An electrical connector and production apparatus

CN224472736UActive Publication Date: 2026-07-07SUNWAY COMM JIANGSU CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SUNWAY COMM JIANGSU CO LTD
Filing Date
2025-06-18
Publication Date
2026-07-07

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  • Figure CN224472736U_ABST
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Abstract

The application relates to the technical field of electric connectors, in particular to an electric connector and a production device. The electric connector comprises a first component and a second component, and the first component is provided with a riveting hole. The second component is provided with a riveting part, the riveting part is provided with a through hole penetrating through the second component, the riveting part penetrates through the riveting hole and is riveted with the riveting hole. The riveting hole and the through hole are both circular holes, the riveting hole and the through hole correspond to each other, the riveting part surrounds the through hole and is in the form of a circular ring. The electric connector of the application can simplify the operation process and improve the riveting precision through the riveting mode of the circular riveting hole and the circular riveting part.
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Description

Technical Field

[0001] This application relates to the field of electrical connector technology, and in particular to an electrical connector and manufacturing equipment. Background Technology

[0002] Electrical connectors typically consist of several components, and two components are usually connected by riveting. Currently, for components A and B that need to be riveted, a square hole is usually set in component A and a bending rivet is set in component B. The bending rivet of component B needs to be inserted into the square hole of component A for riveting first, and then the bending rivet is pressed again to make the bending rivet fit against component A.

[0003] However, during the riveting process between the square hole and the bending rivet, the bending rivet has a high degree of deformation, which easily generates metal wires and metal shavings, requiring cleaning and making the operation more cumbersome. The square hole and the bending rivet have a large fitting gap, resulting in low fitting accuracy. Considering the riveting tightness, the bending rivet needs to be tightened again after riveting, which makes the operation more cumbersome. Utility Model Content

[0004] In view of the above problems, this application provides an electrical connector and manufacturing equipment that overcomes or at least partially solves the above problems.

[0005] According to one aspect of this application, an electrical connector is provided, including a first component and a second component. The first component has a riveting hole. The second component has a riveting portion with a through hole penetrating the second component. The riveting portion passes through the riveting hole and is riveted to the riveting hole. Both the riveting hole and the through hole are circular holes, corresponding to each other, and the riveting portion surrounds the through hole in an annular shape.

[0006] In some embodiments, the first component is provided with a first positioning hole, and the second component is provided with a second positioning hole, the first positioning hole and the second positioning hole corresponding to each other.

[0007] According to one aspect of this application, a production apparatus is provided for manufacturing the aforementioned electrical connector. The production apparatus includes a support assembly, riveting positioning pins, and rivet pins. The support assembly is used to hold a first component and a second component of the electrical connector. The riveting positioning pins are used to position the second component and the first component. The rivet pins are used to rivet a riveted portion of the second component, so that the riveted portion is riveted to a riveting hole in the first component. During operation of the production apparatus, the riveting positioning pins pass through a second positioning hole in the second component and a first positioning hole in the first component to position the second component and the first component. The rivet pins rivet the riveted portion passing through the riveting hole, so that the riveted portion is riveted to the riveting hole.

[0008] In some embodiments, the production equipment further includes a cutting punch for cutting a first component. The support assembly includes a first support plate and a second support plate. The first support plate is vertically positioned above the second support plate and is used to place the first component. The second support plate is used to place the second component. After the riveting positioning pin passes through the second positioning hole and the first positioning hole, the cutting punch and the riveting pin move downwards vertically. The cutting punch cuts the first component on the first support plate and pushes the cut first component along the riveting positioning pin onto the surface of the second component on the second support plate, so that the riveting portion passes through the riveting hole.

[0009] In some embodiments, the production equipment further includes a cutting active module, a force transmission pin, a strong spring, and a drive module. The cutting punch is fixed to the cutting active module, one end of the force transmission pin is connected to the cutting active module, and the other end of the force transmission pin is connected to the strong spring. The strong spring is fixed to the drive module, and the drive module is used to drive the cutting active module to move in the vertical direction, thereby driving the cutting punch to move in the vertical direction.

[0010] In some embodiments, the production equipment further includes a first fixed plate, a stop block, and a limiting post. The first fixed plate is located below the drive module in the vertical direction. The stop block is fixed to the first fixed plate by the limiting post. When the cutting punch pushes the first component to the surface of the second component in the vertical direction, the drive module moves to the surface of the stop block. The stop block can prevent the drive module from continuing to move downward in the vertical direction.

[0011] In some embodiments, the production equipment further includes a cutting and positioning module, which is movably disposed above the first support plate in the vertical direction. Before the cutting punch cuts the first part, the cutting and positioning module can move to the surface of the first part to position the first part.

[0012] In some embodiments, the bottom of the cutting positioning module is provided with a groove, and the production equipment also includes a cutting positioning pin, which is fixed in the groove. During the process of the cutting positioning module moving to the surface of the first component, the cutting positioning pin passes through the third positioning hole of the first component to position the first component.

[0013] In some embodiments, the production equipment further includes a driven slider, a reset slider, a cutting tool, a push rod, and a first surface. The riveting positioning pin is fixed to the driven slider, the driven slider is disposed on the reset slider, the reset slider is movably disposed on the first surface, the first surface is perpendicular to the vertical direction, one end of the cutting tool is used to abut against the reset slider, and the other end of the cutting tool is fixed with a push rod, the push rod is used to drive the cutting tool so that the cutting tool pushes the reset slider to move on the first surface so that the riveting positioning pin corresponds to the second positioning hole and the first positioning hole.

[0014] In some embodiments, the production equipment further includes a return spring and a first wall, with one end of the return spring fixed to the first wall and the other end connected to the return slider. When the inserter pushes the return slider, the return spring deforms and generates a force. When the riveting part is riveted to the riveting hole and the inserter stops pushing the return slider, the return spring, under the action of the force, drives the return slider to return to its initial position.

[0015] The beneficial effects of this application are as follows: Unlike the prior art, this application provides an electrical connector including a first component and a second component. The first component is provided with a riveting hole. The second component is provided with a riveting part, which has a through hole penetrating the second component. The riveting part passes through the riveting hole and is riveted to the riveting hole. In this design, both the riveting hole and the through hole are circular, corresponding to each other. The riveting part surrounds the through hole in a ring shape. The high alignment accuracy of the circular riveting hole and the ring-shaped riveting part improves the precision of the riveting part's insertion into the riveting hole. During the riveting process, the riveting part can be pressed through the riveting hole using a rivet. The rivet can first be inserted into the through hole for alignment with the riveting part. The high alignment accuracy between the circular through hole and the rivet improves the precision of the rivet pressing the riveting part, thereby improving the riveting precision between the riveting part and the riveting hole. Compared to square holes and bent riveting clamps, the riveting with circular riveting holes and ring-shaped riveting parts is more secure, with less deformation of the riveting part, reducing the generation of metal wires and metal chips, simplifying the operation, and eliminating the need for secondary tightening of the riveting part, further simplifying the operation. The electrical connector of this application, through the riveting method of circular riveting holes and ring-shaped riveting parts, simplifies the operation process and improves the riveting precision. Attached Figure Description

[0016] To more clearly illustrate the technical solution of this application, the drawings used in this application will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the drawings without creative effort.

[0017] Figure 1 This is a top view of commonly used electrical connectors;

[0018] Figure 2 yes Figure 1 A cross-sectional view of the electrical connector;

[0019] Figure 3 yes Figure 1 Top view of component A;

[0020] Figure 4 yes Figure 3 A sectional view of component A;

[0021] Figure 5 yes Figure 1Top view of component B;

[0022] Figure 6 yes Figure 5 A sectional view of component B;

[0023] Figure 7 This is a top view of the electrical connector provided in an embodiment of this application;

[0024] Figure 8 yes Figure 7 A cross-sectional view of the electrical connector;

[0025] Figure 9 yes Figure 7 Top view of the first component;

[0026] Figure 10 yes Figure 9 A sectional view of the first component;

[0027] Figure 11 yes Figure 7 Top view of the second component;

[0028] Figure 12 yes Figure 11 A sectional view of the second component;

[0029] Figure 13 This is a side view of the production equipment provided in this application embodiment when the riveting pin is pressing the riveting part;

[0030] Figure 14 yes Figure 13 A front view of the production equipment;

[0031] Figure 15 This is a front view of the production equipment provided in the embodiments of this application when the sleeve support drive module is in use;

[0032] Figure 16 This is a perspective view of the production equipment provided in the embodiments of this application;

[0033] Figure 17 yes Figure 16 Enlarged view of part A.

[0034] The reference numerals in the detailed embodiments are as follows:

[0035] 1. Electrical connector; 11. First component; 111. Riveting hole; 112. First positioning hole; 12. Second component; 121. Riveting part; 1211. Through hole; 122. Second positioning hole; 1a. Component A; 1a1. Square hole; 1b. Component B; 1b1. Bending rivet;

[0036] 2. Production equipment; 21. Support assembly; 211. First support plate; 212. Second support plate; 22. Positioning assembly; 221. Top rod; 222. Inserting knife; 223. Reset slider; 224. Driven slider; 225. Riveting positioning pin; 226. Reset spring; 227. First surface; 228. First wall; 23. Drive assembly; 231. Drive module; 232. Strong spring; 233. Force transmission pin; 2 4. Cutting assembly; 241. Cutting active module; 242. Cutting punch; 243. Cutting positioning module; 2431. Groove; 244. Cutting positioning pin; 25. Riveting assembly; 251. Riveting active module; 252. Rivet pin; 26. Limiting assembly; 261. First fixing plate; 262. Stop block; 263. Limiting post; 264. Second fixing plate; 265. Sleeve; X, vertical direction; Y, first direction. Detailed Implementation

[0037] To facilitate understanding of this utility model, a more detailed description is provided below with reference to the accompanying drawings and specific embodiments. It should be noted that when an element is described as being "fixed to" another element, it can be directly on the other element, or one or more intermediate elements may exist between them. When an element is described as being "connected" to another element, it can be directly connected to the other element, or one or more intermediate elements may exist between them. The terms "vertical," "horizontal," "left," "right," and similar expressions used in this specification are for illustrative purposes only.

[0038] Unless otherwise defined, all technical and scientific terms used in this specification have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used in this specification is for the purpose of describing particular embodiments only and is not intended to limit the scope of the invention. The term "and / or" as used in this specification includes any and all combinations of one or more of the associated listed items.

[0039] Please see Figures 1-6Electrical connector 1 typically comprises several components, and the two components are usually connected electrically by riveting. Currently, for components A 1a and B 1b that need to be riveted, a square hole 1a1 is usually provided in component A 1a, and a bent rivet 1b1 is provided in component B 1b. First, the bent rivet 1b1 of component B 1b needs to be inserted into the square hole 1a1 of component A 1a for riveting, and then the bent rivet 1b1 is tightened a second time to make it fit against component A 1a. However, during the riveting process between the square hole 1a1 and the bent rivet 1b1, due to the high degree of deformation of the bent rivet 1b1, metal wires and metal shavings are easily generated, requiring cleaning, making the operation cumbersome. Furthermore, there is a large gap between the square hole 1a1 and the bent rivet 1b1, resulting in low fitting accuracy. Considering the riveting tightness, the bent rivet 1b1 needs to be tightened a second time after riveting, further complicating the operation.

[0040] The electrical connector of this application uses a riveting method with a circular riveting hole and a ring-shaped riveting part, which can simplify the operation process and improve the riveting accuracy.

[0041] To facilitate the reader's understanding of the inventive concept of this utility model, the specific structure of the electrical connector is described below:

[0042] Please see Figures 7-12 The electrical connector 1 includes a first component 11 and a second component 12. The first component 11 is provided with a riveting hole 111. The second component 12 is provided with a riveting part 121, which has a through hole 1211 penetrating through the second component 12. The riveting part 121 passes through the riveting hole 111 and is riveted to it. Both the riveting hole 111 and the through hole 1211 are circular holes, corresponding to each other. The riveting part 121 surrounds the through hole 1211 in a ring shape. The circular riveting hole 111 and the ring-shaped riveting part 121 have high alignment accuracy, improving the accuracy of the riveting part 121 inserting into the riveting hole 111. During the riveting process, a rivet 252 can be used to press the riveting part 121 through the riveting hole 111. The rivet 252 can first be inserted into the through hole 1211 to align with the riveting part 121. The high alignment accuracy of the circular through hole 1211 and the rivet pin 252 improves the accuracy of the rivet pin 252 in riveting the riveted part 121, thereby improving the riveting accuracy between the riveted part 121 and the riveting hole 111. The riveting of the circular riveting hole 111 and the annular riveting part 121 is more secure than that of the square hole and the bent rivet 1b1. The deformation of the riveting part 121 is lower, reducing the generation of metal wires and metal chips, simplifying the operation. Furthermore, the riveting part 121 does not require secondary tightening, further simplifying the operation. The electrical connector 1 of this application, through the riveting method of the circular riveting hole 111 and the annular riveting part 121, simplifies the operation process and improves the riveting accuracy.

[0043] In some embodiments, the first component 11 is provided with a first positioning hole 112, and the second component 12 is provided with a second positioning hole 122. The first positioning hole 112 and the second positioning hole 122 correspond to each other. The first positioning hole 112 and the second positioning hole 122 can assist in the positioning of the riveting part 121 and the riveting hole 111, and can improve the riveting accuracy of the riveting part 121 and the riveting hole 111.

[0044] Please see Figures 13-14 According to one aspect of this application, a production apparatus 2 is provided for producing the aforementioned electrical connector 1. The production apparatus 2 includes a support assembly 21, a positioning assembly 22, a drive assembly 23, a cutting assembly 24, a riveting assembly 25, and a limiting assembly 26. The support assembly 21 is used to place the first component 11 and the second component 12 of the electrical connector 1. The positioning assembly 22 is used to position the first component 11 and the second component 12. The drive assembly 23 is used to drive the cutting assembly 24 and the riveting assembly 25. The cutting assembly 24 is used to cut the first component 11, the riveting assembly 25 is used to rivet the first component 11 and the second component 12, and the limiting assembly 26 is used to limit the cutting assembly 24. The production apparatus 2 of this application can complete the cutting of the first component 11 and the riveting of the first component 11 and the second component 12 in one operation, thereby improving production efficiency.

[0045] In some embodiments, the positioning assembly 22 includes a riveting positioning pin 225, which is used to position the second component 12 and the first component 11, thereby improving the riveting accuracy of the first component 11 and the second component 12. The riveting assembly 25 includes a rivet 252, which is used to rivet the riveting portion 121 of the second component 12 so that the riveting portion 121 is riveted to the riveting hole 111 of the first component 11. During the operation of the production equipment 2, the riveting positioning pin 225 passes through the second positioning hole 122 of the second component 12 and the first positioning hole 112 of the first component 11 to position the second component 12 and the first component 11. The rivet 252 passes through the through hole 1211 of the second component 12 to position the riveting portion 121 of the second component 12. Then the rivet 252 rivets the riveting portion 121 through the riveting hole 111 so that the riveting portion 121 extends from inside the through hole 1211 to outside the through hole 1211 so that the riveting portion 121 is riveted to the riveting hole 111.

[0046] In some embodiments, the riveting assembly 25 includes a riveting active module 251, which is located above the cutting active module 241 in the vertical direction X. A rivet 252 is fixed to the riveting active module 251, and the riveting active module 251 is used to drive the rivet 252 to move in the vertical direction X.

[0047] In some embodiments, the cutting assembly 24 includes a cutting punch 242 for cutting the first component 11. The support assembly 21 includes a first support plate 211 and a second support plate 212. The first support plate 211 is disposed above the second support plate 212 in the vertical direction X. The first support plate 211 is used to place the first component 11, and the second support plate 212 is used to place the second component 12. After the riveting positioning pin 225 passes through the second positioning hole 122 and the first positioning hole 112, the cutting punch 242 and the rivet pin 252 move downwards in the vertical direction X. The cutting punch 242 cuts the first component 11 of the first support plate 211 and pushes the cut first component 11 along the riveting positioning pin 225 to the surface of the second component 12 of the second support plate 212, so that the riveting part 121 passes through the riveting hole 111. Before the first component 11 is pushed to the surface of the second component 12, the bottom of the rivet pin 252 is higher than the bottom of the cutting punch 242. After the first component 11 is pushed onto the surface of the second component 12, the riveting active module drives the rivet pin 252 to move downwards in the vertical direction X, so that the bottom of the rivet pin 252 is lower than the bottom of the cutting punch 242. Then, the rivet pin 252 passes through the through hole 1211 and rivets the riveting portion 121 that passes through the riveting hole 111. The first component 11 can move on the first support plate 211 in the first direction Y, and the second component 12 can move on the second support plate 212 in the first direction Y, which is perpendicular to the vertical direction X.

[0048] In some embodiments, the cutting punch 242 is provided with a first hole (not shown in the figure), and the rivet 252 is movably disposed in the first hole, and the rivet 252 can pass through the first hole to rivet the riveting part 121.

[0049] In some embodiments, the cutting assembly 24 includes a cutting movable module 241, and the driving assembly 23 includes a force transmission pin 233, a strong spring 232, and the driving module 231. The cutting punch 242 is fixed to the cutting movable module 241. One end of the force transmission pin 233 is connected to the cutting movable module 241, and the other end is connected to the strong spring 232. The strong spring 232 is fixed to the driving module 231. The driving module 231 drives the cutting movable module 241 to move in the vertical direction X, thereby driving the cutting punch 242 to move in the vertical direction X. The strong spring 232 provides a cutting force to the cutting punch 242 to cut the first component 11.

[0050] In some embodiments, the limiting component 26 includes a first fixing plate 261, a stop block 262, and a limiting post 263. The first fixing plate 261 is located below the drive module 231 in the vertical direction X. The stop block 262 is fixed to the first fixing plate 261 by the limiting post 263. When the cutting punch 242 pushes the first component 11 downward in the vertical direction X to the surface of the second component 12, the drive module 231 moves to the surface of the stop block 262. The stop block 262 can prevent the drive module 231 from continuing to move downward in the vertical direction X, which can reduce the possibility of the cutting punch 242 damaging the first component 11 and the second component 12.

[0051] In some embodiments, please refer to the following: Figure 15 The limiting component 26 includes a second fixing plate 264 and a sleeve 265. The second fixing plate 264 is located below the drive module 231 in the vertical direction X. When the production equipment 2 is not in operation, the user can place the sleeve 265 between the second fixing plate 264 and the drive module 231 so that the sleeve 265 can support the drive module 231 and reduce the possibility of the drive module 231 falling downward in the vertical direction X under its own weight or external force.

[0052] In some embodiments, please refer to the following: Figures 16-17 The cutting component 24 includes a cutting positioning module 243, which is movably disposed above the first support plate 211 in the vertical direction X. Before the cutting punch 242 cuts the first component 11, the cutting positioning module 243 can move to the surface of the first component 11 to position the first component 11, which can improve the accuracy of the cutting punch 242 in cutting the first component 11.

[0053] In some embodiments, the cutting positioning module 243 is provided with a second hole (not shown in the figure), through which the cutting punch 242 can cut the first component 11.

[0054] In some embodiments, the bottom of the cutting positioning module 243 is provided with a groove 2431, and the production equipment 2 also includes a cutting positioning pin 244. The cutting positioning pin 244 is fixed in the groove 2431. During the process of the cutting positioning module 243 moving to the surface of the first component 11, the cutting positioning pin 244 passes through the third positioning hole of the first component 11 to position the first component 11, which can further improve the accuracy of the cutting punch 242 cutting the first component 11.

[0055] In some embodiments, the first support plate 211 is provided with a third hole (not shown in the figure). After the cutting positioning pin 244 passes through the third positioning hole, it can pass through the third hole, which can reduce the possibility of the cutting positioning pin 244 squeezing the first support plate 211 and damaging the equipment.

[0056] In some embodiments, the positioning component 22 includes a driven slider 224, a reset slider 223, a insert 222, a push rod 221, and a first surface 227. A riveting positioning pin 225 is fixed to the driven slider 224, the driven slider 224 is disposed on the reset slider 223, and the reset slider 223 is movably disposed on the first surface 227, which is perpendicular to the vertical direction X. One end of the insert 222 is used to abut against the reset slider 223, and the other end of the insert 222 is fixed with a push rod 221. The push rod 221 is used to drive the insert 222 so that the insert 222 pushes the reset slider 223 to move on the first surface 227, so that the riveting positioning pin 225 corresponds to the second positioning hole 122 and the first positioning hole 112.

[0057] In some embodiments, the positioning component 22 includes a return spring 226 and a first wall 228. One end of the return spring 226 is fixed to the first wall 228, and the other end of the return spring 226 is connected to the return slider 223. When the inserter 222 pushes the return slider 223, the return spring 226 deforms and generates a force. When the riveting part 121 and the riveting hole 111 are riveted together, and the inserter 222 stops pushing the return slider 223, the return spring 226, under the action of the force, drives the return slider 223 to return to its initial position.

[0058] To facilitate the reader's understanding of the inventive concept of this utility model, the working process of the production equipment 2 is described below:

[0059] When production equipment 2 is not in operation, sleeve 265 is located between the second fixed plate 264 and drive module 231 to support drive module 231. During operation of production equipment 2, push rod 221 drives insert knife 222, causing insert knife 222 to push reset slider 223 to move on the first surface 227, so that riveting positioning pin 225 corresponds to the second positioning hole 122 and the first positioning hole 112; driven module drives riveting positioning pin 225 to pass through the second positioning hole 122 and the first positioning hole 112 to position the first component 11 and the second component 12; cutting positioning module 243 moves to the surface of the first component 11, and cutting positioning pin 244 passes through the third positioning hole of the first component 11 to position the first component 11; when the user removes sleeve 265, drive module 231 drives cutting motion module 241 to move downward in the vertical direction X, thereby driving cutting punch 242 to move downward in the vertical direction X, and cutting punch 242 moves to the first support plate 211. The first component 11 is cut and the cut first component 11 is pushed along the riveting positioning pin 225 to the surface of the second component 12 of the second support plate 212 so that the riveting part 121 passes through the riveting hole 111; the stop block 262 prevents the drive module 231 from continuing to move downward in the vertical direction X; the riveting active module 251 drives the rivet pin 252 to pass through the through hole 1211 to rivet the riveting part 121 that passes through the riveting hole 111 so that the riveting part 121 is riveted to the riveting hole 111; after the riveting part 121 and the riveting hole 111 are riveted, the driven slider 224 drives the riveting positioning pin 225 to exit the second positioning hole 122 and the first positioning hole 112, the push rod 221 drives the insert knife 222 to return to the initial position, and the return spring 226 drives the return slider 223 to return to the initial position under the action of the force.

[0060] It should be noted that while the preferred embodiments of this utility model are provided in the specification and accompanying drawings, this utility model can be implemented in many different forms and is not limited to the embodiments described herein. These embodiments are not intended to impose additional limitations on the content of this utility model; their purpose is to provide a more thorough and comprehensive understanding of the disclosure of this utility model. Furthermore, the above-described technical features can be combined with each other to form various embodiments not listed above, all of which are considered to be within the scope of this utility model specification. Moreover, those skilled in the art can make improvements or modifications based on the above description, and all such improvements and modifications should fall within the protection scope of the appended claims.

Claims

1. An electrical connector, characterized in that, include: The first component is provided with rivet holes; The second component is provided with a riveting part, the riveting part is provided with a through hole penetrating the second component, the riveting part passes through the riveting hole and is riveted to the riveting hole; Both the riveting hole and the through hole are circular holes, and the riveting hole and the through hole correspond to each other. The riveting part surrounds the through hole and is in a circular shape.

2. The electrical connector according to claim 1, characterized in that, The first component is provided with a first positioning hole, and the second component is provided with a second positioning hole, with the first positioning hole and the second positioning hole corresponding to each other.

3. A production equipment, characterized in that, The production equipment for manufacturing the electrical connector as described in any one of claims 1-2 includes: A support assembly for housing the first and second components of the electrical connector; Riveting positioning pins are used to position the second component and the first component; A rivet pin is used to rivet the riveting part of the second component so that the riveting part is riveted to the riveting hole of the first component; During the operation of the production equipment, the riveting positioning pin passes through the second positioning hole of the second component and the first positioning hole of the first component to position the second component and the first component. The rivet pin presses through the riveting hole to the riveting part so that the riveting part is riveted to the riveting hole.

4. The production equipment according to claim 3, characterized in that, The production equipment also includes a cutting punch for cutting the first component. The support assembly includes a first support plate and a second support plate. The first support plate is vertically positioned above the second support plate. The first support plate is used to place the first component, and the second support plate is used to place the second component. Wherein, after the riveting positioning pin passes through the second positioning hole and the first positioning hole, the cutting punch and the riveting pin move downward in the vertical direction, the cutting punch cuts the first component of the first support plate, and pushes the cut first component along the riveting positioning pin to the surface of the second component of the second support plate, so that the riveting part passes through the riveting hole.

5. The production equipment according to claim 4, characterized in that, The production equipment also includes a cutting module, a force transmission pin, a strong spring, and a drive module. The cutting punch is fixed to the cutting module. One end of the force transmission pin is connected to the cutting module, and the other end of the force transmission pin is connected to the strong spring. The strong spring is fixed to the drive module. The drive module is used to drive the cutting module to move in the vertical direction, thereby driving the cutting punch to move in the vertical direction.

6. The production equipment according to claim 5, characterized in that, The production equipment also includes a first fixed plate, a stop block, and a limiting post. The first fixed plate is located below the drive module in the vertical direction. The stop block is fixed to the first fixed plate by the limiting post. When the cutting punch pushes the first component downward in the vertical direction to the surface of the second component, the drive module moves to the surface of the stop block. The stop block can prevent the drive module from continuing to move downward in the vertical direction.

7. The production equipment according to claim 4, characterized in that, The production equipment also includes a cutting and positioning module, which is movably disposed above the first support plate in the vertical direction. Before the cutting punch cuts the first component, the cutting and positioning module can move to the surface of the first component to position the first component.

8. The production equipment according to claim 7, characterized in that, The bottom of the cutting and positioning module is provided with a groove, and the production equipment also includes a cutting and positioning pin. The cutting and positioning pin is fixed in the groove. During the process of the cutting and positioning module moving to the surface of the first component, the cutting and positioning pin passes through the third positioning hole of the first component to position the first component.

9. The production equipment according to claim 3, characterized in that, The production equipment further includes a driven slider, a reset slider, a cutting tool, a push rod, and a first surface. The riveting positioning pin is fixed to the driven slider, the driven slider is disposed on the reset slider, and the reset slider is movably disposed on the first surface. The first surface is perpendicular to the vertical direction. One end of the cutting tool is used to abut against the reset slider, and the other end of the cutting tool is fixed with the push rod. The push rod is used to drive the cutting tool so that the cutting tool pushes the reset slider to move on the first surface, so that the riveting positioning pin corresponds to the second positioning hole and the first positioning hole.

10. The production equipment according to claim 9, characterized in that, The production equipment also includes a return spring and a first wall. One end of the return spring is fixed to the first wall, and the other end of the return spring is connected to the return slider. When the inserter pushes the return slider to move, the return spring will deform and generate a force. When the riveting part is riveted to the riveting hole and the inserter stops pushing the return slider, the return spring will drive the return slider to its initial position under the action of the force.