阅读说明：本技术 一种电积铜检测用的起吊装置 (Hoisting accessory that electrodeposited copper detected usefulness ) 是由 廖龙江 于 2021-01-18 设计创作，主要内容包括：本发明涉及一种起吊装置,尤其涉及一种电积铜检测用的起吊装置。提供一种操作简便,能够自动对电积铜进行卡紧搬运,人力成本低,工作效率高,方便人们使用的电积铜检测用的起吊装置。一种电积铜检测用的起吊装置,包括有：安装架；升降组件,安装在安装架上,通过滑动的方式进行升降；驱动组件,安装在升降组件上,通过转动的方式进行驱动；夹紧组件,安装在升降组件上,通过滑动的方式进行夹紧。本发明通过升降组件在起吊搬运电积铜时,能够进行升降,同时,能够对电积铜进行起吊搬运,通过驱动组件使设备在对电积铜进行起吊搬运时,能够提供动力,通过夹紧组件能够将电积铜夹紧进行吊起搬运,通过放置组件能够放置电积铜。(The invention relates to a lifting device, in particular to a lifting device for detecting electrodeposited copper. The hoisting device is simple and convenient to operate, capable of automatically clamping and carrying the electro deposited copper, low in labor cost, high in working efficiency and convenient for people to use and detect the electro deposited copper. A hoisting accessory that electrodeposited copper detected usefulness, including: a mounting frame; the lifting component is arranged on the mounting rack and is lifted in a sliding mode; the driving assembly is arranged on the lifting assembly and is driven in a rotating mode; and the clamping assembly is arranged on the lifting assembly and is used for clamping in a sliding mode. According to the invention, the lifting assembly can lift when lifting and carrying the electrodeposited copper, meanwhile, the electrodeposited copper can be lifted and carried, the driving assembly can provide power when equipment lifts and carries the electrodeposited copper, the clamping assembly can clamp the electrodeposited copper for lifting and carrying, and the placing assembly can place the electrodeposited copper.)

1. The utility model provides a hoisting accessory of electrodeposited copper detection usefulness, characterized by, including:

a mounting frame (1);

the lifting component (2) is arranged on the mounting rack (1) and is lifted in a sliding mode;

the driving component (3) is arranged on the lifting component (2) and is driven in a rotating mode;

and the clamping assembly (4) is arranged on the lifting assembly (2) and is used for clamping in a sliding mode.

2. The hoisting device for detecting the electrodeposited copper as claimed in claim 1, wherein the elevating assembly (2) comprises:

two first guide rods (21) are arranged on the mounting frame (1);

two first sliding sleeves (22), wherein the two first sliding sleeves (22) are arranged on the first guide rod (21) in a sliding manner;

two first springs (23) are arranged and are respectively arranged between the first sliding sleeve (22) and the first guide rod (21);

two first mounting blocks (24) are arranged, and are mounted on the first sliding sleeve (22);

a square frame (25) mounted between the two first mounting blocks (24);

a rotating shaft (26) rotatably mounted between the two first mounting blocks (24);

two first torsion springs (261), wherein the two first torsion springs (261) are installed between the rotating shaft (26) and the first installation block (24);

a rotating plate (27) mounted on the rotating shaft (26);

two second guide rods (28) are arranged on the rotating plate (27);

two second sliding sleeves (29), wherein the two second sliding sleeves (29) are arranged on the second guide rod (28) in a sliding manner;

and the second mounting block (291) is mounted between the two second sliding sleeves (29).

3. The hoisting device for detecting electrodeposited copper as claimed in claim 2, wherein the driving unit (3) comprises:

a mounting plate (31) mounted between the two first guide rods (21);

a reduction motor (32) mounted on the mounting plate (31);

a sector gear (33) mounted on an output shaft of the reduction motor (32);

and the full gear (34) is arranged on the rotating shaft (26), and the full gear (34) is matched with the sector gear (33).

4. A hoisting device for electro deposited copper detection as claimed in claim 3, characterized in that the clamping assembly (4) comprises:

two V-shaped plates (41), wherein the two V-shaped plates (41) are arranged on the second mounting block (291);

a cross bar (42) installed between the two V-shaped plates (41);

at least two third guide rods (43) are arranged on the cross rod (42);

at least two clamping plates (44) are arranged, and the two clamping plates (44) are arranged on the third guide rod (43) in a sliding mode;

and at least two second springs (45) are arranged between the clamping plate (44) and the third guide rod (43).

5. The hoisting device for detecting the electrodeposited copper according to claim 4, further comprising a placing component (5), wherein the placing component (5) comprises:

two fixing plates (51), wherein the two fixing plates (51) are arranged on the mounting rack (1);

a placing frame (52) installed between the two fixing plates (51);

the supporting blocks (53), supporting block (53) are two at least, all install on placing frame (52).

6. The hoisting device for detecting the electro deposited copper according to claim 5, further comprising a loosening assembly (6), wherein the loosening assembly (6) comprises:

two prismatic rods (61), wherein the prismatic rods (61) are arranged between the two third guide rods (43);

at least two sliding sleeves (62) are arranged, the sliding sleeves (62) are arranged on the prismatic rod (61) in a sliding mode, and the sliding sleeves (62) are connected with the clamping plate (44);

two cylindrical rods (63), wherein the two cylindrical rods (63) are arranged on the prismatic rod (61);

two third sliding sleeves (64) are arranged, and are both arranged on the cylindrical rod (63) in a sliding manner;

at least two connecting rods (65) are arranged, and the connecting rods (65) are rotatably arranged between the third sliding sleeve (64) and the sliding sleeve (62);

two L-shaped rods (66) are arranged, and are mounted on the third sliding sleeve (64);

the two push blocks (67) are arranged on the mounting frame (1), and the two push blocks (67) are arranged on the mounting frame (1) respectively

L-shaped bars (66) are engaged.

7. The hoisting device for detecting the electrodeposited copper according to claim 6, further comprising a pushing assembly (7), wherein the pushing assembly (7) comprises:

two pushing blocks (71), wherein the two pushing blocks (71) are rotatably arranged on the rotating plate (27);

two second torsion springs (72) are arranged, and are mounted between the pushing block (71) and the rotating plate (27);

two contact blocks (73), wherein the two contact blocks (73) are arranged on the pushing block (71);

the two arc-shaped rods (74) are arranged on the mounting frame (1);

the number of the push rods (75) is two, the push rods (75) are arranged on the arc-shaped rod (74), and the push rods (75) are matched with the contact block (73);

and two contact rods (76) are arranged, and are respectively arranged on the second mounting block (291), and the contact rods (76) are respectively matched with the contact block (73).

8. The hoisting device for detecting the electrodeposited copper according to claim 7, further comprising a rotating assembly (8), wherein the rotating assembly (8) comprises:

two third mounting blocks (81) are arranged and are mounted on the mounting frame (1);

a sloping plate (82) rotatably mounted between the two third mounting blocks (81);

and two third torsion springs (83) are arranged between the inclined plate (82) and the third mounting block (81).

Technical Field

The invention relates to a lifting device, in particular to a lifting device for detecting electrodeposited copper.

Background

One ship is suitable for low-grade copper oxide, and the produced fine copper is called electrodeposited copper. After the production of the electrodeposited copper is finished, the electrodeposited copper needs to be detected so as not to influence the subsequent use.

At present, when examining the electrodeposited copper, need detect the electrodeposited copper transport to detection device on, examine the electrodeposited copper transport at existing equipment time measuring, existing equipment operation is more loaded down with trivial details, when lifting by crane the transport, need hang the electrodeposited copper to the couple through manual, need consume great human cost, and simultaneously, at the in-process that lifts by crane, the electrodeposited copper drops easily, need stabilize the electrodeposited copper through the instrument, lead to needing to consume longer time when equipment lifts by crane and takes off the detection, inconvenient people use.

Therefore, how to design the hoisting device which is simple and convenient to operate, can automatically clamp and carry the electrodeposited copper, has low labor cost and high working efficiency, and is convenient for people to use for detecting the electrodeposited copper is the technical problem to be solved by the invention.

Disclosure of Invention

In order to overcome the defects that the existing equipment is complex to operate, the electrodeposited copper needs to be fixed by a tool when being lifted and carried, and the electrodeposited copper is easy to fall off in the carrying process and is inconvenient for people to use, the invention has the technical problems that: the hoisting device is simple and convenient to operate, capable of automatically clamping and carrying the electro deposited copper, low in labor cost, high in working efficiency and convenient for people to use and detect the electro deposited copper.

A hoisting accessory that electrodeposited copper detected usefulness, including: a mounting frame; the lifting component is arranged on the mounting rack and is lifted in a sliding mode; the driving assembly is arranged on the lifting assembly and is driven in a rotating mode; and the clamping assembly is arranged on the lifting assembly and is used for clamping in a sliding mode.

In a preferred embodiment of the present invention, the lifting assembly comprises: two first guide rods are arranged on the mounting frame; two first sliding sleeves are arranged and are arranged on the first guide rod in a sliding manner; two first springs are arranged and are arranged between the first sliding sleeve and the first guide rod; two first mounting blocks are arranged and are mounted on the first sliding sleeve; the square frame is arranged between the two first mounting blocks; the rotating shaft is rotatably arranged between the two first mounting blocks; two first torsion springs are arranged between the rotating shaft and the first mounting block; the rotating plate is arranged on the rotating shaft; two second guide rods are arranged on the rotating plate; two second sliding sleeves are arranged and are arranged on the second guide rod in a sliding manner; and the second mounting block is mounted between the two second sliding sleeves.

In a preferred embodiment of the present invention, the driving assembly comprises: the mounting plate is arranged between the two first guide rods; the speed reducing motor is arranged on the mounting plate; the sector gear is arranged on an output shaft of the speed reducing motor; and the full gear is arranged on the rotating shaft and matched with the sector gear.

In a preferred embodiment of the present invention, the clamping assembly comprises: two V-shaped plates are arranged and are mounted on the second mounting block; the cross bar is arranged between the two V-shaped plates; at least two third guide rods are arranged on the cross rod; at least two clamping plates are arranged and are arranged on the third guide rod in a sliding manner; and at least two second springs are arranged and are arranged between the clamping plate and the third guide rod.

In a preferred embodiment of the present invention, the present invention further comprises a placing component, wherein the placing component comprises: two fixing plates are arranged and are mounted on the mounting rack; the placing frame is arranged between the two fixing plates; the supporting shoe, the supporting shoe is two at least, all installs on placing the frame.

In a preferred embodiment of the present invention, a release assembly is further included, the release assembly including: two prismatic rods are arranged and are arranged between the two third guide rods; at least two sliding sleeves are arranged and are arranged on the prismatic rod in a sliding manner, and the sliding sleeves are connected with the clamping plate; two cylindrical rods are arranged and are arranged on the prismatic rod; two third sliding sleeves are arranged and are arranged on the cylindrical rod in a sliding manner; at least two connecting rods are arranged and are rotatably mounted between the third sliding sleeve and the sliding sleeve; two L-shaped rods are arranged and are arranged on the third sliding sleeve; the ejector pad, the ejector pad is two, all installs on the mounting bracket, and the ejector pad all cooperates with L type pole.

In a preferred embodiment of the present invention, the present invention further comprises a pushing assembly, the pushing assembly comprises: two pushing blocks are arranged on the rotating plate in a rotating mode; two second torsion springs are arranged and are arranged between the pushing block and the rotating plate; two contact blocks are arranged on the pushing block; the two arc-shaped rods are arranged on the mounting frame; the two push rods are arranged on the arc-shaped rod and matched with the contact block; and the two contact rods are arranged on the second mounting block and are matched with the contact block.

In a preferred embodiment of the present invention, the present invention further comprises a rotating assembly, wherein the rotating assembly comprises: two third mounting blocks are arranged and are mounted on the mounting frame; the inclined plate is rotatably arranged between the two third mounting blocks; and the two third torsion springs are arranged between the inclined plate and the third mounting block.

Has the advantages that: according to the invention, when lifting and carrying the electro-deposited copper, the lifting assembly can lift, meanwhile, the electro-deposited copper can be lifted and carried, the driving assembly can provide power for equipment when lifting and carrying the electro-deposited copper, the clamping assembly can clamp the electro-deposited copper for lifting and carrying, the placing assembly can place the electro-deposited copper, the loosening assembly can automatically loosen the equipment after carrying the electro-deposited copper to the left side, the pushing assembly can push the second mounting block to rotate forwards, the situation that the pushing block cannot push the L-shaped rod when loosening is finished is prevented, and the rotating assembly can prevent the electro-deposited copper from falling to the inner side of the equipment when loosening.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of the lifting assembly of the present invention.

Fig. 3 is a schematic perspective view of the driving assembly of the present invention.

Fig. 4 is a perspective view of the clamping assembly of the present invention.

Fig. 5 is a schematic perspective view of the placement module of the present invention.

Figure 6 is a perspective view of the release assembly of the present invention.

Fig. 7 is a schematic perspective view of the pushing assembly of the present invention.

Fig. 8 is a perspective view of the rotating assembly of the present invention.

Wherein the figures include the following reference numerals: 1. mounting bracket, 2, lifting component, 21, first guide rod, 22, first sliding sleeve, 23, first spring, 24, first mounting block, 25, square frame, 26, rotating shaft, 261, first torsion spring, 27, rotating plate, 28, second guide rod, 29, second sliding sleeve, 291, second mounting block, 3, driving component, 31, mounting plate, 32, reducing motor, 33, sector gear, 34, full gear, 4, clamping component, 41, V-shaped plate, 42, cross rod, 43, third guide rod, 44, clamping plate, 45, second spring, 5, placing component, 51, fixing plate, 52, placing frame, 53, supporting block, 6, loosening component, 61, prismatic rod, 62, sliding sleeve, 63, cylindrical rod, 64, third sliding sleeve, 65, connecting rod, 66, L-shaped rod, 67, pushing block, 7, pushing component, 71, pushing block, 72, second torsion spring, 73, Contact block, 74, arc pole, 75, push rod, 76, contact rod, 8, rotating assembly, 81, third installation block, 82, inclined plate, 83 and third torsion spring.

Detailed Description

The invention is described in detail below with reference to the drawings and specific examples, but the invention is not limited thereto.

Example 1

A hoisting accessory that electrodeposited copper detected usefulness, as shown in figure 1, including mounting bracket 1, lifting unit 2, drive assembly 3 and clamping component 4, be equipped with lifting unit 2 that goes up and down through gliding mode on the mounting bracket 1, be equipped with drive assembly 3 that goes up and down through the pivoted mode and carry out the drive on lifting unit 2, be equipped with clamping component 4 that presss from both sides through gliding mode on lifting unit 2.

When lifting by crane the transport to the electrodeposited copper, the staff puts the electrodeposited copper that needs to detect to the equipment right side, afterwards, and control lifting unit 2 drives clamping unit 4 and moves down and presss from both sides the electrodeposited copper tightly, and afterwards, control lifting unit 2 rises, accomplishes the back, makes lifting unit 2 rotate through drive assembly 3 to carry the electrodeposited copper that needs to detect through clamping unit 4, accomplish the back, close drive assembly 3 can.

As shown in fig. 1, 2, 3, 4 and 7, the lifting assembly 2 includes a first guide rod 21, a first sliding sleeve 22, a first spring 23, a first mounting block 24, a square frame 25, a rotating shaft 26, a first torsion spring 261, a rotating plate 27, a second guide rod 28, a second sliding sleeve 29 and a second mounting block 291, the first guide rod 21 is symmetrically welded to the front and the rear of the upper portion of the mounting frame 1, the first sliding sleeve 22 is slidably disposed on the first guide rod 21, the first spring 23 is wound between the first sliding sleeve 22 and the first guide rod 21, the first mounting block 24 is rotatably welded to the inner side of the first sliding sleeve 22, the square frame 25 is fixedly secured between the front and the rear first mounting blocks 24 by bolts, the rotating shaft 26 is disposed between the lower portions of the front and rear first mounting blocks 24, the first torsion spring 261 is connected between the rotating shaft 26 and the first mounting block 24, the rotating plate 27 is disposed on the rotating shaft 26, the second guide rods 28 are welded to the front and rear sides of the lower portion of the rotating, the second guide rod 28 is provided with a second sliding sleeve 29 in a sliding manner, and a second mounting block 291 is welded between the front and rear second sliding sleeves 29.

When hoisting and carrying the electrodeposited copper, a worker pushes the first sliding sleeve 22 to slide downwards on the first guide rod 21, the first spring 23 is compressed, the first mounting block 24 drives the rotating plate 27 to move downwards through the rotating shaft 26, the second mounting block 291 drives the clamping assembly 4 to move downwards, then the electrodeposited copper to be detected is clamped through the clamping assembly 4, after the completion, the worker loosens the first sliding sleeve 22, at this time, under the action of the resetting of the first spring 23, the first sliding sleeve 22 drives the first mounting block 24 to move upwards and reset, the rotating shaft 26 drives the rotating plate 27 to move upwards, so as to hoist the electrodeposited copper, then, the worker drives the rotating shaft 26 to rotate anticlockwise through the driving assembly 3, the rotating plate 27 rotates anticlockwise, the first torsion spring 261 is compressed, at this time, the second sliding sleeve 29 slides leftwards on the second guide rod 28, second installation piece 291 drives the electrodeposited copper through clamping component 4 thereupon and moves left and carry, and the back is accomplished, closes drive assembly 3, and under the effect that first torsion spring 261 resets, revolving plate 27 clockwise rotates and resets, and second sliding sleeve 29 drives second installation piece 291 and slides right thereupon and resets, so, when lifting by crane the transport electrodeposited copper, can go up and down, simultaneously, can lift by crane the transport to the electrodeposited copper.

As shown in fig. 1 and 3, the driving assembly 3 includes a mounting plate 31, a reduction motor 32, a sector gear 33 and a full gear 34, the mounting plate 31 is fixedly connected between the upper portions of the front and rear first guide rods 21 through bolts, the reduction motor 32 is fixedly connected to the bottom of the mounting plate 31 through bolts, the sector gear 33 is connected to an output shaft of the reduction motor 32 through a key, the full gear 34 is connected to the rear side of the rotating shaft 26 through a key, and the full gear 34 is matched with the sector gear 33.

After pressing from both sides the deposit copper tight through clamping assembly 4, the staff starts gear motor 32 and drives sector gear 33 clockwise rotation, when sector gear 33 clockwise rotation to with full gear 34 meshing, sector gear 33 clockwise rotation drives full gear 34 anticlockwise rotation, pivot 26 is anticlockwise rotation therewith, thereby carry the deposit copper, when sector gear 33 clockwise rotation to break away from the back with full gear 34, at this moment, pivot 26 resets clockwise, after the completion, staff closes gear motor 32, and thus, make equipment lift by crane the transport to the deposit copper, can provide power, it can to stop gear motor 32 after the transport finishes.

As shown in fig. 1, 4 and 6, the clamping assembly 4 includes V-shaped plates 41, a cross bar 42, a third guide rod 43, a clamping plate 44 and a second spring 45, the V-shaped plates 41 are welded to the front and rear sides of the lower portion of the second mounting block 291, the cross bar 42 is welded between the lower portions of the front and rear V-shaped plates 41, the third guide rods 43 are welded to the front and rear sides of the cross bar 42 in a bilateral symmetry manner, the clamping plate 44 is slidably arranged on the third guide rods 43, and the second spring 45 is wound between the clamping plate 44 and the third guide rods 43.

When hoisting and carrying the electro-deposited copper, the second mounting block 291 moves downwards to drive the cross rod 42 to move downwards through the V-shaped plate 41, the third guide rod 43 drives the clamping plate 44 to move downwards, when the clamping plate 44 moves downwards to be in contact with the electro-deposited copper, the electro-deposited copper pushes the clamping plate 44 to slide outwards on the third guide rod 43, the second spring 45 is compressed, the clamping plate 44 moves downwards to a proper distance and then is separated from the electro-deposited copper, under the reset action of the second spring 45, the clamping plate 44 slides inwards to clamp the electro-deposited copper, then, the second mounting block 291 moves upwards to reset, so that the electro-deposited copper is hoisted, after hoisting, the second mounting block 291 moves leftwards to drive the electro-deposited copper to move leftwards, then, a worker pushes the clamping plate 44 to slide outwards to loosen the electro-deposited copper for detection, and therefore, the electro-deposited copper can be hoisted and carried tightly.

Example 2

On the basis of embodiment 1, as shown in fig. 1 and 5, the installation rack further comprises a placement component 5, wherein the placement component 5 comprises a fixing plate 51, a placement frame 52 and supporting blocks 53, the fixing plate 51 is fixedly connected to the front side and the rear side of the right part of the installation rack 1 through bolts, the placement frame 52 is fixedly connected between the front fixing plate 51 and the rear fixing plate 51 through bolts, and the four supporting blocks 53 are welded in the placement frame 52.

When carrying the detection to the electrodeposited copper, the staff puts the electrodeposited copper that needs to detect to placing in the frame 52, and supporting shoe 53 can prop up the electrodeposited copper that needs to detect, and convenient the clamp is tight.

On the basis of the embodiment 1, as shown in fig. 1 and 6, the loosening assembly 6 is further included, the loosening assembly 6 includes a prismatic rod 61, a sliding sleeve 62, a cylindrical rod 63, a third sliding sleeve 64, a connecting rod 65, an L-shaped rod 66 and a pushing block 67, the prismatic rod 61 is welded between the upper portions of the left and right third guide rods 43, the prismatic rod 61 is provided with two sliding sleeves 62 in a sliding manner, the sliding sleeves 62 are connected with the clamping plate 44, the cylindrical rod 63 is welded on the outer side of the middle portion of the prismatic rod 61, the third sliding sleeve 64 is arranged on the cylindrical rod 63 in a sliding manner, the connecting rods 65 are rotatably arranged between the left and right sides of the third sliding sleeve 64 and the sliding sleeve 62, the top of the third sliding sleeve 64 is provided with the L-shaped rod 66, the pushing blocks 67 are symmetrically arranged on the front and back of the left portion of the mounting frame 1.

When carrying after clamping the electrodeposited copper, the third guide rod 43 moves leftwards to drive the prismatic rod 61 to move leftwards, the cylindrical rod 63 drives the third sliding sleeve 64 to move leftwards, so as to drive the L-shaped rod 66 to move leftwards, when the L-shaped rod 66 moves leftwards to be in contact with the pushing block 67, the pushing block 67 pushes the L-shaped rod 66 to move inwards, the third sliding sleeve 64 slides inwards on the cylindrical rod 63, the sliding sleeve 62 is further pushed to slide outwards through the connecting rod 65, the clamping plate 44 moves outwards along with the third sliding sleeve, the electrodeposited copper is loosened, and therefore the electrodeposited copper can be automatically loosened after being carried to the left side.

On the basis of embodiment 1, as shown in fig. 1, 4 and 7, the device further comprises a pushing assembly 7, the pushing assembly 7 comprises a pushing block 71, a second torsion spring 72, a contact block 73, an arc-shaped rod 74, a push rod 75 and a contact rod 76, the pushing block 71 is rotatably arranged on the front side and the rear side of the left portion of the rotating plate 27, the second torsion spring 72 is arranged between the pushing block 71 and the rotating plate 27, the contact block 73 is welded on the left side of the pushing block 71, the arc-shaped rods 74 are symmetrically welded on the front side and the rear side of the upper portion of the left side of the mounting frame 1, the push rod 75 is welded on the inner side of the upper portion of the arc-shaped rod 74, the push rod 75 is matched with the contact block 73, the contact rod 76 is welded on the front side and.

When hoisting and carrying the electro-deposited copper, the rotating plate 27 rotates anticlockwise to drive the pushing block 71 to move downwards, the contact block 73 moves downwards along with the pushing block, when the contact block 73 moves downwards to be contacted with the push rod 75, the push rod 75 pushes the contact block 73 to rotate upwards, the pushing block 71 rotates downwards, the second torsion spring 72 is compressed, when the pushing block 71 rotates downwards to be contacted with the contact rod 76, the pushing block 71 rotates downwards to push the second mounting block 291 to move leftwards through the contact rod 76, when the rotating plate 27 rotates clockwise to reset, the pushing block 71 drives the contact block 73 to move upwards to reset and is separated from the push rod 75, at the moment, under the reset action of the second torsion spring 72, the pushing block 71 rotates upwards to reset along with the contact rod, so that when hoisting and carrying the electro-deposited copper, the second mounting block 291 can be pushed to move leftwards, and the force is prevented from being insufficient when loosening after carrying is completed, the push block 67 cannot push the L-shaped lever 66.

On the basis of embodiment 1, as shown in fig. 1 and 8, the power transmission device further includes a rotating assembly 8, the rotating assembly 8 includes a third mounting block 81, an inclined plate 82 and a third torsion spring 83, the third mounting block 81 is symmetrically welded to the front and back of the left portion of the mounting frame 1, the inclined plate 82 is rotatably disposed between the front and back third mounting blocks 81, and the third torsion spring 83 is disposed between the inclined plate 82 and the third mounting block 81.

When lifting by crane the transport to the electro-deposited copper, when the electro-deposited copper moved to left and contact with swash plate 82, the electro-deposited copper promoted swash plate 82 and rotates downwards, and third torsion spring 83 is compressed, afterwards, detect the electro-deposited copper, detect the back, tak away the electro-deposited copper, at this moment, under the effect that third torsion spring 83 reset, swash plate 82 upwards rotated and resets, so, when lifting by crane the transport electro-deposited copper, can prevent that the electro-deposited copper from dropping when unclamping inboard at the equipment.

Although the present invention has been described in detail with reference to the above embodiments, it will be apparent to those skilled in the art from this disclosure that various changes or modifications can be made herein without departing from the principles and spirit of the invention as defined by the appended claims. Therefore, the detailed description of the embodiments of the present disclosure is to be construed as merely illustrative, and not limitative of the remainder of the disclosure, but rather to limit the scope of the disclosure to the full extent set forth in the appended claims.