A new automatic assembling machine for mobile phone keys

By designing a balancing mechanism and directional components, the problem of material tilting during mobile phone button assembly was solved, enabling precise and stable placement of materials and efficient automated production.

CN122165156APending Publication Date: 2026-06-09HUIZHOU ZHONGRUI INTELLIGENT EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
HUIZHOU ZHONGRUI INTELLIGENT EQUIP CO LTD
Filing Date
2026-04-30
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

During the assembly process, the removal of the grippers may cause the buttons to tilt, resulting in a misalignment of the installation position and affecting accuracy.

Method used

By employing a balancing mechanism and directional components, and through the coordinated action of clamping components, pressing components, reverse pushing components, driving components, and fixing components, the material is ensured to remain horizontal and stable during clamping and movement, reducing the impact of friction.

Benefits of technology

It improves the accuracy, stability, and consistency of material placement during the automatic assembly of mobile phone buttons, reduces labor costs, and increases production efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to the technical field of automatic assembly, and discloses a novel automatic mobile phone key assembling machine, which comprises a main body and a placing plate and further comprises a balancing mechanism, which is installed on the side wall of the main body and can reduce the inclination of the main body during movement. The two ends of the rubber plate move simultaneously, so that the pressure on the two sides of the material is the same, the friction between the top groove of the placing wheel and the side wall of the material is reduced when the material is clamped, the material is clamped and then inclined, the deviation of the material during placement is avoided, and the accuracy of the material placement position during automatic assembly of the mobile phone key is further improved.
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Description

Technical Field

[0001] This invention relates to the field of automatic assembly technology, specifically a novel automatic assembly machine for mobile phone buttons. Background Technology

[0002] The new type of automatic mobile phone button assembly machine is a core non-standard automated equipment in the electronic precision assembly process. It occupies a strategic position in the industry as a key process node, a core support for efficiency and quality, and a pioneer in domestic substitution. Its role is to completely replace manual labor, improve precision and consistency, reduce costs and increase efficiency, support flexible production, and play a long-term role as a technology benchmark, industrial upgrading, ecological driving force, and intelligent manufacturing foundation in the future. During the assembly process of mobile phone buttons, the processed buttons are usually removed from the mold and placed into the corresponding installation position by grippers. When the grippers remove the buttons from the mold, the side wall of the button will generate friction with the inner wall of the mold. Under the action of friction, the gripped button may rotate around the gripping point, which will cause it to tilt during the gripping process. When the tilted button is assembled, its lower side will contact the installation position first, which can easily cause the installation position to shift, thereby reducing the accuracy of the mobile phone button installation position. Summary of the Invention

[0003] The purpose of this invention is to provide a novel automatic mobile phone button assembly machine to solve the problems mentioned in the background art.

[0004] To solve the above-mentioned technical problems, the present invention is achieved through the following technical solution: This invention relates to a novel automatic mobile phone button assembly machine, comprising a main body and a placement plate, and further comprising: The balancing mechanism is installed on the side wall of the main body. The balancing mechanism can reduce the tilting of materials when the main body moves. The directional component is located at the bottom of the balancing mechanism. The directional component can reduce deviations that occur when the balancing mechanism moves.

[0005] Furthermore, the main body includes: The clamping assembly is located on the side wall of the main body. The clamping assembly can clamp the material and move it to a designated position. Placement components are positioned on top of the placement plate.

[0006] Furthermore, the balancing mechanism includes: A pressing component is located at the bottom of the clamping component; The reverse push component is located at the bottom of the pressing component. The reverse push component can reduce the chance of the pressing component pushing away the clamped material during operation.

[0007] Furthermore, the orientation component includes: The drive component is located at the bottom of the pressing component; The fixing component is located at the bottom of the pressing component. The operation of the fixing component can reduce the movement of materials pushed by the pressing component during operation.

[0008] Furthermore, the clamping assembly includes a sliding plate slidably connected to the side wall of the main body, and an actuating block is fixedly connected to the side wall of the sliding plate; The bottom of the starting block has two sliding connections, and the sliding blocks are symmetrically distributed around the sliding plate. A clamping block is fixedly connected to the bottom of the moving block, and the clamping blocks are symmetrically distributed around the starting block; The side walls of the two moving blocks are rotatably connected to rubber plates.

[0009] Furthermore, the placement assembly includes a material bin fixedly connected to the top of the placement plate, and placement wheels are provided on the right side of the material bin, with the placement wheels fixedly connected to the top of the placement plate.

[0010] Furthermore, the pressing component includes a sliding groove formed inside the sliding plate, and a pushing block is slidably connected to the sliding groove; Two extrusion rods are provided at the bottom of the push block, and the extrusion rods are symmetrically distributed around the sliding groove. The extrusion rod is slidably connected to the inside of the sliding groove, and a contact head is fixedly connected to the side wall of the extrusion rod; The top of the extrusion rod contacts the side wall of the push block, and the outer surface of the contact head contacts the top of the rubber plate.

[0011] Furthermore, the reverse thrust assembly includes connecting rods fixedly connected to the bottom of the extrusion rod, and fixing plates are fixedly connected to the bottom of the two connecting rods; A spring piece is fixedly connected to the bottom of the fixed plate, and the spring piece is slidably connected to the inside of the clamping block; One end of the spring piece away from the fixed plate is fixedly connected to a movable block, and the movable block is slidably connected to the inside of the clamping block; The middle part of the first shrapnel has a V-shaped design.

[0012] Furthermore, the driving component includes a rotating rod rotatably connected to the side wall of the connecting rod, and a number of rubber blocks are fixedly connected to the end of the rotating rod away from the connecting rod; Several rubber blocks are equidistantly distributed around the rotating rod; The two rubber blocks located on the same side of the clamping block are arranged in a cross configuration.

[0013] Furthermore, the fixing component includes several blocking blocks fixedly connected to the top of the rubber plate; Several occlusion blocks are grouped in pairs and symmetrically distributed around the moving block; Each set of blocking blocks has two rotating spring contacts inside.

[0014] The present invention has the following beneficial effects: 1. In this invention, the extrusion rod gradually slides downward under the push of the push block. The downward sliding of the extrusion rod applies a downward pressure to the rubber plate through the contact head. At this time, the two ends of the rubber plate gradually approach the material surface, and the upward deformation of the middle of the rubber plate gives the rubber plate a certain supporting force. When the two ends of the rubber plate rotate downward, they provide a pushing force to the bottom material. Since the two ends of the rubber plate move simultaneously, the pressure on both sides of the material is the same, reducing the friction between the groove at the top of the placement wheel and the side wall of the material when the material is clamped, which causes the material to tilt after being clamped, resulting in deviation of the material during placement. This further improves the accuracy of the material placement position during the automatic assembly of mobile phone buttons.

[0015] 2. In this invention, the spring sheet 1 undergoes secondary deformation under the influence of the inner wall curvature of the clamping block and the pressure of the top push assembly. At this time, the end of the spring sheet 1 away from the fixed plate will move towards the connecting rod. The secondary deformation of the spring sheet 1 will drive the movable block to slide upward within the clamping block. Simultaneously, since the spring sheet 1 is V-shaped, the sliding of the movable block has a certain delay. When the movable block is about to slide upward, the end of the clamping block near the material has already contacted the side wall of the material. The relative movement of the two clamping blocks will form a clamping force on the material. At this time, the movable block will slide upward under the push of the deformation of the spring sheet 1. The two spring sheets 1 will move synchronously. At this time, the material will be subjected to an upward pushing force while being clamped by the clamping blocks on both sides. This reduces the situation where the material rotates around the clamping block when the rubber plate deforms downward and pushes the material to a horizontal state, causing the clamping point to change and the material to fall off. This further improves the stability of the material during the automatic assembly of the mobile phone buttons.

[0016] 3. In this invention, when the connecting rod is reset, the intersecting rotating rods will gradually open under the drive of the connecting rod. Since the rubber block set at the end of the rotating rod near the rubber plate will contact the bottom of the deformed rubber plate, when the intersection of the rotating rods gradually opens, the friction force generated between the rubber block and the bottom of the rubber plate will drive the top rubber plate to reset. At the same time, since the two sets are located on both sides of the clamping block, the reset of the clamping block will provide a stable support force for the top rubber plate, thereby reducing the asymmetry of the rubber plate when the sliding plate moves. Due to the setting of the rubber block, the rubber plate is less likely to fail to reset according to its own elasticity when the clamping block is held for a long time, resulting in a lack of subsequent material pushing force. This further improves the consistency of the deformation direction of the rubber plate and the smoothness of the reset when the mobile phone button is automatically assembled.

[0017] 4. In this invention, the rubber plates rotate on both sides and move closer to each other. At this time, the second spring sheet will deform under the influence of the two sides of the rubber plate moving closer to each other. At this time, the bottom of the second spring sheet moves closer to the material surface. Meanwhile, the rubber plate will bend under the pressure of the downward movement of the contact head. When the two ends of the rubber plate bend, the bottoms of the second spring sheet will move closer to each other, thereby forming a relative compressive force on the bottom material. This reduces the slippage that occurs when the rubber plate presses the bottom material, thereby further improving the accuracy of the material position during the automatic assembly of mobile phone buttons.

[0018] Of course, any product implementing this invention does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description

[0019] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0020] Figure 1 This is a schematic diagram of the overall structure of the present invention; Figure 2 This is a schematic diagram of the overall partial structure of the present invention; Figure 3 This is a schematic diagram of the clamping component of the present invention; Figure 4 This is a schematic diagram of the pressing component of the present invention; Figure 5 This is a schematic diagram of the reverse-engineering component of the present invention; Figure 6 This is a schematic diagram of the component driving the present invention; Figure 7 For the present invention Figure 6 Enlarged diagram of A in the middle; Figure 8 This is a schematic diagram of the fixing component of the present invention.

[0021] The attached diagram lists the components represented by each number as follows: In the diagram: 1. Main body; 11. Clamping assembly; 111. Sliding plate; 112. Starting block; 113. Moving block; 114. Clamping block; 115. Rubber plate; 12. Placement assembly; 121. Material bin; 122. Placement wheel; 2. Balancing mechanism; 21. Pressing assembly; 211. Sliding groove; 212. Pushing block; 213. Extrusion rod; 214. Contact head; 22. Reverse thrust assembly; 221. Connecting rod; 222. Fixing plate; 223. Spring piece one; 224. Moving block; 3. Orientation assembly; 31. Driving assembly; 311. Rotating rod; 312. Rubber block; 32. Fixing assembly; 321. Blocking block; 322. Spring piece two; 4. Placement plate. Detailed Implementation

[0022] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0023] Please see Figure 1 - Figure 8 As shown, the present invention is a novel automatic mobile phone button assembly machine, comprising a main body 1 and a placement plate 4, and further comprising: The balancing mechanism 2 is installed on the side wall of the main body 1. The balancing mechanism 2 can reduce the tilting of materials when the main body 1 moves. Orientation component 3 is located at the bottom of the balancing mechanism 2. The orientation component 3 can reduce deviations when the balancing mechanism 2 moves. Entity 1 includes: The clamping assembly 11 is disposed on the side wall of the main body 1. The clamping assembly 11 can clamp the material and move it to a specified position. Placement component 12 is positioned on top of placement plate 4; When the clamping component 11 is driven by an external drive device, it can clamp the material to be assembled and move it to a designated position. After the clamping component 11 moves to the designated position, the placement component 12 can place the processed material to the required position for assembly.

[0024] Balancing mechanism 2 includes: The pressing component 21 is disposed at the bottom of the clamping component 11; The reverse push component 22 is located at the bottom of the pressing component 21. The reverse push component 22 can reduce the situation where the pressing component 21 pushes away the clamped material during operation. The pressing component 21 presses down on the clamped material by the movement of the clamping component 11, keeping both ends of the material horizontal during clamping. At the same time, the movement of the pressing component 21 drives the counter-pushing component 22 to provide an upward pushing force to the clamped material, thereby counteracting the downward pressure from the pressing component 21 on the top of the material.

[0025] Orientation component 3 includes: Drive component 31, which is located at the bottom of the pressing component 21; The fixing component 32 is located at the bottom of the pressing component 21. The operation of the fixing component 32 can reduce the movement of materials pushed by the pressing component 21 during operation. The operation of the drive component 31 can pull and push the reset of the pressing component 21, so that the reset of the pressing component 21 after being under pressure for a long time can be carried out smoothly. At the same time, the fixing component 32 will squeeze the material on the placement component 12 towards the center when it is in operation.

[0026] The clamping assembly 11 includes a sliding plate 111 slidably connected to the side wall of the main body 1, and a starting block 112 is fixedly connected to the side wall of the sliding plate 111; The bottom of the starting block 112 is slidably connected to two moving blocks 113, which are symmetrically distributed with the sliding plate 111 as the center. A clamping block 114 is fixedly connected to the bottom of the moving block 113, and the clamping blocks 114 are symmetrically distributed with the starting block 112 as the center; Rubber plates 115 are rotatably connected to the side walls of the two moving blocks 113. The main body 1 moves to the top of the material bin 121 first. At this time, the sliding plate 111 on the side wall of the main body 1 will slide downward. When the sliding plate 111 slides to the designated position, the starting block 112 will be activated. The starting block 112 will cause the two moving blocks 113 at the bottom to move closer to each other. The movement of the moving blocks 113 will drive the clamping blocks 114 to move synchronously. The mutual approach of the clamping blocks 114 will form a clamping force on both sides of the material inside the material bin 121.

[0027] The placement assembly 12 includes a material bin 121 fixedly connected to the top of the placement plate 4. A placement wheel 122 is provided on the right side of the material bin 121. The placement wheel 122 is fixedly connected to the top of the placement plate 4. The sliding plate 111 slides upward. When the sliding plate 111 moves to the designated position, the main body 1 moves towards the placement wheel 122. After reaching the top of the placement wheel 122, the clamping block 114 gradually approaches the placement wheel 122 under the drive of the sliding plate 111 and places the material on the top of the placement wheel 122. Then, the bottom of the main body 1 processes the material on the top of the placement wheel 122. After processing, the clamping block 114 picks up the material and transfers it to the installation position to complete the assembly, thereby realizing automated production, reducing labor costs, and improving production efficiency and product stability.

[0028] The pressing component 21 includes a sliding groove 211 formed inside the sliding plate 111, and a pushing block 212 is slidably connected to the sliding groove 211; Two extrusion rods 213 are provided at the bottom of the push block 212, and the extrusion rods 213 are symmetrically distributed with the sliding groove 211 as the center; The extrusion rod 213 is slidably connected to the inside of the sliding groove 211, and the side wall of the extrusion rod 213 is fixedly connected to the contact head 214; The top of the extrusion rod 213 contacts the side wall of the push block 212, and the outer surface of the contact head 214 contacts the top of the rubber plate 115. The movement of the moving block 113 will drive the extrusion rod 213 synchronously. The two sets of extrusion rods 213 move relative to each other under the drive of the two moving blocks 113. The movement of the extrusion rod 213 will cause the contact head 214 on the side wall to extrude on both sides of the rubber plate 115. The rubber plate 115 will deform under the extrusion on both sides. At this time, the middle of the rubber plate 115 will bulge upward. At the same time, the push block 212 will apply a downward pushing force to the top of the extrusion rod 213. At this time, the extrusion rod 213 will gradually slide downward under the push of the push block 212.

[0029] The reverse thrust assembly 22 includes connecting rods 221 fixedly connected to the bottom of the extrusion rod 213, and fixing plates 222 are fixedly connected to the bottom of the two connecting rods 221. A spring piece 223 is fixedly connected to the bottom of the fixing plate 222, and the spring piece 223 is slidably connected to the inside of the clamping block 114; The end of the spring piece 223 away from the fixed plate 222 is fixedly connected to a movable block 224, and the movable block 224 is slidably connected to the inside of the clamping block 114. Among them, the middle part of the spring piece 223 is designed in a V shape. The descent of the connecting rod 221 will push the fixing plate 222 to descend smoothly. The descent of the fixing plate 222 will put downward pressure on the top of the spring piece 223. At this time, the V-shaped area in the middle of the spring piece 223 will gradually close under the influence of the continuous descent of the top fixing plate 222. When the V-shaped area in the middle of the spring piece 223 is closed, the top fixing plate 222 is still descending. At this time, the spring piece 223 will undergo secondary deformation under the influence of the inner wall curvature of the clamping block 114 and the pressure of the top push assembly 22.

[0030] The drive assembly 31 includes a rotating rod 311 rotatably connected to the side wall of the connecting rod 221, and a number of rubber blocks 312 are fixedly connected to one end of the rotating rod 311 away from the connecting rod 221. Several rubber blocks 312 are equidistantly distributed around the rotating rod 311; Two rubber blocks 312 located on the same side of the clamping block 114 are arranged in a cross configuration. The rotating rod 311 rotates around the rotating axis. When the rotating rod 311 rotates, the end of the rotating rod 311 near the rubber plate 115 will generate an upward pushing force on the center of the rubber plate 115. Since there are four rotating rods 311, every two intersecting rotating rods 311 will push the rubber plate 115 at two points simultaneously under the driving force of the descending connecting rod 221, thereby reducing the situation where the rubber plate 115's pushing ability on the material decreases due to the uncertainty of the deformation direction. When the connecting rod 221 is reset, the intersecting rotating rods 311 will gradually open under the driving force of the connecting rod 221.

[0031] The fixing component 32 includes several blocking blocks 321 fixedly connected to the top of the rubber plate 115; Several blocking blocks 321 are grouped in pairs and symmetrically distributed around the moving block 113; Each set of blocking blocks 321 is internally connected to a spring sheet 322. The two sides of the rubber plate 115 will bend downward under the influence of the central protrusion. The bending of the two sides of the rubber plate 115 will drive the blocking blocks 321 to move synchronously. The movement of the blocking blocks 321 will cause the spring sheet 322 to move closer to the material. As the rubber plates 115 move closer to each other while rotating on both sides, the spring sheet 322 will deform under the influence of the two sides of the rubber plate 115 moving closer to each other. At this time, the bottom of the spring sheet 322 will move closer to the material surface. At the same time, the rubber plate 115 will bend under the compression of the downward movement of the contact head 214.

[0032] In use, the operator first starts the equipment. After starting, the main body 1 moves to the top of the material bin 121. At this time, the sliding plate 111 on the side wall of the main body 1 slides downward. When the sliding plate 111 slides to the designated position, the starting block 112 is activated. The starting block 112 causes the two moving blocks 113 at the bottom to move closer to each other. The movement of the moving blocks 113 will drive the clamping blocks 114 to move synchronously. The close proximity of the clamping blocks 114 will form a clamping force on both sides of the material inside the material bin 121. Then the sliding plate 111... 11 Slides upward. When the sliding plate 111 moves to the designated position, the main body 1 moves towards the placement wheel 122. After reaching the top of the placement wheel 122, the clamping block 114 gradually approaches the placement wheel 122 under the drive of the sliding plate 111 and places the material on the top of the placement wheel 122. Then, the bottom of the main body 1 processes the material on the top of the placement wheel 122. After processing, the clamping block 114 picks up the material and moves it to the installation position to complete the assembly, thereby realizing automated production, reducing labor costs, and improving production efficiency and product stability.

[0033] When the moving blocks 113 approach each other, the sidewalls of the two pushing blocks 212 will press against each other under the influence of the movement of the moving blocks 113. At the same time, the movement of the moving blocks 113 will drive the pressing rods 213 synchronously. The two sets of pressing rods 213 move relative to each other under the drive of the two moving blocks 113. The movement of the pressing rods 213 will cause the contact heads 214 of the sidewalls to press against both sides of the rubber plate 115. The rubber plate 115 will deform under the pressure from both sides. At this time, the middle of the rubber plate 115 will bulge upward. At the same time, the pushing blocks 212 will apply a downward pushing force to the top of the pressing rods 213. The pressing rods 213 will gradually slide downward under the push of the pushing blocks 212. The contact head 214 applies a downward pressure to the rubber plate 115. At this time, the two ends of the rubber plate 115 gradually approach the material surface, and the upward deformation of the middle of the rubber plate 115 gives it a certain supporting force. When the two ends of the rubber plate 115 rotate downward, they provide a pushing force to the bottom material. Since the two ends of the rubber plate 115 move at the same time, the pressure on both sides of the material is the same. This reduces the friction between the top groove of the placement wheel 122 and the side wall of the material when the material is clamped, which would cause the material to tilt after being clamped, resulting in deviation of the material during placement. This further improves the accuracy of the material placement position during the automatic assembly of mobile phone buttons.

[0034] When the pressing rod 213 descends, it drives the connecting rod 221 at the bottom to move synchronously. The descent of the connecting rod 221 pushes the fixing plate 222 to descend smoothly. The descent of the fixing plate 222 causes the top of the spring piece 223 to be subjected to downward pressure. At this time, the V-shaped area in the middle of the spring piece 223 will gradually close under the influence of the continuous descent of the top fixing plate 222. When the V-shaped area in the middle of the spring piece 223 closes, the top fixing plate 222 is still descending. At this time, the spring piece 223 will undergo secondary deformation under the influence of the inner wall curvature of the clamping block 114 and the pressure of the top push assembly 22. The end of the spring piece 223 away from the fixing plate 222 will move towards the connecting rod 221. The secondary deformation of the spring piece 223 will drive the movable block 224 within the clamping block 114. As the movable block 224 slides upward, the V-shaped arrangement of the spring 223 delays its movement. When the movable block 224 slides upward, the end of the clamping block 114 closest to the material is already in contact with the side wall of the material. The relative movement of the two clamping blocks 114 creates a clamping force on the material. At this time, the movable block 224 slides upward under the deformation of the spring 223. The two springs 223 move synchronously. The material is subjected to the clamping force of the clamping blocks 114 on both sides and an upward pushing force. This reduces the possibility of the material falling off when the rubber plate 115 deforms downward and pushes the material to a horizontal state, causing the material to rotate around the clamping block 114. This further improves the stability of the material during the automatic assembly of the mobile phone buttons.

[0035] When the connecting rod 221 slides downward under the action of the extrusion rod 213, the movement of the connecting rod 221 will cause the rotating rod 311 to rotate around the rotating axis. When the rotating rod 311 rotates, the end of the rotating rod 311 near the rubber plate 115 will generate an upward pushing force on the center of the rubber plate 115. Since there are four rotating rods 311, every two intersecting rotating rods 311 will push the rubber plate 115 at two points simultaneously under the action of the descending connecting rod 221, thereby reducing the situation where the rubber plate 115's pushing ability on the material decreases due to the uncertainty of the deformation direction. When the connecting rod 221 resets, the intersecting rotating rods 311 will gradually open under the action of the connecting rod 221. Since the rubber block 312 set at the end of the rotating rod 311 near the rubber plate 115 will interact with the deformed rubber plate 115... When the bottom of the 5 contacts each other, as the rotating rod 311 gradually opens at the cross position, the friction generated between the rubber block 312 and the bottom of the rubber plate 115 will drive the top rubber plate 115 to reset. At the same time, since the two sets are located on both sides of the clamping block 114, the reset of the clamping block 114 will provide a stable support force for the top rubber plate 115, thereby reducing the asymmetry of the rubber plate 115 when the sliding plate 111 moves. Due to the setting of the rubber block 312, the rubber plate 115 is reduced from being unable to reset according to its own elasticity when the clamping block 114 has been clamped for a long time, resulting in the loss of subsequent pushing force on the material. This further improves the consistency of the deformation direction of the rubber plate 115 and the smoothness of the reset when the mobile phone button is automatically assembled.

[0036] When the middle of the rubber plate 115 deforms and bulges upward, the two sides of the rubber plate 115 will bend downward under the influence of the bulge. The bending of the two sides of the rubber plate 115 will cause the blocking block 321 to move synchronously. The movement of the blocking block 321 will cause the spring piece 322 to move closer to the material. Since the rubber plate 115 will move closer to each other while rotating on both sides, the spring piece 322 will deform under the influence of the two sides of the rubber plate 115 moving closer to each other. The bottom of the spring piece 322 will move closer to the surface of the material. At the same time, the rubber plate 115 will bend under the compression of the downward movement of the contact head 214. When the two ends of the rubber plate 115 bend, the bottoms of the spring piece 322 will move closer to each other, thereby forming a relative compressive force on the bottom material. This reduces the slippage that occurs when the rubber plate 115 presses the bottom material, thereby further improving the accuracy of the material position during the automatic assembly of the mobile phone buttons.

[0037] The preferred embodiments of the present invention disclosed above are merely illustrative of the invention. These preferred embodiments do not exhaustively describe all details, nor do they limit the invention to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of the invention, thereby enabling those skilled in the art to better understand and utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. A novel automatic mobile phone button assembly machine, comprising a main body (1) and a placement plate (4), characterized in that, Also includes: The balancing mechanism (2) is installed on the side wall of the main body (1). The balancing mechanism (2) can reduce the tilting of materials when the main body (1) moves. Orientation component (3) is located at the bottom of the balancing mechanism (2). The orientation component (3) can reduce the deviation that occurs when the balancing mechanism (2) moves.

2. The novel automatic mobile phone button assembly machine according to claim 1, characterized in that: The main body (1) includes: Clamping assembly (11) is disposed on the side wall of the main body (1). The clamping assembly (11) can clamp the material and move it to a specified position. Placement component (12) is disposed on top of placement plate (4).

3. A novel automatic mobile phone button assembly machine according to claim 2, characterized in that: The balancing mechanism (2) includes: A pressing component (21) is disposed at the bottom of the clamping component (11); The reverse push assembly (22) is located at the bottom of the pressing assembly (21). The reverse push assembly (22) can reduce the chance of the pressing assembly (21) pushing away the clamped material during operation.

4. A novel automatic mobile phone button assembly machine according to claim 3, characterized in that: The orientation component (3) includes: A drive component (31) is disposed at the bottom of the pressing component (21); The fixing component (32) is located at the bottom of the pressing component (21). The operation of the fixing component (32) can reduce the movement of materials pushed by the pressing component (21) during operation.

5. A novel automatic mobile phone button assembly machine according to claim 4, characterized in that: The clamping assembly (11) includes a sliding plate (111) slidably connected to the side wall of the main body (1), and a starting block (112) is fixedly connected to the side wall of the sliding plate (111). The bottom of the starting block (112) is slidably connected to two moving blocks (113), which are symmetrically distributed with the sliding plate (111) as the center. The bottom of the moving block (113) is fixedly connected to a clamping block (114), and the clamping blocks (114) are symmetrically distributed with the starting block (112) as the center. The sidewalls of the two movable blocks (113) are rotatably connected to rubber plates (115).

6. A novel automatic mobile phone button assembly machine according to claim 5, characterized in that: The placement assembly (12) includes a material bin (121) fixedly connected to the top of the placement plate (4), and a placement wheel (122) is provided on the right side of the material bin (121), and the placement wheel (122) is fixedly connected to the top of the placement plate (4).

7. A novel automatic mobile phone button assembly machine according to claim 5, characterized in that: The pressing component (21) includes a sliding groove (211) formed inside the sliding plate (111), and a push block (212) is slidably connected inside the sliding groove (211). The bottom of the push block (212) is provided with two extrusion rods (213), which are symmetrically distributed around the sliding groove (211). The extrusion rod (213) is slidably connected to the inside of the sliding groove (211), and a contact head (214) is fixedly connected to the side wall of the extrusion rod (213). The top of the extrusion rod (213) is in contact with the side wall of the push block (212), and the outer surface of the contact head (214) is in contact with the top of the rubber plate (115).

8. A novel automatic mobile phone button assembly machine according to claim 7, characterized in that: The reverse thrust assembly (22) includes a connecting rod (221) fixedly connected to the bottom of the extrusion rod (213), and a fixing plate (222) is fixedly connected to the bottom of the two connecting rods (221). The bottom of the fixing plate (222) is fixedly connected to a spring piece (223), and the spring piece (223) is slidably connected to the inside of the clamping block (114); The end of the spring piece (223) away from the fixed plate (222) is fixedly connected to a movable block (224), and the movable block (224) is slidably connected to the inside of the clamping block (114); The middle part of the first spring piece (223) is designed in a V shape.

9. A novel automatic mobile phone button assembly machine according to claim 8, characterized in that: The drive assembly (31) includes a rotating rod (311) rotatably connected to the side wall of the connecting rod (221), and a plurality of rubber blocks (312) are fixedly connected to one end of the rotating rod (311) away from the connecting rod (221). Several of the rubber blocks (312) are equidistantly distributed around the rotating rod (311); The two rubber blocks (312) located on the same side of the clamping block (114) are arranged in a cross configuration.

10. A novel automatic mobile phone button assembly machine according to claim 5, characterized in that: The fixing component (32) includes several blocking blocks (321) fixedly connected to the top of the rubber plate (115); Several of the aforementioned blocking blocks (321) are arranged in pairs and symmetrically distributed around the moving block (113); Each of the aforementioned shielding blocks (321) has a spring plate (322) rotatably connected inside.