An automatic assembling device for ceramic capacitors
By designing limiting components and mold components, the problem of mold offset in the automatic assembly equipment for ceramic capacitors was solved, achieving precise assembly and improving product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FUJIAN RUISHENG ELECTRONIC TECH CO LTD
- Filing Date
- 2025-06-16
- Publication Date
- 2026-06-26
AI Technical Summary
Existing automated ceramic capacitor assembly equipment lacks a fixed mold structure, resulting in inaccurate assembly and reduced product quality.
By employing limiting components and mold components, and through the cooperation of limiting grooves and electromagnets, ceramic dielectric capacitors are fixed, and by combining transportation components, gluing components, assembly components and mold closing components, precise assembly is achieved.
It improves the accuracy of automated assembly and enhances product quality.
Smart Images

Figure CN224417646U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of ceramic dielectric capacitor processing technology, and in particular to an automated assembly device for ceramic capacitors. Background Technology
[0002] Ceramic dielectric capacitors, also known as ceramic capacitors or monolithic capacitors, are capacitors whose dielectric material is ceramic. Based on the different ceramic dielectric materials, they can be divided into low-frequency ceramic dielectric capacitors and high-frequency ceramic dielectric capacitors. According to their structural form, they can be further classified into various types such as disc capacitors, tubular capacitors, rectangular capacitors, chip capacitors, and feedthrough capacitors.
[0003] The existing Chinese patent with authorization announcement number CN222705325U discloses an automatic assembly equipment for ceramic capacitors, including a frame and a support preparation device, a conveying mechanism, an assembly fixture, a first feeding device, a dispensing device, a second feeding device, and a flipping device arranged sequentially on the frame. By defining the structure of the automatic assembly equipment, this application can realize the automated assembly of ceramic dielectric capacitors, which not only reduces labor costs but also increases production efficiency several times over, meeting the needs of mass production of ceramic dielectric capacitors.
[0004] Although the aforementioned equipment automates the assembly of ceramic dielectric capacitors and reduces labor costs, it lacks a structure to fix the mold, causing the mold to shift during assembly. This results in the equipment being unable to perform the assembly work accurately, thus reducing product quality. Utility Model Content
[0005] In view of the shortcomings of the existing technology, the purpose of this utility model is to provide an automated ceramic capacitor assembly device, which aims to solve the technical problem that the above-mentioned equipment does not have a fixed mold structure, making it impossible to accurately assemble capacitors and reducing product quality.
[0006] To achieve the above objectives, the present invention adopts the following technical solution:
[0007] An automated ceramic capacitor assembly device includes a chassis, an operation panel, and further includes:
[0008] A transport component, mounted on the chassis, is used to transport materials required for processing;
[0009] A limiting component is provided on the transport component to prevent the ceramic dielectric capacitor from moving during assembly;
[0010] A mold assembly, disposed on the limiting assembly, is used to carry a ceramic dielectric capacitor;
[0011] A capacitor assembly is disposed on the mold assembly;
[0012] An adhesive application assembly, mounted on the chassis, is used to connect the capacitor assembly;
[0013] Assembly components, mounted on the chassis, are used to assemble ceramic dielectric capacitors;
[0014] A mold closing assembly, mounted on the chassis, is used to close the mold assembly.
[0015] Preferably, the transport component includes:
[0016] The first drive motor is mounted on the fixedly connected chassis;
[0017] A rotating shaft is fixedly connected to the output shaft of the first drive motor, and the rotating shaft is rotatably connected to the chassis;
[0018] A first rolling roller is disposed on the rotating shaft and fixedly connected to the rotating shaft;
[0019] A belt is tumblingly connected to the first rolling roller;
[0020] The collection box is slidably connected to the chassis.
[0021] Preferably, the limiting component includes:
[0022] The connecting plate is fixedly connected to the belt;
[0023] The base is fixedly connected to the connecting plate;
[0024] A limiting groove is provided on the base;
[0025] The first electromagnet is disposed on the limiting groove and is fixedly connected to the base.
[0026] Preferably, the mold assembly includes:
[0027] The first mold is disposed on the limiting groove and slidably connected to the base; the first mold is magnetically connected to the first electromagnet.
[0028] Positioning bolts are fixedly connected to the first mold;
[0029] The second mold is disposed on the first mold and is magnetically connected to the first mold; the second mold is slidably connected to the positioning bolt.
[0030] Positioning holes are provided on the second mold.
[0031] Preferably, the capacitor assembly includes:
[0032] The electrode plate is slidably connected to the first mold;
[0033] A ceramic medium is disposed on the first mold and slidably connected to the first mold, and the ceramic medium is slidably connected to the second mold.
[0034] Preferably, the adhesive application assembly includes:
[0035] A servo motor is fixedly connected to the chassis;
[0036] A threaded rod is mounted on the chassis and rotatably connected to the chassis; the threaded rod is fixedly connected to the output shaft of the servo motor.
[0037] The guide rod is fixedly connected to the chassis;
[0038] A lifting platform is slidably connected to the chassis, the lifting platform is slidably connected to the guide rod, and the lifting platform is threadedly connected to the threaded rod;
[0039] The plaster gun is fixedly connected to the lifting platform;
[0040] The paste storage box is fixedly connected to the chassis;
[0041] The hose is mounted on the fixedly connected lifting platform and is fixedly connected to the ointment storage tank.
[0042] Preferably, the assembly component includes:
[0043] Mounting plate, fixedly connected to the chassis;
[0044] The robotic arm is slidably connected to the mounting plate;
[0045] The mounting frame is fixedly connected to the chassis;
[0046] A storage bin is mounted on the mounting frame and is slidably connected to the mounting frame.
[0047] Preferably, the mold clamping assembly includes:
[0048] The second drive motor is mounted on the fixedly connected chassis;
[0049] The second rolling roller is rotatably connected to the housing and fixedly connected to the output shaft of the second drive motor;
[0050] The conveyor belt is tumblingly connected to the second rolling roller;
[0051] A square groove is provided on the conveyor belt;
[0052] A second electromagnet is disposed on the square groove and fixedly connected to the conveyor belt; the second electromagnet is magnetically connected to the second mold.
[0053] Guide plate, fixedly connected to the chassis;
[0054] The feed inlet is located on the chassis;
[0055] A baffle is fixedly connected to the chassis;
[0056] A positioning channel is provided on the chassis and is fixedly connected to the chassis.
[0057] Preferably, there are several limiting grooves, which are evenly distributed on the base.
[0058] Preferably, the guide plate has a plurality of square holes on the side that contacts the conveyor belt, and the sum of the height of the square holes and the height from the upper surface of the second electromagnet to the upper surface of the conveyor belt is equal to the thickness of the second mold, and the width of the square holes is equal to the width of the second mold.
[0059] Preferably, both the first mold and the second mold are provided with magnets.
[0060] In summary, due to the adoption of the above technical solution, the beneficial effects of this utility model are:
[0061] By cooperating with the belt, the limiting component and the first mold, the base is first fixed on the belt using the connecting plate, and then the limiting groove on the limiting component and the first electromagnet are used to fix the first mold in the limiting groove by magnetic force, thereby improving the accuracy of the automated assembly of the device and improving product quality. Attached Figure Description
[0062] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments 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 these drawings without creative effort.
[0063] Figure 1 A three-dimensional structural schematic diagram of an automated ceramic capacitor assembly device is shown.
[0064] Figure 2 A cross-sectional view of an automated ceramic capacitor assembly apparatus is shown.
[0065] Figure 3 It shows Figure 2 A magnified view of a portion of point A in the middle.
[0066] Figure 4 It shows Figure 2 A magnified view of a portion of point B in the middle.
[0067] Figure 5 It shows Figure 2 A magnified view of a portion of point C.
[0068] Figure 6 It shows Figure 2 A magnified view of a portion of point D.
[0069] Figure 7 Another cross-sectional view of an automated ceramic capacitor assembly device is shown.
[0070] Legend:
[0071] 1. Chassis; 2. Control panel; 3. Belt; 4. Connecting plate; 5. Base; 6. Limiting groove; 7. First electromagnet; 8. First drive motor; 9. Rotating shaft; 10. First rolling roller; 11. Collection box; 12. First mold; 13. Positioning bolt; 14. Second mold; 15. Positioning hole; 16. Electrode plate; 17. Ceramic medium; 18. Servo motor; 19. Threaded rod; 20. Guide rod; 21. Lifting platform; 22. Applying gun; 23. Paste storage box; 24. Hose; 25. Mounting plate; 26. Robot arm; 27. Mounting frame; 28. Storage box; 29. Second drive motor; 30. Second rolling roller; 31. Conveyor belt; 32. Square groove; 33. Second electromagnet; 34. Guide plate; 35. Feed inlet; 36. Baffle; 37. Positioning channel. Detailed Implementation
[0072] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of the present utility model.
[0073] In the description of this utility model, it should be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0074] It should be noted that when a component is described as "fixed to" another component, it can be directly on the other component or may have a component in between. When a component is considered "connected to" another component, it can be directly connected to the other component or may have a component in between. When a component is considered "set on" another component, it can be directly set on the other component or may have a component in between. The terms "vertical," "horizontal," "left," "right," and similar expressions used in this document are for illustrative purposes only.
[0075] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this utility model, "a plurality of" means two or more, unless otherwise explicitly specified.
[0076] Reference Figures 1 to 7 The present invention provides a further description of an embodiment of an automated ceramic capacitor assembly device.
[0077] An automated ceramic capacitor assembly device includes a chassis 1, an operation panel 2, and further includes:
[0078] A transport component, mounted on the chassis 1, is used to transport materials required for processing. The transport component includes:
[0079] The first drive motor 8 is mounted on the fixedly connected chassis 1;
[0080] A rotating shaft 9 is fixedly connected to the output shaft of the first drive motor 8, and the rotating shaft 9 is rotatably connected to the housing 1.
[0081] The first rolling roller 10 is disposed on the rotating shaft 9 and is fixedly connected to the rotating shaft 9;
[0082] The belt 3 is tactilely connected to the first rolling roller 10;
[0083] The collection box 11 is slidably connected to the chassis 1.
[0084] When the first drive motor 8 is started, the output shaft of the first drive motor 8 rotates, which drives the rotating shaft 9 fixedly connected to the output shaft of the first drive motor 8 to rotate, thereby driving the first rolling roller 10 fixedly connected to the rotating shaft 9 to rotate. The rotation of the rolling roller drives the belt 3 rolledly connected to the rolling roller to rotate, thus achieving the transportation effect.
[0085] Reference Figures 1 to 7A limiting component, disposed on the transport component, prevents the ceramic dielectric 17 capacitor from moving during assembly. The limiting component includes:
[0086] Connecting plate 4 is fixedly connected to the belt 3;
[0087] The base 5 is fixedly connected to the connecting plate 4;
[0088] A limiting groove 6 is provided on the base 5, and there are several limiting grooves 6, which are evenly distributed on the base 5;
[0089] The first electromagnet 7 is disposed on the limiting groove 6 and is fixedly connected to the base 5.
[0090] Insert the electrode plate 16 into the first mold 12, then place the mold with the electrode plate 16 inserted into the limiting groove 6. Start the first electromagnet 7 through the operation panel 2. The magnetic force generated by the first electromagnet 7 will tightly attract the first mold 12, which is magnetically connected to the first electromagnet 7, into the limiting groove 6, thus achieving a fixing effect.
[0091] By cooperating with the belt 3, the limiting component and the first mold 12, the base 5 is first fixed on the belt 3 by the connecting plate 4, and then the first mold 12 is fixed in the limiting groove 6 by the limiting groove 6 on the limiting component and the first electromagnet 7 through magnetic force, thereby improving the accuracy of the automated assembly of the device and improving the product quality.
[0092] A mold assembly, disposed on the limiting assembly, is used to carry the ceramic dielectric 17 capacitor. The mold assembly includes:
[0093] The first mold 12 is disposed on the limiting groove 6 and slidably connected to the base 5. The first mold 12 is magnetically connected to the first electromagnet 7. A magnet is disposed on the first mold 12.
[0094] Positioning bolt 13 is fixedly connected to the first mold 12;
[0095] The second mold 14 is disposed on the first mold 12 and is magnetically connected to the first mold 12. The second mold 14 is slidably connected to the positioning bolt 13. A magnet is provided on the second mold 14.
[0096] Positioning hole 15 is provided on the second mold 14.
[0097] Reference Figures 1 to 7 A capacitor assembly is disposed on the mold assembly, the capacitor assembly comprising:
[0098] The electrode plate 16 is slidably connected to the first mold 12;
[0099] A ceramic medium 17 is disposed on the first mold 12 and slidably connected to the first mold 12, and the ceramic medium 17 is slidably connected to the second mold 14.
[0100] An adhesive application assembly, disposed on the chassis 1, is used to connect the capacitor assembly. The adhesive application assembly includes:
[0101] The servo motor 18 is fixedly connected to the chassis 1;
[0102] A threaded rod 19 is disposed on the housing 1 and rotatably connected to the housing 1. The threaded rod 19 is fixedly connected to the output shaft of the servo motor 18.
[0103] Guide rod 20 is fixedly connected to the chassis 1;
[0104] The lifting platform 21 is slidably connected to the housing 1, the lifting platform 21 is slidably connected to the guide rod 20, and the lifting platform 21 is threadedly connected to the threaded rod 19;
[0105] The paste gun 22 is fixedly connected to the lifting platform 21;
[0106] The paste storage box 23 is fixedly connected to the chassis 1;
[0107] The hose 24 is mounted on the fixedly connected lifting platform 21 and is fixedly connected to the ointment storage tank 23.
[0108] When the height of the adhesive application assembly needs to be adjusted, the servo motor 18 is started via the operation panel 2. The output shaft of the servo motor 18 rotates, causing the threaded rod 19, which is fixedly connected to the output shaft of the servo motor 18, to rotate. This causes the lifting platform 21, which is threadedly connected to the threaded rod 19 and slidably connected to the housing 1 and the guide rod 20, to slide up and down. The sliding of the lifting platform 21 causes the paste gun 22, which is fixedly connected to the lifting platform 21, to move up and down until the distance between the paste gun 22 and the electrode plate 16 reaches a suitable distance. When the electrode plate 16 on the first mold 12 moves to below the adhesive application assembly, the paste gun 22 is started. The solder paste in the paste tank 23 enters the paste gun 22, which is fixedly connected to the lifting platform 21, through the hose 24. The solder paste is dotted onto the electrode plate 16 by the paste gun 22, completing the paste application work.
[0109] Reference Figures 1 to 7 An assembly component, disposed on the chassis 1, is used to assemble ceramic dielectric 17 capacitors. The assembly component includes:
[0110] Mounting plate 25 is fixedly connected to the chassis 1;
[0111] The robotic arm 26 is slidably connected to the mounting plate 25;
[0112] Mounting frame 27 is fixedly connected to the chassis 1;
[0113] The storage box 28 is disposed on the mounting frame 27 and is slidably connected to the mounting frame 27.
[0114] When the electrode plate 16 on the first mold 12 moves to the assembly component area, the robot arm 26 is activated through the operation panel 2. The robot arm 26 takes out the ceramic medium 17 placed in the storage box 28 and places it between the two electrode plates 16, so that the solder paste applied on the electrode plate 16 connects the electrode plate 16 and the ceramic medium 17, completing the assembly work. When the ceramic medium 17 in the storage box 28 is used up, the storage box 28, which is slidably connected to the mounting frame 27, can be pulled out for material feeding.
[0115] A mold closing assembly, disposed on the chassis 1, is used for closing the mold assembly. The mold closing assembly includes:
[0116] The second drive motor 29 is mounted on the fixedly connected chassis 1;
[0117] The second rolling roller 30 is rotatably connected to the housing 1 and fixedly connected to the output shaft of the second drive motor 29;
[0118] Conveyor belt 31 is tactilely connected to the second rolling roller 30;
[0119] A square groove 32 is disposed on the conveyor belt 31;
[0120] The second electromagnet 33 is disposed on the square groove 32 and fixedly connected to the conveyor belt 31. The second electromagnet 33 is magnetically connected to the second mold 14.
[0121] The guide plate 34 is fixedly connected to the housing 1. The guide plate 34 has several square holes on the side that contacts the conveyor belt 31. The height of the square holes and the sum of the height from the upper surface of the second electromagnet 33 to the upper surface of the conveyor belt 31 are equal to the thickness of the second mold 14, and the width of the square holes is equal to the width of the second mold 14.
[0122] The feed inlet 35 is located on the chassis 1;
[0123] Baffle 36 is fixedly connected to the chassis 1;
[0124] Positioning channel 37 is disposed on the chassis 1 and fixedly connected to the chassis 1.
[0125] Several second molds 14 are added to the conveyor belt 31 through the feed port 35. The second drive motor 29 is started through the operation panel 2. The output shaft of the second drive motor 29 rotates, which drives the second rolling roller 30 fixedly connected to the output shaft of the second drive motor 29 to rotate, thereby driving the conveyor belt 31, which is rolledly connected to the second rolling roller 30, to move. At the same time, the second electromagnet 33 is started. When the second molds 14 on the conveyor belt 31 move to the guide plate 34, they are pushed up by the guide plate 34 into the square groove 32 and attracted and fixed in the square groove 32 by the magnetic force generated by the second electromagnet 33. When the fixed second molds 14 move to the positioning channel 37, the second electromagnet 33 is turned off. The second molds 14 lose the magnetic restraint and, under the action of their own gravity, fall along the positioning channel 37 to the first mold 12 directly below the positioning channel 37. Due to the magnet, the first mold 12 and the second mold 14 are attracted and fixed, thereby fixing the assembled capacitor assembly by the mold assembly.
[0126] Working principle: Refer to Figures 1 to 7 First, insert the electrode plate 16 into the first mold 12, then place the mold with the electrode plate 16 inserted into the limiting groove 6. Start the first electromagnet 7 through the operation panel 2. The magnetic force generated by the first electromagnet 7 will tightly attract the first mold 12, which is magnetically connected to the first electromagnet 7, into the limiting groove 6 to achieve a fixing effect. Start the first drive motor 8. The output shaft of the first drive motor 8 rotates, which drives the rotating shaft 9, which is fixedly connected to the output shaft of the first drive motor 8, to rotate. This drives the first rolling roller 10, which is fixedly connected to the rotating shaft 9, to rotate. The rotation of the rolling roller drives the belt 3, which is rolled and connected to the rolling roller, to rotate. This drives the first mold 12, which is fixed to the fixing component, and the electrode plate 16 inserted into the first mold 12, which are on the belt 3, to move towards the glue coating component.
[0127] When the height of the adhesive application assembly needs to be adjusted, the servo motor 18 is started via the operation panel 2. The output shaft of the servo motor 18 rotates, which drives the threaded rod 19, which is fixedly connected to the output shaft of the servo motor 18, to rotate. This drives the lifting platform 21, which is threadedly connected to the threaded rod 19 and slidably connected to the housing 1 and the guide rod 20, to slide up and down. The sliding of the lifting platform 21 drives the paste gun 22, which is fixedly connected to the lifting platform 21, to move up and down until the distance between the paste gun 22 and the electrode plate 16 reaches a suitable distance. When the electrode plate 16 on the first mold 12 moves to the bottom of the adhesive application assembly, the paste gun 22 is started. The solder paste in the paste tank 23 enters the paste gun 22, which is fixedly connected to the lifting platform 21, through the hose 24. The solder paste is dotted onto the electrode plate 16 by the paste gun 22, completing the paste application work.
[0128] When the electrode plate 16 on the first mold 12 moves to the assembly component area, the robot arm 26 is activated through the operation panel 2. The robot arm 26 takes out the ceramic medium 17 placed in the storage box 28 and places it between the two electrode plates 16, so that the solder paste applied on the electrode plate 16 connects the electrode plate 16 and the ceramic medium 17, completing the assembly work. When the ceramic medium 17 in the storage box 28 is used up, the storage box 28, which is slidably connected to the mounting frame 27, can be pulled out for material feeding.
[0129] When the assembly work is completed and the mold closing work is carried out, several second molds 14 are first added to the conveyor belt 31 through the feed port 35. The second drive motor 29 is started through the operation panel 2. The output shaft of the second drive motor 29 rotates, which drives the second rolling roller 30 fixedly connected to the output shaft of the second drive motor 29 to rotate, thereby driving the conveyor belt 31, which is rolledly connected to the second rolling roller 30, to move. At the same time, the second electromagnet 33 is activated. When the second molds 14 on the conveyor belt 31 move to the guide plate 34, they are pushed up by the guide plate 34 into the square groove 32 and fixed in the square groove 32 by the magnetic attraction generated by the magnetically connected second electromagnet 33. When the fixed second mold 14 moves to the positioning channel 37, the second electromagnet 33 is turned off. The second mold 14 loses its magnetic restraint and, under its own gravity, falls along the positioning channel 37 onto the first mold 12 directly below the positioning channel 37. Due to the magnets, the first mold 12 and the second mold 14 are attracted and fixed, thereby fixing the assembled capacitor assembly to the mold assembly. When the mold assembly moves above the collection box 11 after the mold is closed, the first electromagnet 7 is turned off. The mold assembly loses its magnetic restraint, and the assembled capacitor assembly falls into the collection box 11 under gravity along with the mold assembly, completing the collection.
[0130] The above description of the embodiments enables those skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the present invention. Therefore, the present invention is not to be limited to the embodiments shown herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
Claims
1. An automated ceramic capacitor assembly device, comprising a chassis (1) and an operation panel (2), characterized in that, Also includes: A transport component, mounted on the chassis (1), is used to transport materials required for processing; A limiting component is provided on the transport component to prevent the ceramic dielectric (17) capacitor from moving during assembly; The belt (3) is used to provide a load-bearing space for the installation of the limit assembly; The limiting component includes: The connecting plate (4) is fixedly connected to the belt (3); The base (5) is fixedly connected to the connecting plate (4); A limiting groove (6) is provided on the base (5); The first electromagnet (7) is disposed on the limiting groove (6) and fixedly connected to the base (5); A mold assembly, disposed on the limiting assembly, is used to carry a ceramic dielectric (17) capacitor; A capacitor assembly is disposed on the mold assembly; An adhesive application assembly is mounted on the chassis (1) and is used to connect the capacitor assembly; Assembly components are disposed on the chassis (1) for assembling ceramic dielectric (17) capacitors; The mold closing assembly is mounted on the chassis (1) and is used to perform mold closing operations on the mold assembly.
2. The automated ceramic capacitor assembly device according to claim 1, characterized in that, The transport component includes: The first drive motor (8) is mounted on the fixedly connected chassis (1); A rotating shaft (9) is fixedly connected to the output shaft of the first drive motor (8), and the rotating shaft (9) is rotatably connected to the chassis (1); The first rolling roller (10) is disposed on the rotating shaft (9) and fixedly connected to the rotating shaft (9). The first rolling roller (10) is tumblingly connected to the belt (3). The collection box (11) is slidably connected to the chassis (1).
3. The automated ceramic capacitor assembly device according to claim 2, characterized in that, The mold assembly includes: The first mold (12) is set on the limiting groove (6) and is slidably connected to the base (5). The first mold (12) is magnetically connected to the first electromagnet (7). Positioning bolt (13) is fixedly connected to the first mold (12); The second mold (14) is disposed on the first mold (12) and is magnetically connected to the first mold (12). The second mold (14) is slidably connected to the positioning bolt (13). Positioning holes (15) are provided on the second mold (14).
4. The automated ceramic capacitor assembly device according to claim 3, characterized in that, The capacitor assembly includes: The electrode plate (16) is slidably connected to the first mold (12); A ceramic medium (17) is disposed on the first mold (12) and slidably connected to the first mold (12). The ceramic medium (17) is slidably connected to the second mold (14).
5. The automated ceramic capacitor assembly device according to claim 4, characterized in that, The adhesive coating assembly includes: A servo motor (18) is fixedly connected to the chassis (1); A threaded rod (19) is disposed on the chassis (1) and rotatably connected to the chassis (1). The threaded rod (19) is fixedly connected to the output shaft of the servo motor (18). The guide rod (20) is fixedly connected to the chassis (1); The lifting platform (21) is slidably connected to the chassis (1), the lifting platform (21) is slidably connected to the guide rod (20), and the lifting platform (21) is threadedly connected to the threaded rod (19); The paste gun (22) is fixedly connected to the lifting platform (21); The paste storage box (23) is fixedly connected to the machine casing (1); The hose (24) is mounted on the fixedly connected lifting platform (21) and is fixedly connected to the ointment storage tank (23).
6. The automated ceramic capacitor assembly device according to claim 5, characterized in that, The assembly components include: Mounting plate (25) is fixedly connected to the chassis (1); The robotic arm (26) is slidably connected to the mounting plate (25); Mounting frame (27) is fixedly connected to the chassis (1); The storage box (28) is disposed on the mounting frame (27) and is slidably connected to the mounting frame (27).
7. The automated ceramic capacitor assembly device according to claim 6, characterized in that, The mold clamping assembly includes: The second drive motor (29) is mounted on the fixedly connected chassis (1); The second rolling roller (30) is rotatably connected to the housing (1) and fixedly connected to the output shaft of the second drive motor (29); The conveyor belt (31) is tumbled onto the second roller (30); A square groove (32) is provided on the conveyor belt (31); The second electromagnet (33) is disposed on the square groove (32) and fixedly connected to the conveyor belt (31). The second electromagnet (33) is magnetically connected to the second mold (14). Guide plate (34) is fixedly connected to the chassis (1); The feed inlet (35) is located on the chassis (1); A baffle (36) is fixedly connected to the chassis (1); The positioning channel (37) is set on the chassis (1) and fixedly connected to the chassis (1).
8. The automated ceramic capacitor assembly device according to claim 7, characterized in that, There are several limiting grooves (6), and they are evenly distributed on the base (5).
9. The automated ceramic capacitor assembly device according to claim 8, characterized in that, The guide plate (34) has several square holes on the side that contacts the conveyor belt (31), and the sum of the height of the square holes and the height from the upper surface of the second electromagnet (33) to the upper surface of the conveyor belt (31) is equal to the thickness of the second mold (14), and the width of the square holes is equal to the width of the second mold (14).
10. The automated ceramic capacitor assembly device according to claim 9, characterized in that, Both the first mold (12) and the second mold (14) are equipped with magnets.