A precisely positioned tantalum capacitor case package structure

Abstract

The utility model discloses a kind of tantalum capacitor shell packaging structures of accurate positioning, it is related to tantalum capacitor shell packaging technical field, including workbench, positioning adjusting assembly and automatic positioning assembly, the upper side of workbench is provided with feeding belt, and the upper front side of workbench is welded with fixed plate, the both sides of the fixed plate are respectively equipped with servo motor and positioning adjusting assembly.The tantalum capacitor shell packaging structure of accurate positioning, the rotation of rotating frame is facilitated by servo motor and its output shaft, so as to facilitate automatic positioning assembly to be turned to upside or back side when tantalum capacitor shell feeding, avoid the normal feeding of tantalum capacitor shell to be shielded by positioning side plate, positioning adjusting assembly is convenient for adjusting the movement of positioning side plate, two push plates can retract and push the movement of tantalum capacitor shell, so as to push tantalum capacitor shell to push plate and resist plate between realization the multi-face positioning of tantalum capacitor shell, avoid the situation of positioning inclination.

Description

Technical Field

[0001] This utility model relates to the field of tantalum capacitor shell packaging technology, specifically a tantalum capacitor shell packaging structure with precise positioning. Background Technology

[0002] Tantalum capacitors are capacitors that use tantalum metal as electrodes. They are characterized by high stability, high precision, and excellent frequency response. Due to their unique physical and chemical properties, tantalum capacitors have become an important type of capacitor in electronic circuits. The processing of tantalum capacitors requires the use of casing equipment, and capacitor casing is a key process in capacitor manufacturing.

[0003] While existing tantalum capacitor casings can be automatically positioned during the packaging process, multi-faceted positioning is not convenient, which may lead to positioning errors. Furthermore, automatic feeding is not convenient during positioning, thus limiting their application. Utility Model Content

[0004] The purpose of this invention is to provide a precisely positioned tantalum capacitor housing packaging structure to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a tantalum capacitor shell packaging structure for precise positioning, comprising a worktable, a positioning adjustment component, and an automatic positioning component. A feeding belt is provided on the upper side of the worktable, and a fixed plate is welded to the front upper side of the worktable. A servo motor and a positioning adjustment component are respectively installed on both sides of the fixed plate. The positioning adjustment component includes a rotating frame, a bidirectional lead screw, a movable sleeve, and a connecting block. The bidirectional lead screw is rotatably installed inside the rotating frame. Two movable sleeves are symmetrically sleeved on the outer side of the bidirectional lead screw, and a connecting block is fixed to the outer side of each movable sleeve. An automatic positioning component is installed on one side of each of the two connecting blocks. The automatic positioning component includes a positioning side plate, a fixed frame, a micro motor, a rotating shaft, an electric telescopic rod, and a push plate. A fixed frame is fixed on the upper side of the positioning side plate, and the fixed frame has an "L"-shaped structure. A micro motor is installed on one side of the fixed frame, and a rotating shaft is provided on one side of the micro motor. An electric telescopic rod is fixed on one side of the rotating shaft, and a push plate is connected to one end of the electric telescopic rod.

[0006] Furthermore, the rotating frame and the fixed plate are rotatably connected, and the output shaft of the servo motor passes through the fixed plate and is fixedly connected to one end of the rotating frame.

[0007] Furthermore, the positioning adjustment component also includes a drive motor, which is mounted on the outer side of the other end of the rotating frame.

[0008] Furthermore, both of the movable sleeves are slidably connected to the inner wall of the rotating frame, and the rotating frame is a hollow cylindrical structure with an opening on one side.

[0009] Furthermore, the positioning side plate and the connecting block are fixedly connected, and the positioning side plates are parallel to each other.

[0010] Furthermore, a stop plate is fixed to the lower side of one side of the fixing plate, and the stop plate is located on the lower side of the rotating frame and is rotatably connected to the rotating frame.

[0011] Furthermore, an upper frame is fixed above both sides of the workbench, and a cylinder is installed on the upper side of the middle part of the upper frame.

[0012] Furthermore, a piston rod penetrating the upper frame is provided on the lower side of the cylinder, and a pressing seat is fixed to the bottom of the piston rod.

[0013] This invention provides a precisely positioned tantalum capacitor housing packaging structure, which has the following advantages:

[0014] This utility model is equipped with a positioning adjustment component and an automatic positioning component. The positioning adjustment component facilitates the adjustment of the movement of the positioning side plate. The extension and retraction of the electric telescopic rod facilitates the pushing and adjusting of the position of the push plate, making the position of the push plate adjustable. The micro motor and rotating shaft facilitate the rotation of the electric telescopic rod and the push plate, thereby facilitating the adjustment of the orientation of the push plate. Finally, the two push plates can retract to push the tantalum capacitor shell to move, thereby pushing the tantalum capacitor shell between the push plate and the back plate to achieve multi-faceted positioning of the tantalum capacitor shell and avoid positioning tilt.

[0015] This utility model is equipped with a servo motor and a feeding belt for feeding the tantalum capacitor shell to be packaged. The servo motor and its output shaft facilitate the rotation of the rotating frame, thereby allowing the automatic positioning component to be rotated to the upper or rear side when feeding the tantalum capacitor shell, avoiding the positioning side plate from obstructing the normal feeding of the tantalum capacitor shell. The rotating frame can be rotated back and forth during positioning. The cylinder and piston rod facilitate the lifting and lowering of the pressing seat, so that the pressing seat can tightly bond the sealing body to the tantalum capacitor shell through mechanical pressure, thereby realizing the packaging of the tantalum capacitor shell. Attached Figure Description

[0016] Figure 1 This is a three-dimensional structural diagram of a tantalum capacitor shell packaging structure for precise positioning according to the present invention.

[0017] Figure 2 This is a half-sectional schematic diagram of the positioning adjustment component of a tantalum capacitor shell packaging structure for precise positioning according to this utility model.

[0018] Figure 3 This is a schematic diagram of the rotating frame structure of a tantalum capacitor shell packaging structure for precise positioning according to this utility model.

[0019] In the diagram: 1. Workbench; 2. Feeding belt; 3. Fixing plate; 4. Servo motor; 5. Positioning adjustment assembly; 501. Rotating frame; 502. Drive motor; 503. Two-way lead screw; 504. Moving sleeve; 505. Connecting block; 6. Automatic positioning assembly; 601. Positioning side plate; 602. Fixing frame; 603. Micro motor; 604. Rotating shaft; 605. Electric telescopic rod; 606. Push plate; 7. Support plate; 8. Upper frame; 9. Cylinder; 10. Piston rod; 11. Pressing seat. Detailed Implementation

[0020] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and should not be construed as limiting the scope of this utility model.

[0021] like Figure 1 and Figure 2 As shown, a precise positioning tantalum capacitor casing encapsulation structure includes a worktable 1, a positioning adjustment component 5, and an automatic positioning component 6. A feeding belt 2 is provided on the upper side of the worktable 1, and a fixing plate 3 is welded to the front upper side of the worktable 1. A servo motor 4 and the positioning adjustment component 5 are respectively installed on both sides of the fixing plate 3. The positioning adjustment component 5 includes a rotating frame 501, a bidirectional lead screw 503, a movable sleeve 504, and a connecting block 505. The bidirectional lead screw 503 is rotatably mounted inside the rotating frame 501. Two movable sleeves 504 are symmetrically sleeved on the outer side of the bidirectional lead screw 503, and a connecting block 505 is fixed to the outer side of each movable sleeve 504. The positioning adjustment component 5... It also includes a drive motor 502. The drive motor 502 is installed on the outer side of the other end of the rotating frame 501. Both movable sleeves 504 are slidably connected to the inner wall of the rotating frame 501. The rotating frame 501 is a hollow cylindrical structure with an opening on one side. The drive motor 502 facilitates the rotation of the bidirectional lead screw 503, which in turn drives the two movable sleeves 504 on the outer side of the bidirectional lead screw 503 to move towards each other. This allows the movable sleeves 504 and the connecting block 505 on both sides to drive the movement of the two positioning side plates 601, thereby enabling the two positioning side plates 601 to position and clamp the tantalum capacitor shell between them. This is suitable for tantalum capacitor shells of different sizes.

[0022] like Figure 1 and Figure 3As shown, an automatic positioning component 6 is installed on one side of the two connecting blocks 505. The automatic positioning component 6 includes a positioning side plate 601, a fixing frame 602, a micro motor 603, a rotating shaft 604, an electric telescopic rod 605, and a push plate 606. The fixing frame 602 is fixed to the upper side of the positioning side plate 601, and the fixing frame 602 has an "L" shaped structure. The micro motor 603 is installed on one side of the inside of the fixing frame 602, and a rotating shaft 604 is provided on one side of the micro motor 603. An electric telescopic rod 605 is fixed to one side of the rotating shaft 604, and one end of the electric telescopic rod 605 is connected to the push plate 606. Plate 601 and connecting block 505 are fixedly connected, and the positioning side plates 601 are parallel to each other. The extension and retraction of electric telescopic rod 605 facilitates the adjustment of the position of push plate 606, making the position of push plate 606 adjustable. The micro motor 603 and rotating shaft 604 facilitate the rotation of electric telescopic rod 605 and push plate 606, thereby facilitating the adjustment of the orientation of push plate 606. Ultimately, the two push plates 606 can retract to push the tantalum capacitor shell to move, thereby pushing the tantalum capacitor shell between push plate 606 and abutment plate 7 to achieve multi-faceted positioning of tantalum capacitor shell and avoid positioning tilt.

[0023] like Figure 1 and Figure 3 As shown, the rotating frame 501 is rotatably connected to the fixed plate 3, and the output shaft of the servo motor 4 passes through the fixed plate 3 and is fixedly connected to one end of the rotating frame 501. A stop plate 7 is fixed to the lower side of one side of the fixed plate 3, and the stop plate 7 is located on the lower side of the rotating frame 501 and is rotatably connected to the rotating frame 501. An upper frame 8 is fixed above both sides of the worktable 1, and a cylinder 9 is installed on the upper side of the middle of the upper frame 8. A piston rod 10 passing through the upper frame 8 is provided on the lower side of the cylinder 9, and a pressing seat 11 is fixed to the bottom of the piston rod 10. The feeding belt 2 is used for the material to be packaged. The tantalum capacitor casing is fed into the system. The servo motor 4 and its output shaft drive the rotating frame 501 to rotate, which allows the automatic positioning component 6 to be rotated to the upper or rear side during the loading of the tantalum capacitor casing. This prevents the positioning side plate 601 from obstructing the normal loading of the tantalum capacitor casing. During the reversal positioning, the rotating frame 501 can be rotated back. The cylinder 9 and piston rod 10 drive the lifting and lowering of the pressing seat 11, so that the pressing seat 11 can tightly bond the sealing body to the tantalum capacitor casing through mechanical pressure, thereby realizing the encapsulation of the tantalum capacitor casing.

[0024] In summary, as Figures 1-3As shown, this precisely positioned tantalum capacitor casing encapsulation structure, in use, firstly, the tantalum capacitor casing to be encapsulated is fed into the feeder belt 2. At this time, the servo motor 4 and its output shaft drive the rotating frame 501 to rotate, thereby rotating the automatic positioning component 6 to the upper or rear side when the tantalum capacitor casing is being fed, preventing the positioning side plate 601 from obstructing and affecting the normal feeding of the tantalum capacitor casing. When the tantalum capacitor casing moves to the front of the rotating frame 501, the rotating frame 501 is rotated back, and then the drive motor 502 drives the bidirectional lead screw 503 to rotate, thereby driving the two moving sleeves 504 on the outer side of the bidirectional lead screw 503 to move towards each other. This causes the moving sleeves 504 and the connecting block 505 on both sides to drive the two positioning side plates 601 to move respectively, so that the two positioning side plates 601 can position and clamp the tantalum capacitor casing between them. During this process, the push plate 606 is located at the positioning... On the upper side of the side plate 601, the position of the push plate 606 can be adjusted by the extension and retraction of the electric telescopic rod 605, moving the push plate 606 to the other side of the tantalum capacitor shell on the upper side of the feeding belt 2. Then, the micro motor 603 and the rotating shaft 604 drive the electric telescopic rod 605 and the push plate 606 to rotate, thereby turning the push plate 606 to the side close to the tantalum capacitor shell. Then, the two push plates 606 retract and push the tantalum capacitor shell to move, thereby pushing the tantalum capacitor shell between the push plate 606 and the abutment plate 7 to achieve multi-face positioning of the tantalum capacitor shell and avoid positioning tilt. Finally, the cylinder 9 and the piston rod 10 drive the lifting and lowering of the pressing seat 11, so that the pressing seat 11 can tightly combine the sealing body with the tantalum capacitor shell through mechanical pressure, thereby realizing the encapsulation of the tantalum capacitor shell. This completes the use process of the precise positioning tantalum capacitor shell encapsulation structure.

[0025] The embodiments of this utility model are given for illustrative and descriptive purposes only, and are not intended to be exhaustive or to limit the utility model to the forms disclosed. Many modifications and variations will be apparent to those skilled in the art. The embodiments were chosen and described in order to better illustrate the principles and practical applications of this utility model, and to enable those skilled in the art to understand this utility model and design various embodiments with various modifications suitable for a particular purpose.

Claims

1. A precision-positioning tantalum capacitor casing packaging structure, comprising a worktable (1), a positioning adjustment assembly (5), and an automatic positioning assembly (6), characterized in that, A feeding belt (2) is provided on the upper side of the workbench (1), and a fixing plate (3) is welded to the front upper side of the workbench (1). A servo motor (4) and a positioning adjustment assembly (5) are respectively installed on both sides of the fixing plate (3). The positioning adjustment assembly (5) includes a rotating frame (501), a two-way lead screw (503), a moving sleeve (504), and a connecting block (505). The two-way lead screw (503) is rotatably installed inside the rotating frame (501). Two moving sleeves (504) are symmetrically sleeved on the outer side of the two-way lead screw (503), and a connecting block (505) is fixed on the outer side of the moving sleeve (504). A connecting block (505) is installed on one side of the two connecting blocks (505). An automatic positioning component (6) is provided, comprising a positioning side plate (601), a fixing frame (602), a micro motor (603), a rotating shaft (604), an electric telescopic rod (605), and a push plate (606). The positioning side plate (601) is fixed with a fixing frame (602) on its upper side, and the fixing frame (602) has an "L" shaped structure. A micro motor (603) is installed on one side of the interior of the fixing frame (602), and a rotating shaft (604) is provided on one side of the micro motor (603). An electric telescopic rod (605) is fixed on one side of the rotating shaft (604), and one end of the electric telescopic rod (605) is connected to the push plate (606).

2. The precisely positioned tantalum capacitor casing packaging structure according to claim 1, characterized in that, The rotating frame (501) is rotatably connected to the fixed plate (3), and the output shaft of the servo motor (4) passes through the fixed plate (3) and is fixedly connected to one end of the rotating frame (501).

3. The precisely positioned tantalum capacitor casing packaging structure according to claim 1, characterized in that, The positioning adjustment component (5) also includes a drive motor (502), and the drive motor (502) is installed on the outer side of the other end of the rotating frame (501).

4. The precisely positioned tantalum capacitor casing packaging structure according to claim 1, characterized in that, Both of the movable sleeves (504) are slidably connected to the inner wall of the rotating frame (501), and the rotating frame (501) is a hollow cylindrical structure with an opening on one side.

5. The precisely positioned tantalum capacitor casing packaging structure according to claim 1, characterized in that, The positioning side plate (601) and the connecting block (505) are fixedly connected, and the positioning side plates (601) are parallel to each other.

6. The precisely positioned tantalum capacitor casing packaging structure according to claim 1, characterized in that, A stop plate (7) is fixed to the lower side of one side of the fixed plate (3), and the stop plate (7) is located on the lower side of the rotating frame (501) and is rotatably connected to the rotating frame (501).

7. The precisely positioned tantalum capacitor casing packaging structure according to claim 1, characterized in that, The workbench (1) has an upper frame (8) fixed on both sides above it, and a cylinder (9) is installed on the upper side of the middle part of the upper frame (8).

8. The precisely positioned tantalum capacitor casing packaging structure according to claim 7, characterized in that, The cylinder (9) has a piston rod (10) that passes through the upper frame (8) on its lower side, and a pressing seat (11) is fixed at the bottom of the piston rod (10).

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