Electrolytic copper drying oven

By designing an electrolytic copper drying oven with a flip-up lid, internal partitions, and elastic clamping components, the problems of low drying efficiency and omissions in plate-type electrolytic copper drying have been solved, achieving simultaneous drying of multiple plates and safe and efficient drying results.

CN224470615UActive Publication Date: 2026-07-07JIANGXI YIXIN COPPER MATERIALS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGXI YIXIN COPPER MATERIALS CO LTD
Filing Date
2025-07-09
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

In existing technologies, plate-type electrolytic copper drying is inefficient and prone to omissions, resulting in poor drying effects.

Method used

An electrolytic copper drying oven was designed, which is equipped with a flip-up lid, equidistant inner partitions and elastic clamping components. Combined with a heating chamber, a filter-type bottom plate and a fan system, it can dry multiple plates simultaneously and avoid omissions.

Benefits of technology

It improves the efficiency and effectiveness of electrolytic copper drying, avoids the problem of omissions when drying a single plate, and enhances safety and practicality.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an electrolytic copper drying oven, its structure includes drying case, inner baffle and bottom board, through the inner baffle divides the drying case into several layers, makes the electrolytic copper can reduce the situation of mutual contact when putting into the inside, makes dry mutual interference, accelerates the drying rate, and when putting down, the spring compression of inside opens the force block of both and inserts the electrolytic copper into the inside clamping, makes dry stability better, reduces the inclination side, and the electrolytic copper plate can make the position of the electrolytic copper plate clamping of the rolling bar change under the adjustment of bottom board under the rolling down of the rolling bar, so that it is clamped at different positions, and the drying heating effect is better, reduces the drying omission situation of electrolytic copper plate, and the heat penetration hole is arranged on the both sides of the heating cavity in the inner baffle, so that the both sides dry the electrolytic copper plate, and the drying efficiency is faster.
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Description

Technical Field

[0001] This utility model relates to the field of electrolytic copper processing technology, and in particular to an electrolytic copper drying oven. Background Technology

[0002] In the electrolytic copper production process, drying ovens are generally required to dry the materials to prevent excessive moisture content from affecting the production process. Drying ovens typically use high-temperature air to evaporate moisture, making the materials dry and easier to use later.

[0003] Electrolytic copper is mostly produced in slab form, and when drying slab electrolytic copper, box-type drying is mostly used for single slab drying. This method is inefficient and may result in omissions at the contact points with the electrolytic copper, leading to poor drying effect.

[0004] Therefore, an electrolytic copper drying oven is proposed. Utility Model Content

[0005] (a) Technical problems to be solved

[0006] To overcome the shortcomings of existing technologies, an electrolytic copper drying oven is proposed to solve the problems of low drying efficiency of a single plate and poor drying effect caused by omissions during the drying process of plate electrolytic copper.

[0007] (II) Technical Solution

[0008] This utility model is achieved through the following technical solution: This utility model proposes an electrolytic copper drying oven, including a drying chamber with an upward opening inside, and a hinged, flip-openable lid installed at the upper opening of the drying chamber. The bottom of the drying chamber is provided with an installation cavity.

[0009] The drying oven has several layers of inner partitions installed at equal intervals to form insertion slots. The outer side of the inner partitions and the inner side of the drying oven are symmetrically provided with elastic clamping elements. The inner side of the inner partitions and the inner side of the drying oven are both provided with heating chambers. Heating elements are installed inside the heating chambers. The inner side of the heating chambers is provided with through heat-transmitting holes.

[0010] The bottom of the drying oven is provided with a filter-type bottom plate, and an electric push rod is installed inside the mounting cavity, with the output end of the electric push rod passing through the mounting cavity and connected to the bottom plate.

[0011] Furthermore, the lid is provided with a handle on the side, and the lid has a ventilation grille that extends through the inside and outside.

[0012] Furthermore, the elastic clamping component includes force-bearing blocks symmetrically arranged on the outer side of the inner partition and the inner side of the drying chamber. A first rotating hole is provided at the upper end of the force-bearing block. A first fixed rod is provided inside the drying chamber and rotatably connected to the first rotating hole. A second rotating hole is provided at the lower end of the force-bearing block. A roller is rotatably installed inside the second rotating hole through the second fixed rod, and the two corresponding rollers are in contact with each other. A spring is provided at the lower inner end of the force-bearing block and connected to the outer side of the inner partition and the inner side of the drying chamber. The spring wraps around a telescopic rod.

[0013] Furthermore, the elastic clamping element is provided in two locations: one on the outer side of the inner partition and the other on the upper and lower sides of the inner side of the drying oven.

[0014] Furthermore, an exhaust vent is installed inside the mounting cavity, and several air jets are provided at the upper end of the exhaust vent, penetrating the interior of the drying chamber. A fan is installed inside the mounting cavity, and the air supply end of the fan is connected to one side of the exhaust vent through an air supply pipe.

[0015] Furthermore, a controller is installed on the outside of the drying chamber.

[0016] (III) Beneficial Effects

[0017] Compared with the prior art, this utility model has the following advantages:

[0018] 1. In this utility model, the interior of the drying chamber is divided into multiple sets of insertion slots by an inner partition. This allows electrolytic copper plates to be placed into different insertion slots, thus separating the electrolytic plates and preventing them from contacting each other during drying and affecting the drying effect. Furthermore, this allows multiple electrolytic copper plates to be dried at the same time, avoiding the low efficiency of drying one at a time and making the work more efficient.

[0019] 2. In this utility model, the electrolytic copper is clamped by rollers on both sides, so that the electrolytic copper can fall downwards under the rolling action when clamped. This allows the clamping position of the electrolytic copper to be changed by adjusting the bottom plate, so that the drying effect at the clamping point is not poor and the drying is not missed. This results in better drying effect and reduces the chance of omission. Attached Figure Description

[0020] Other features, objects, and advantages of this invention will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:

[0021] Figure 1 This is a schematic diagram of the structure of this utility model;

[0022] Figure 2 This is a schematic diagram of the internal structure of the present invention;

[0023] Figure 3 This is a partially enlarged structural diagram of point A in this utility model;

[0024] In the diagram: Drying oven-1, Controller-2, Mounting cavity-3, Cover-4, Lifting buckle-5, Ventilation grille-6, Electric push rod-7, Fan-8, Air supply pipe-9, Inner partition-10, Heating cavity-11, Heat transmission hole-12, Heating element-13, Bottom plate-14, Air exhaust-15, Air jet nozzle-16, Stress block-17, Rotating hole one-18, Fixing rod one-19, Rotating hole two-110, Roller-111, Fixing rod two-112, Spring-113, Telescopic rod-114. Detailed Implementation

[0025] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain this utility model and are not intended to limit this utility model.

[0026] Please see Figure 1 , Figure 2 and Figure 3 This utility model provides an electrolytic copper drying oven, including a drying chamber 1 with an upward opening inside, in which electrolytic copper is dried. A controller 2 is installed on the outside of the drying chamber 1, which facilitates the operation of the electrical components in the device by the staff under the control of the externally purchased controller 2, so as to improve the operation effect. The top opening of the drying chamber 1 is equipped with a flip-open box cover 4 by a hinge, so that the box cover 4 can be opened to facilitate the removal and replacement of the electrolytic copper inside. A lifting buckle 5 is provided on the side of the box cover 4, so that the lifting buckle 5 is less likely to come into contact with the box cover 4, which can avoid the box cover 4 from being heated in the later stage of drying and affecting the safety of the staff, thus improving safety. The inside of the box cover 4 is provided with a ventilation grille 6 that runs through the inside and outside, so that the water vapor generated during the drying process can be discharged upward.

[0027] The drying chamber 1 has several layers of inner partitions 10 installed at equal intervals inside, forming insertion slots. Each slot can accommodate an electrolytic copper plate for drying, allowing multiple sets of plates to be inserted and dried simultaneously. This avoids the inefficiency of single-plate drying and prevents copper from piling up during drying, resulting in better performance. The outer sides of the inner partitions 10 are symmetrically equipped with elastic clamps on the inner sides of the drying chamber 1 to clamp electrolytic copper plates of different thicknesses, enhancing practicality. Two clamping points are provided on the upper and lower sides of the inner side of the drying oven 1 to improve the stability when clamping the electrolytic copper plate. The elastic clamping element includes force-bearing blocks 17 symmetrically arranged on the outer side of the inner partition 10 and the inner side of the drying oven 1. The force-bearing blocks 17 are inclined downward to facilitate downward force insertion. A rotating hole 18 is provided at the upper end of the force-bearing block 17. A fixed rod 19 is provided inside the drying oven 1 and is rotatably connected to the rotating hole 18, so that the force-bearing block 17 can rotate to avoid up and down wobbling and make the rotation adjustment distance more effective. A rotating hole 18 is provided at the lower end of the force-bearing block 17. Hole 110, through which a roller 111 is rotatably mounted via a fixed rod 112, allows the electrolytic copper plate to move downwards under pressure during clamping. The two rollers 111 contact each other, clamping the electrolytic copper plate and preventing it from tipping over during drying, thus facilitating its vertical movement. A spring 113 is located at the lower inner end of the force-bearing block 17, connecting to the outer side of the inner partition 10 and the inner side of the drying chamber 1. This allows the force-bearing block 17 to be subjected to elastic force under the pressure of the spring 113. The inner rollers 111 clamp the electrolytic copper together, and the compression spring 113 can clamp the copper when inserting electrolytic copper plates of different thicknesses, making it more practical. The spring 113 is wrapped around the telescopic rod 114, so that the spring 113 is inside the telescopic rod 114, which reduces the impact of heat on it. The inner partition 10 and the inner side of the drying chamber 1 are provided with heating chambers 11. Heating elements 13 are installed inside the heating chambers 11. The inner side of the heating chambers 11 is provided with through heat-transmitting holes 12, so that both sides are heated, resulting in better drying effect.

[0028] The drying oven 1 has a mounting cavity 3 at the bottom for easy replacement and maintenance. The bottom of the drying oven 1 has a filter-type bottom plate 14, which facilitates air permeability. An electric push rod 7 is installed inside the mounting cavity 3, and the output end of the electric push rod 7 passes through the mounting cavity 3 and connects to the bottom plate 14. When the electric push rod 7 pushes the bottom plate 14 up and down, the bottom of the electrolytic copper plate contacts the bottom plate 14. As the bottom plate 14 moves downwards, the electrolytic copper plate also moves downwards. This allows the clamping point to be moved downwards after a period of drying, making it possible to change the position of the clamping point and avoiding poor drying results at the clamping point. Furthermore, to reduce omissions and improve drying effect, an exhaust vent 15 is installed inside the mounting cavity 3, and several air jets 16 are provided at the upper end of the exhaust vent 15, penetrating the interior of the drying chamber 1. A fan 8 is installed inside the mounting cavity 3, and the air supply end of the fan 8 is connected to one side of the exhaust vent 15 through the air supply pipe 9. The fan 8 supplies air to the interior of the exhaust vent 15 and inputs it into the interior of the drying chamber 1 through the air jets 16. This can quickly dissipate the internal heat, reduce the inconvenience caused by excessive internal heat when removing and replacing the internal electrolytic copper plates, and facilitate the enhanced removal of moisture during the drying process, resulting in better drying efficiency.

[0029] Working principle: In use, first connect the electric push rod 7, fan 8, heating element 13 to the controller 2 and connect it to an external power source. Then, after opening the cover 4, insert the electrolytic copper plate into the insertion slot between the inner partitions 10, so that the bottom of the electrolytic copper plate contacts the roller 111, compressing the spring 113 and the telescopic rod 114 inward, allowing the electrolytic copper plate to be inserted. After the bottom end contacts the bottom plate 14, the roller 111 clamps the electrolytic copper plate with force on both sides. Then, the heating element 13 inside the heating chamber 11 heats up, drying the electrolytic copper plate on both sides. After processing and drying for a period of time, the electric push rod 7 can pull down the bottom plate 14 to change the clamping position of the electrolytic copper plate, and then continue drying to improve the drying effect. The fan 8 introduces external gas into the exhaust 15 through the air pipe 9 and discharges it into the drying chamber 1 through the air nozzle 16 to accelerate the removal of internal moisture. After drying, the fan can continue to blow air into the interior and remove heat through the ventilation grille 6. After opening the chamber cover 4, the bottom plate 14 can be pushed upward to push the electrolytic copper plate upward a certain distance, and then the electrolytic copper plate can be removed and replaced to complete the work.

[0030] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. An electrolytic copper drying oven, comprising a drying chamber (1) with an upward opening inside, and a hinged cover (4) installed at the upper opening of the drying chamber (1), wherein the bottom of the drying chamber (1) is provided with an installation cavity (3). Its characteristics are: The drying oven (1) has several layers of inner partitions (10) installed at equal intervals inside, forming insertion slots between them. The outer side of the inner partitions (10) and the inner side of the drying oven (1) are symmetrically provided with elastic clamping elements. The inner side of the inner partitions (10) and the inner side of the drying oven (1) are both provided with heating chambers (11). Heating elements (13) are installed inside the heating chambers (11). The inner side of the heating chambers (11) is provided with through heat-transmitting holes (12). The bottom of the drying oven (1) is provided with a filter-type bottom plate (14), and an electric push rod (7) is installed inside the mounting cavity (3), and the output end of the electric push rod (7) passes through the mounting cavity (3) and is connected to the bottom plate (14).

2. The electrolytic copper drying oven according to claim 1, characterized in that: The lid (4) is provided with a handle (5) on the side, and the lid (4) is provided with a ventilation grille (6) that runs through the inside and outside.

3. The electrolytic copper drying oven according to claim 1, characterized in that: The elastic clamping component includes a force-bearing block (17) symmetrically arranged on the outer side of the inner partition (10) and the inner side of the drying box (1). The upper end of the force-bearing block (17) is provided with a rotating hole (18). The drying box (1) is provided with a fixing rod (19) rotatably connected to the rotating hole (18). The lower end of the force-bearing block (17) is provided with a rotating hole (110). The rotating hole (110) is rotatably installed with a roller (111) through a fixing rod (112). The two rollers (111) are in contact with each other. The lower end of the inner side of the force-bearing block (17) is provided with a spring (113) connected to the outer side of the inner partition (10) and the inner side of the drying box (1). The spring (113) is wrapped with a telescopic rod (114).

4. The electrolytic copper drying oven according to claim 1, characterized in that: The elastic clamping element is provided at two locations: one on the outer side of the inner partition (10) and the other on the upper and lower sides of the inner side of the drying box (1).

5. The electrolytic copper drying oven according to claim 1, characterized in that: An exhaust vent (15) is installed inside the mounting cavity (3), and several air jets (16) are provided at the upper end of the exhaust vent (15) to penetrate the interior of the drying box (1). A fan (8) is installed inside the mounting cavity (3), and the air supply end of the fan (8) is connected to one side of the exhaust vent (15) through an air supply pipe (9).

6. The electrolytic copper drying oven according to claim 1, characterized in that: A controller (2) is installed on the outside of the drying oven (1).