and a mold frame 3.

[0041] The stamping device 2 and the riveting device 1 are spaced apart on the mold frame 3. The stamping device 2 is used to stamp the steel strip to form metal parts; the riveting device 1 is used to rivet the buckles of the metal parts to the slots of another metal part so that multiple metal parts are riveted together to form metal products.

[0042] By synchronously controlling the operation of the stamping device 2 and the riveting device 1 through the mold frame 3, the stamping device 2 and the riveting device 1 can operate synchronously. The metal parts stamped in the stamping device 2 can be directly entered into the riveting device 1 for riveting to form metal products, thereby improving the processing efficiency of metal products.

[0043] This application solves the problem of low processing efficiency caused by the need to transfer metal parts during different processing steps in the prior art by integrating the stamping device 2 and the riveting device 1 into the same processing equipment A. The processing equipment A can directly stamp the steel strip into metal parts and rivet the metal parts in the mold to form metal products, thereby realizing the automation of metal product processing, improving the efficiency of metal product processing, and enhancing the user experience of the processing equipment A.

[0044] Alternatively, please continue reading Figure 2 and Figure 3 , Figure 2 This is a schematic diagram of the structure of an embodiment of the riveting device of this application. Figure 3 yes Figure 2 A schematic diagram of the structure of the riveting device area B. The riveting device 1 provided in this application embodiment includes a clamping assembly 11, a pressing member 12 and a riveting assembly 13.

[0045] The clamping assembly 11 includes a clamping position 11a and a receiving cavity 11b, which are arranged sequentially along the height of the clamping assembly 11. The clamping position 11a is used to place the metal part to be riveted, and the receiving cavity 11b is used to place the riveted metal part. A pressing member 12 is disposed above the clamping assembly 11 and is used to push the metal part to be riveted into the clamping position 11a. A riveting assembly 13 is inserted through the clamping assembly 11 and is used to rivet the clips of the riveted metal part to the metal part to be riveted, thereby riveting the metal part to be riveted to the riveted metal part.

[0046] For details, please refer to Figure 3 Metal parts that are not riveted to other metal parts, such as Figure 3 Metal part B1, whose clips are not riveted to other metal parts and are not riveted by the clips of other metal parts, is defined as the metal part to be riveted; while metal parts that are already riveted to other metal parts, such as... Figure 3 In the context of B2, if the buckle of metal part B2 is not riveted to other metal parts, but metal part B2 is riveted to the buckles of other metal parts, then metal part B2 is defined as a riveted metal part.

[0047] The pressing member 12 is used to push the first metal part to be riveted to the clamping position 11a. At this time, the first metal part to be riveted is metal part B1. Then the riveting assembly 13 is activated to rivet the buckle of the metal part adjacent to metal part B1 to metal part B1. Then the pressing member 12 can push the second metal part to be riveted to the clamping position 11a. Due to the action of the second metal part to be riveted, the first metal part (at this time the metal part has been riveted by the buckle of other metal parts, so it is no longer a metal part to be riveted. For clarity, it is referred to as the first metal part. It can be understood that the first metal part is the first metal part to be riveted mentioned above) is pushed away from the clamping position 11a and enters the receiving cavity 11b. Since the first metal part is riveted by the buckle of other metal parts, the first metal part is now defined as metal part B2, and the second metal part to be riveted is metal part B1. After the pressing member 12 pushes the second metal part to be riveted to the clamping position 11a, the riveting assembly 13 acts again to rivet the buckle of the metal part B2 onto the metal part B1, thereby realizing the mutual riveting of multiple metal parts.

[0048] This embodiment automates the riveting process by setting up a clamping assembly 11 to position the metal parts to be riveted and to accommodate the riveted metal parts. The pressing member 12 pushes the metal parts to be riveted to the clamping position 11a, and the riveting assembly 13 rivets the clips of the riveted metal parts to the metal parts to be riveted. This reduces the manual intervention rate in the riveting process, avoids errors caused by human intervention, improves the efficiency of riveting metal parts, enhances the practicality of the riveting device 1, and improves the user's experience with the riveting device 1.

[0049] Optionally, please refer back to the previous section. Figure 1 The mold frame 3 provided in this application embodiment includes an upper mold frame 31 and a corresponding lower mold frame 32. The stamping device 2 includes an upper mold core 21 and a corresponding lower mold core 22. The upper mold core 21 is disposed on the upper mold frame 31, and the lower mold core 22 is disposed on the lower mold frame 32.

[0050] Furthermore, the clamping assembly 11 is disposed within the lower die holder 32 and spaced apart from the lower die core 22, while the lower pressing member 12 is mounted on the upper die holder 31 and spaced apart from the upper die core 21. The upper die holder 31 is used to move relative to the lower die holder 32 to move the upper die core 21 closer to the lower die core 22, stamping the steel strip to form a metal part, and to move the lower pressing member 12 closer to the clamping assembly 11 to push the metal part onto the clamping assembly 11.

[0051] Specifically, the upper die holder 31 can move closer to the lower die holder 32, thereby causing the upper die core 21 to move closer to the lower die core 22. The upper die core 21 and the lower die core 22 fit together to stamp the steel strip to form a metal part. At the same time, the upper die holder 31 also causes the lower pressing member 12 to move closer to the clamping assembly 11. The lower pressing member 12 is used to push the metal part stamped by the stamping device 2 onto the clamping assembly 11 for riveting by the riveting assembly 13 to form a metal product.

[0052] By cooperating with the upper die holder 31 and the lower die holder 32, the stamping device 2 and the riveting device 1 can operate synchronously, enabling the steel strip to be stamped into metal parts and then directly riveted to form metal products, thereby improving the processing efficiency of the processing equipment A for metal products.

[0053] Alternatively, please continue reading Figure 2 and Figure 3 The riveting assembly 13 includes at least one riveting pin 131, which is inserted into the clamping assembly 11 and is slidably disposed relative to the clamping assembly 11. The riveting pin 131 is used to move close to the clamping position 11a to press the buckle of the riveted metal part and rivet the buckle of the riveted metal part to the slot of the metal part to be riveted, so as to rivet the metal part to be riveted to the riveted metal part.

[0054] Specifically, the end of the riveting pin 131 near the clamping position 11a can be provided with a protrusion that matches the snap fastener of the metal part. As the riveting pin 131 moves closer to the clamping position 11a, the protrusion abuts against the snap fastener of the metal part. Furthermore, as the riveting pin 131 approaches the clamping position 11a, the protrusion presses against the snap fastener of the metal part. For example, if the snap fastener on the metal part was originally inclined, such as… Figure 2 The riveting pin 131 presses the buckle to make the buckle of the metal part vertical, and then rivets it to other metal parts. This allows the buckle of a riveted metal part to be riveted to the slot of a metal part to be riveted, thus achieving the riveting of the metal parts to be riveted and the already riveted metal parts.

[0055] Optionally, the riveting pin 131 is provided with a first guide surface 1311;

[0056] The riveting assembly 13 also includes at least one driving member 132. The first end of the driving member 132 can be disposed on the upper mold base 31, so that the upper mold base 31 can synchronously drive the lower pressing member 12 and the driving member 132 to move closer to the lower mold base 32. The second end of the driving member 132 is spaced apart from the riveting pin 131 and is provided with a second guide surface 1321. The first guide surface 1311 and the second guide surface 1321 are arranged in parallel. The driving member 132 is used to drive the riveting pin 131 to move closer to the clamping position 11a through the cooperation of the first guide surface 1311 and the second guide surface 1321.

[0057] For details, please refer to the following: Figures 2-5 , Figure 4 This is a schematic diagram of another embodiment of the riveting device of this application. Figure 5 yes Figure 4 A schematic diagram of the structure of the riveting device area B'.

[0058] The first guide surface 1311 can be extended toward the central axis away from the riveting pin 131, and the second guide surface 1321 can be extended toward the central axis of the drive member 132, so that the first guide surface 1311 and the second guide surface 1321 are arranged in parallel.

[0059] First, the upper mold base 31 moves closer to the lower mold base 32, causing the lower pressing member 12 and the driving member 132 to move. The lower pressing member 12 pushes the metal part to be riveted into the clamping position 11a, while the driving member 132 moves vertically towards the riveting pin 131 until the first guide surface 1311 and the second guide surface 1321 contact. As the driving member 132 gradually approaches the riveting pin 131, the first guide surface 1311 and the second guide surface 1321 slide relative to each other. The second guide surface 1321 exerts a force on the first guide surface 1311 as it approaches the clamping position 11a, causing the riveting pin 131 to move closer to the clamping position 11a, gradually pressing the metal part's clip to rivet it onto another metal part.

[0060] Among them, metal part B1 is the metal part pushed onto clamping assembly 11 by pressing member 12 at this time. At the same time as pressing member 12 pushes, driving member 132 can drive riveting pin 131 to squeeze the buckle of metal part B2, so that metal part B2 is riveted to metal part B1 immediately when pressing member 12 finishes pushing, thus improving the efficiency of riveting metal parts.

[0061] In another embodiment, the driving component 132 may not be mounted on the upper mold base 31, but may be driven by a separate drive motor. This allows the driving component 132 to drive the riveting pin 131 to rivet the metal part only after the lower pressing component 12 pushes the metal part onto the clamping assembly 11. Specific configurations can be made according to user requirements, and this application does not impose any limitations on this.

[0062] Optionally, the riveting assembly 13 further includes a first elastic element 133. The first end of the first elastic element 133 abuts against the riveting pin 131, and the second end of the first elastic element 133 abuts against the clamping assembly 11. When the riveting pin 131 moves closer to the clamping position 11a, the first elastic element 133 is compressed. When the compressed first elastic element 133 returns to its original length, it will push the riveting pin 131 away from the clamping position 11a.

[0063] Specifically, during the process of the driving component 132 driving the riveting pin 131 to move relative to the clamping assembly 11 and move closer to the clamping position 11a, since one end of the first elastic element 133 abuts against the riveting pin 131 and the other end of the first elastic element 133 abuts against the clamping assembly 11, the first elastic element 133 will be compressed during the process of the riveting pin 131 moving closer to the clamping position 11a.

[0064] After the riveting pin 131 has finished riveting the metal part, the driving member 132 can move away from the riveting pin 131 in the vertical direction. Since there is no force from the driving member 132, the first elastic member 133 returns to its original length, which in turn gives the riveting pin 131 a force to move away from the clamping position 11a. The riveting pin 131 moves away from the clamping position 11a and returns to the initial position, waiting for the next drive of the driving member 132.

[0065] By driving the riveting pin 131 through the driving component 132, the placement of each component in the riveting device 1 is simplified. It eliminates the need to space the drive motor and the riveting pin 131 together to move the pin; instead, the drive motor drives the driving component 132, which in turn moves the riveting pin 131. This improves the flexibility of the drive motor's position and enhances the user experience of the riveting device 1. Furthermore, the presence of the first elastic element 133 eliminates the need for additional driving devices to return the riveting pin 131 to its initial position, simplifying the component structure in the riveting device 1, reducing manufacturing costs, and further improving the user experience.

[0066] Optionally, the processing equipment A provided in this application embodiment further includes multiple floating pins, please refer to... Figure 6 , Figure 6 This is a schematic diagram of the structure of an embodiment of the floating material pin of this application.

[0067] Multiple floating pins 4 are spaced apart along the extension direction of the steel strip on the surface of the lower mold frame 32 near the upper mold frame 31, and the multiple floating pins 4 are located on both sides of the steel strip. The side of the floating pin 4 is provided with a support groove, and the edge of the steel strip is located in the support groove. The height of the support groove is greater than the height of the steel strip.

[0068] In practice, the steel strip is typically driven by a power unit, allowing it to pass between the upper die core 21 and the lower die core 22, the clamping assembly 11, and the pressing member 12. The upper die core 21 and the lower die core 22 then stamp the steel strip to form a metal part. As the steel strip is driven, the metal part is conveyed between the pressing member 12 and the clamping assembly 11. The pressing member 12 then separates the metal part from the steel strip, completing the riveting of multiple metal parts. In one embodiment, the pressing member 12 may also include a cutting section. After the metal part is conveyed to the riveting area, the pressing member 12 contacts the metal part and cuts the connection between the metal part and the steel strip, separating the metal part from the steel strip. The pressing member 12 then pushes the metal part onto the clamping assembly 11.

[0069] In this embodiment, multiple floating pins 4 are provided on the surface of the lower mold frame 32, and the multiple floating pins 4 are provided on both sides of the steel strip. The edge portions on both sides of the steel strip can be provided in the support groove, so that the floating pins 4 can restrict the transmission direction of the steel strip.

[0070] Furthermore, the height of the support groove is greater than the thickness of the steel strip, so that during the transmission of the steel strip by the power unit, the part of the steel strip located in the support groove can be suspended in the air without contacting the groove wall, thus avoiding wear of the support groove by the steel strip during transmission.

[0071] In one embodiment, as described above, during normal transmission of the steel strip, the steel strip is suspended in the air. Therefore, the steel strip is located in the support groove but does not contact the support groove. However, during abnormal transmission of the steel strip, such as when the steel strip accumulates or breaks, since the edge portion of the steel strip is located in the support groove, the steel strip contacts the groove wall. The support groove provides support for the steel strip, preventing it from falling directly onto the lower die holder 32 and affecting the operating components on the lower die holder 32, thus improving the safety of the processing equipment A.

[0072] Optionally, the processing equipment A also includes a plurality of second elastic elements (not shown in the figure). One end of the second elastic element is connected to the corresponding float pin 4, and the other end of the second elastic element is connected to the lower mold base 32. The upper mold base 31 is used to move closer to the lower mold base 32 to drive the float pin 4 to move closer to the lower mold base 32, compress the second elastic elements, and drive the steel strip to move closer to the lower mold base 32.

[0073] Specifically, as the upper die holder 31 moves closer to the lower die holder 32, it simultaneously presses down on the floating pin 4, causing it to move closer to the lower die holder 32. Since the steel strip is partially positioned in the support groove of the floating pin 4, the movement of the floating pin 4 towards the lower die holder 32 drives the entire steel strip to move closer to the lower die holder 32, bringing it closer to the lower die core 22 and the clamping assembly 11. This improves the efficiency of the upper and lower die cores 21 and 22 in pressing the steel strip, as well as the efficiency of the pressing component 12 in pushing the metal part into the clamping assembly 11. This avoids situations where the distance between the steel strip and the lower die holder 32 is too large, and the upper die holder 31 moves closer to the lower die holder 32, pushing the steel strip towards the lower die holder 32 while the floating pin 4 remains stationary, causing the steel strip to detach from the floating pin 4 and affecting subsequent operations. This improves the orderly operation of the processing equipment A.

[0074] At the same time, as the floating pin 4 moves closer to the lower mold frame 32, it will compress the second elastic element. As the upper mold frame 31 moves away from the lower mold frame 32, the force exerted by the upper mold frame 31 on the floating pin 4 disappears, and the second elastic element will return to its original length, exerting a force on the floating pin 4 away from the lower mold frame 32. The floating pin 4 drives the steel strip to return to its initial position, waiting for the next action.

[0075] By setting the second elastic element, the number of drive motors for the floating pin 4 can be reduced, simplifying the device setup in the processing equipment A and improving the practicality of the processing equipment A.

[0076] Optionally, the clamping assembly 11 includes a first clamping block 111, a second clamping block 112, a third clamping block (not shown), and a fourth clamping block (not shown). The first clamping block 111 and the second clamping block 112 are spaced apart along the extension direction of the steel strip, and the third clamping block and the fourth clamping block are spaced apart along a direction perpendicular to the extension direction of the steel strip. The first clamping block 111, the second clamping block 112, the third clamping block, and the fourth clamping block form a clamping position 11a, and the end of the first clamping block 111, the second clamping block 112, the third clamping block, and the fourth clamping block away from the pressing member 12 forms a receiving cavity 11b. Through the cooperation of the first clamping block 111, the second clamping block 112, the third clamping block, and the fourth clamping block, the metal part can be positioned and accommodated, improving the riveting efficiency of the riveting device 1 for the metal part.

[0077] Optionally, the metal parts are provided with buckles and slots on opposite sides. The riveting assembly 13 includes a first riveting pin 131a and a second riveting pin 131b. The first riveting pin 131a is inserted into the first clamping block 111, and the second riveting pin 131b is inserted into the second clamping block 112.

[0078] The first riveting pin 131a and the second riveting pin 131b are symmetrically arranged along the central axis of the clamping assembly 11. The first riveting pin 131a and the second riveting pin 131b are used to rivet the opposite sides of the metal part at the same time.

[0079] Specifically, the riveting assembly 13 may also include two driving members 132, each driving member 132 corresponding to a riveting pin 131. After the pressing member 12 pushes the metal part to be riveted into the clamping position 11a, the two driving members 132 simultaneously move in the vertical direction toward the corresponding riveting pin 131 to drive the first riveting pin 131a and the second riveting pin 131b to move toward the clamping position 11a. Since the first riveting pin 131a and the second riveting pin 131b are symmetrically arranged with respect to the central axis of the clamping assembly 11, that is, the first riveting pin 131a and the second riveting pin 131b are symmetrically arranged with respect to the central axis of the metal part on the clamping position 11a, under the action of the driving member 132, the first riveting pin 131a and the second riveting pin 131b will move towards each other to squeeze the buckles on opposite sides of the metal part, thereby riveting the buckles on opposite sides of the metal part to opposite sides of another metal part, thus improving the stability of the metal part riveting.

[0080] Optionally, the end of the first clamping block 111 away from the pressing member 12 is provided with a metal part guide surface (not shown). The metal part guide surface extends axially towards the first clamping block 111 to guide the riveted metal parts, so that the metal product formed after riveting is bent. Specifically, such as Figure 2 or Figure 4 As shown, due to the guiding effect of the metal guide surface on the riveted metal parts, the resulting metal product is bent, which can meet the different needs of users for metal products and improve the user experience of the riveting device 1.

[0081] In summary, by integrating the stamping device 2 and the riveting device 1 onto the same processing equipment A, the stamping device 2 can stamp the steel strip into a metal part, and the riveting device 1 can then rivet the metal part to form a metal product. This improves the processing efficiency of the processing equipment A for metal products and enhances the user experience of the processing equipment A.

[0082] Meanwhile, the riveting device 1 of this application achieves automation of metal part riveting through the cooperation of clamping component 11, pressing component 12 and riveting component 13, reduces the manual intervention rate in the metal part riveting process, reduces errors caused by manual intervention, improves the riveting efficiency of metal parts, improves the practicality of riveting device 1 and enhances the user's experience of using riveting device 1.

[0083] The above description is merely an embodiment of this application and does not limit the patent scope of this application. Any equivalent structural or procedural transformations made using the content of this application's specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this application.

Claims

1. A processing equipment, characterized in that, The equipment is used to process steel strips into metal products, the metal products comprising multiple riveted metal parts, each metal part having at least one buckle and at least one slot; the processing equipment includes a stamping device, a riveting device, and a die frame. The stamping device and the riveting device are spaced apart on the mold frame. The stamping device is used to stamp the steel strip to form the metal part. The riveting device is used to rivet the buckle of the metal part to the slot of another metal part, so that multiple metal parts are riveted together to form the metal product.

2. The processing equipment according to claim 1, characterized in that, The riveting device includes: A clamping assembly has a clamping position and a receiving cavity, wherein the clamping position and the receiving cavity are arranged sequentially along the height direction of the clamping assembly; the clamping position is used to place the metal part to be riveted, and the receiving cavity is used to place the riveted metal part. A pressing member, positioned above the clamping assembly, is used to push the metal part to be riveted into the clamping position; A riveting assembly, partially inserted into the clamping assembly, is used to rivet the buckle of the riveted metal part to the slot of the metal part to be riveted, so as to rivet the metal part to be riveted to the riveted metal part.

3. The processing equipment according to claim 2, characterized in that, The mold frame includes an upper mold frame and a corresponding lower mold frame. The stamping device includes an upper mold core and a corresponding lower mold core. The upper mold core is disposed on the upper mold frame, and the lower mold core is disposed on the lower mold frame. The clamping assembly is disposed within the lower mold frame and spaced apart from the lower mold core; The lower pressing component is installed on the upper mold frame and is spaced apart from the upper mold core; The upper die frame is used to move toward the lower die frame to move the upper die core closer to the lower die core, to stamp the steel strip to form the metal part, and to move the lower pressing member closer to the clamping assembly to push the metal part onto the clamping assembly.

4. The processing equipment according to claim 3, characterized in that, The riveting assembly includes at least one riveting pin, which is inserted through the clamping assembly and slidably disposed with respect to the clamping assembly. The riveting pin is used to move close to the clamping position to press the buckle of the riveted metal part, thereby riveting the buckle of the riveted metal part to the slot of the metal part to be riveted, so as to rivet the metal part to be riveted to the riveted metal part.

5. The processing equipment according to claim 4, characterized in that, The riveting pin is provided with a first guide surface; The riveting assembly further includes at least one driving member, the first end of which is disposed on the upper mold frame, and the second end of which is provided with a second guide surface; The first guide surface and the second guide surface are arranged in parallel; The driving component is used to drive the riveting pin to move closer to the clamping position through the cooperation of the first guide surface and the second guide surface.

6. The processing equipment according to claim 4, characterized in that, The riveting assembly further includes a first elastic element, abutting the first end of the first elastic element with the riveting pin and the second end of the first elastic element with the clamping assembly. When the riveting pin moves closer to the clamping position, the first elastic element is compressed.

7. The processing equipment according to claim 3, characterized in that, The processing equipment also includes a plurality of floating pins, which are spaced apart along the extension direction of the steel strip on the surface of the lower mold frame near the upper mold frame, and the plurality of floating pins are located on both sides of the steel strip. The floating pin has a support groove on its side, the edge of the steel strip is located in the support groove, and the height of the support groove is greater than the thickness of the steel strip.

8. The processing equipment according to claim 7, characterized in that, The processing equipment also includes a plurality of second elastic elements, one end of which is connected to the corresponding floating pin, and the other end of which is connected to the lower mold frame; The upper mold frame is used to move closer to the lower mold frame, so as to drive the floating pin to move closer to the lower mold frame, compress the second elastic element, and drive the steel strip to move closer to the lower mold frame.

9. The processing equipment according to claim 2, characterized in that, The clamping assembly includes a first clamping block, a second clamping block, a third clamping block, and a fourth clamping block. The first clamping block and the second clamping block are spaced apart along the extension direction of the steel strip, and the third clamping block and the fourth clamping block are spaced apart along the width direction of the steel strip. The first clamping block, the second clamping block, the third clamping block, and the fourth clamping block surround and form the clamping position.

10. The processing equipment according to claim 9, characterized in that, The metal part is provided with the buckle and the slot on both sides opposite to each other. The riveting assembly includes a first riveting pin and a second riveting pin. The first riveting pin passes through the first clamping block, and the second riveting pin passes through the second clamping block. The first riveting pin and the second riveting pin are symmetrically arranged along the central axis of the clamping assembly, and the first riveting pin and the second riveting pin are used to simultaneously rivet the opposite sides of the metal part.