TWM503420U - Removable insulation coverage device - Google Patents

Description

Detachable insulation coating device

The present invention relates to a detachable insulation coating device, and more particularly to a coating device for applying a clamping position on the outer periphery of a cathode plate in an electrolysis process.

In order to achieve the purpose of resource recycling, various recycling methods are used to recover the recyclable materials. The electrolysis method is widely used in the field of metal recycling. Please refer to Figure 11, the electrolytic recovery method is based on electrolysis. In the tank 80, the cathode plate 81 and the anode plate 82 are arranged in a row, and the lines are connected in series on the side. When the recovered liquid is poured into the electrolytic cell 80, the resolved metal is attached to the peripheral surface of the cathode plate 81 by an electrolysis program. .

As shown in Fig. 12, the cathode plate 81 is placed in the electrolytic cell 80 for electrolysis. Since the cathode plate 81 is directly placed at the frame edge of the electrolytic cell 80, the cathode plate 81 is provided with the entire peripheral surface and the recovered liquid. After the completion of the electrolysis, the metal deposit is coated on the entire peripheral surface of the yin-yang plate 81, as shown in FIG. 13 and FIG. 14, which is the front view and the side view of the cathode plate 81 taken out from the electrolytic cell 80. And the region where the cathode plate 81 is in contact with the recovered liquid is covered with a metal layer 90, and the metal layer 90 is removed for reuse, and the worker must use a tool to discharge the material, such as the cooperation of the shovel and the hammer, to the metal layer 90. Separated from the cathode plate 81.

However, since the metal layer 90 is tightly wrapped around the entire circumference of the cathode plate 81, it takes a lot of time to perform tapping during the reclaiming, which is a time-consuming method of retrieving and tapping with a tool. Metal collisions can cause metal contamination problems, which affect the purity of the metal layer 90, and can easily cause worker injury during the tapping process. Moreover, since the metal layer 90 is currently stacked by metal deposits At present, since the thickness of the cathode plate 81 is very thin, the adhesion of the peripheral surface is relatively low. Therefore, in the electrolysis process, the metal falling out of the electrolysis may occur, and even the metal deposit may be peeled off.

Therefore, it can be seen from the above that the electrolysis method in which the cathode plate is directly installed in the electrolytic cell in a completely exposed state, that is, the above-mentioned requisition takes time, has safety concerns, is liable to cause metal contamination, and easily causes the deposit to peel off and fall. .

Therefore, in view of the above existing problems, the creator thinks that if a detachable insulating coating device is designed for the cathode plate, the periphery of the cathode plate is covered in the insulating member, so that the metal deposit is deposited on the specific In the region, after the electrolysis is completed, a peeling region which is easy to take out is formed on the periphery of the cathode plate, and the metal deposit is attached to a large area of the cathode plate, thereby not only taking the material quickly and safely, but also reducing the metal. It is polluted and can reduce the peeling and dropping of metal deposits.

Therefore, in order to achieve the above object, the present invention provides a detachable insulating covering device comprising a frame made of an insulating material, two clamping members and a plurality of fixing members; the frame comprising two longitudinal members a rod and a bottom cross rod, the two longitudinal rods are respectively located at the upper ends of the two sides of the bottom cross rod, and the space around the two longitudinal rods and the bottom cross rod area is a deposition space, and the two longitudinal rods and the bottom cross rod face the end face of the deposition space The positioning groove is formed at the location, the positioning groove is a stepped groove, and the deposition groove area is a region with a large distance between the front and rear ends in the area adjacent to the deposition space, and the surrounding area outside the deposition groove area is a fixed groove area with a small distance between the front and rear ends, outside the fixed groove area The surrounding area is closed; the two clamps form a positioning rod extending downwardly from the front and the rear, and a positioning space is formed between the front and rear positioning rods, and the two clamps are respectively disposed at the top end of the frame longitudinal rod, and are respectively fixed by the components Secure the clamp to the top of the longitudinal rod.

By the above-mentioned coating device, the peripheral edge of the cathode plate can be adhered to the appropriate area without metal deposits, so that not only the material is convenient and safe to be taken, but also the metal contamination and the sediment peeling off can be prevented.

In the above detachable insulation coating device, the top end of the frame longitudinal rod forms a screw hole and a rear screw hole before and after the front and rear through the positioning groove, and the positioning rods before and after the other clips are also formed to pass through the fixing hole and the rear fixing hole before the positioning space. The consolidating element is of a bolt type, which is fastened to the front screw hole through the front fixing hole, or is locked to the rear screw hole through the rear fixing hole.

By means of the consolidation element before and after the cathode plate is placed in the frame, the position can be set by the consolidation element clamp.

Referring to Figure 1, the present invention includes a frame 10, two clamps 20 and a plurality of consolidation elements 30, each of which is made of an insulating material.

Referring to FIG. 1 and FIG. 2 , the frame 10 includes two longitudinal rods 11 , 12 and a bottom cross bar 13 . The two longitudinal rods 11 and 12 are respectively located at the upper ends of the two sides of the bottom cross bar 13 to form an opening. The upper frame 10, the space surrounded by the two vertical bars 11, 12 and the bottom cross bar 13 is the deposition space 14, and the positioning groove 15 is formed at the end faces of the two vertical bars 11, 12 and the bottom cross bar 13 facing the deposition space 1. The positioning groove 15 extends downward from the top end surface of the vertical rod 11 to the bottom cross bar 13, and then extends along the end surface of the bottom cross bar 13 toward the bottom end of the longitudinal rod 12, to the bottom end of the vertical rod 12, and then along the longitudinal The end face of the rod 12 extends upward to the top end of the longitudinal rod 12, so that the positioning groove 15 is located at the periphery of the deposition space 14.

The positioning groove 15 is in the form of a stepped groove, and the area adjacent to the deposition space 14 is a deposition groove area 151 having a large distance between the front and rear ends, and the surrounding area outside the deposition groove area 151 is a fixed groove area having a small distance between the front and rear ends. 152, the surrounding area outside the fixing groove area 152 is closed; the two clamping members 20 are respectively disposed at the top ends of the two vertical rods 11, 12, and the clamping members 20 are integrated into one shape, and the front and rear portions are formed downward. The positioning rods 21 and 22 are extended, and the positioning spaces 23 are formed between the front and rear positioning rods 21 and 22. The positioning space 23 is slightly larger than the thickness of the front and rear ends of the longitudinal rods 11 and 12, so that the two clamping members 20 can be spanned on the longitudinal rods. At the top end of the 11, 12, the top ends of the longitudinal rods 11, 12 are located in the positioning space 23, and the clamping members 20 are fixed to the top ends of the longitudinal rods 11, 12 on both sides of the frame 10 by the fixing member 30.

The fixing manner between the frame 10 and the two clamping members 20 is performed on the top ends of the longitudinal rods 11 and 12 of the frame 10 to form a screw hole 153 and a rear screw hole 154 before and after the front and rear through the positioning groove 15, and before and after the clamping member 20 The positioning rods 21 and 22 are also respectively formed with a fixing hole 211 and a rear fixing hole 221 before the positioning space 23, and the two clamping members 20 are respectively disposed at the top ends of the longitudinal rods 11, 12 of the frame 10, so that the front fixing holes 211 and The front screw holes 153 correspond to each other. When the rear fixing holes 221 correspond to the rear screw holes 154, the respective fixing elements 30 of the bolt type can be locked to the front screw holes 153 through the front fixing holes 211 and pass through the rear fixing holes 221. It is locked at the rear screw hole 154 to form the original covering device shown in FIG.

The covering device of the present invention is for coating the cathode plate 40. When the two clamping members 20 have not been combined with the frame 10, the cathode plate 40 is placed in the frame 10, because the fixing groove portion 152 of the positioning groove 15 of the creation frame 10 is In combination with the cathode plate 40, the area enclosed by the fixed groove region 152 is equivalent to the area of the cathode plate 40, and the distance between the front and rear of the fixed groove portion 152 is equivalent to the thickness of the cathode plate 40, so when the cathode plate 40 penetrates the frame 10, The peripheral surface of the lower end is inserted in the area enclosed by the fixed groove area 152. Please refer to FIG. 3, and then the two clamps 20 are spanned over the side plate area 41 of the top end of the cathode plate 40, and then consolidated. Element 30 locks clamp 20 and frame 10 in place.

Referring to FIG. 4 and FIG. 5, the original consolidation element 30 is separately fixed from the front end or the rear end of the frame 10, and the front screw hole 153 and the rear screw hole 154 of the frame 10 are connected to At the positioning groove 15, when the cathode plate 40 is inserted into the frame 10, and the fixing members 30 are locked, the front and rear fixing members 30 are positioned to clamp the cathode plate 40, as shown in FIG. In the state shown here, it can be seen from FIG. 4 and FIG. 5 that there is an appropriate distance between the deposition groove region 151 of the positioning groove 15 and the cathode plate 40, which is the region where the deposition is preset.

Referring to FIG. 6, when electrolysis is performed, the cathode plate 40 on which the inventive cladding device is disposed is placed in the electrolytic cell 50, so that most of the cladding device and the cathode plate 40 are immersed in the liquid, but The outer periphery of the cathode plate 40 is located at the fixed groove area 152 of the frame 10, and the frame 10 is made of an insulating material, so that the cathode plate 40 does not generate electrolysis in this area. When the electrolysis process is completed, please refer to FIG. 7 and As shown in FIG. 8, a metal layer 60 is deposited on the surface of the cathode plate 40 in contact with the liquid, and the metal layer 60 is filled in the deposition groove region 151 of the positioning groove 15, and the metal layer 60 is visible in FIG. The peripheral edge is located inside the deposition bath region 151, so that curling around the metal layer 60 can be avoided.

Then, the fixing member 30 can be removed to separate the clamping member 20 from the frame 10. The cathode plate 40 can be pulled up out of the frame 10, as shown in FIG. 9 and FIG. 10, and before and after the cathode plate 40 is visible. The metal layer 60 is formed at a large area of the end surface, but the peripheral edge of the cathode plate 40 has no metal deposits at the same width as the fixed groove region 152. Therefore, it is only necessary to apply a slight force from the end corner of the metal layer 60. The metal layer 60 is removed, and the tooling is not required to be tapped by the tool, which not only increases the safety of the material, but also reduces the metal contamination, and there is no metal deposit in the thin side of the cathode plate 40. Adhesion, so that the occurrence of deposit peeling and dropping can be further prevented.

In summary, the creation of the insulation coating device can quickly and safely take the material after electrolysis, and can reduce the problem of metal contamination and sediment peeling and falling.

10‧‧‧Frame
11‧‧‧ longitudinal rod
12‧‧‧ longitudinal rod
13‧‧‧ bottom rail
14‧‧‧Sediment space
15‧‧‧ positioning slot
151‧‧‧Sedimentation tank area
152‧‧‧fixed trough area
153‧‧‧ front screw hole
154‧‧‧ rear screw hole
20‧‧‧Clamp firmware
21‧‧‧ Positioning rod
211‧‧‧ front fixing hole
22‧‧‧ Positioning rod
221‧‧‧ rear fixing hole
23‧‧‧ Positioning space
30‧‧‧Consolidation components
40‧‧‧ cathode plate
41‧‧‧Side panel area
50‧‧‧electrolyzer
60‧‧‧metal layer
80‧‧‧electrolyzer
81‧‧‧ cathode plate
82‧‧‧Anode plate
90‧‧‧metal layer

Figure 1 is a perspective view of the present invention.

Figure 2 is an exploded perspective view of the inventive wrapping device.

Figure 3 is a front plan view of the present invention.

Figure 4 is a side cross-sectional view showing the sandwiched cathode plate of the present invention.

Figure 5 is a top cross-sectional view showing the sandwiched cathode plate of the present invention.

Fig. 6 is a view showing an embodiment of a plane before the electrolytic coating device is clamped into the electrolytic cell.

Figure 7 is a front plan view of the present invention in which the inventive cladding device clamps the cathode plate and completes the electrolysis process.

Figure 8 is a top cross-sectional view of the inventive cladding device clamping the cathode plate and completing the electrolysis process.

Figure 9 is a front plan view of a cathode plate in which the electrolysis process is completed by the present invention.

Figure 10 is a side view of a cathode plate in which the electrolysis process is completed by the present invention.

Fig. 11 is a side elevational view showing an electrolysis process of a conventional cathode plate and an anode plate in an electrolytic cell.

Figure 12 is a plan view of a prior art cathode plate before electrolysis in an electrolytic cell.

Figure 13 is a front plan view of a prior art cathode plate after completion of the electrolysis process.

Figure 14 is a side plan view showing the completion of the electrolysis process of the prior cathode plate.

10‧‧‧Frame

11‧‧‧ longitudinal rod

12‧‧‧ longitudinal rod

13‧‧‧ bottom rail

14‧‧‧Sediment space

15‧‧‧ positioning slot

151‧‧‧Sedimentation tank area

152‧‧‧fixed trough area

20‧‧‧Clamp firmware

21‧‧‧ Positioning rod

22‧‧‧ Positioning rod

23‧‧‧ Positioning space

30‧‧‧Consolidation components

Claims (2)

The utility model relates to a detachable insulation coating device, which comprises a frame made of an insulating material, two clamps and a plurality of consolidation elements; the frame comprises two longitudinal rods and a bottom cross rod, and the two vertical rods respectively Located at the upper ends of the two sides of the bottom rail, the space between the two longitudinal rods and the bottom rail is a deposition space, and the positioning holes are formed at the end faces of the two vertical rods and the bottom rail toward the deposition space, and the positioning grooves are stepped grooves. The area adjacent to the deposition space is a deposition groove area with a large distance between the front and rear ends, and the surrounding area outside the deposition groove area is a fixed groove area with a small distance between the front and rear ends, and the surrounding area of the fixed groove area is closed; Each of the positioning rods extending downwardly forms a positioning space between the front and rear positioning rods, and the two clamp members are respectively disposed at the top end of the frame longitudinal rod, and the clamp members are fixed to the top end of the longitudinal rod by the reinforcing elements. The detachable insulation coating device according to claim 1, wherein the top end of the frame longitudinal rod is formed before and after the threaded hole and the rear screw hole are penetrated to the positioning groove, and the positioning rods before and after the other clamping are also formed before being penetrated to the positioning space. The hole and the rear fixing hole, and the fixing component is a bolt type, which is fixed to the front screw hole through the front fixing hole, or is locked at the rear screw hole through the rear fixing hole.