JP6115309B2 - Chemical processing equipment - Google Patents

Description

  The present invention relates to a chemical processing apparatus.

  In recent years, so-called flexible circuit boards in which a wiring circuit is formed on a flexible insulating substrate are increasingly used in electronic devices such as liquid crystal televisions and mobile phones.

  2. Description of the Related Art Conventionally, as a plating apparatus used for manufacturing such a flexible circuit board, a plating apparatus that feeds power while holding a work surface in a vertical direction and sandwiching the upper end of the work is known (for example, a patent) Reference 1).

  FIG. 1 is a top view showing an example of the above-described conventional plating apparatus. A conventional plating apparatus shown in FIG. 1 includes a workpiece supply device 220 for supplying a workpiece (long sheet-like material to be plated) 210 wound on a reel and having a metal thin film formed on a surface thereof, and the workpiece 210. This is a device in which a pretreatment tank 230, a plating tank 240, and a posttreatment tank 290 for plating the workpiece 210 are arranged and configured in a straight line between the workpiece winding device 221 wound on a reel. In such a conventional plating apparatus, an endless belt 340 provided with a clamp is rotated by pulleys 330 and 331, and the upper end of the work 210 is clamped between the upper portions of the pretreatment tank 230, the plating tank 240, and the posttreatment tank 290 with clamps. Then, the plating is performed while the workpiece 210 is continuously conveyed from the workpiece supply device 220 to the workpiece winding device 221 with the surface of the workpiece 210 in the vertical direction.

  According to the plating apparatus having the configuration shown in FIG. 1, the current density of the current supplied to the workpiece 210 can be made uniform and high, and the plating tank can be lengthened to one tank. Plating can be applied to the long sheet-like workpiece 210 without applying tension.

JP 2006-193794 A

  However, even in the plating apparatus shown in FIG. 1 described above, if the plating current density is increased in order to further improve the productivity, the metal thin film in the vicinity of the power feeding portion at the upper end is dissolved, so that the productivity can be improved. There was a problem that improvement was difficult.

  Then, an object of this invention is to provide the chemical processing apparatus excellent in productivity improvement.

In order to achieve the above object, a chemical treatment apparatus according to one aspect of the present invention is a chemical treatment apparatus that performs electrochemical treatment on the surface of a continuous long sheet-like workpiece,
A chemical treatment tank capable of storing a chemical treatment liquid, and having slit-like workpiece inlets and outlets on opposite side surfaces,
A transport mechanism that transports the workpiece while immersing the workpiece in the chemical treatment liquid in the chemical treatment tank with the surface of the workpiece in a vertical direction and holding the upper end of the workpiece.
A plurality of electrodes arranged along the longitudinal direction in the chemical treatment tank according to the distance from the inlet of the chemical treatment tank,
A plurality of rectifiers provided corresponding to each of the plurality of electrodes, and capable of independently controlling electrochemical processing on the workpiece for each of the plurality of electrodes,
Between the plurality of adjacent electrodes, it extends inward from an inner surface in the chemical treatment tank, divides the inside of the chemical treatment tank into a plurality of regions in the longitudinal direction, and allows the workpiece to pass therethrough. A partition plate with holes is provided ,
The plurality of rectifiers control the electrochemical treatment by a current density of a current supplied to the plurality of electrodes,
Current density of the current supplied to the plurality of electrodes from said plurality of rectifier that have been set larger toward from the inlet to the outlet at least three or more stages.

  According to the present invention, the average current density during the electrochemical treatment can be increased, and the productivity of the electrochemical treatment can be improved.

It is the top view which showed an example of the above-mentioned conventional plating apparatus. It is the perspective view which showed an example of the chemical processing apparatus which concerns on embodiment of this invention. It is the top view which showed an example of the chemical processing tank of the chemical processing apparatus which concerns on this embodiment. It is the figure which showed the relationship between the current density which can be flowed stably, and plating thickness.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  FIG. 2 is a perspective view showing an example of a chemical treatment apparatus according to an embodiment of the present invention. In FIG. 2, the chemical treatment apparatus according to the present embodiment includes a work supply apparatus 20, a work winding apparatus 21, a pretreatment tank 30, a plating tank 40, a posttreatment tank 90, a plating stripping tank 100, It has horizontal rollers 110 and 111, conveyance direction changing rollers 120 and 121, pulleys 130 and 131, an endless belt 140, a clamp 141, and a low tension heat treatment device 160. The pulleys 130 and 131, the endless belt 140, and the clamp 141 constitute a transport mechanism 150. The plating tank 40 has side surfaces 41, 42, 43, 44, an inlet 45 is formed on the side surface 41, and an outlet 46 is formed on the side surface 42. Further, in FIG. 2, a workpiece 10 that is an object to be processed is shown.

  The workpiece 10 is an object to be processed having a long or sheet shape, and may be composed of various materials. For example, the workpiece 10 may be made of a resin material. Since the workpiece 10 has a sheet-like thin and elongated shape, the workpiece 10 is supplied in a wound state, for example.

  A seed layer made of a metal thin film may be formed on the surface of the workpiece 10. In the chemical processing apparatus according to the present embodiment, an example in which electroplating is performed in the plating tank 40 will be described. However, when performing electroplating, it is necessary to energize the workpiece 10 as a cathode. The workpiece 10 may have a seed layer made of a conductor formed on the surface so that current can be applied. In addition, when the to-be-processed surface of the workpiece | work 10 is single side | surface, a seed layer should just be formed only on one side, but when both surfaces are to-be-processed surfaces, the workpiece | work 10 in which the seed layer was formed on both surfaces is used. Use.

  The workpiece supply device 20 is a supply means for supplying the workpiece 10 to a chemical processing line performed in the chemical processing apparatus, and may supply the workpiece 10 in a state of being wound in a cylindrical shape by feeding it out by rotation. .

  The work take-up device 21 is a collecting means for taking up the work 10 that has been subjected to the chemical treatment by the chemical treatment apparatus. In contrast to the work supply device 20, the work take-up device 21 collects the work 10 in a cylindrical shape. It's okay.

  The horizontal rollers 110 and 111 are rollers installed horizontally to feed the workpiece 10 horizontally when the unwinding roller and the winding roller of the workpiece supply device 20 and the workpiece winding device 21 are installed horizontally. is there.

  The conveyance direction change rollers 120 and 121 are rollers for switching between conveyance of the workpiece 10 in the horizontal direction by the horizontal rollers 110 and 111 and conveyance of the workpiece 10 in the vertical direction (vertical direction) by the conveyance mechanism 150. Accordingly, the transport direction changing rollers 120 and 121 are inclined in the middle of the horizontal and vertical directions (for example, an inclination of 45 degrees) as the installation direction. In addition, the conveyance direction advance roller 120 converts the workpiece 10 sent horizontally from the horizontal roller 110 into a vertical shape so that the conveyance mechanism 150 can convey the workpiece 10 and sends it out. Further, the transport direction advance roller 121 feeds the work 10 being transported vertically by the transport mechanism 150 to the horizontal roller 111 so that the work take-up device 21 can take up the work 10 horizontally.

  The pretreatment tank 30 is a treatment tank for performing a pretreatment before the workpiece 10 is plated. For example, a treatment for cleaning the surface of the workpiece 10 or a wettability of the surface of the workpiece 10 is improved. Various processing may be performed. The pretreatment tank 30 includes a vertically long slit-shaped inlet 31 for receiving the workpiece 10 conveyed in a vertical state as it is, and an outlet 32 for feeding the workpiece 10 in a vertical state.

  The plating tank 40 is a chemical processing tank for performing a plating process on the workpiece 10. The plating tank 40 can store a plating solution, and a metal thin film is formed on the surface of the workpiece 10 by performing a plating process by immersing the workpiece 10 in the plating solution. In the present embodiment, an example of performing electroplating using an electrode will be described. In addition, in this embodiment, although the example which has installed the plating tank 40 which performs an electroplating process as a chemical processing tank is given and demonstrated, a chemical processing tank is a tank which performs another electrochemical process, Also good. For example, instead of the plating tank 40, an electrolytic etching tank for performing electrolytic etching or the like may be installed.

  The plating tank 40 may have, for example, a shape that extends long along the traveling direction of the workpiece 10. Thereby, the time of a plating process can be taken long and productivity can be improved by performing sufficient plating process with one tank. The plating tank 40 has, for example, a rectangular parallelepiped shape and has side surfaces 41 to 44. When the traveling direction of the workpiece 10 is from the left side to the right side in FIG. 2, the workpiece 10 has a side surface 41 on the inlet side, a side surface 42 on the outlet side, and side surfaces 43 and 44 in the longitudinal direction. The entrance-side side surface 41 is formed with a vertically long slit-like entrance 45 that can pass when the surface of the workpiece 10 is in the vertical direction, and the exit-side side surface 42 is also perpendicular to the surface of the workpiece 10. A vertically long slit-like outlet 46 is formed which can pass through the direction. When the workpiece 10 passes through the inlet 45, the workpiece 10 is immersed in a plating solution stored in the plating tank 40 to perform the plating process, and the plating process is completed by passing through the outlet 46.

  The post-treatment tank 90 is a treatment tank for performing the post-treatment of the workpiece 10 that has been subjected to the plating process, and may be cleaned, for example. When cleaning is performed in the post-treatment tank 90, the cleaning may be water cleaning or chemical liquid cleaning using a predetermined chemical liquid. The post-treatment tank 90 also has an elongated slit-shaped inlet 91 and outlet 92.

  The workpiece 10 that has passed through the post-treatment tank 90 is released from being held by the clamp 141 and travels straight toward the conveyance direction changing roller 121. On the other hand, the clamp 141 in the open state that does not hold the workpiece 10 changes the path and passes through the plating stripping tank 100.

  The plating peeling tank 100 is a tank for peeling the plating film attached to the clamp 141. Therefore, for example, a plating stripping solution for stripping the plating may be stored in the plating stripping tank 100 and the plating stripping treatment may be performed in the plating stripping tank 100. The plating stripping treatment may be performed only by immersion in a plating stripping solution, or may be performed by electrolytic etching using the plating stripping solution as an electrolytic etching solution.

  The transport mechanism 150 is a mechanism for transporting the workpiece 10 and sequentially immersing it in each tank such as the pretreatment tank 30, the plating tank 40, and the post-treatment tank 90 to perform a series of processes. The transport mechanism 150 includes pulleys 130 and 131, an endless belt 140, and a clamp 141.

  The pulley 130 is a rotation mechanism for carrying the workpiece 10, contacts the workpiece 10, sends the workpiece 10, and directs the workpiece 10. In FIG. 2, it is provided at four corners in the conveyance path of the workpiece 10.

  The pulley 131 is a rotation mechanism for sending out the endless belt 140, and contacts the endless belt 140 and rotates to send out the endless belt 140 with a frictional force. The pulley 131 is provided at a location where the endless belt 140 changes direction. Incidentally, although the pulleys 131 are originally provided at the four corners above the pulley 130, the pulleys 131 at the four corners are omitted in FIG.

  The endless belt 140 is a means for transporting the workpiece 10 in a vertically standing state. The endless belt 140 is provided with a plurality of clamps 141 at predetermined intervals, and holds the upper end of the workpiece 10 in a state where each clamp 141 is vertically set. Then, when the pulley 131 rotates and feeds the endless belt 140, the workpiece 10 held by the clamp 141 moves and is conveyed along with the movement of the endless belt 140. With such a mechanism, the workpiece 10 is conveyed along the longitudinal direction with the surface in the width direction being set up vertically, and sequentially passes through each processing tank including the plating tank 40 and is subjected to each processing. The endless belt 140 may be composed of a metal belt such as stainless steel, for example.

  The clamp 141 is a holding jig that holds the workpiece 10 by clamping the upper end portion of the workpiece 10. Various clamping mechanisms may be used for the clamp 141, and various clamping mechanisms can be used depending on the application.

  The clamp 141 is made of a conductor such as metal, for example, and may have a function of an electrode for energizing the workpiece 10. For example, when performing an electroplating process, the workpiece 10 is used as a cathode, and an anode is installed in the plating tank 40 to perform an electrodeposition process, so that the clamp 141 functions as a cathode electrode or a cathode energization mechanism. You can do it.

  In FIG. 2, the transport mechanism 150 that holds only the upper end of the workpiece 10 is shown, but a transport mechanism that clamps the lower end of the workpiece 10 may be used. In this case, generation of wrinkles or the like of the workpiece 10 can be suppressed, so that a more uniform plating process can be performed. For clamping the lower end of the workpiece 10, a mechanism similar to the clamp 141 at the upper end may be used, or a different clamp mechanism may be used. Moreover, the structure which provides the groove | channel which guides the lower end of the workpiece | work 10 without performing to a clamp may be sufficient.

  The low-tension heat treatment apparatus 160 is a heat treatment apparatus for performing a heat treatment for heating and annealing the post-processed workpiece 10.

  The operation in the chemical treatment apparatus shown in FIG. 2 is as follows. First, the workpiece 10 supplied from the workpiece supply device 20 is conveyed horizontally by the horizontal roller 110, and the surface is made vertical by the conveying direction changing roller 120, and is supplied to the conveying mechanism 150. The workpiece 10 whose upper end is held by the clamp 141 of the transport mechanism 150 moves along with the movement of the endless belt 140 due to the rotation of the pulley 131, passes through the pretreatment tank 30, the plating tank 40, and the posttreatment tank 90, and has a low tension. Heat treatment is performed by the heat treatment apparatus 160. And the workpiece | work 10 after a heating is converted into the conveyance of a horizontal direction with the conveyance direction change roller 121, is wound up by the workpiece | work winding device 21 through the horizontal roller 111, and a chemical process is complete | finished. The chemical processing apparatus according to this embodiment performs such a series of processes.

  FIG. 3 is a plan view showing an example of a chemical treatment tank of the chemical treatment apparatus according to the present embodiment. In addition, also in FIG. 3, it demonstrates by giving the example which comprised the chemical processing tank as a plating tank. Therefore, the same components as those in FIG. 2 are denoted by the same reference numerals, and the description thereof is omitted.

  In FIG. 3, the chemical treatment apparatus according to this embodiment includes a plating tank 40, a plating solution jet nozzle 50, an anode 60, rectifiers 70, 71, 72, and a partition plate 80.

  As described with reference to FIG. 2, the plating tank 40 has a rectangular parallelepiped shape extending in the longitudinal direction, and a slit-like inlet 45 is formed on the side surface 41 in the width direction. In the plating tank 40, a plurality of anodes 60 divided by a predetermined length in the longitudinal direction are installed. The anode 60 is disposed along the side surfaces 43 and 44 in the longitudinal direction of the plating tank 40 so as to face each other in the width direction. A partition plate 80 extending from the side surfaces 43 and 44 toward the inside of the plating tank 40 is disposed between the anodes 70 adjacent in the longitudinal direction. Inside the anode 70, a plurality of plating solution jet nozzles 50 are also arranged along the longitudinal direction. A plurality of rectifiers 70, 71, 72 corresponding to the divided anodes 60, 61, 62 are provided outside the plating tank.

  The inlet 45 of the plating tank 40 is formed in the center of the side surface 41 in a slit shape extending in the vertical direction. Therefore, the workpiece 10 having its upper end clamped by the clamp 141 is transported through the center in the width direction of the plating tank 40 by being transported through the inlet 45.

  The plurality of plating solution jet nozzles 50 are disposed facing each other so as to be able to spray the plating solution from both sides to the workpiece 10 passing through the center, and have a predetermined distance along the longitudinal direction. Be placed. For example, each plating solution jet nozzle extends in the vertical direction, and a plurality of nozzles facing the center along the extending direction are formed, so that the plating solution jet can be supplied almost uniformly from the upper end to the lower end of the workpiece 10. Configured as follows. With this configuration, the plating solution jet can be supplied substantially uniformly both in the longitudinal direction and in the vertical direction.

  As described above, the plurality of anodes 60, 61, 62 are arranged along the inner side surfaces 43, 44 of the plating tank 40, but each of the anodes 60, 61, 62 has a predetermined length along the longitudinal direction so as to cover a predetermined region. The anodes 60, 61, 62 adjacent to each other having a length are configured to be electrically independent from each other and divided. The plurality of anodes 60 to 62 are arranged to face each other along the side surfaces 43 and 44 so as to sandwich the workpiece 10 passing through the center. The opposed anodes 60 to 62 are divided at the same position in the longitudinal direction, and are configured so that independent zones can be formed in regions where the anodes 60 face each other. Since such a zone is formed along the longitudinal direction of the plating tank 40, each zone is formed according to the distance from the inlet 45.

  The plurality of rectifiers 70 to 72 are power supplies for supplying power to the anodes 60 to 62, and are provided corresponding to the electrodes 60 to 62 provided separately. Each of the plurality of rectifiers 70 to 72 is configured to be capable of adjusting a current supplied to the anodes 60 to 62, supplies a different current to each of the plurality of anodes 60 to 62, and performs a different electrochemical process for each zone. It is possible. Specifically, the rectifier 70 supplies a first current to the anode 60, the rectifier 71 supplies a second current different from the first current to the anode 61, and the rectifier 72 receives the first current from the anode 62. And a third current different from the second current can be supplied.

  The rectifiers 70 to 72 may have a plurality of positive terminals 73 and negative terminals 74 and may be configured to be able to supply power to the anodes 60 to 62 and the cathode from a plurality of points. In FIG. 2, the anodes 60, 61 and 62 on the side surface 43 side are each provided with two conduction mechanisms 76, and the anodes 60, 61 and 62 on the side surface 44 side are also provided with two conduction mechanisms 76, respectively. Each of the rectifiers 70 to 72 includes four positive terminals 73. In addition, the cathode may be provided with variously configured contacts as long as the work 10 can be energized. For example, the cathode 141 may be a cathode contact and the negative electrode terminal 72 may be connected to the clamp 141. Good. In FIG. 2, an example in which the number of negative electrode terminals 72 is four is shown, but the number of these terminals can be changed according to the application.

  Here, each of the first to third current densities supplied from the rectifiers 70 to 72 to the anodes 60 to 62 may be set to an appropriate current according to the application. For example, the first current density < It may be set such that the value of the current density increases as the distance from the inlet 45 increases so as to satisfy the relationship of the second current density <the third current density. Thereby, since a current density can be increased in steps as the plating process proceeds, the step-up plating can be performed in one plating tank 40, and the plating process can be performed without preparing a plurality of plating tanks 40. Can increase productivity.

  The partition plate 80 is installed between the divided electrodes 60, 61, 62 and plays a role of preventing current from interfering between adjacent zones. The partition plate 80 extends from the side surfaces 43 and 44 in the longitudinal direction of the plating tank 40 toward the central region substantially perpendicular to the side surfaces 43 and 44. Since it is necessary to have a hole through which the workpiece 10 passes, it is not possible to completely partition each zone with the partition plate 80. However, diffusion of metal ions between the zones is prevented, and according to the purpose in each zone. A throughput of plating can be performed. That is, for example, when performing step-up plating in which the current density is increased as the plating process proceeds away from the inlet 45, the plating process according to the current density setting can be performed in each zone, and productivity is increased. Can be reliably increased.

  In addition, you may make it provide the partition plate 80 as needed, and may change the shape variously according to a use.

  As described above, according to the chemical treatment apparatus according to the present embodiment, the anodes 60 to 62 are divided into a plurality of parts according to the progress of the plating process, and a plurality of rectifiers 70 to 72 are provided correspondingly. The productivity of the plating process can be improved by performing a desired plating process for each zone corresponding to ˜62 and each of the rectifiers 70 to 72.

  In the present embodiment, the plating process has been described as an example. However, if the anodes 60 to 62 are the cathodes 60 to 62 and the workpiece 10 is the anode, different electrolytic etching processes are performed in each zone. It is possible.

  Hereinafter, the Example which implemented the chemical processing apparatus based on this embodiment demonstrated in FIG.2 and FIG.3 is demonstrated. For easy understanding, constituent elements corresponding to the constituent elements described so far will be described with corresponding reference numerals.

First, the chemical processing apparatus shown in FIG. 2 in which the substrate transfer is U-turned twice by providing a plating process length of 14.5 m and providing a processing step all around the apparatus was produced. As the upper end jig 141 serving both as power supply and conveyance of the apparatus, a contact area between the power supply unit and the workpiece 10 per jig was 18 mm ² and the surface of the power supply unit was coated with platinum with a thickness of 10 μm. . These upper end jigs 141 are arranged at equal intervals with a 75 mm pitch, and the workpiece 10 is sandwiched and conveyed and fed. In the plating tank 40 of this chemical treatment apparatus, 120 g / L of sulfuric acid, 120 g / L of copper sulfate, 50 mg / L of chlorine, and a plating brightener made by Cookson Electronics Co., Ltd. are bathed at 20 mg / L. The relationship between the number of divisions and productivity was verified.

  Table 1 shows the relationship between the number of rectifier divisions in the step-up unit and productivity.

表１に示される通り、ステップアップ部の整流器分割幅を狭くし、分割数を増やすことで生産性が向上し、０．５ｍ幅の８分割とすることで、１．６ｍ幅の４分割制御に比べて１０％以上生産性が向上した。かかる結果から、アノード６０〜６２及び整流器７０〜７２を複数とすることにより、単数のものよりも生産性を向上させることができるが、更にその数を増加させることにより、生産性を一層向上させることができることが分かる。

As shown in Table 1, productivity is improved by narrowing the rectifier division width of the step-up unit and increasing the number of divisions, and by dividing the 0.5 m width into 8 divisions, the 1.6 m width is divided into 4 divisions. Productivity improved by 10% or more. From this result, by making the anodes 60 to 62 and the rectifiers 70 to 72 plural, productivity can be improved as compared with a single one, but by further increasing the number, productivity is further improved. I can see that

  FIG. 4 is a diagram showing the relationship between the current density that can flow stably and the plating thickness. FIG. 4 shows that when a current equal to or higher than the current density corresponding to the plating thickness is passed, the coating is dissolved at the power feeding portion. In the chemical processing apparatus according to the present embodiment, by dividing the rectifier of the step-up unit finely, it is possible to step up to a high current density more efficiently and quickly, and thus productivity can be improved.

  Thus, according to this embodiment and the chemical processing apparatus which concerns on a present Example, productivity can be improved by carrying out zone control of a plating processing tank with a plurality of rectifiers. More specifically, by further finely dividing and controlling the step-up zone with a plurality of rectifiers, it is possible to lead to the maximum current density more quickly and efficiently.

  The preferred embodiments and examples of the present invention have been described in detail above. However, the present invention is not limited to the above-described embodiments and examples, and the above-described embodiments and examples can be performed without departing from the scope of the present invention. Various modifications and substitutions can be made to the embodiments.

10 Work 40 Plating tank 41, 42, 43, 44 Side 45 Inlet 46 Outlet 60, 61, 62 Anode 70, 71, 72 Rectifier 80 Partition plate 130, 131 Pulley 140 Endless belt 141 Clamp 150 Conveying mechanism

Claims (7)

A chemical treatment apparatus for performing electrochemical treatment on the surface of a continuous long sheet-like workpiece,
A chemical treatment tank capable of storing a chemical treatment liquid, and having slit-like workpiece inlets and outlets on opposite side surfaces,
A transport mechanism that transports the workpiece while immersing the workpiece in the chemical treatment liquid in the chemical treatment tank with the surface of the workpiece in the vertical direction and holding the upper end of the workpiece.
A plurality of electrodes arranged along the longitudinal direction in the chemical treatment tank according to the distance from the inlet of the chemical treatment tank,
A plurality of rectifiers provided corresponding to each of the plurality of electrodes, and capable of independently controlling electrochemical processing on the workpiece for each of the plurality of electrodes,
Between the plurality of adjacent electrodes, it extends inward from an inner surface in the chemical treatment tank, divides the inside of the chemical treatment tank into a plurality of regions in the longitudinal direction, and allows the workpiece to pass therethrough. A partition plate with holes is provided ,
The plurality of rectifiers control the electrochemical treatment by a current density of a current supplied to the plurality of electrodes,
The chemical processing apparatus , wherein a current density of the current supplied from the plurality of rectifiers to the plurality of electrodes is set to increase from the inlet toward the outlet in at least three stages or more .   The chemical treatment apparatus according to claim 1, wherein the electrochemical treatment is an electroplating treatment. 3. The chemical treatment apparatus according to claim 1, wherein the plurality of electrodes are provided to face each other so as to sandwich the workpiece along inner surfaces facing each other of the chemical treatment tank. Wherein the plurality of electrodes and said plurality of rectifiers, a chemical processing apparatus according to any one of claims 1 to 3 are respectively provided four or more. The transport mechanism clamps the upper end of the workpiece by a clamping means,
The chemical processing apparatus according to any one of claims 1 to 4 , wherein the rectifier performs energization to the workpiece through the clamp means. The transport mechanism further chemical treatment apparatus according to any one of claims 1 to 5 for transporting the lower clamping to the workpiece of the workpiece.   The chemical processing apparatus according to claim 2, wherein the plurality of electrodes are anodes.

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