CN220028596U

CN220028596U - Anode plate die

Info

Publication number: CN220028596U
Application number: CN202321283861.6U
Authority: CN
Inventors: 姚雁斌; 冉兴健; 甘宇
Original assignee: Vital Thin Film Materials Guangdong Co Ltd
Current assignee: Vital Thin Film Materials Guangdong Co Ltd
Priority date: 2023-05-24
Filing date: 2023-05-24
Publication date: 2023-11-17
Anticipated expiration: 2033-05-24

Abstract

The utility model relates to the field of indium metal purification, in particular to an anode plate die, which comprises a die frame and a die plate fixed at the upper part of the die frame, wherein a forming groove matched with the outer contour of an anode plate is arranged at the middle part of the die plate, a bottom plate is arranged in the forming groove in a vertically sliding matching way, a telescopic driving device is fixed at the lower part of the die frame, the telescopic driving device contracts to enable the bottom plate to slide downwards, the top wall of the bottom plate and the side wall of the forming groove can be enclosed to form a die cavity for pouring molten metal liquid, the telescopic driving device stretches and can push the bottom plate to slide upwards, so that the bottom plate pushes solidified metal in the die cavity upwards, and the solidified metal is pushed out of the die cavity; therefore, the anode plate die can realize the adjustment of the depth of the die cavity by adjusting the retracted position of the telescopic driving device, and realize that the same die plate can process anode plates with different thicknesses; and moreover, the anode plate in the die cavity can be pushed out of the die cavity by extending the telescopic driving device, so that the anode plate is convenient to separate out.

Description

Anode plate die

Technical Field

The utility model relates to the field of indium metal purification, in particular to an anode plate die.

Background

The melting point of the indium metal is 156.3 ℃, the melting point is low, the fluidity and the heat conduction performance are good when the indium metal is in a solution state, and the indium metal is mostly purified by adopting an electrolytic purification technology. In the process of electrolyzing metal indium, coarse indium is first molten and cast into anode plate mold to produce anode plate, and then the anode plate and the cathode plate are separated in certain interval into electrolytic tank with electrolyte for electrolysis.

The existing anode plate die for electrolytic indium is a die plate, the upper end of the die plate is provided with a groove with an upward opening, the shape of the groove is matched with that of the anode plate, the die plate is horizontally placed on a casting platform when in use, molten indium liquid is injected into the groove, the die plate is turned over after the indium liquid is cooled to form the anode plate, and the die plate is knocked on the casting platform to enable the anode plate to be separated from the groove. When the anode plate mold with the structure is adopted, the depth of the groove is fixed, so that the same mold plate can only process the anode plate with the same thickness as the depth of the groove, and the adaptability of the guide pillar mold plate is low.

Disclosure of Invention

The technical problems to be solved by the utility model are as follows: in the existing anode plate die, the same die plate can only process the anode plate with the same thickness as the depth of the groove, and the adaptability of the guide post die plate is low.

In order to solve the technical problems, the utility model aims to provide an anode plate mold, which comprises a mold frame and a mold plate fixed at the upper part of the mold frame, wherein a forming groove matched with the outer side contour of an anode plate is arranged in the middle of the mold plate, a bottom plate is arranged in the forming groove in a vertically sliding matching manner, and a telescopic driving device is fixed at the lower part of the mold frame; the telescopic driving device contracts to enable the bottom plate to slide downwards, the top wall of the bottom plate and the side wall of the forming groove enclose a die cavity for pouring molten metal, the telescopic driving device stretches to enable the bottom plate to slide upwards, and the bottom plate pushes solidified metal in the die cavity upwards.

Preferably, the anode plate mold comprises vertically arranged scales, and the scales are arranged on one side of the template at intervals; the lower extreme of scale is fixed with to be close to the first connecting plate that the direction of bottom plate extends, first connecting plate is located the below of bottom plate, first connecting plate is kept away from the one end of scale is fixed with the second connecting plate that upwards extends, the second connecting plate with the lower extreme of bottom plate is connected.

Preferably, the zero scale of the scale is flush with the upper end surface of the bottom plate.

Preferably, the distance between the first connecting plate and the bottom plate is greater than the thickness of the template.

Preferably, the second connecting plate is fastened to the lower end of the bottom plate.

Preferably, the telescopic driving device is a hydraulic cylinder.

As a preferred scheme, the anode plate die comprises a push plate and a plurality of vertically arranged ejector rods, wherein each ejector rod is horizontally arranged below the bottom plate at intervals, the upper end of each ejector rod is fixedly connected or abutted to the lower end of the bottom plate, the lower end of each ejector rod is fixedly connected with the upper end of the push plate, and the telescopic end of the telescopic driving device is fixedly connected or abutted to the lower end of the push plate.

As a preferable scheme, the telescopic end of the telescopic driving device is abutted with the lower end of the push plate; the anode plate die comprises a plurality of elastic compression pieces, wherein each elastic compression piece is arranged on the periphery of the upper end of the push plate at intervals, the lower end of each elastic compression piece is abutted with the upper end of the push plate, and the upper end of each elastic compression piece is abutted with the lower end of the template.

Preferably, each elastic compression member is a compression spring, each compression spring is internally provided with a guide post in a penetrating way, one end of each guide post is fixedly connected with one of the template or the pushing plate, and the other end of each guide post is penetrated in the other of the pushing plate or the template.

Preferably, the push plate slides up and down to be connected with the middle part of the die carrier in a guiding way.

Compared with the prior art, the utility model has the beneficial effects that:

the utility model relates to an anode plate die, which comprises a die frame and a die plate fixed at the upper part of the die frame, wherein the middle part of the die plate is provided with a forming groove matched with the outer side contour of an anode plate, a bottom plate is arranged in the forming groove in a vertically sliding mode, a telescopic driving device is fixed at the lower part of the die frame, the telescopic driving device contracts to enable the bottom plate to slide downwards, the top wall of the bottom plate and the side wall of the forming groove are enclosed to form a die cavity for pouring molten metal, the telescopic driving device stretches, the bottom plate can be pushed to slide upwards, the bottom plate can be pushed to push solidified metal in the die cavity upwards, and the solidified metal is pushed out of the die cavity; therefore, the anode plate die can realize the adjustment of the depth of the die cavity by adjusting the retracted position of the telescopic driving device, and realize that the same die plate can process anode plates with different thicknesses; and moreover, the anode plate formed by solidifying the metal in the die cavity can be pushed out of the die cavity by extending the telescopic driving device, so that the anode plate can be conveniently pulled out.

Drawings

Fig. 1 is an isometric view of an anode plate die of the present utility model;

FIG. 2 is a cross-sectional view taken at A-A of FIG. 1;

FIG. 3 is a schematic diagram of the arrangement of the push plate, bottom plate and ejector pins;

FIG. 4 is a schematic illustration of the arrangement of the pusher plate, guide posts and templates;

in the figure, 1, a die carrier; 2. a template; 21. a forming groove; 3. a bottom plate; 4. a telescopic driving device; 51. a ruler; 52. a first connection plate; 53. a second connecting plate; 6. a push plate; 7. nailing the rod; 8. an elastic compression member; 9. and a guide post.

Detailed Description

The following describes in further detail the embodiments of the present utility model with reference to the drawings and examples. The following examples are illustrative of the utility model and are not intended to limit the scope of the utility model.

In the description of the present utility model, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "left", "right", "top", "bottom", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model. It should be understood that the terms "first," "second," and the like are used herein to describe various information, but such information should not be limited to these terms, which are used merely to distinguish one type of information from another. For example, a "first" message may also be referred to as a "second" message, and similarly, a "second" message may also be referred to as a "first" message, without departing from the scope of the utility model.

As shown in fig. 1 to 4, a preferred embodiment of an anode plate mold of the present utility model includes a mold frame 1 and a mold plate 2 fixed at the upper portion of the mold frame 1, wherein a forming groove 21 matching with the outer profile of the anode plate is provided at the middle portion of the mold plate 2, a bottom plate 3 is provided in the forming groove 21 in a vertically sliding matching manner, and a telescopic driving device 4 is fixed at the lower portion of the mold frame 1; the telescopic driving device 4 is contracted to enable the bottom plate 3 to slide downwards, so that the top wall of the bottom plate 3 and the side wall of the forming groove 21 enclose a die cavity for pouring molten metal, and the telescopic driving device 4 is extended to enable the bottom plate 3 to slide upwards, so that the bottom plate 3 pushes upwards solidified metal in the die cavity. Therefore, the anode plate die can realize the adjustment of the depth of the die cavity by adjusting the retracted position of the telescopic driving device 4, and realize that the same die plate can process anode plates with different thicknesses; in addition, the anode plate formed by solidifying metal in the die cavity can be pushed out of the die cavity by extending the telescopic driving device 4, so that the anode plate can be conveniently pulled out, and the die plate does not need to be manually turned over.

The telescopic driving device 4 can be a pneumatic cylinder and an electric push rod, and can also be realized by adopting a mode that a motor drives a telescopic mechanism to stretch, if the telescopic mechanism is arranged into a screw rod sliding block structure, the height of the sliding block is higher, the upper end of the screw rod is arranged on the lower portion of the sliding block in a penetrating mode, the upper end of the sliding block pushes the bottom plate 3 to move up and down, the lifting height of the sliding block can be adjusted by controlling the rotation number of the motor, and in the embodiment, the telescopic driving device 4 is arranged into the hydraulic cylinder 2 for simplifying the structure and ensuring the telescopic force of the telescopic driving device.

In this embodiment, in order to facilitate the operator to quickly adjust the thickness of the anode plate, the anode plate mold includes vertically arranged scales 51, and the scales 51 are arranged at intervals on one side of the template 2; the lower end of the scale 51 is fixed with a first connecting plate 52 extending towards the direction close to the bottom plate 3, the first connecting plate 52 is positioned below the bottom plate 3, one end of the first connecting plate 52 away from the scale 51 is fixed with a second connecting plate 53 extending upwards, and the second connecting plate 53 is connected with the lower end of the bottom plate 3. Specifically, as shown in fig. 1 and 2, the scale 51 can move synchronously with the bottom plate 3, and the depth of the cavity can be determined according to the scale on the scale 51 corresponding to the upper end surface of the template 2, so as to obtain the thickness of the anode plate.

Further, in order to facilitate the operator to quickly identify the distance between the upper end surface of the bottom plate 3 and the upper end surface of the template 2, the zero scale of the scale 51 is flush with the upper end surface of the bottom plate 3.

When the telescopic driving device 4 pushes the bottom plate 3 to move upwards to push the solidified anode plate, the bottom plate 3 can push the anode plate upwards until one part of the anode plate is positioned in the die cavity, the other part of the anode plate protrudes out of the upper end of the die plate 2, and a worker pulls out the anode plate; in this embodiment, in order to further facilitate the staff to take out the anode plate, the spacing distance between the first connecting plate 52 and the bottom plate 3 is greater than the thickness of the template 2, so that the first connecting plate 52 and the lower end surface of the template 2 interfere when the bottom plate 3 is pushed upwards, so that the bottom plate 3 can push the lower end of the anode plate to a position higher than the top end of the template 2, the staff can directly take away the pushed anode plate, the working efficiency of the anode plate mold of this embodiment is further provided, and the requirement of mass production of the anode plate is met.

The connection mode between the second connecting plate 53 and the bottom plate 3 is various, for example, the upper end of the second connecting plate 53 is welded at the lower end of the bottom plate 3, or the scale 51, the first connecting plate 52, the second connecting plate 53 and the bottom plate 3 are integrally processed, in this embodiment, in order to facilitate processing of the bottom plate 3, the second connecting plate 53 is fastened and connected with the lower end of the bottom plate 3, specifically, the upper end of the second connecting plate 53 may be provided with a lug, a screw is inserted into the lug, a screw hole opposite to the screw is provided at the lower end of the bottom plate 3, and the screw is connected in the screw hole.

In this embodiment, the anode plate mold includes a push plate 6 and a plurality of vertically arranged push rods 7, each push rod 7 is horizontally arranged below the bottom plate 3 at intervals, the upper end of each push rod 7 is fixedly connected or abutted with the lower end of the bottom plate 3, the lower end of each push rod 7 is fixedly connected with the upper end of the push plate 6, and the telescopic end of the telescopic driving device 4 is fixedly connected or abutted with the lower end of the push plate 6. Specifically, when the upper ends of the ejector rods 7 are fixedly connected with the lower end of the bottom plate 3, the ejector rods 7 are integrally linked with the bottom plate 3, at the moment, the telescopic end of the telescopic driving device 4 can be fixedly connected or abutted with the lower end of the push plate 6, and when the telescopic end of the telescopic driving device 4 is fixedly connected with the lower end of the push plate 6, the telescopic driving device 4 applies downward tension to the push plate 6 through retraction of the telescopic driving device 4, so that the push plate 6, the ejector rods 7 and the bottom plate 3 are integrally linked and lowered, and the position of the bottom plate 3 is reset; when the telescopic end of the telescopic driving device 4 is abutted with the lower end of the push plate 6, the telescopic driving device 4 cannot apply downward tension to the push plate 6 when the telescopic driving device 4 retracts, and each ejector rod 7 and the bottom plate 3 slide downwards under the action of self gravity so that the bottom plate 3 resets, or an operator knocks the bottom plate 3 through a rubber hammer so that the bottom plate 3 resets.

In the embodiment, the telescopic end of the telescopic driving device 4 is abutted with the lower end of the push plate 6; the anode plate mould comprises a plurality of elastic compression pieces 8, each elastic compression piece 8 is arranged on the periphery of the upper end of the push plate 6 at intervals, the lower end of each elastic compression piece 8 is abutted with the upper end of the push plate 6, and the upper end of each elastic compression piece 8 is abutted with the lower end of the template 2. When the telescopic driving device 4 stretches, the upward pushing force applied by the telescopic driving device 4 to the push plate 6 is larger than the elastic force applied by the elastic compression piece 8 to the push plate 6, so that the push plate 6 pushes the push rod 7 upwards; when the telescopic driving device 4 is contracted, the upward acting force applied by the telescopic driving device 4 to the push plate 6 is eliminated, the push plate 6 moves downwards under the action of the elastic force of the elastic compression piece 8 and the self gravity, and the reset of the push plate 6 is further ensured.

In this embodiment, in order to ensure that the elastic compression members operate stably, each elastic compression member 8 is a compression spring, and each compression spring is penetrated with a guide post 9, one end of each guide post 9 is fixedly connected with one of the template 2 or the push plate 6, and the other end of each guide post 9 is penetrated in the other of the push plate 6 or the template 2. The arrangement of the guide post 9 can prevent the compression spring from bending to one side in the working process, and ensures the working stability of the compression spring.

In order to improve the working stability of the push plate 6, in this embodiment, the push plate 6 is connected to the middle of the mold frame 1 in a vertically sliding and guiding manner. Specifically, a guiding structure which is arranged up and down can be arranged between the push plate 6 and the die frame 1, a guiding groove is arranged on one side of the push plate 6, a guiding protrusion which protrudes into the guiding groove is arranged on the inner side of the die 1, and the die frame 1 can adopt a welding structure of a plurality of cylinders or a box type structure.

In summary, the anode plate mold comprises a mold frame 1 and a mold plate 2 fixed at the upper part of the mold frame 1, wherein a forming groove 21 matched with the outer contour of the anode plate is arranged in the middle of the mold plate 2, a bottom plate 3 is arranged in the forming groove 21 in a vertically sliding matching manner, and a telescopic driving device 4 is fixed at the lower part of the mold frame 1; the telescopic driving device 4 is contracted to enable the bottom plate 3 to slide downwards, so that the top wall of the bottom plate 3 and the side wall of the forming groove 21 enclose a die cavity for pouring molten metal, and the telescopic driving device 4 is extended to enable the bottom plate 3 to slide upwards, so that the bottom plate 3 pushes upwards solidified metal in the die cavity. Therefore, the anode plate die can realize the adjustment of the depth of the die cavity by adjusting the retracted position of the telescopic driving device 4, and realize that the same die plate can process anode plates with different thicknesses; in addition, the anode plate formed by solidifying metal in the die cavity can be pushed out of the die cavity by extending the telescopic driving device 4, so that the anode plate can be conveniently pulled out, and the die plate does not need to be manually turned over.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that modifications and substitutions can be made by those skilled in the art without departing from the technical principles of the present utility model, and these modifications and substitutions should also be considered as being within the scope of the present utility model.

Claims

1. The anode plate die is characterized by comprising a die frame (1) and a die plate (2) fixed at the upper part of the die frame (1), wherein a forming groove (21) matched with the outer side outline of an anode plate is formed in the middle of the die plate (2), a bottom plate (3) is arranged in the forming groove (21) in a vertically sliding matching manner, and a telescopic driving device (4) is fixed at the lower part of the die frame (1); the telescopic driving device (4) is contracted to enable the bottom plate (3) to slide downwards, so that the top wall of the bottom plate (3) and the side wall of the forming groove (21) enclose a die cavity for pouring molten metal, the telescopic driving device (4) is stretched to enable the bottom plate (3) to slide upwards, and the bottom plate (3) pushes upwards solidified metal in the die cavity.

2. Anode plate mould according to claim 1, characterized in that it comprises vertically arranged scales (51), said scales (51) being arranged at intervals on one side of the template (2); the lower extreme of scale (51) is fixed with to be close to first connecting plate (52) that the direction of bottom plate (3) extends, first connecting plate (52) are located the below of bottom plate (3), first connecting plate (52) are kept away from one end of scale (51) is fixed with second connecting plate (53) that upwards extends, second connecting plate (53) with the lower extreme of bottom plate (3) is connected.

3. Anode plate mould according to claim 2, characterized in that the zero graduation of the ruler (51) is flush with the upper end face of the bottom plate (3).

4. Anode plate mould according to claim 2, characterized in that the distance between the first connection plate (52) and the bottom plate (3) is greater than the thickness of the template (2).

5. Anode plate mould according to claim 2, characterized in that the second connection plate (53) is fastened to the lower end of the bottom plate (3).

6. Anode plate mould according to claim 1, characterized in that the telescopic driving means (4) are hydraulic cylinders.

7. The anode plate mold according to any one of claims 1 to 6, characterized in that the anode plate mold comprises a push plate (6) and a plurality of vertically arranged ejector rods (7), each ejector rod (7) is horizontally arranged below the bottom plate (3) at intervals, the upper end of each ejector rod (7) is fixedly connected or abutted with the lower end of the bottom plate (3), the lower end of each ejector rod (7) is fixedly connected with the upper end of the push plate (6), and the telescopic end of the telescopic driving device (4) is fixedly connected or abutted with the lower end of the push plate (6).

8. The anode plate mold according to claim 7, characterized in that the telescopic end of the telescopic driving device (4) is abutted with the lower end of the push plate (6); the anode plate die comprises a plurality of elastic compression pieces (8), wherein the elastic compression pieces (8) are arranged on the periphery of the upper end of the push plate (6) at intervals, the lower ends of the elastic compression pieces (8) are abutted with the upper end of the push plate (6), and the upper ends of the elastic compression pieces (8) are abutted with the lower end of the template (2).

9. The anode plate mold according to claim 8, wherein each elastic compression member (8) is a compression spring, each compression spring is internally provided with a guide post (9) in a penetrating manner, one end of each guide post (9) is fixedly connected with one of the template (2) or the pushing plate (6), and the other end of each guide post (9) is penetrated in the other one of the pushing plate (6) or the template (2).

10. The anode plate mold according to claim 7, wherein the push plate (6) is connected to the middle of the die frame (1) in a vertically sliding guide manner.