Temperature-controllable drying device for ceramic capacitor processing

By designing a temperature-controlled drying device, utilizing desiccant to absorb moisture and a movable frame design, the problem of uneven drying of ceramic capacitors was solved, achieving uniform drying and efficient operation.

CN224365199UActive Publication Date: 2026-06-16XILUOSHENG AUTOMATION TECH (SUZHOU) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
XILUOSHENG AUTOMATION TECH (SUZHOU) CO LTD
Filing Date
2025-05-29
Publication Date
2026-06-16

AI Technical Summary

Technical Problem

Existing drying equipment suffers from inconsistent drying results due to internal moisture during the drying process of ceramic capacitors, and cannot effectively control temperature and humidity.

Method used

A temperature-controlled drying device was designed, equipped with a hot air blower, a temperature sensor, a breathable grille, a drying mechanism, and auxiliary mechanisms. It absorbs moisture through a desiccant placement tank, and the design of a movable frame improves working efficiency and prevents heat loss.

Benefits of technology

This achieves uniform drying of ceramic capacitors, maintains consistent internal dryness, improves working efficiency, and reduces heat loss.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a drying device for ceramic capacitor processing of controllable temperature formula, including drying box, the top fixed connection of drying box has the hot -blast machine, the outer wall fixed connection of hot -blast machine has the conveying pipeline, the one end of conveying pipeline is away from the hot -blast machine and is fixedly connected in the inside of drying box, the bottom of hot -blast machine is installed with temperature sensor, the inside of drying box is provided with drying mechanism, through the rotation limit block, limit block is separated from the contact of mounting block, and the convex block is pulled outwards, and the convex block drives mounting block to separate the inside of installation groove, and at this moment, the pull ring is turned over, and the pull ring is pulled outwards, and the pull ring drives the press plate to turn over, and the press plate separates the shelter of drying agent holding groove, and drive the first spring to be in the tensile state, at this moment, the drying agent holding groove is placed with drying agent, and the mounting block is installed to the inside of drying box again, and then the moisture produced in drying is absorbed, and the dry degree of internal ceramic capacitor is maintained same.
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Description

Technical Field

[0001] This utility model relates to the field of ceramic capacitor processing technology, specifically a temperature-controlled drying device for processing ceramic capacitors. Background Technology

[0002] Ceramic capacitors are a common type of capacitor widely used in electronic circuits, especially in high-frequency applications and small devices. Their main characteristic is the use of ceramic material as the capacitor dielectric, hence the name "ceramic capacitor." These capacitors offer advantages such as small size, low cost, and good stability, making them suitable for a variety of applications.

[0003] While existing drying devices can achieve the drying effect on ceramic capacitors, the moisture inside the ceramic capacitors may affect the ceramic capacitors above them, resulting in inconsistent drying effects for ceramic capacitors in different positions. Utility Model Content

[0004] The purpose of this invention is to provide a temperature-controlled drying device for processing ceramic capacitors, so as to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a temperature-controlled drying device for processing ceramic capacitors, comprising a drying chamber, a hot air blower fixedly connected to the top of the drying chamber, a conveying pipe fixedly connected to the outer wall of the hot air blower, the end of the conveying pipe away from the hot air blower passing through and fixedly connected to the interior of the drying chamber, a temperature sensor installed at the bottom of the hot air blower, a breathable grille passing through and fixedly connected to the inner wall of the drying chamber, a drying mechanism provided inside the drying chamber, and an installation groove provided on the outer wall of the drying chamber.

[0006] As a further preferred embodiment of this technical solution, the inner wall of the mounting groove is slidably connected to a mounting block, the outer wall of the mounting block is fixedly connected to a protrusion, and the outer wall of the drying oven is rotatably connected to a limit block.

[0007] As a further preferred embodiment of this technical solution, the outer wall of the limiting block is fitted to the outer wall of the mounting block, and a desiccant placement groove is provided at the top of the mounting block, with a pressure plate rotatably connected to the inner wall of the desiccant placement groove.

[0008] As a further preferred embodiment of this technical solution, a first spring is fixedly connected to the bottom end of the pressure plate, and the end of the first spring away from the pressure plate is fixedly connected to the bottom end of the desiccant placement groove. A groove is provided at the top end of the pressure plate, and a pull ring is rotatably connected to the inner wall of the groove.

[0009] As a further preferred embodiment of this technical solution, the drying oven is provided with an auxiliary mechanism inside, and the inner wall of the drying oven is provided with a sliding groove.

[0010] As a further preferred embodiment of this technical solution, the inner wall of the chute is slidably connected to a slider, the outer wall of the slider is fixedly connected to a movable frame, and the bottom end of the movable frame is provided with a vent hole.

[0011] As a further preferred embodiment of this technical solution, a second spring is fixedly connected to the inner wall of the slide groove, and the end of the second spring away from the slide groove is fixedly connected to the outer wall of the slider. A handle is fixedly connected to the outer wall of the movable frame.

[0012] This utility model provides a temperature-controlled drying device for processing ceramic capacitors, which has the following features:

[0013] Beneficial effects:

[0014] (1) By rotating the limiting block, the limiting block is disengaged from the mounting block, and the protrusion is pulled outward. The protrusion drives the mounting block to disengage from the inside of the mounting groove. At this time, the pull ring is flipped and pulled outward. The pull ring drives the pressure plate to flip. The pressure plate is disengaged from the desiccant placement groove and at the same time, it drives the first spring to be in a stretched state. At this time, the desiccant is placed inside the desiccant placement groove. The mounting block is reinstalled inside the drying box, thereby absorbing the moisture generated during drying and maintaining the same degree of dryness of the internal ceramic capacitors.

[0015] (2) By pulling the handle outward, the handle moves the moving frame outward. The moving frame moves the slider inside the slide groove, and the slider squeezes the second spring. The second spring is compressed. The moving frame moves to the outside of the drying box. After the operator takes the ceramic capacitor, he releases the force on the handle. The second spring, without being affected by external force, drives the moving frame to reset by its own elasticity, which greatly improves work efficiency and prevents the leakage of internal heat. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall three-dimensional appearance structure of this utility model;

[0017] Figure 2 This is a schematic cross-sectional view of the overall structure of this utility model;

[0018] Figure 3 This is a schematic diagram of the drying mechanism of this utility model;

[0019] Figure 4 This is a schematic diagram of the auxiliary mechanism structure of this utility model.

[0020] In the diagram: 1. Drying oven; 2. Hot air blower; 3. Conveying pipe; 4. Temperature sensor; 5. Ventilation grille; 6. Drying mechanism; 61. Mounting slot; 62. Mounting block; 63. Protrusion; 64. Limiting block; 65. Desiccant placement slot; 66. Pressure plate; 67. First spring; 68. Groove; 69. Pull ring; 7. Auxiliary mechanism; 71. Slide groove; 72. Sliding block; 73. Moving frame; 74. Second spring; 75. Vent hole; 76. Handle. Detailed Implementation

[0021] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0022] This utility model provides a technical solution: such as Figures 1 to 4 As shown in this embodiment, a temperature-controlled ceramic capacitor processing drying device includes a drying chamber 1. A hot air blower 2 is fixedly connected to the top of the drying chamber 1. A conveying pipe 3 is fixedly connected to the outer wall of the hot air blower 2. The end of the conveying pipe 3 away from the hot air blower 2 passes through and is fixedly connected to the inside of the drying chamber 1. A temperature sensor 4 is installed at the bottom of the hot air blower 2. A breathable grille 5 passes through and is fixedly connected to the inner wall of the drying chamber 1. A drying mechanism 6 is provided inside the drying chamber 1. An installation groove 61 is opened on the outer wall of the drying chamber 1.

[0023] The inner wall of the mounting groove 61 is slidably connected to the mounting block 62, the outer wall of the mounting block 62 is fixedly connected to the protrusion 63, and the outer wall of the drying oven 1 is rotatably connected to the limit block 64.

[0024] The position of the mounting block 62 can be limited by the limiting block 64.

[0025] The outer wall of the limiting block 64 is in contact with the outer wall of the mounting block 62. The top of the mounting block 62 is provided with a desiccant placement groove 65, and the inner wall of the desiccant placement groove 65 is rotatably connected to a pressure plate 66.

[0026] The desiccant placement tank 65 is used to place desiccant inside, thereby absorbing the moisture generated by drying and heating.

[0027] The bottom end of the pressure plate 66 is fixedly connected to a first spring 67. The end of the first spring 67 away from the pressure plate 66 is fixedly connected to the bottom end of the desiccant placement groove 65. The top end of the pressure plate 66 is provided with a groove 68, and a pull ring 69 is rotatably connected to the inner wall of the groove 68.

[0028] The pressure plate 66 can be easily lifted by workers by flipping the pull ring 69.

[0029] The drying oven 1 is equipped with an auxiliary mechanism 7 inside, and the inner wall of the drying oven 1 is provided with a sliding groove 71.

[0030] The auxiliary mechanism 7 facilitates the placement of ceramic capacitors by staff and reduces the loss of internal heat.

[0031] The inner wall of the slide groove 71 is slidably connected to a slider 72, and the outer wall of the slider 72 is fixedly connected to a movable frame 73. The bottom end of the movable frame 73 is provided with a vent hole 75.

[0032] The slider 72 moves inside the slide groove 71, which can cause the moving frame 73 to detach from the inside of the drying oven 1.

[0033] The inner wall of the slide groove 71 is fixedly connected to a second spring 74, and the end of the second spring 74 away from the slide groove 71 is fixedly connected to the outer wall of the slider 72. The outer wall of the moving frame 73 is fixedly connected to a handle 76.

[0034] The second spring 74 can drive the slider 72 to reset without being affected by external force.

[0035] This utility model provides a temperature-controlled drying device for processing ceramic capacitors. The specific working principle is as follows: When it is necessary to replace the desiccant inside the desiccant placement tank 65, rotate the limiting block 64. The limiting block 64 disengages from the mounting block 62, and pulls the protrusion 63 outward. The protrusion 63 causes the mounting block 62 to disengage from the mounting groove 61. At this time, flip the pull ring 69 and pull it outward. The pull ring 69 causes the pressure plate 66 to flip, and the pressure plate 66 disengages from covering the desiccant placement tank 65. Simultaneously, it causes the first spring 67 to be in a stretched state. At this time, desiccant is placed inside the desiccant placement tank 65. The mounting block 62 is then reinstalled inside the drying chamber 1, thereby drying the product. The generated moisture is absorbed to maintain the same level of dryness in the internal ceramic capacitors. After drying, when the ceramic capacitors need to be removed, the handle 76 is pulled outward. The handle 76 moves the moving frame 73 outward. The moving frame 73 moves the slider 72 inside the slide groove 71, and the slider 72 compresses the second spring 74. The second spring 74 is compressed. The moving frame 73 moves to the outside of the drying chamber 1. After the operator removes the ceramic capacitor, the force on the handle 76 is released. The second spring 74, without being affected by external force, uses its own elasticity to drive the moving frame 73 to return to its original position, which greatly improves work efficiency and prevents internal heat from leaking out.

[0036] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A temperature-controlled drying device for processing ceramic capacitors, comprising a drying chamber (1), characterized in that: A hot air blower (2) is fixedly connected to the top of the drying box (1). A conveying pipe (3) is fixedly connected to the outer wall of the hot air blower (2). The end of the conveying pipe (3) away from the hot air blower (2) passes through and is fixedly connected to the inside of the drying box (1). A temperature sensor (4) is installed at the bottom of the hot air blower (2). A breathable grille (5) passes through and is fixedly connected to the inner wall of the drying box (1). A drying mechanism (6) is provided inside the drying box (1). An installation groove (61) is opened on the outer wall of the drying box (1).

2. The drying device for processing temperature-controlled ceramic capacitors according to claim 1, characterized in that: The inner wall of the mounting groove (61) is slidably connected to a mounting block (62), the outer wall of the mounting block (62) is fixedly connected to a protrusion (63), and the outer wall of the drying box (1) is rotatably connected to a limit block (64).

3. The drying device for processing temperature-controlled ceramic capacitors according to claim 2, characterized in that: The outer wall of the limiting block (64) is in contact with the outer wall of the mounting block (62). The top of the mounting block (62) is provided with a desiccant placement groove (65), and the inner wall of the desiccant placement groove (65) is rotatably connected with a pressure plate (66).

4. The drying device for processing temperature-controlled ceramic capacitors according to claim 3, characterized in that: The bottom end of the pressure plate (66) is fixedly connected to a first spring (67), and the end of the first spring (67) away from the pressure plate (66) is fixedly connected to the bottom end of the desiccant placement groove (65). The top end of the pressure plate (66) is provided with a groove (68), and a pull ring (69) is rotatably connected to the inner wall of the groove (68).

5. The drying apparatus for processing temperature-controlled ceramic capacitors according to claim 4, characterized in that: The drying oven (1) is equipped with an auxiliary mechanism (7) inside, and the inner wall of the drying oven (1) is provided with a sliding groove (71).

6. The drying apparatus for processing temperature-controlled ceramic capacitors according to claim 5, characterized in that: The inner wall of the slide groove (71) is slidably connected to a slider (72), and the outer wall of the slider (72) is fixedly connected to a movable frame (73). The bottom end of the movable frame (73) is provided with a vent hole (75).

7. The drying apparatus for processing temperature-controlled ceramic capacitors according to claim 6, characterized in that: The inner wall of the slide (71) is fixedly connected to a second spring (74), and the end of the second spring (74) away from the slide (71) is fixedly connected to the outer wall of the slider (72). The outer wall of the movable frame (73) is fixedly connected to a handle (76).