CN218542898U - Anode hanging tool - Google Patents

Abstract

The application discloses an anode hanger, which comprises a hanger, a bearing plate, a first clamping mechanism, a second clamping mechanism and a driving mechanism; the hanger comprises a hanger body, a first hanger unit and a second hanger unit; the first clamping mechanism and the second clamping mechanism are used for extruding the first hanger unit and the second hanger unit; the driving mechanism comprises a driving component, a first abutting component, a second abutting component, a first resetting component and a second resetting component; the driving assembly is used for pushing the first pushing assembly and the second pushing assembly so as to respectively drive the second clamping mechanism and the first clamping mechanism to approach each other; the driving assembly is also used for separating from the first abutting and pushing assembly and the second abutting and pushing assembly so as to respectively drive the second clamping mechanism and the first clamping mechanism to be away from each other. According to the anode hanger provided by the embodiment of the application, the hanger unit is clamped or loosened to realize automatic operation, and an operator does not need to manually clamp or loosen, so that the feeding efficiency of the operator is improved, and the labor intensity of the operator is reduced.

Description

Anode hanging tool

Technical Field

The application relates to the technical field of hanger equipment, in particular to an anode hanger.

Background

Before welding, materials are generally required to be hung on a hanger of a hanger and subjected to anodic oxidation in an oxidation pond. At present, materials are usually hung on a hanging piece through manual operation. The manual work mode is roughly as follows: the left hand clamps the pendant tightly, and the right hand hangs the material on the pendant that is tightly clamped, and the pendant is loosened again to the left hand at last for the pendant resumes to natural state in order to prop up the material, thereby realizes the material loading. However, the manual operation method has the defects of low efficiency and high labor intensity.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is necessary to provide an anode hanger to improve the material loading efficiency and reduce the labor intensity of the operator.

The embodiment of the application provides an anode hanger, which comprises a hanger, a bearing plate, a first clamping mechanism, a second clamping mechanism and a driving mechanism; the hanger comprises a hanger body, a first hanger unit and a second hanger unit, wherein the first hanger unit and the second hanger unit are arranged on the hanger body in a staggered mode; the bearing plate is provided with a bearing position for bearing the hanger; the first clamping mechanism and the second clamping mechanism are movably arranged on the bearing plate, and are positioned on two opposite sides of the bearing position; the first clamping mechanism and the second clamping mechanism are used for extruding the first hanger unit and the second hanger unit; the driving mechanism is arranged on one side, away from the hanger, of the bearing plate and comprises a driving assembly, a first abutting assembly, a second abutting assembly, a first resetting assembly and a second resetting assembly; the first abutting and pushing assembly and the second abutting and pushing assembly are arranged opposite to the first clamping mechanism and the second clamping mechanism, the first abutting and pushing assembly is connected with the second clamping mechanism, the second abutting and pushing assembly is connected with the first clamping mechanism, and the driving assembly is rotatably arranged between the first abutting and pushing assembly and the second abutting and pushing assembly; one end of the first reset assembly is connected with the bearing plate, and the other end of the first reset assembly is abutted against the first abutting assembly; one end of the second reset assembly is connected with the bearing plate, and the other end of the second reset assembly is abutted against the second abutting assembly; the driving assembly is used for pushing the first pushing assembly and the second pushing assembly to be away from each other, so that the first pushing assembly and the second pushing assembly drive the second clamping mechanism and the first clamping mechanism to be close to each other to extrude the first hanger unit and the second hanger unit and compress the first resetting assembly and the second resetting assembly; the driving assembly is further used for separating from the first abutting assembly and the second abutting assembly so that the first resetting assembly and the second resetting assembly elastically abut against and push the first abutting assembly and the second abutting assembly to be close to each other, and then the first abutting assembly and the second abutting assembly respectively drive the second clamping mechanism and the first clamping mechanism to be away from each other so as to loosen the first hanger unit and the second hanger unit.

In some embodiments, the first hanger unit and the second hanger unit each include a plurality of spaced hangers, and the plurality of hangers of the first hanger unit and the plurality of hangers of the second hanger unit are sequentially arranged in a staggered manner.

In some embodiments, the loading board is provided with a positioning groove, a first sliding groove, a second sliding groove and a third sliding groove, the positioning groove is located at the bearing position for bearing the hanger body and positioning the hanger, the first sliding groove is arranged at the bearing position and penetrates through two opposite sides of the loading board, the first sliding groove is communicated with the positioning groove, the second sliding groove and the third sliding groove are located at two opposite sides of the positioning groove, and the second sliding groove and the third sliding groove penetrate through two opposite sides of the loading board.

In some embodiments, the first clamping mechanism includes a first connecting plate, a first clamping plate, and a plurality of first clamping fingers arranged at intervals, the first clamping plate is slidably disposed in the second sliding groove, two ends of the first clamping plate protrude out of the second sliding groove, the plurality of first clamping fingers are located in the first sliding groove, two ends of each first clamping finger protrude out of the first sliding groove, the first connecting plate is located on a side of the bearing plate away from the hanger, one end of the first connecting plate is connected to the first clamping plate, the other end of the first connecting plate is connected to the plurality of first clamping fingers, and the first connecting plate is further connected to the second pushing assembly; the first connecting plate is used for driving the first clamping plate and the first clamping fingers to move in the second sliding groove and the first sliding groove under the driving of the second abutting and pushing assembly; the first hanger unit is located between the first clamping plate and the first clamping fingers, and the first clamping fingers and the hanging pieces of the second hanger unit are arranged in a one-to-one opposite mode.

In some embodiments, the second clamping mechanism includes a second connecting plate, a second clamping plate, and a plurality of second clamping fingers arranged at intervals, the second clamping plate is slidably disposed in the third sliding groove, two ends of the second clamping plate protrude out of the third sliding groove, the plurality of second clamping fingers are located in the first sliding groove, two ends of each second clamping finger protrude out of the first sliding groove, the plurality of second clamping fingers and the plurality of first clamping fingers are sequentially arranged in a staggered manner, the second connecting plate is located on a side of the bearing plate away from the hanger, one end of the second connecting plate is connected to the second clamping plate, the other end of the second connecting plate is connected to the plurality of second clamping fingers, and the second connecting plate is further connected to the first pushing assembly; the second connecting plate is used for driving the second clamping plate and the second clamping fingers to move in the third sliding groove and the first sliding groove under the drive of the first abutting-pushing assembly; the second hanger unit is located between the second clamping plate and the plurality of second clamping fingers, and the plurality of second clamping fingers and the plurality of hanging pieces of the first hanger unit are arranged in a one-to-one opposite mode.

In some embodiments, the first pushing assembly comprises a first guide plate and a first pushing plate; the second pushing component comprises a second guide plate and a second pushing plate; the first guide plate and the second guide plate are arranged opposite to the first connecting plate and the second connecting plate, the first pushing plate and the second pushing plate are arranged in a staggered mode, the second pushing plate is located between the first guide plate and the first connecting plate, the first pushing plate is located between the second guide plate and the second connecting plate, the first pushing plate is connected with the second connecting plate through the first pushing plate, and the second pushing plate is connected with the first connecting plate through the second pushing plate; one side of the first pushing plate is used for being abutted against the driving assembly, and the other side of the first pushing plate is abutted against the first resetting assembly; one side of the second pushing plate is used for being abutted against the driving assembly, and the other side of the second pushing plate is abutted against the second resetting assembly; the first pushing plate is used for driving the second clamping mechanism to move through the first guide plate under the driving of the driving assembly and compressing the first resetting assembly; the second abutting and pushing plate is used for driving the first clamping mechanism to move through the second guide plate under the driving of the driving assembly and compressing the second resetting assembly.

In some embodiments, the first guide plate includes a first guide main body, a first limiting portion and a first guide portion, the first guide main body is connected to one side of the second connecting plate away from the bearing plate, the first limiting portion and the first guide portion are disposed at an interval and are respectively connected to two ends of the first guide main body, the first limiting portion and the first guide portion extend toward the second guide plate, one end of the first guide main body close to the first limiting portion is provided with a first guide groove, the first guide portion has a first step, and the first pushing plate is connected to the first limiting portion and the first guide portion; the second guide plate comprises a second guide main body, a second limiting part and a second guide part, the second guide main body is connected with one side, away from the bearing plate, of the first connecting plate, the second limiting part and the second guide part are arranged at intervals and are respectively connected to two ends of the second guide main body, the second limiting part and the second guide part extend towards the first guide plate, one end, close to the second limiting part, of the second guide main body is provided with a second guide groove, the second guide part is provided with a second step, and the second pushing plate is connected with the second limiting part and the second guide part; the first guide part is arranged in the second guide groove in a sliding mode, and the second guide part is arranged in the first guide groove in a sliding mode.

In some embodiments, the first clamping plate, the first clamping finger, the second clamping plate and the second clamping finger are provided with a pressing surface matched with the corresponding hanging piece on the side, corresponding to the hanging piece, of the first clamping plate, the first clamping finger, the second clamping finger and the second clamping finger, and the pressing surface is used for being matched with the corresponding hanging piece to press the corresponding hanging piece.

In some embodiments, the first reset assembly includes a first stopper plate and a first resilient member; the first stop plate is positioned on one side, away from the second abutting assembly, of the first abutting assembly, the first stop plate is connected with one side, away from the hanger, of the bearing plate, one end of the first elastic piece is connected with the first stop plate, and the other end of the first elastic piece abuts against the first abutting assembly; the second reset assembly comprises a second stop plate and a second elastic piece; the second stop plate is positioned on one side, away from the first abutting assembly, of the second abutting assembly, the second stop plate is connected with one side, away from the hanging tool, of the bearing plate, one end of the second elastic piece is connected with the second stop plate, and the other end of the second elastic piece abuts against the second abutting assembly.

In some embodiments, the drive assembly includes a handle and a cam; the cam is rotatably arranged between the first abutting assembly and the second abutting assembly, and the handle is connected with the cam; the cam is used for rotating under the driving of the handle to push the first pushing component and the second pushing component to be away from each other, so that the first pushing component and the second pushing component respectively drive the second clamping mechanism and the first clamping mechanism to be close to each other and compress the first resetting component and the second resetting component.

The anode hanger, the bearing plate, the first clamping mechanism, the second clamping mechanism and the driving mechanism are matched with each other, the driving assembly pushes the first pushing assembly and the second pushing assembly, so that the first pushing assembly and the second pushing assembly respectively drive the second clamping mechanism and the first clamping mechanism to approach each other and compress the first resetting assembly and the second resetting assembly, the first clamping mechanism and the second clamping mechanism extrude the first hanger unit and the second hanger unit due to the mutual approach, the first hanger unit and the second hanger unit are in a clamping state, and an operator can place materials on the clamped first hanger unit and the clamped second hanger unit, so that the materials can be loaded; the driving assembly is separated from the first abutting and pushing assembly and the second abutting and pushing assembly, so that the first resetting assembly and the second resetting assembly elastically abut and push the first abutting and pushing assembly and the second abutting and pushing assembly, and then the first abutting and pushing assembly and the second abutting and pushing assembly respectively drive the second clamping mechanism and the first clamping mechanism to be away from each other, so that the first hanger unit and the second hanger unit are loosened, the first hanger unit and the second hanger unit are enabled to be in a natural state, and the first hanger unit and the second hanger unit in the natural state can tightly support materials, so that the materials are fixed. According to the anode hanger provided by the embodiment of the application, the hanger unit is clamped or loosened to realize automatic operation, the hanger unit does not need to be manually clamped or loosened by an operator, the feeding efficiency of the operator is favorably improved, and the labor intensity of the operator is reduced.

In addition, the anode hanger tightly supports the material in a natural state, the material tightly supporting action has high stability, and the situation that the driving assembly loses the supporting and pushing force on the first supporting and pushing assembly and the second supporting and pushing assembly due to misoperation of the driving assembly under the condition that the driving assembly supports and pushes the first supporting and pushing assembly and the second supporting and pushing assembly to tightly support the material is avoided, so that the first hanger unit and the second hanger unit cannot effectively tightly support the material.

Drawings

Fig. 1 is a schematic perspective view of an anode hanger according to an embodiment of the present application.

Fig. 2 is a schematic perspective view of the anode hanger shown in fig. 1 with the bracket assembly and the driving assembly disassembled from another perspective view.

Fig. 3 is an exploded view of the anode hanger shown in fig. 1.

Fig. 4 is an exploded schematic view of the first pushing assembly and the second pushing assembly shown in fig. 3.

Fig. 5 is a schematic view of the anode hanger shown in fig. 2, in which the bracket assembly, the sliding assembly, and a part of the driving assembly are omitted, and the rear cam pushes the first pushing assembly and the second pushing assembly.

Description of the main elements

Anode hanging tool 100

Hanging tool 10

Hanger body 11

First hanger unit 12

Second hanger unit 13

Pendant 14

Carrier plate 20

Bearing bit 21

Positioning groove 22

First chute 23

Second chute 24

Third slide groove 25

First clamping mechanism 30

First connecting plate 31

First clamping plate 32

First clamping finger 33

Second clamping mechanism 40

Second connecting plate 41

Second clamping plate 42

Second clamping finger 43

Pressing surface 44

Drive mechanism 50

Drive assembly 51

Base 511

Handle 512

Cam 513

First pushing component 52

First guide plate 521

First guide body 5211

First position-limiting portion 5212

First guide part 5213

First guide groove 5214

First step 5215

First push-against plate 522

Second pushing component 53

Second guide plate 531

Second guide body 5311

The second position-limiting portion 5312

Second guide portion 5313

Second guide groove 5314

Second step 5315

Second push plate 532

First reduction assembly 54

First stopper 541

First elastic member 542

Second reduction assembly 55

Second stopper plate 551

Second elastic member 552

Bracket assembly 60

Substrate 61

Support post 62

Supporting seat 63

Slide rail assembly 70

Guide rail 71

Slider 72

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative and are only for the purpose of explaining the present application and are not to be construed as limiting the present application.

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be construed as limiting the present application. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first" and "second" may explicitly or implicitly include one or more of the described features. In the description of the present application, it is to be noted that the meaning of "a plurality" is two or more unless specifically defined otherwise.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be mechanically, electrically, or communicatively linked, directly or indirectly through intervening media, or in a communication or interaction between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

Some embodiments of the present application will be described in detail below with reference to the accompanying drawings.

Referring to fig. 1, some embodiments of the present application provide an anode hanger 100. The anode hanger 100 is used for placing and holding materials (not shown) to facilitate the anodic oxidation of the materials in the oxidation pond. Wherein, the material can be an object such as a middle frame.

Referring to fig. 1, an anode hanger 100 includes a hanger 10, a carrier plate 20, a first clamping mechanism 30, a second clamping mechanism 40, and a driving mechanism 50.

The hanger 10 comprises a hanger body 11, a first hanger unit 12 and a second hanger unit 13, wherein the first hanger unit 12 and the second hanger unit 13 are arranged on the hanger body 11 in a staggered mode, and the first hanger unit 12 and the second hanger unit 13 are used for placing and tightly supporting materials. The bearing plate 20 has a bearing position 21, the hanger 10 is installed at the bearing position 21, and the hanger 10 can be taken down from the bearing plate 20, so as to conveniently place the hanger 10 and the tightly supported material on the hanger 10 into the oxidation pond for anodic oxidation. The first clamping mechanism 30 and the second clamping mechanism 40 are movably arranged on the bearing plate 20, the first clamping mechanism 30 and the second clamping mechanism 40 are located on two opposite sides of the bearing position 21, and the first clamping mechanism 30 and the second clamping mechanism 40 are used for cooperatively pressing the first hanger unit 12 and the second hanger unit 13 so as to place materials on the first hanger unit 12 and the second hanger unit 13. The driving mechanism 50 is disposed on a side of the loading plate 20 away from the hanger 10, and is used for driving the first clamping mechanism 30 and the second clamping mechanism 40 to move toward or away from each other so as to press or release the first hanger unit 12 and the second hanger unit 13.

Referring to fig. 2, the driving mechanism 50 includes a driving element 51, a first pushing element 52, a second pushing element 53, a first resetting element 54 and a second resetting element 55. The driving assembly 51, the first abutting assembly 52, the second abutting assembly 53, the first resetting assembly 54 and the second resetting assembly 55 are all disposed on a side of the bearing plate 20 away from the hanger 10. The first abutting assembly 52 and the second abutting assembly 53 are disposed opposite to the first clamping mechanism 30 and the second clamping mechanism 40, the first abutting assembly 52 is connected to the second clamping mechanism 40, the second abutting assembly 53 is connected to the first clamping mechanism 30, and the driving assembly 51 is rotatably disposed between the first abutting assembly 52 and the second abutting assembly 53. One end of the first restoring member 54 is connected to the carrier plate 20, and the other end of the first restoring member 54 abuts against the first abutting member 52. One end of the second reset component 55 abuts against the bearing plate 20, and the other end of the second reset component 55 abuts against the second abutting component 53. The driving assembly 51 is used for pushing the first pushing assembly 52 and the second pushing assembly 53 to move away from each other, so that the first pushing assembly 52 and the second pushing assembly 53 respectively drive the second clamping mechanism 40 and the first clamping mechanism 30 to approach each other and compress the first resetting assembly 54 and the second resetting assembly 55, the first resetting assembly 54 and the second resetting assembly 55 generate elasticity, the first clamping mechanism 30 and the second clamping mechanism 40 approach each other to extrude the first hanger unit 12 and the second hanger unit 13, and therefore materials can be placed on the extruded first hanger unit 12 and the extruded second hanger unit 13. The driving assembly 51 is further configured to be separated from the first abutting assembly 52 and the second abutting assembly 53, so that the first resetting assembly 54 and the second resetting assembly 55 elastically abut against and push the first abutting assembly 52 and the second abutting assembly 53 to approach each other, and further the first abutting assembly 52 and the second abutting assembly 53 respectively drive the second clamping mechanism 40 and the first clamping mechanism 30 to move away from each other, the first clamping mechanism 30 and the second clamping mechanism 40 lose the pressing force on the first hanger unit 12 and the second hanger unit 13, and the first hanger unit 12 and the second hanger unit 13 are released to be in a natural state, so as to tightly support the material in the natural state.

Therefore, in order to improve the material loading efficiency of the material and reduce the labor intensity of the operator, in the anode hanger 100 provided in the embodiment of the present application, the driving assembly 51 pushes the first pushing assembly 52 and the second pushing assembly 53, so that the first pushing assembly 52 and the second pushing assembly 53 respectively drive the second clamping mechanism 40 and the first clamping mechanism 30 to approach each other and compress the first resetting assembly 54 and the second resetting assembly 55, the first clamping mechanism 30 and the second clamping mechanism 40 press the first hanger unit 12 and the second hanger unit 13 due to the approach of each other, so that the first hanger unit 12 and the second hanger unit 13 are in the clamping state, and the operator can place the material on the clamped first hanger unit 12 and the clamped second hanger unit 13, thereby implementing the material loading; the driving assembly 51 is separated from the first abutting assembly 52 and the second abutting assembly 53, so that the first resetting assembly 54 and the second resetting assembly 55 elastically abut against the first abutting assembly 52 and the second abutting assembly 53, the first abutting assembly 52 and the second abutting assembly 53 respectively drive the second clamping mechanism 40 and the first clamping mechanism 30 to be away from each other, the first hanger unit 12 and the second hanger unit 13 are loosened, the first hanger unit 12 and the second hanger unit 13 are in a natural state, and the first hanger unit 12 and the second hanger unit 13 in the natural state can tightly support materials, so that the materials are fixed. According to the anode hanger 100 provided by the embodiment of the application, the hanger unit is clamped or loosened to realize automatic operation, and the hanger unit is not required to be manually clamped or loosened by an operator, so that the feeding efficiency of the operator is improved, and the labor intensity of the operator is reduced.

In addition, since the anode hanger 100 tightly supports the material in a natural state, the tightening action of the material has higher stability, and it is avoided that the driving assembly 51 loses the pushing force on the first pushing assembly 52 and the second pushing assembly 53 due to the misoperation of the driving assembly 51 under the condition that the driving assembly 51 pushes the first pushing assembly 52 and the second pushing assembly 53 to tightly support the material, so that the first hanger unit 12 and the second hanger unit 13 cannot effectively tighten the material, which is beneficial to improving the stability of the anode hanger 100.

Referring to fig. 1 and fig. 2, in the embodiment of the present application, the anode hanger 100 further includes a bracket assembly 60 and a slide rail assembly 70. The bracket assembly 60 includes a base plate 61, a supporting column 62 and a supporting seat 63, and the slide rail assembly 70 includes a guide rail 71 and a slider 72. The base plate 61 is disposed opposite to the carrier plate 20 and below the carrier plate 20, and the number of the support pillars 62 is four, and the four support pillars are respectively connected to the base plate 61 and the carrier plate 20 for supporting the carrier plate 20, so that a space for accommodating the driving mechanism 50 and other mechanisms is formed between the carrier plate 20 and the base plate 61. The supporting seats 63 are arranged on the base plate 61, the number of the supporting seats 63 is four, the number of the slide rail assemblies 70 is also four, the guide rails 71 of the slide rail assemblies 70 are arranged on the corresponding supporting seats 63, and the sliders 72 are arranged on the corresponding guide rails 71 and connected with the corresponding first clamping mechanisms 30 and the corresponding second clamping mechanisms 40, so that the first clamping mechanisms 30 and the second clamping mechanisms 40 can move along the length direction of the guide rails 71 to be close to or away from each other. Wherein the driving assembly 51 is disposed on the substrate 61.

Referring to fig. 3, in the embodiment of the present application, the first hanger unit 12 and the second hanger unit 13 both include a plurality of hangers 14 arranged at intervals, and the plurality of hangers 14 of the first hanger unit 12 and the plurality of hangers 14 of the second hanger unit 13 are arranged in a staggered manner in sequence. The number of the hangers 14 may be one, two, three, or more. When the pendant 14 is extruded, materials can be placed on the extruded pendant 14; when the hanging member 14 is in a natural state, the hanging member 14 is spread to support the material tightly. According to the shape and size of the material, one hanging member 14 can be used for tightly supporting one material, and two, three or more hanging members 14 can be used for tightly supporting one material, which is not described in detail in the embodiment of the present application.

Referring to fig. 1 and fig. 3, in the embodiment of the present application, a positioning groove 22, a first sliding groove 23, a second sliding groove 24, and a third sliding groove 25 are formed on a supporting plate 20. The positioning groove 22 is located at the bearing position 21 for bearing the hanger body 11 and positioning the hanger body 11, the positioning groove 22 is approximately located in the middle of the bearing plate 20, and the hanger body 11 is adapted to the positioning groove 22, so that the hanger body 11 is accurately placed in the positioning groove 22. The first sliding groove 23 is disposed on the bearing position 21 and penetrates through two opposite sides of the bearing plate 20, the first sliding groove 23 is communicated with the positioning groove 22, the second sliding groove 24 and the third sliding groove 25 are respectively disposed on two opposite sides of the bearing position 21, and the second sliding groove 24 and the third sliding groove 25 both penetrate through two opposite sides of the bearing plate 20. Wherein the first hanger unit 12 is located between the first chute 23 and the second chute 24, and the second hanger unit 13 is located between the first chute 23 and the third chute 25. The first clamping mechanism 30 is slidably disposed in the first sliding groove 23 and the second sliding groove 24, the second clamping mechanism 40 is slidably disposed in the first sliding groove 23 and the third sliding groove 25, and the first clamping mechanism 30 and the second clamping mechanism 40 cooperate to press the first hanger unit 12 and the second hanger unit 13. Thus, the positioning groove 22 is formed on the carrier plate 20, so that the hanger 10 can be conveniently positioned. Through the arrangement of the first sliding chute 23, the second sliding chute 24 and the third sliding chute 25, both the first clamping mechanism 30 and the second clamping mechanism 40 can penetrate through the bearing plate 20, so that the parts of the first clamping mechanism 30 and the second clamping mechanism 40, which are positioned below the bearing plate 20, are used for being connected with the second abutting-against component 53 and the first abutting-against component 52, and the parts of the first clamping mechanism 30 and the second clamping mechanism 40, which are positioned above the bearing plate 20, are used for extruding and loosening the first hanger unit 12 and the second hanger unit 13, so that the first clamping mechanism 30 and the second clamping mechanism 40 can move on the bearing plate 20 under the driving of the second abutting-against component 53 and the first abutting-against component 52, and can extrude and loosen the first hanger unit 12 and the second hanger unit 13.

Referring to fig. 3, in the embodiment of the present application, the first clamping mechanism 30 includes a first connecting plate 31, a first clamping plate 32, and a plurality of first clamping fingers 33 arranged at intervals.

Specifically, the first clamping plate 32 is slidably disposed in the second sliding groove 24, two ends of the first clamping plate 32 protrude out of the second sliding groove 24, the plurality of first clamping fingers 33 are slidably disposed in the first sliding groove 23, two ends of each first clamping finger 33 protrude out of the first sliding groove 23, the first connecting plate 31 is located on one side of the bearing plate 20 away from the hanger 10, one end of the first connecting plate 31 is connected with the first clamping plate 32, the other end of the first connecting plate 31 is connected with the plurality of first clamping fingers 33, and the first connecting plate 31 is further connected with the second abutting and pushing assembly 53. The first connecting plate 31 is used for driving the first clamping plate 32 and the plurality of first clamping fingers 33 to move in the second sliding groove 24 and the first sliding groove 23 under the driving of the second abutting-pushing component 53. The first hanger unit 12 is located between the first clamping plate 32 and the first clamping fingers 33, and the first clamping fingers 33 are arranged opposite to the hanging members 14 of the second hanger unit 13. The first connecting plate 31 is further connected to the slider 72 of the slide assembly 70 to slide the first clamping mechanism 30 relative to the carrier plate 20.

Referring to fig. 3, in the embodiment of the present application, the second clamping mechanism 40 includes a second connecting plate 41, a second clamping plate 42 and a plurality of second clamping fingers 43.

Specifically, the second clamping plate 42 is slidably disposed in the third sliding groove 25, two ends of the second clamping plate 42 protrude out of the third sliding groove 25, the plurality of second clamping fingers 43 are slidably disposed in the first sliding groove 23, two ends of each second clamping finger 43 protrude out of the first sliding groove 23, the plurality of second clamping fingers 43 and the plurality of first clamping fingers 33 are sequentially arranged in a staggered manner, the second connecting plate 41 is located on one side of the bearing plate 20 away from the hanger 10, one end of the second connecting plate 41 is connected with the second clamping plate 42, the other end of the second connecting plate 41 is connected with the plurality of second clamping fingers 43, and the second connecting plate 41 is further connected with the first pushing component 52. The second connecting plate 41 is used for driving the second clamping plate 42 and the plurality of second clamping fingers 43 to move in the third sliding slot 25 and the first sliding slot 23 under the driving of the first pushing component 52. The second hanger unit 13 is located between the second clamping plate 42 and the second clamping fingers 43, and the second clamping fingers 43 are arranged opposite to the hanging members 14 of the first hanger unit 12 one by one. The second connecting plate 41 is also connected to the slider 72 of the slide rail assembly 70 to slide the second clamping mechanism 40 relative to the carrier plate 20.

Referring to fig. 1 and 3, when the first clamping mechanism 30 and the second clamping mechanism 40 are used, the first abutting assembly 52 and the second abutting assembly 53 respectively drive the second connecting plate 41 and the first connecting plate 31 to approach each other, the first connecting plate 31 drives the first clamping plate 32 and the plurality of first clamping fingers 33 to move towards the second clamping plate 42, so that the first clamping plate 32 presses one side of the plurality of hangers 14 on the first hanger unit 12, and the plurality of first clamping fingers 33 and the plurality of second clamping fingers 43 move in a staggered manner to press one side of the plurality of hangers 14 on the second hanger unit 13; the second connecting plate 41 drives the second clamping plate 42 and the second clamping fingers 43 to move towards the first clamping plate 32, so that the second clamping plate 42 presses the other sides of the hangers 14 on the second hanger unit 13, the second clamping fingers 43 and the first clamping fingers 33 move in a staggered manner to press the other sides of the hangers 14 on the first hanger unit 12, and thus when the first clamping mechanism 30 and the second clamping mechanism 40 approach each other, the first clamping plate 32 and the second clamping fingers 43 cooperate to press the hangers 14 on the first hanger unit 12, and the second clamping plate 42 and the first clamping fingers 33 cooperate to press the hangers 14 on the second hanger unit 13, so that the plurality of hangers 14 on the first hanger unit 12 and the plurality of hangers 14 on the second hanger unit 13 are pressed, and a material can be placed on the pressed hangers 14.

Referring to fig. 1, in order to better press the hanging member 14 without damaging the hanging member 14, in the embodiment of the present application, the first clamping plate 32, the first clamping finger 33, the second clamping plate 42 and the second clamping finger 43 have a pressing surface 44 adapted to the corresponding hanging member 14 on a side facing the corresponding hanging member 14, the pressing surface 44 is used for adapting to press the corresponding hanging member 14, and the pressing surface 44 is an inclined surface, a curved surface or other surface type adapted to the hanging member 14. Thus, the first clamping plate 32, the first clamping fingers 33, the second clamping plates 42 and the second clamping fingers 43 are provided with the extrusion surfaces 44 matched with the corresponding hanging parts 14 on the sides facing the corresponding hanging parts 14, so that the hanging parts 14 can be better extruded by the first clamping plate 32, the first clamping fingers 33, the second clamping fingers 42 and the second clamping fingers 43, the hanging parts 14 cannot be crushed, and the service life of the hanging parts 14 is prolonged.

Referring to fig. 3, 4 and 5, in the embodiment of the present application, the first abutting assembly 52 includes a first guiding plate 521 and a first abutting plate 522, and the second abutting assembly 53 includes a second guiding plate 531 and a second abutting plate 532.

The first guide plate 521 and the second guide plate 531 are arranged opposite to the first connecting plate 31 of the first clamping mechanism 30 and the second connecting plate 41 of the second clamping mechanism 40, the first abutting push plate 522 and the second abutting push plate 532 are arranged in a staggered manner, the second abutting push plate 532 is located between the first guide plate 521 and the first connecting plate 31, the first abutting push plate 522 is located between the second guide plate 531 and the second connecting plate 41, the first abutting push plate 522 is connected with the second connecting plate 41 through the first abutting push plate 522, and the second abutting push plate 532 is connected with the first connecting plate 31 through the second abutting push plate 532. One side of the first pushing plate 522 is used for pushing against the driving assembly 51, and the other side of the first pushing plate 522 is used for pushing against the first restoring assembly 54. One side of the second pushing plate 532 is used for pushing against the driving assembly 51, and the other side of the second pushing plate 532 is pushed against the second reset assembly 55. The first pushing plate 522 is driven by the driving assembly 51 to drive the second clamping mechanism 40 to move through the first guiding plate 521, and compresses the first restoring assembly 54. The second pushing plate 532 drives the first clamping mechanism 30 to move through the second guiding plate 531 under the driving of the driving assembly 51, and compresses the second restoring assembly 55. Thus, when the driving assembly 51 pushes the first pushing plate 522 and the second pushing plate 532 to move away from each other, the first pushing plate 522 drives the second clamping mechanism 40 to move through the first guide plate 521, and the second pushing plate 532 drives the first clamping mechanism 30 to move through the second guide plate 531, so as to drive the second clamping mechanism 40 and the first clamping mechanism 30 to approach each other to extrude the pendant 14; after the driving assembly 51 is separated from the first abutting assembly 52 and the second abutting assembly 53, the first abutting assembly 52 and the second abutting assembly 53 approach each other under the elastic abutting action of the first restoring assembly 54 and the second restoring assembly 55, so as to drive the second clamping mechanism 40 and the first clamping mechanism 30 to move away from each other to release the hanger 14, thereby enabling the anode hanger 100 to support the material in a natural state.

Referring to fig. 4, in order to prevent the first abutting assembly 52 and the second abutting assembly 53 from shifting and moving beyond the range during the relative movement, in the embodiment of the present application, the first guide plate 521 includes a first guide body 5211, a first limiting portion 5212 and a first guide portion 5213, and the second guide plate 531 includes a second guide body 5311, a second limiting portion 5312 and a second guide portion 5313. The first abutting plate 522, the first guide plate 521, the second abutting plate 532 and the second guide plate 531 are substantially U-shaped.

Specifically, the first guide body 5211 is connected to a side of the second connecting plate 41 away from the bearing plate 20, the first limiting portion 5212 and the first guide portion 5213 are disposed at an interval and connected to two ends of the first guide body 5211, the first limiting portion 5212 and the first guide portion 5213 extend toward the second guide body 5311 of the second guide plate 531, a first guide groove 5214 is formed in one end of the first guide body 5211 close to the first limiting portion 5212, the first guide portion 5213 has a first step 5215, and the first pushing plate 522 is connected to the first limiting portion 5212 and the first guide portion 5213. The second guiding body 5311 is connected to a side of the first connecting plate 31 away from the bearing plate 20, the second limiting portion 5312 and the second guiding portion 5313 are disposed at an interval and connected to two ends of the second guiding body 5311, respectively, the second limiting portion 5312 and the second guiding portion 5313 extend toward the first guiding body 5211 of the first guiding plate 521, a second guiding groove 5314 is disposed at an end of the second guiding body 5311 close to the second limiting portion 5312, the second guiding portion 5313 has a second step 5315, and the second pushing plate 532 is connected to the second limiting portion 5312 and the second guiding portion 5313. The first guide portion 5213 is slidably disposed in the second guide groove 5314, and the second guide portion 5313 is slidably disposed in the first guide groove 5214. In this way, the first guide portion 5213 and the second guide groove 5314 which are matched with each other, and the second guide portion 5313 and the first guide groove 5214 which are matched with each other are provided, so that the moving directions of the first guide plate 521 and the second guide plate 531 can be conveniently guided, the moving directions of the second clamping mechanism 40 and the first clamping mechanism 30 are ensured not to be deviated, and the like, and the second clamping mechanism 40 and the first clamping mechanism 30 can accurately press the plurality of hangers 14 which are arranged in a staggered manner. In addition, by arranging the first step 5215 and the second step 5315, the first guide plate 521 and the second guide plate 531 can be limited when the first guide plate 521 and the second guide plate 531 are close to each other, and the second clamping mechanism 40 and the first clamping mechanism 30 are prevented from excessively extruding the pendant 14 due to the fact that the movement exceeds the range, so that the pendant 14 is poor, and the service life of the pendant 14 is prolonged.

Referring to fig. 2 and 3, in the embodiment of the present invention, the first restoring assembly 54 includes a first stopping plate 541 and a first elastic member 542, and the second restoring assembly 55 includes a second stopping plate 551 and a second elastic member 552. Wherein, the first and second elastic members 542 and 552 may be springs, and the number of the first and second elastic members 542 and 552 may be one, two, three, or more. In the embodiment of the present application, the number of the first elastic member 542 and the second elastic member 552 is not limited, and may be specifically set according to actual situations.

Specifically, the first blocking plate 541 is disposed on a side of the first abutting plate 522 departing from the second abutting plate 532, the first blocking plate 541 is connected to a side of the loading plate 20 departing from the hanger 10, one end of the first elastic member 542 is connected to the first blocking plate 541, and the other end of the first elastic member 542 abuts against the first abutting plate 522 of the first abutting assembly 52. The second stop plate 551 is disposed on a side of the second pushing plate 532 departing from the first pushing plate 522, the second stop plate 551 is connected to a side of the loading plate 20 departing from the hanger 10, one end of the second elastic member 552 is connected to the second stop plate 551, and the other end of the second elastic member 552 abuts against the second pushing plate 532 of the second pushing assembly 53. In this way, by providing the first and second stop plates 541 and 551, the first and second elastic members 542 and 552 are easy to mount, and the first and second reset assemblies 54 and 55 have simple structures, which is beneficial to reducing the manufacturing cost of the anode hanger 100.

Referring to fig. 2 and 3, in the embodiment of the present application, the driving assembly 51 includes a base 511, a handle 512 and a cam 513. The base 511 is disposed below the loading board 20 and disposed on the substrate 61, the handle 512 is rod-shaped, the handle 512 is rotatably connected to one side of the base 511 facing the loading board 20, and the handle 512 is disposed below the first pushing component 52 and the second pushing component 53, so that the handle 512 does not interfere with the first pushing component 52 or the second pushing component 53 when being rotated. The cam 513 is substantially elliptical and cylindrical, and the cam 513 is connected to a side of the handle 512 facing the loading plate 20 and is located between the first abutting assembly 52 and the second abutting assembly 53, so that the cam 513 can abut against the first abutting plate 522 and the second abutting plate 532. The cam 513 is driven by the handle 512 to rotate to push the first pushing plate 522 and the second pushing plate 532 to be away from each other, so that the first pushing plate 522 and the second pushing plate 532 respectively drive the second clamping mechanism 40 and the first clamping mechanism 30 to approach each other through the first guide plate 521 and the second guide plate 531, and compress the first elastic member 542 of the first resetting component 54 and the second elastic member 552 of the second resetting component 55 through the first pushing plate 522 and the second pushing plate 532. Thus, the driving assembly 51 has a simple structure, which is advantageous for reducing the manufacturing cost of the driving assembly 51. In addition, the driving assembly 51 is a mechanical component, so that failure is not easy to occur, and the service life of the driving assembly 51 is prolonged.

Some embodiments provide an implementation process of the anode hanger 100, which is substantially as follows: as shown in fig. 1, the plurality of hangers 14 of the first hanger unit 12 and the plurality of hangers 14 of the second hanger unit 13 are in a naturally spread state. Firstly, the driving handle 512 rotates 90 ° so that the handle 512 drives the cam 513 to rotate 90 °, wherein the state before the cam 513 rotates 90 ° is shown in fig. 2, and the state after the cam 513 rotates 90 ° is shown in fig. 5; in the process of rotating the cam 513, the cam 513 pushes the first pushing plate 522 and the second pushing plate 532 to move away from each other, the first pushing plate 522 and the second pushing plate 532 respectively drive the first guide plate 521 and the second guide plate 531 to approach each other, the first guide plate 521 and the second guide plate 531 respectively drive the second clamping mechanism 40 and the first clamping mechanism 30 to approach each other to press the plurality of hangers 14 of the first hanger unit 12 and the plurality of hangers 14 of the second hanger unit 13, so that the hangers 14 are in a pressed state, and the first pushing plate 522 and the second pushing plate 532 compress the first elastic member 542 and the second elastic member 552 in the process of moving away from each other. The material is then placed on the extruded pendant 14 until placement is complete. Then, the handle 512 is driven to rotate reversely by 90 °, so that the handle 512 drives the cam 513 to rotate reversely by 90 °, wherein the state after the cam 513 rotates reversely by 90 ° is shown in fig. 2; in the process of the reverse rotation of the cam 513, the cam 513 is separated from the first abutting plate 522 and the second abutting plate 532, the first abutting plate 522 and the second abutting plate 532 do not receive the abutting force applied by the cam 513 any more, the first abutting plate 522 and the second abutting plate 532 respectively receive the elastic action of the first elastic member 542 and the second elastic member 552 and approach to each other, the first abutting plate 522 and the second abutting plate 532 respectively drive the first guide plate 521 and the second guide plate 531 to move away from each other, and the first guide plate 521 and the second guide plate 531 respectively drive the second clamping mechanism 40 and the first clamping mechanism 30 to move away from each other to loosen the plurality of hangers 14 of the first hanger unit 12 and the plurality of hangers 14 of the second hanger unit 13, so that the hangers 14 are in a naturally stretched state, thereby stretching the material. So, realize the material loading to the material.

The anode hanger 100 provided by the embodiment of the application is characterized in that the hanger 10, the bearing plate 20, the first clamping mechanism 30, the second clamping mechanism 40 and the driving mechanism 50 are mutually matched, so that automatic operation is realized for clamping and loosening the hanger 14, the hanger 14 does not need to be manually clamped or loosened by an operator, the feeding efficiency of the operator is improved, and the labor intensity of the operator is reduced. In addition, since the anode hanger 100 tightly supports the material in a natural state, the material tightly supporting action has higher stability, and it is avoided that the cam 513 loses the pushing force on the first pushing component 52 and the second pushing component 53 due to the misoperation of the handle 512 under the condition that the cam 513 pushes the first pushing component 522 and the second pushing component 532 to tightly support the material, so that the hanger 14 cannot effectively support the material, which is beneficial to improving the stability of the anode hanger 100.

It will be evident to those skilled in the art that the present application is not limited to the details of the foregoing illustrative embodiments, and that the present application may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the application being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present application and not for limiting, and although the present application is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made to the technical solutions of the present application without departing from the spirit and scope of the technical solutions of the present application.

Claims (10)

1. An anode hanger, comprising:

the hanger comprises a hanger body, a first hanger unit and a second hanger unit, wherein the first hanger unit and the second hanger unit are arranged on the hanger body in a staggered mode;

the bearing plate is provided with a bearing position and used for bearing the hanging tool;

the first clamping mechanism and the second clamping mechanism are movably arranged on the bearing plate and are positioned on two opposite sides of the bearing position; the first clamping mechanism and the second clamping mechanism are used for extruding the first hanger unit and the second hanger unit;

the driving mechanism is arranged on one side, away from the hanger, of the bearing plate and comprises a driving assembly, a first abutting assembly, a second abutting assembly, a first resetting assembly and a second resetting assembly; the first abutting and pushing assembly and the second abutting and pushing assembly are arranged opposite to the first clamping mechanism and the second clamping mechanism, the first abutting and pushing assembly is connected with the second clamping mechanism, the second abutting and pushing assembly is connected with the first clamping mechanism, and the driving assembly is rotatably arranged between the first abutting and pushing assembly and the second abutting and pushing assembly; one end of the first reset assembly is connected with the bearing plate, and the other end of the first reset assembly is abutted against the first abutting assembly; one end of the second reset assembly is connected with the bearing plate, and the other end of the second reset assembly is abutted against the second abutting-pushing assembly; the driving assembly is used for pushing the first pushing assembly and the second pushing assembly to be away from each other so that the first pushing assembly and the second pushing assembly drive the second clamping mechanism and the first clamping mechanism to be close to each other to extrude the first hanger unit and the second hanger unit and compress the first resetting assembly and the second resetting assembly; the driving assembly is further used for separating from the first abutting assembly and the second abutting assembly so that the first resetting assembly and the second resetting assembly elastically abut against and push the first abutting assembly and the second abutting assembly to be close to each other, and then the first abutting assembly and the second abutting assembly respectively drive the second clamping mechanism and the first clamping mechanism to be away from each other so as to loosen the first hanger unit and the second hanger unit.

2. The anode hanger of claim 1, wherein the first hanger unit and the second hanger unit each comprise a plurality of spaced hangers, and the plurality of hangers of the first hanger unit are sequentially arranged in a staggered manner from the plurality of hangers of the second hanger unit.

3. The anode hanger of claim 2, wherein the loading plate is provided with a positioning groove, a first sliding groove, a second sliding groove and a third sliding groove, the positioning groove is located at the bearing position for bearing the hanger body and positioning the hanger, the first sliding groove is arranged at the bearing position and penetrates through two opposite sides of the loading plate, the first sliding groove is communicated with the positioning groove, the second sliding groove and the third sliding groove are located at two sides of the positioning groove, and the second sliding groove and the third sliding groove both penetrate through two opposite sides of the loading plate.

4. The anode hanger according to claim 3, wherein the first clamping mechanism comprises a first connecting plate, a first clamping plate and a plurality of first clamping fingers arranged at intervals, the first clamping plate is slidably arranged in the second sliding groove, two ends of the first clamping plate protrude out of the second sliding groove, the plurality of first clamping fingers are positioned in the first sliding groove, two ends of each first clamping finger protrude out of the first sliding groove, the first connecting plate is positioned on one side of the bearing plate, which is far away from the hanger, one end of the first connecting plate is connected with the first clamping plate, the other end of the first connecting plate is connected with the plurality of first clamping fingers, and the first connecting plate is further connected with the second pushing assembly; the first connecting plate is used for driving the first clamping plate and the first clamping fingers to move in the second sliding groove and the first sliding groove under the driving of the second abutting and pushing assembly; the first hanger unit is located between the first clamping plate and the first clamping fingers, and the first clamping fingers and the hanging pieces of the second hanger unit are arranged in a one-to-one opposite mode.

5. The anode hanger of claim 4, wherein the second clamping mechanism comprises a second connecting plate, a second clamping plate and a plurality of second clamping fingers arranged at intervals, the second clamping plate is slidably arranged in the third sliding groove, two ends of the second clamping plate protrude out of the third sliding groove, the plurality of second clamping fingers are positioned in the first sliding groove, two ends of each second clamping finger protrude out of the first sliding groove, the plurality of second clamping fingers and the plurality of first clamping fingers are arranged in a staggered manner in sequence, the second connecting plate is positioned on one side of the bearing plate, away from the hanger, one end of the second connecting plate is connected with the second clamping plate, the other end of the second connecting plate is connected with the plurality of second clamping fingers, and the second connecting plate is further connected with the first pushing assembly; the second connecting plate is used for driving the second clamping plate and the second clamping fingers to move in the third sliding groove and the first sliding groove under the driving of the first abutting and pushing assembly; the second hanger unit is located between the second clamping plate and the plurality of second clamping fingers, and the plurality of second clamping fingers and the plurality of hanging pieces of the first hanger unit are arranged in a one-to-one opposite mode.

6. The anode hanger of claim 5, wherein the first pushing assembly comprises a first guide plate and a first pushing plate; the second pushing component comprises a second guide plate and a second pushing plate;

the first guide plate and the second guide plate are arranged opposite to the first connecting plate and the second connecting plate, the first pushing plate and the second pushing plate are arranged in a staggered mode, the second pushing plate is located between the first guide plate and the first connecting plate, the first pushing plate is located between the second guide plate and the second connecting plate, the first pushing plate is connected with the second connecting plate through the first pushing plate, and the second pushing plate is connected with the first connecting plate through the second pushing plate;

one side of the first pushing plate is used for being abutted against the driving assembly, and the other side of the first pushing plate is abutted against the first resetting assembly; one side of the second pushing plate is used for being abutted against the driving assembly, and the other side of the second pushing plate is abutted against the second resetting assembly; wherein, the first and the second end of the pipe are connected with each other,

the first pushing plate is used for driving the second clamping mechanism to move through the first guide plate under the driving of the driving assembly and compressing the first resetting assembly; the second pushing plate is used for driving the first clamping mechanism to move through the second guide plate under the driving of the driving assembly and compressing the second resetting assembly.

7. The anode hanger of claim 6, wherein the first guide plate comprises a first guide body, a first limiting portion and a first guide portion, the first guide body is connected with one side of the second connecting plate away from the loading plate, the first limiting portion and the first guide portion are arranged at intervals and are respectively connected with two ends of the first guide body, the first limiting portion and the first guide portion extend towards the second guide plate, one end of the first guide body close to the first limiting portion is provided with a first guide groove, the first guide portion is provided with a first step, and the first pushing plate is connected with the first limiting portion and the first guide portion;

the second guide plate comprises a second guide main body, a second limiting part and a second guide part, the second guide main body is connected with one side, away from the bearing plate, of the first connecting plate, the second limiting part and the second guide part are arranged at intervals and are respectively connected to two ends of the second guide main body, the second limiting part and the second guide part extend towards the first guide plate, one end, close to the second limiting part, of the second guide main body is provided with a second guide groove, the second guide part is provided with a second step, and the second pushing plate is connected with the second limiting part and the second guide part; wherein, the first and the second end of the pipe are connected with each other,

the first guide part is arranged in the second guide groove in a sliding mode, and the second guide part is arranged in the first guide groove in a sliding mode.

8. The anode hanger of claim 5, wherein the first clamping plate, the first clamping finger, the second clamping plate and the second clamping finger have a pressing surface adapted to the corresponding hanger on a side corresponding to the hanger, and the pressing surface is used for being adapted to press the corresponding hanger.

9. The anode hanger of claim 1 wherein the first reset assembly comprises a first stop plate and a first resilient member; the first stop plate is positioned on one side, away from the second abutting assembly, of the first abutting assembly, the first stop plate is connected with one side, away from the hanger, of the bearing plate, one end of the first elastic piece is connected with the first stop plate, and the other end of the first elastic piece abuts against the first abutting assembly;

the second reset assembly comprises a second stop plate and a second elastic piece; the second stop plate is positioned on one side, away from the first abutting assembly, of the second abutting assembly, the second stop plate is connected with one side, away from the hanging tool, of the bearing plate, one end of the second elastic piece is connected with the second stop plate, and the other end of the second elastic piece abuts against the second abutting assembly.

10. The anode hanger of claim 1, wherein the drive assembly comprises a handle and a cam; the cam is rotatably arranged between the first abutting component and the second abutting component, and the handle is connected with the cam; the cam is used for rotating under the driving of the handle to push the first pushing component and the second pushing component to be away from each other, so that the first pushing component and the second pushing component respectively drive the second clamping mechanism and the first clamping mechanism to be close to each other and compress the first resetting component and the second resetting component.

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