KR20130092378A - Apparatus for the electrolytic deposition of metal foil - Google Patents

Abstract

The present invention provides a metal foil electrolytic precipitation apparatus that enables the electric cable connected to the feed terminal to be detachable from the outside of the tank by realizing forging of the electrolytic cell while facing the surface side on which the feed terminal of the positive electrode plate is provided.
In the bottom plate portion of the electrolytic cell, a window portion is formed to pass outside the tank, and the positive electrode plate is mounted on the bottom plate portion so as to close the window portion, thereby having an electrolytic surface facing the cathode drum and an exposed surface exposed to the outside of the tank. A plurality of feed terminals arranged in an arrangement pattern of ss is provided, and an annular seal means is provided between the periphery of the bipolar plate and the periphery of the window to prevent leakage of electrolyte from the window to the outside of the bath, overflowing from the electrolytic cell. The plurality of power supply terminals are configured to face the outside of the tank via the window so as to be able to attach and detach each electric cable from the outside of the tank, respectively.

Description

Apparatus for the electrolytic deposition of metal foil

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a metal foil electrolytic deposition apparatus for depositing a metal foil on a peripheral surface of a cathode drum by energizing a negative electrode drum and a positive electrode through an electrolyte solution. It relates to a metal foil electrolytic precipitation device in which a terminal is disposed.

An electrolytic cell capable of storing a predetermined electrolytic solution, and a negative electrode drum which is rotationally driven in the electrolytic cell and at least two positive electrode plates disposed opposite to the peripheral surface of the negative electrode drum in the electrolytic cell are provided with the electrolyte flowing from the lower part of the electrolytic cell. The metal foil electrolytic deposition apparatus which continuously manufactures metal foil by making it pass-through while passing through and depositing a metal foil on the peripheral surface of a negative electrode drum, and winding up the precipitated metal foil from the peripheral surface of a negative electrode drum. Is known.

As described in Patent Literature 1, the electrolytic cell of such a metal foil electrolytic precipitation apparatus is formed so as to be able to store an inner bath formed between a negative electrode drum and a positive electrode plate and an electrolyte overflowed from the inner bath. It is a two-piece structure having an outer tank.

Therefore, since the positive electrode plate is exposed not only to the electrolytic surface facing the negative electrode drum, but also to the electrolyte overflowed from the shaving bath on the opposite side and subjected to erosion by the electrolyte, the positive electrode plate is made of a valve metal such as titanium having corrosion resistance to the electrolyte. Consists of.

In addition, the deposited metal foil is required to have a uniform thickness, and in order to satisfy this demand, it is necessary to maintain a uniform distance between the anode drum and the anode between the anode plates and to form an electric field with a uniform current density in the cathode plates. There is.

In such a necessity, Patent Document 2 proposes a power supply structure of a metal foil electrolytic precipitation apparatus, in which a proper number of power supply terminals (connection terminals) are provided at almost uniform positions throughout the positive electrode plate, and each of the power supply terminals is capable of feeding power. .

Document 1: Japanese Unexamined Patent Publication No. 2002-294481 (See FIG. 4, page 6) Document 2: Japanese Patent Laid-Open No. 9-87883

However, although each of the plurality of feed terminals is arranged so as to be almost uniform throughout the positive electrode plate, the metal foil that is precipitated by itself is not necessarily uniform, but not only the adjustment control for increasing or decreasing the amount of current supplied to each feed terminal, but also feeding the predetermined portion. It was necessary to make physical adjustments such as removing the connecting strip connected to the terminal or replacing the connecting strip connected to one feed terminal with the connecting strip connected to the other feed terminal.

The obstacle to this physical adjustment is the two-piece structure of the electrolytic cell, and since both surfaces of the positive electrode plate are immersed in the electrolyte and cannot be touched directly by the power supply terminal, the preliminary work such as collecting the electrolyte solution in the outer tank is performed. It was forced to become a factor that made coordination difficult.

Therefore, it is also conceivable for the electrolytic cell to have a forged structure in which the positive electrode plate forms part of the wall surface of the electrolytic cell, with one surface (the side of the feed terminal provided) facing the outside of the tank. However, since the positive electrode plate is a member that needs to be peeled off for restoration, due to concentration of electric current due to electrolytic precipitation or the like, wear and tear of iridium oxide or the like that covers the surface, deterioration of activity, etc., and the like need to be removed. It is comprised so that attachment and detachment are possible.

The structure which can be attached or detached with respect to such an electrolytic cell has caused the leakage of electrolyte solution from the mounting part of a positive electrode plate, and became a factor which inhibits the forging of an electrolytic cell.

In order to solve the problems as described above, the inventors have conducted a thorough study and realized that the feed side terminals of the positive electrode plate faced to the outside of the tank while realizing forging of the electrolytic cell. The present invention has been conceived of enabling the attachment and detachment from the outside of a tank of a connected electric cable.

That is, the present invention has been proposed to solve the problem of the above-described technology, and in order to form a constant electric current field in the positive electrode plate, a plurality of feed terminals are provided on one positive electrode plate and each power supply is provided. It is an object of the present invention to provide a metal foil electrolytic precipitation apparatus that enables attachment and detachment from the outside of a tank of an electric cable connected to a terminal.

In order to achieve the above object, the metal foil electrolytic precipitation apparatus of the present invention is disposed to face a peripheral surface of the electrolytic cell capable of storing a predetermined electrolyte and a negative electrode drum which is rotationally driven in the electrolytic cell and a peripheral surface of the negative electrode drum in the electrolytic cell. A metal foil electrolytic deposition apparatus having at least two positive electrode plates and passing through the electrolyte flowing from the lower part of the electrolytic cell while passing between the negative electrode drum and the positive electrode plate, thereby depositing a metal foil on the peripheral surface of the negative electrode drum, The electrolytic cell is formed in an arc shape having a predetermined curvature and is surrounded by a bottom plate portion disposed to face the peripheral surface of the cathode drum and a side plate portion orthogonally disposed in the axial direction of the cathode drum. At the same time the outside of the tank is immersed in the electrolyte It is installed so as to be exposed to an atmospheric atmosphere without any work, and the bottom plate portion has an opening area except the periphery of the anode plate, and has a substantially rectangular window portion that passes through the outside of the tank, and the anode plate is formed in an arc shape having a predetermined curvature. And disposed between the bottom plate portion and the negative electrode drum and mounted on the bottom plate portion so as to close the window portion, thereby exposing the electrolyte surface facing the cathode drum and facing the cathode drum and without being exposed to the electrolyte solution. A plurality of feed terminals arranged in a predetermined arrangement pattern are provided on the exposed surface, and electrical cables for feeding the positive electrode plate are connected to the plurality of feed terminals, respectively, and a peripheral portion of the positive plate Between the window and the peripheral edge of the window, the leakage of the electrolyte from the window to the outside of the bath An annular seal means is provided to prevent the leakage of the electrolyte from overflowing the electrolytic bath without contacting the exposed surface, and the plurality of feed terminals respectively connect the respective electric cables from the outside of the bath. Removably, it is the structure which goes to a tank exterior through the said window part.

According to the metal foil electrolytic precipitation apparatus of the present invention, the electric current supplied to the positive electrode plate can be adjusted while detaching and operating the electric cables connected to the plurality of feed terminals to the outside of the electrolytic cell from the outside of the tank, thereby reducing the work effort required for the adjustment. The thickness of the deposited metal foil can be made uniform.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic perspective view which shows the metal foil electrolytic precipitation apparatus which concerns on one Embodiment of this invention.
It is a figure which shows typically the internal structure of the metal foil electrolytic precipitation apparatus which concerns on one Embodiment of this invention, and is a schematic sectional drawing which shows the state which removed one positive electrode plate of two positive electrode plates.

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of the metal foil electrolytic precipitation apparatus which concerns on this invention is described with reference to FIG. 1, FIG.

The metal foil electrolytic precipitation apparatus 1 which concerns on this embodiment is the electrolytic cell 10 which can store electrolyte solution L, the negative electrode drum 20 rotationally driven in the electrolytic cell 10, as shown in each figure, The electrolyte (L) flowing from the supply pipe (60) provided at the lower part of the electrolytic cell (10) with two positive plates (30) disposed opposite the peripheral surface (20a) of the negative electrode drum (20) in the electrolytic cell (10). Passing through between the negative electrode drum 20 and the positive electrode plate 30 to energize them, thereby depositing the metal foil S on the peripheral surface 20a of the negative electrode drum 20, and depositing the deposited metal foil S on the negative electrode drum. By winding while peeling off from the peripheral surface 20a of the 20 by the peeling roll 70, it is comprised so that manufacture of metal foil S can be carried out continuously and the some feed terminal 31 is provided in the positive electrode plate 30. At the same time, the electrical cable 40 connected to each feed terminal 31 It is constructed detachably from.

Hereinafter, the metal foil electrolytic precipitation apparatus 1 of this embodiment is explained in full detail.

The electrolytic cell 10 is formed in an arc shape having a predetermined curvature and is orthogonal to the rotational axis direction of the bottom plate portion 11 and the cathode drum 20 which are arranged to face the peripheral surface 20a of the cathode drum 20. It is comprised so that the electrolyte solution L (for example, copper sulfate) can be stored in the tank inside which the side board part 12 arrange | positioned is enclosed by these.

The bottom plate part 11 is a site | part which becomes a bottom face of the electrolytic cell 10, forms the substantially semi-cylindrical shape which has the curvature which becomes concentric with the negative electrode drum 20, and has the peripheral surface 20a of the negative electrode drum 20. FIG. It is arrange | positioned so that the clearance of an equal space | interval may be secured in between.

The bottom plate portion 11 has an opening area (for example, 800 mm x 800 mm) except for the periphery of the anode plate 30, and is formed in two places with a substantially rectangular window portion 111 passing through the outside of the tank. One surface of the positive electrode plate 30 is exposed to the outside of the tank through the window 111.

The side plate part 12 is a site | part which becomes a side wall surface of the electrolytic cell 10, and supports the whole electrolyzer 10 by the lower end part contacting an installation surface, while supporting the bottom plate part 11 joined by welding etc. have.

The electrolytic cell 10 configured as described above stores the electrolyte L in the space surrounded by the bottom plate portion 11 and the side plate portion 12 by blocking the window portion 111 with the positive electrode plate 30. It is provided so that it may be exposed to air | atmosphere atmosphere without being immersed in electrolyte solution (L).

The negative electrode drum 20 is a site in which the metal foil S (for example, copper foil) is deposited, and has a cylindrical shape in which a titanium plate is wound around the peripheral surface 20a, and the lower half of the negative electrode drum 20 is formed in the electrolytic cell 10. It is axially supported by the side plate part 12 so that rotation may be carried out. The cathode drum 20 is rotated in one direction by being driven by a predetermined motor.

The positive electrode plate 30 is a member that is connected to a predetermined power source and is supplied with power, and is formed in an arc shape having a concentric curvature with the negative electrode drum 20 and disposed between the bottom plate portion 11 and the negative electrode drum 20. At the same time, it is attached to the bottom plate portion 11 to block the window portion 111.

In this embodiment, two positive plates 30 are attached to the bottom plate portion 11 so that each positive plate 30 has a larger appearance than the window portion 111 (for example, (1000 mm × 1000 mm), Each window 111 is covered.

Mounting of the positive electrode plate 30 to the bottom plate portion 11 is, in this embodiment, as shown in FIG. 2, the positive plate 30 and the cross-section of the positive plate 30 are substantially L-shaped washers 35 and the bottom plate portion 11. It is realized by interposing the leading edge of the.

Specifically, a plurality of male screws 33 joined to the positive electrode plate 30 by welding or the like are planted and installed along the window 111 to insert the washers 35 into them, and at the same time, the bottom plate portion of the washer 35. By screwing the female screw 34 to the male screw 33 while making contact with the periphery of the 11, the bottom plate portion 11 between the positive plate 30 and the washer 35 having a substantially L-shaped cross section. ) Is pinched and fixed to the positive electrode plate 30 and the bottom plate portion 11.

By this mounting, the window portion 111 is blocked by the positive electrode plate 30, and the positive electrode plate 30 is exposed to the electrolyte solution L and is disposed on the electrolytic surface 30a and the electrolyte solution L facing the negative drum 20. It has an exposed surface 30b which is exposed to the exterior of the tank without being exposed.

In addition, an annular seal means is formed between the periphery of the positive electrode plate 30 and the periphery of the window 111.

This sealing means consists of the ring 37 which connected the elastic member, such as rubber | gum or silicone of circular cross section, to ring shape (rectangle), for example, and this ring 37 is provided in the periphery part of the positive electrode plate 30, The groove 36 to be fitted is formed concave over the entire circumference.

Thus, when the positive electrode plate 30 is fixed to the bottom plate portion 11, the ring 37 is sandwiched between the periphery of the positive plate 30 and the periphery of the window portion 111 so that the positive plate 30 and the window portion 111 are separated from each other. Since there is no gap between them, leakage of the electrolyte L from the window 111 outside the tank is prevented.

That is, since the leakage of the electrolyte L from the electrolytic cell 10 can be prevented while making the positive electrode plate 30 detachable with respect to the electrolytic cell 10 for the purpose of restoration, the electrolytic cell 10 can be forged. Can be.

In addition, on the exposed surface 30b of the positive electrode plate 30 exposed to the outside of the bath, a plurality of power supply terminals 31 serving as a contact point with the electric cable 40 connected to a predetermined power source are provided (for example, one positive electrode plate). 9 to 20) are provided at (30).

Each feed terminal 31 is composed of male screws joined to the exposed surface 30b of the positive electrode plate 30 by welding or the like, and the terminal portion of the electric cable 40 is provided between the feed terminal 31 and the female screw 32. The electric cable 40 can be connected to the power supply terminal 31 by tightening the female screw 32 with the 41 (eg, O-type terminal and Y-type terminal) sandwiched therebetween.

Thus, only by loosening or tightening the female screw 32, the electric cable 40 can be detached and detached at will, and the electric cable 40 connected to the power supply terminal 31 at a predetermined portion is removed or a single power supply is provided. The adjustment work which replaces the electric cable 40 connected to the terminal 31 with the electric cable 40 connected to the other power supply terminal 31 can be easily performed outside a tank.

In addition, each power supply terminal 31 is formed in the length which can insert a plurality (for example, three maximum) of the terminal parts 41 of the electric cable 40 (multiple cable connection means).

Thus, since each feed terminal 31 has the length which can insert the some electric cable 40, it removed from the feed terminal 31 corresponding to the thick part of the metal foil S which precipitates, for example. One electric cable 40 can be connected to the feed terminal 31 corresponding to the thin part of the thickness of the metal foil S to which the other electric cable 40 is already connected, so that the thickness of the metal foil S precipitated. Adjustment to achieve uniformity can be made.

In addition, each feed terminal 31 is arrange | positioned in the arrangement pattern of substantially equal intervals over the whole surface of the exposed surface 30b. Thereby, the current density of the electric field formed in the electrolytic surface 30a can be made uniform.

The electrolyte L passed through the negative electrode drum 20 and the positive electrode plate 30 is configured to flow in from the lower part of the electrolytic cell 10.

Specifically, two supply pipes 60 connected to a predetermined pump are disposed below the electrolytic cell 10, and the electrolyte L is supplied from the supply pipe 60 to the electrolytic cell 10 through the electrolyte supply part 13. It is supposed to flow in.

The electrolyte supply part 13 is a site | part which is provided in the lower part of the electrolytic cell 10, and supplies electrolyte solution L from the lower side of the negative electrode drum 20 between the negative electrode drum 20 and the positive electrode plate 30, and is a negative electrode. It has a function to uniformly maintain the flow rate of the electrolyte L passing through the drum 20 and the positive electrode plate 30 over the axial direction of the negative electrode drum 20.

Specifically, the electrolyte solution supply part 13 is provided extending in the axial direction of the cathode drum 20 and having a predetermined storage capacity capable of storing the electrolyte solution L flowing in from the inlet 131. And a plurality of jet ports 133 which are disposed evenly on the upper portion of the liquid storage chamber 132 and eject the electrolyte solution L stored in the liquid storage chamber 132 toward the lower portion of the negative electrode drum 20.

The jet port 133 consists of a pipe of a predetermined length extending upward from the liquid reservoir chamber 132, and the liquid reservoir chamber 132 is an electrolyte solution L from the outside of the electrolytic cell 10 to the liquid reservoir chamber 132. ) Is provided with an inlet 131 in communication with the supply pipe 60 as an inlet for inflow.

The inlet 131 is disposed at a position which does not directly face the outlet 133. For example, in the present embodiment, the inlet 131 is parallel to the side plate portion 12 and orthogonal to the outlet 133. It is located at the position.

By such a configuration, the electrolyte L supplied from the supply pipe 60 flows into the liquid storage chamber 132 through the inlet 131 and is once stored, so that the pressure applied to the electrolyte L is reduced in the cathode drum 20. It is dispersed along the axial direction and jetted toward the lower portion of the negative electrode drum 20 from the jet port 133 evenly disposed in the upper portion of the liquid reservoir chamber 132, so that the negative drum 20 and the positive electrode plate 30 The flow velocity of the electrolyte solution L flowing therebetween becomes uniform over the axial direction of the negative electrode drum 20.

In addition, by arranging the inlet 131 at a position not directly facing the ejection opening 133, the flow of the electrolyte L can be formed in the liquid storage chamber 132 along the axial direction of the cathode drum 20. have. As a result, the pressure applied to the electrolyte L is dispersed along the axial direction of the cathode drum 20, so that the flow rate of the electrolyte L ejected from the jet port 133 becomes more uniform over the axial direction of the cathode drum 20. .

Moreover, electrolyte L which flowed into the electrolytic cell 10 rises along the peripheral surface 20a of the negative electrode drum 20, and overflows from the upper edge of the bottom plate part 11, but this bottom plate part 11 The upper edge portion of the upper portion is provided with a recovery means 50 for recovering the electrolyte L without contacting the exposed surface 30b.

The recovery means 50 according to the present embodiment includes a recovery trough 51 for receiving the electrolyte L overflowing from the upper edge portion of the electrolytic cell 10 and an electrolyte L for the recovery trough 51. It consists of the collection pipe | tube 52 which collect | recovers.

The recovery trough 51 opens the upper portion along the axial direction of the cathode drum 20 so as to receive the electrolyte L overflowed from the upper edge of the electrolytic cell 10, and receives the electrolyte L ) Is inclined to flow toward the recovery pipe (52).

Thereby, since the electrolyte L which overflowed from the upper edge part of the electrolytic cell 10 does not return to the outer side of the electrolytic cell 10, the exposed surface 30b does not contact the electrolyte L.

The recovery pipe 52 recovers the electrolyte L flowing in from the recovery trough 51 and guides the recovered electrolyte L to the tank for electrolyte circulation.

In this way, the electrolyte L that overflows from the electrolytic cell 10 can be recovered without contacting the exposed surface 30b, so that the electrolytic cell 10 is not immersed in the electrolytic solution L. Can be installed to expose to the atmosphere.

In addition, the collecting trough 51 is provided with a cover covering the upper opening and a duct for exhausting air in the cover while allowing the electrolyte electrolyte L to overflow (both not shown), and sucking the vaporized copper sulfate. It is possible to preserve the work environment by preventing the damage.

Thus, the metal foil electrolytic precipitation apparatus 1 of this embodiment prevents the leakage of the electrolyte solution L from the electrolytic cell 10, making the positive electrode plate 30 detachable with respect to the electrolytic cell 10, and also the electrolytic cell ( By recovering the electrolyte L that overflows from 10), the electrolytic cell 10 is forged, and the entire surface of the positive electrode plate 30 is secured while securing a tank external space not immersed in the electrolyte L. The plurality of power supply terminals 31 disposed almost at equal intervals are exposed to the outside of the tank.

The metal foil electrolytic precipitation apparatus 1 comprised in this way is made to precipitate metal foil S by operating as follows.

First, the electrolyte L flowing in from the supply pipe 60 is supplied to the electrolytic cell 10 from the lower part of the negative electrode drum 20, so that the peripheral surface 20a of the negative electrode drum 20 and the electrolytic surface of the positive electrode plate 30 ( Pass between 30a). At this time, the electrolyte L is uniformly flown by the liquid reservoir chamber 132 and the jet port 133 provided in the electrolyte supply part 13, and the peripheral surface 20a of the negative electrode drum 20 and the positive electrode plate 30 Pass between the electrolytic surface 30a of

Since the positive electrode plate 30 is formed in an arc shape having a concentric curvature with the negative electrode drum 20, the positive electrode plate 30 is disposed between the peripheral surface 20a of the negative electrode drum 20 and the electrolytic surface 30a of the positive electrode plate 30. In the same gap, a plurality of feed terminals 31 provided on the exposed surface 30b are arranged almost evenly, so that the cathode drum 20 and the cathode plate 30 are energized, thereby providing a constant current between the anodes. An electric field of density is formed.

Thereby, the metal foil S of uniform thickness precipitates on the circumferential surface 20a of the negative electrode drum 20. And the deposited metal foil S is peeled off by the peeling roll 70 from the peripheral surface 20a of the negative electrode drum 20, and it is wound by the predetermined | prescribed roll.

In addition, the electrolyte L that has passed between the peripheral surface 20a of the negative electrode drum 20 and the electrolytic surface 30a of the positive electrode plate 30 includes a peripheral edge of the positive electrode plate 30 and a peripheral edge of the window 111. The ring-shaped seal means (ring 37) and the recovery means 50 disposed between them are recovered from the electrolytic cell 10 without contacting the exposed surface 30b.

As a result, the electrolytic bath 10 can be installed so that the outside of the bath is exposed to the atmosphere without being immersed in the electrolyte L, and thus, when an unevenness occurs in the thickness of the deposited metal foil S, the feed terminal 31 By attaching and detaching the connected electric cable 40 directly from the exterior of a tank, the fine adjustment which makes thickness of the metal foil S uniform can be performed.

For example, only by loosening or tightening the female screw 32 from the outside of the bath, the electric cable 40 connected to the power supply terminal 31 at a predetermined portion is removed or connected to one power supply terminal 31. The electrical cable 40 connected can be replaced with the electrical cable 40 connected to the other power supply terminal 31.

In addition, since each feed terminal 31 has a length into which the plurality of electric cables 40 can be inserted, one electric cable separated from the feed terminal 31 corresponding to the thick portion of the metal foil S to be deposited is thick. The 40 can be connected to the feed terminal 31 corresponding to the thin part of the thickness of the metal foil S to which the other electric cable 40 is already connected, so that fine adjustment of the thickness of the deposited metal foil S can be performed. Can be.

As explained above, the metal foil electrolytic precipitation apparatus 1 of this embodiment realizes forging of the electrolytic cell 10, making the surface side in which the feed terminal 31 of the positive electrode plate 30 was installed to the exterior of a tank, The electrical cable 40 connected to the power supply terminal 31 can be easily detached from the outside of the tank.

Thereby, fine adjustment of the thickness of the copper foil which precipitates can be made to outside of a tank, adjusting the attachment and detachment of the electric cable 40. FIG.

In addition, since one surface of the positive electrode plate 30 is exposed to the outside of the tank, and the electrolytic cell 10 has a forging structure, maintenance work from the outside of the tank with respect to the positive electrode plate 30 and detachment of the positive electrode plate 30 are performed. Work becomes easy.

As mentioned above, although preferred embodiment of the metal foil electrolytic precipitation apparatus 1 of this invention was described, the metal foil electrolytic precipitation apparatus which concerns on this invention is not limited only to embodiment mentioned above, Various changes are possible in the scope of this invention. Needless to say.

For example, the metal foil which precipitates is not limited to copper foil, According to electrolyte solution, other metal foils, such as nickel, can be manufactured, for example.

In addition, although the sealing means of this embodiment used the elastic member which has a circular cross section, you can also use the elastic member which has a rectangular cross section.

In addition, in this embodiment, although the positive electrode plate 30 was made into 2 sheets of one piece total, it is also possible to set it as 2 sheets or more in total, for example, 4 sheets of two pieces of one sheet.

In this case, a total of four window portions 111 corresponding to the respective anode plates 30 are formed in the bottom plate portion 11 to seal between the peripheral edges of the respective window portions 111 and the peripheral edges of the respective anode plates 30. It is necessary to form the means (ring 37), respectively.

2 shows a state in which one of the two positive plates is removed for convenience, and it is said that at the time of electrolytic precipitation, two positive plates are mounted symmetrically with respect to the electrolyte supply unit 13. There is no need.

In addition, in this embodiment, although the feed terminal 31 was formed in the length which can insert the terminal part 41 of the some electric cable 40, it was made into multiple cable connection means, However, multiple cable connection means is limited to this. For example, the terminal portion 41 of the electric cable 40 may be formed in the shape of a clip (for example, an alligator clip), and the feed terminal 31 may be formed in a shape in which a plurality of clips can be fitted. have.

In addition, in this embodiment, the inlet 131 is disposed at a position which does not directly face the outlet 133 in the electrolyte supply part 13, and in this embodiment, the inlet 131 is parallel to the side plate portion 12 and has a outlet. Although arranged in the position orthogonal to 133, the structure which arrange | positions the inlet 131 in the position which does not directly face the ejection opening 133 is not limited to this example, The inlet 131 and the ejection opening 133 directly Any path may be used as long as the flow path of the electrolyte L is not formed in a straight line and the flow of the electrolyte L is formed in the liquid reservoir chamber 132 along the axial direction of the cathode drum 20.

For example, the inlet 131 is opposed to the outlet 133, but a partition plate is disposed in parallel between them, or the inlet 131 is opposed to the outlet 133 so as to be out of position. There is no positional relationship that directly faces (faces) 133, so it is included in the technical scope of the present invention.

INDUSTRIAL APPLICABILITY The present invention can be used in a metal foil electrolytic deposition apparatus in which a negative electrode drum and a positive electrode plate flow through an electrolysis liquid to deposit a metal foil on the peripheral surface of the negative electrode drum.

1 metal foil electrolytic precipitation apparatus
10 electrolyzer
11 Base Plate
111 Window
12 side plate
13 electrolyte supply
131 inlet
132 Liquid reservoir
133 spout
20 cathode drum
Around 20a
30 positive plate
30a electrolytic surface
30b exposed surface
31 Feed Terminal
37 rings (sealing means)
40 electrical cables
50 recovery means
51 Recovery Bin
52 recovery tube
60 supply pipe
70 Peeling Roll

Claims (3)

An electrolytic cell capable of storing a predetermined electrolyte solution, a negative electrode drum which is rotationally driven in the electrolytic cell, and at least two positive electrode plates disposed opposite to the peripheral surface of the negative electrode drum in the electrolytic cell, and are introduced from the lower part of the electrolytic cell. It is a metal foil electrolytic precipitation apparatus which deposits a metal foil on the circumferential surface of the said negative electrode drum by making an electricity pass through these electrolytes, passing between the said negative electrode drum and the said positive electrode plate,
The electrolytic cell is
An electrolyte solution is stored in a tank formed in an arc shape having a predetermined curvature and surrounded by a bottom plate portion disposed to face a peripheral surface of the negative electrode drum and a side plate portion disposed orthogonally in the axial direction of the negative drum. At the same time, it is installed so that the outside of the bath is exposed to the atmosphere without being immersed in the electrolyte solution.
The bottom plate portion has an opening area except the periphery of the bipolar plate and is formed in a substantially rectangular window portion that passes through the outside of the tank.
The positive plate,
An electrolytic surface which is formed in an arc shape having a predetermined curvature and is disposed between the bottom plate portion and the cathode drum and attached to the bottom plate portion to block the window portion, thereby being exposed to the electrolyte and facing the cathode drum. And an exposed surface exposed to the outside of the bath without being exposed to the electrolyte solution,
On the exposed surface, a plurality of feed terminals arranged in a predetermined arrangement pattern are provided
Electrical cables for feeding power to the positive electrode plate are connected to the plurality of feed terminals, respectively.
Between the periphery of the bipolar plate and the periphery of the window, annular seal means for preventing leakage of the electrolyte from the window to the outside of the bath is provided.
And a recovery means for recovering the electrolyte solution overflowing from the electrolytic cell without contacting the exposed surface.
The plurality of feed terminals are directed to the outside of the tank via the window portion so that the respective electric cables can be detached from the outside of the tank, respectively.
The metal foil electrolytic deposition apparatus according to claim 1, further comprising a plurality of cable connecting means capable of connecting one of said electric cables separated from one said power supply terminal to another said power supply terminal to which another electric cable is already connected. .
The electrolyte solution supply unit according to claim 1 or 2, further comprising an electrolyte supply unit for supplying an electrolyte solution from the lower side of the cathode drum between the cathode drum and the cathode plate at the lower portion of the electrolytic cell.
The electrolyte supply unit,
A plurality of liquid reservoirs extending in the axial direction of the negative electrode drum and having a predetermined storage capacity capable of storing the electrolyte solution and arranged above the liquid reservoir chamber to eject the electrolyte solution stored in the liquid reservoir chamber toward the lower side of the negative electrode drum; Equipped with spout
The liquid storage chamber has an inlet for introducing an electrolyte into the liquid storage chamber from outside the electrolytic cell,
The metal foil electrolytic precipitation apparatus, characterized in that the inlet is arranged at a position not directly facing the spout.

Images