JP6095600B2 - Rod mounting structure for electrode plate transfer device - Google Patents

Description

  The present invention relates to a rod mounting structure for an electrode plate transport device, and more particularly, to a frame of an electrode plate transport device with a rod attached to the tip of a hook for supporting a plurality of electrode plates used for electrolytic refining of metal. The present invention relates to a rod mounting structure of an electrode plate transport device for mounting.

  Electrorefining of metals such as copper and zinc is carried out by using a plurality of (usually about 20 to 60 in the case of Cu) cathode plates (cathode plates) and ear-type anodes (anodes) in an electrolytic cell in which an electrolytic solution is stored. Plate) are alternately immersed in parallel, and a voltage is applied. Then, the loading, lifting and transport of these electrode plates into the electrolytic cell are performed by hooking and supporting the electrode plate transport device with hooks provided on the tip end side of the rod. That is, a plurality of pairs of anode hooks for supporting the anode plate and a plurality of pairs of cathode hooks for supporting the cathode plate are installed in the suspension frame in the electrode plate transport device, and an electrode plate in which a large number of electrode plates are suspended. The transfer device is moved horizontally to the upper side of the electrolytic cell by a moving device such as an overhead crane, and the electrode plate can be inserted into or raised from the predetermined position of the electrolytic cell by raising and lowering the hanging frame of the electrode plate transfer device at a predetermined position. Done. The cathode plate that has been electrolyzed is inserted into the conveyor of the stripper receiving port, and the electrodeposited metal is stripped from the surface. Then, the stripped cathode plate is transported by the electrode transport device from the conveyor at the stripper carry-out port, and is again inserted into the electrolytic cell for electrolytic purification.

  As a mounting structure of the rod of the conventional electrode plate conveying apparatus, for example, there is one shown in Patent Document 1. That is, there are about 50 to 60 hangers corresponding to the number of electrode plates between two main beams arranged in parallel, and each hanger has an anode electrode plate hanging hook at each end, A pair of cathode electrode plate hanging hooks are provided in the section, and each hook shaft extending in the vertical direction is rotatably supported by a hanger via a bearing. Each hook shaft is configured to be able to turn at a predetermined angle by operating a guide rail driving means or the like connected to the top of the hook shaft by an air cylinder mechanism as a driving means. The hangers are connected to each other by a link mechanism arranged at the center so that the pitch between the hangers is variable.

Japanese Patent Publication No. 6-96788

  However, in the case of the rod mounting structure of the electrode plate transport device of Patent Document 1, each hook shaft is rotatably mounted around the hook shaft in a state of being inserted into a through hole provided in the hanger. When removing from the electrode plate transport device for maintenance or hook replacement work, it is necessary to release the connection of the guide rail drive means etc. connected to the top of the hook shaft and pull it down from the through hole and remove it. there were. Therefore, there is a problem that the work is troublesome and the hook shaft cannot be pulled out from the through hole when the hook shaft is distorted. In addition, in order to pull the hook shaft downward from the through hole, it is necessary to secure a clearance corresponding to the length of the hook shaft on the lower side. Therefore, the hook shaft is pulled out at a predetermined height. While the work must be performed in the above-stated state, the guide rail drive means is connected to the top of the hook shaft, so the electrode plate can be transported to a position where work can be easily performed in order to release the connection. There was a problem that the workability was hindered because the apparatus had to be lowered.

  In view of the above problems, an object of the present invention is to provide a rod mounting structure for an electrode plate transport apparatus that can easily and quickly attach and detach a hook of the electrode plate transport apparatus.

In order to solve the above-mentioned problem, the present invention according to claim 1 is directed to a rod mounting structure for an electrode plate transport device for detachably mounting a rod having a hook for supporting the electrode plate in a suspended manner to a frame of the electrode plate transport device. in, the frame, the order for attaching the rod accommodating portion which is formed in an edge portion of the frame has an opening is formed in, the rod, the flange portion of larger diameter than the housing part It has a larger diameter than the opening width of the opening and having a movable bearing member is mounted along the rod, the fixed member the bearing member while interposing the bearing member in the housing portion The rod can be attached and detached from the lateral direction of the frame by being fixed by.

  In order to solve the above-mentioned problem, the present invention according to claim 2 is arranged in the rod mounting structure of the electrode plate transport device according to claim 1 so as to be horizontally movable along the frame on the upper end portion side of the rod. By attaching a pinion gear screwed to the rack gear, the hook can be turned at least 90 ° about the rod.

In order to solve the above-mentioned problem, the present invention according to claim 3 is the rod mounting structure of the electrode plate transport device according to claim 1 or 2, wherein the frame includes an upper frame projecting in a horizontal direction, and the upper part. parallel to the upper frame on the lower side of the frame, and comprises a lower frame which projects horizontally, on the edge of the upper frame the first housing portion is drilled with a first opening large is formed, the second housing portion is an edge portion of the lower frame drilled with a second opening is formed, said rod, than the in the upper side the first housing portion A first bearing member having a first flange portion with a diameter and a diameter larger than the opening width of the first opening portion, and a second flange having a diameter larger than that of the second housing portion on the lower side And a width larger than the opening width of the second opening Second bearing member movable along said rod is mounted with a a diameter, the first is interposed said first bearing member to the housing portion, the second further to the second housing part The rod is detachable from the lateral direction of the frame by fixing the second bearing member with a fixing member with two bearing members interposed.

  In order to solve the above-mentioned problem, the present invention according to claim 4 is the rod mounting structure of the electrode plate transport device according to any one of claims 1 to 3, wherein the fixing member and the bearing member or the second bearing are provided. An elastic member is interposed between the members.

  In order to solve the above-mentioned problem, the present invention according to claim 5 is the rod mounting structure of the electrode plate transport device according to any one of claims 1 to 4, wherein the fixing member is a set collar. Features.

  According to the rod mounting structure of the electrode plate transport device according to the present invention, the rod is mounted not on the through-hole but on the C-shaped housing portion or the first housing portion and the second housing portion. The attachment / detachment can be performed not in the vertical direction but in the horizontal direction (lateral direction), and there is an effect that the attachment / detachment operation can be performed without a clearance corresponding to the length of the rod on the lower side. Further, there is an effect that the rod can be easily removed even if there is some distortion in the rod.

  Further, according to the rod mounting structure of the electrode plate transport device according to the present invention, the rod and the rack gear serving as the driving means for rotating the rod are connected by screwing the rack gear and the pinion gear. There is an effect that the connection and the removal with the driving means can be performed very easily and quickly.

It is a perspective view which shows the outline | summary of an electrolytic purification equipment. It is a front view showing a cathode hook F ₁ attached to Tsuwaku. Cathode hooks F ₁ and anode hook F ₂ is a side view showing a Tsuwaku attached. Shows a state of attaching the anode hook F ₂ in Tsuwaku, the (a) is a front view showing a state before the horizontal movement of the anode hook F _2, (b) a horizontal state of moving the anode hook F ₂ FIG. It is a perspective view which shows the arrangement | sequence state of an electrode plate. It is explanatory drawing which shows the rod attachment structure of the electrode plate conveying apparatus which concerns on this invention. It is explanatory drawing which shows the structure of the bearing member shown in FIG. 6, the structure of the opening part provided in the flange, and the structure of a 1st bearing member. (A)-(e) is explanatory drawing which shows the removal procedure of the rod R. FIG.

[Configuration of electrolytic purification equipment]
First, an outline of electrolytic purification equipment will be described with reference to FIG. 1, and then a preferred embodiment of a rod mounting structure for an electrode plate transport device according to the present invention will be described. FIG. 1 is a perspective view showing an outline of the electrolytic purification equipment. The illustrated electrolytic refining equipment 100 generally includes an electrode plate transfer device 10 that is arranged to be movable in the front-rear and left-right directions while being suspended from an overhead crane (not shown) by wires W, and an electrolytic solution such as dilute sulfuric acid. The electrolyzer unit 30 includes a plurality of electrolyzers 32 and 32, and the conveyor 40 for transporting the electrode plates 20 and 20 pulled up from the electrolyzers 32 and 32 to the next process. ing.

  The electrolytic cell unit 30 is composed of a plurality of electrolytic cells 32 and 32 having the same volume and fixed to the whole, and these are adjusted on the floor so as not to be rattled by the plurality of legs 34 and 34. . A plurality of electrode plates 20 and 20 are immersed in each of the electrolytic baths 32 and 32, whereby electrolysis is performed. The electrode plates 20 and 20 are an anode plate A which is an anode side electrode and a cathode plate K which is a cathode side electrode. The anode plate A and the cathode plate K are alternately supported in parallel and arranged in the electrolytic cells 32 and 32. Is done. On the other hand, on the upper edge surface 30a of each electrolytic cell 32, 32, a plurality of left and right convex members 36, 36 projecting upward are arranged along the longitudinal direction of the electrolytic cells 32, 32. 36 and 36 are adapted to be fitted with a guide rod 14 (described later) provided in the electrode plate transport device 10.

  The electrode plate transport device 10 includes a suspension frame 12, and is suspended horizontally by wires W at portions of suspension members 18 and 18 provided at four locations on the upper surface of the suspension frame 12. Above the wire W, a winding mechanism (not shown) such as an overhead crane that winds the wire W, and a frame in which a number of frames on which the winding mechanism is mounted are arranged in the vertical direction X or the horizontal direction of the electrolytic cells 32 and 32. A horizontal moving means (not shown) whose position is controlled to move to Y (only a plurality of electrolytic cells 32, 32 continuous in the lateral direction Y are shown in FIG. 1) and a frame above the desired electrolytic cell 32 are provided. Position control means (not shown) for stopping.

  The electrode plate transport device 10 moves horizontally between a predetermined position above the electrolyzers 32 and 32 and a top of the conveyor 40 that transports and discharges the cathode plate K after electrolysis to a stripping device (not shown). At the same time, the cathode plates K are moved up and down in the Z direction, and a large number of cathode plates K can be loaded into or suspended from the rails 41 and 41 at predetermined positions of the electrolytic cells 32 and 32 or at predetermined positions of the conveyor 40 shown in FIG. Yes.

  A pair of left and right guide rods 14 and 14 are attached to the vicinity of both ends in the longitudinal direction of the suspension frame 12 so as to be slidable in the vertical direction by a pair of slide bearings 16 and 16, respectively. Conical recesses are formed on the lower end surfaces of the guide rods 14, 14, and can be easily fitted with convex members 36, 36 projecting upward from the upper edge surface 30 a of the electrolytic cells 32, 32. In addition, it can be precisely aligned.

Figure 2 is a front view showing a Tsuwaku cathode hooks F ₁ is attached, FIG. 3 is a side view showing a Tsuwaku cathode hooks F ₁ and anode hook F ₂ is attached. As shown in FIGS. 2 and 3, a hoisting device 42 is installed on the upper part of the hanging frame 12. The hoisting device 42 can wind or unwind the two first chains 45 and 45 that are directed downward through two of the both ends of the first chain wheels 44 and 44 provided on the same axis. It has become. In addition, the second chain 47 can be wound or unwound downwardly via the second chain wheel 46 shown on the right side of FIG. 2 through the central one of the first chain wheel 44. Yes.

  The lower ends of the two first chains 45, 45 and the second chain 47 (see FIG. 3) are connected to the cathode frame 22 as shown in FIG. That is, the cathode frame 22 is horizontally suspended by the three chains and can be moved up and down by driving the winding device 42. Further, as shown in FIG. 3, the cathode frame 22 is guided to move up and down so as to be sandwiched from both sides by a pair of guide mechanisms 50 and 50 fixed to the suspension frame 12 and extending downward. It has become. In the guide mechanisms 50, 50, a plurality of guide rollers 50b are rotatably provided on the side surfaces of the cathode frame 22 by roller brackets 50c, and these guide rollers 50b roll on the inner wall of the guide member 50a, whereby the cathode frame 22 is provided. As shown in FIG. 2, two mechanisms are provided in the longitudinal direction of the suspension frame 12.

In the lower part of the suspension frame 12, cathode hooks F ₁ and F ₁ for suspending the cathode plate K can be rotated perpendicularly to the tips of a number of rods R along the longitudinal direction with a certain interval. Is arranged. In addition, anode hooks F ₂ and F ₂ for suspending the anode plate A on the lower side of the guide member 50a can be rotated perpendicularly to the tips of a large number of rods R along the longitudinal direction with a certain interval. It is arranged.

Furthermore, an anode frame 52 is connected and fixed below the suspension frame 12 by a plurality of brackets 54 as shown in FIG. Then, the bracket 54, anode frame 52 and anode hook F ₂ is provided as a pair on both sides of the cathode frame 22. Further, a suspension part 23 bent into a J-shape is formed at the tip of the anode hooks F ₂ and F ₂ , and the suspension part 23 hangs the ears Aa and Aa (see FIG. 5) of the anode electrode. Stop. Further, as shown in FIG. 4A, the bracket 54 is suspended by a moving member 56 that horizontally moves. The moving member 56 uses a cylinder 58 attached to the suspension frame 12 as a drive source. As shown in FIG. 4, the stroke can be moved in the horizontal direction by one stroke (the distance from the adjacent anode hooks F ₂ and F ₂ ) via the rollers 59 and 59 above the bracket 54. By providing the slide mechanism on the anode hook F ₂ in this manner, an operation by an overhead crane is not required, and therefore the positions of the anode hooks F ₂ and F ₂ can be easily finely adjusted when the anode plate is loaded and pulled up. It becomes possible.

Next, the configuration of the electrode plate 20 will be described with reference to FIG. 5. The electrode plate 20 includes a cathode plate K and an anode plate A, as shown in FIG. And has a conductor bar Ka hooked on the upper edge of the electrolytic cell 32 at the top. Then, rectangular window portions Kb for inserting and hooking the pair of cathode hooks F ₁ and F ₁ are formed at two positions below the conductor bar Ka. On the other hand, the anode plate A is a substantially rectangular flat plate-like anode electrode, and ears Aa and Aa slightly thinner than the thickness of the main body portion protruding in a pair on the left and right are formed on the anode plate A. The ears Aa and Aa are hooked on the upper edge of the electrolytic cell 32 and are hooked on the pair of anode hooks F ₂ and F ₂ . A concave portion Ab that is recessed in a concave shape is formed between the pair of ear portions Aa and Aa. The cathode plate K and the anode plate A are conveyed in a state of being suspended by a number of cathode hooks F ₁ or anode hooks F ₂ in a state where they are alternately arranged in multiple layers at regular intervals. The

[Configuration of rod mounting structure of electrode plate transport device]
Next, the rod mounting structure of the electrode plate transport device according to the present invention will be described. FIG. 6 is an explanatory view showing an embodiment of the rod mounting structure of the electrode plate transport device. Here although an example the case of mounting the detachable frame 25 rod R with cathodes hooks F _1, it can be similarly constructed structure for mounting a rod R having an anode hook F _2. The rods R and R are prepared in accordance with the number of electrode plates 20 (K and A) charged in the electrolytic cell 32, respectively, but only two rods R are shown in FIG. Each of the rods R, R having the cathode hooks F ₁ , F ₁ is arranged along the longitudinal direction on the frame 25 constituting the cathode frame 22 described above. The frame 25 has such a shape that the H-shaped steel is placed horizontally so that the flanges are positioned vertically, and the upper frame 25a and the lower flange corresponding to the upper flange of the horizontally placed H-shaped steel are provided. A corresponding lower frame 25b and a main body 25c corresponding to an H-shaped steel web that connects the upper frame 25a and the lower frame 25b in the longitudinal direction at the center are formed. And as shown in FIG.7 (b), the 1st accommodating part 25d of planar view substantially C-shape provided with the 1st opening part 25e for attaching the rods R and R to the edge of the upper frame 25a. Are arranged at regular intervals, and the second frame having a substantially C-shape in plan view provided with a second opening 25f for attaching the rods R and R to the edge of the lower frame 25b in the same manner. A plurality of storage portions 25g are continuously provided at regular intervals. In addition, the center of the 1st accommodating part 25d and the center of the 2nd accommodating part 25f are arrange | positioned so that it may correspond along a perpendicular direction.

  The first housing portion 25d and the second housing portion 25g have a width that allows the rod R to be taken out, that is, a first opening portion 25e and a second opening portion having an opening width L that is slightly larger than the diameter D of the rod R. 25f is formed, respectively, and the first storage portion 25d and the second storage portion 25g are substantially C-shaped in plan view. And while inserting the rod R in the 1st accommodating part 25d and the 2nd accommodating part 25g via the 1st opening part 25e and the 2nd opening part 25f, it pulls out and removes to the near side in FIG. Is possible.

  On the other hand, pinion gears 24, 24 are attached to upper ends of the rods R, R by attachment members 60, 60. As the mounting members 60, 60, for example, “Power Lock” manufactured by Enomoto Chain Co., Ltd. can be used. In the “power lock”, the pinion gear 24 can be fixed to the rod R without using a key by tightening the tightening bolt while the rod R is inserted into the rotation center of the pinion gear 24. On the other hand, a rack gear 26 screwed into the pinion gears 24 and 24 is disposed in the frame 25 so as to be reciprocally movable in the longitudinal direction (horizontal direction) of the frame 25 using a cylinder (not shown) as a drive source. By reciprocating the rack gear 26 by the cylinder, the rods R and R attached to the first housing portion 25d and the second housing portion 25g are simultaneously rotated at the same posture and angle via the pinion gears 24 and 24, respectively. Move.

  The rods R, R have a first flange 28a having a diameter larger than that of the first housing portion 25d and a first bearing member 28 having a diameter larger than the opening width L of the first opening 25e; A second bearing member 61 having a second flange portion 61a having a diameter larger than that of the second accommodating portion 25f and having a diameter larger than the opening width L of the second opening portion 25g is attached. The bearing member 61 is freely movable along the rod R. The first bearing member 28 and the second bearing portion 61 are bearings for rotatably supporting the rods R and R on the frame 25. For example, an oilless bush can be used. There are various types of oilless bushes, but in this embodiment, as shown in FIG. 7 (c), a single-wing pincushion type having a collar 28a (61a) is used. And the 1st bearing member 28 arrange | positioned at the 1st accommodating part 25d is arrange | positioned so that the 1st collar part 28a may be located above the upper surface of the upper frame 25a, and it arrange | positions at the 2nd accommodating part 25g. The second bearing member 61 is disposed such that the second flange 61a is positioned below the lower surface of the lower frame 25b. Further, a pincushion holding member 27 is interposed between the pinion gear 24 and the upper frame 25a to prevent the pinion gear 24 from being lowered from a fixed position.

  An elastic member 62 formed of a coil spring is disposed below the second bearing member 61 disposed in the second housing portion 25f, and the second bearing member 61 is disposed below the second bearing member 61 via the elastic member 62. A fixing member 63 to be fixed is externally fitted. As the fixing member 63, for example, a set collar can be used. That is, as shown in FIG. 7A, the fixing member 63 includes a main body 63a provided with a slit 63b and formed in a substantially C shape, and is screwed so as to pass through the notch. It is fixed to the rod R by tightening. And by fixing the second bearing member 61 to the rod R so as to press the lower surface of the lower frame 25b with the elastic member 62 interposed between the second bearing member 61 and the fixing member 63, In the unlikely event that a load is applied to the rod R from the lower side, the elastic member 62 absorbs the load so that the rod R can be held safely and reliably. The holding member 27, the first bearing member 28, the first bearing member 29, the second bearing member 61, the elastic member 62, and the fixing member 63 are previously attached to the rod R before the pinion gear 24 is attached to the rod R. Wear it.

[Removal of rod R]
Next, a procedure for attaching and detaching the rod R will be described. First, a procedure for removing the rod R from the frame 25 will be described. FIG. 8 is an explanatory view showing a procedure for removing the rod R, and FIGS. 8A to 8D show a state where the rod R attached to the frame 25 is viewed from the front side, and FIG. Indicates a side view. As shown in FIG. 8A, in the state where the rod R is attached to the frame 25, the set collar fastening screw 63a which is the fixing member 63 is loosened, and the fixing member 63 is moved downward as shown in FIG. 8B. To lower. When the fixing member 63 is lowered, as shown in FIG. 8C, the elastic member 62 and the second bearing member 61 become free, so the second bearing member 61 is moved downward together with the elastic member 62. Then, the second bearing member 61 is extracted from the accommodating portion 25f. The flange portion 28a of the first bearing member 28 is in contact with the upper surface of the upper frame 25a. However, the elastic member 62 and the second bearing member 61 are lowered downward, and the first bearing member 28 and The distance from the second bearing member 61 is relatively long. When the rod R is lifted upward while maintaining this state, the first bearing member 28 is extracted from the first housing portion 25d as shown in FIG. 8 (d). Since the opening width L of the first opening 25e of the first housing portion 25d and the second opening 25g of the second housing portion 25f is formed larger than the diameter D of the rod R, FIG. In the state shown in FIG. 8 (e), the rod R is pulled out to the near side (left side in FIG. 8 (e)) as shown in FIG. 8 (e), so that the rod R is removed from the first opening 25e and the second opening. Can be removed laterally from 25g. In this way, the rod R can be removed from the frame 25.

[Attaching rod R]
Next, a procedure for attaching the rod R to the frame 25 will be described. Specifically, the procedure is the reverse of the procedure for removing the rod R from the frame 25 described above. The rod R is in a state in which the pinion gear 24, the holding member 27, the first bearing member 28, the second bearing member 61, the elastic member 62, and the fixing member 63 are attached in advance. First, the screw 63a of the fixing member 63 is loosened, and as shown in FIG. 8D, the rod R is made to face the first housing portion 25d and the second housing portion 25f of the predetermined frame 25 to which the rod R is to be attached. As shown in FIG. 8E, the second bearing member 61 and the elastic member 62 are lowered. And the rod R is arrange | positioned from the horizontal direction (lateral direction) to the 1st accommodating part 25d and the 2nd accommodating part 25f through the 1st opening part 25e and the 2nd opening part 25g from the horizontal direction (lateral direction). . At this time, the first flange portion 28a of the first bearing member 28 is positioned above the upper surface of the upper frame 25a, and the second flange portion 61a of the second bearing member 61 is lower than the lower surface of the lower frame 25b. Arrange them so that they are located below.

  If necessary, the mounting position of the holding member 27 at the upper end of the rod R is adjusted to adjust the height position of the pinion gear 24 with respect to the rack gear 25, and then the second bearing member 61 and the elastic member 62 are moved upward. Thus, the flange portion 61a of the second bearing member 61 is brought into contact with the lower surface of the lower frame 25b. Then, the fixing member 63 is fixed to the rod R with the screw 63a in a state in which the elastic member 62 is pressed by the fixing member 63 and the second bearing member 61 is positioned in the second accommodating portion 25f. Since the diameters of the first bearing member 28 and the second bearing member 61 are larger than the opening width L of the first opening 25e and the second opening 25g, respectively, the first bearing member 28 and the second bearing member 61 are formed. The second bearing member 61 does not come out of the frame 25. Thus, the attachment of the rod R to the frame 25 is completed.

[Effect of the embodiment]
According to the rod mounting structure of the electrode plate transport device according to the present embodiment, the rod R is not a through-hole, but a substantially C-shaped first accommodating portion 25d having a first opening 25e and a second opening. The rod R can be attached / detached not in the vertical direction but in the horizontal direction (lateral direction) since it is attached to the substantially C-shaped second housing part 25f provided with the part 25g. Therefore, there is an effect that the rod R can be attached and detached even when there is no clearance for the length of the rod R on the lower side. Further, there is an effect that the rod R can be easily removed even if there is some distortion.

  In addition, according to the rod mounting structure of the electrode plate transport device according to the present embodiment, the connection between the rod R and the rack gear 26 serving as a driving means for rotating the rod R is screwed between the rack gear 26 and the pinion gear 24. Therefore, there is an effect that the connection and removal of the rod R and the driving means can be performed very easily and quickly.

  As described above, the preferred embodiments of the present invention have been described in detail. However, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist of the present invention described in the claims. Needless to say, it is possible to modify or change the above. In the above embodiment, the frame 25 has a two-stage shape of the upper frame 25a and the lower frame 25b. However, the frame may be a single stage.

DESCRIPTION OF SYMBOLS 10 Electrode board conveying apparatus 12 Hanging frame 20 Electrode plate 23 Hanging part 24 Pinion gear 25 Frame 25a Upper frame 25b Lower frame 25c Main body 25d First accommodating part 25e First opening part 25f Second accommodating part 25g Second opening Part 26 rack gear 27 holding member 28 first bearing member 28a first flange 30a upper edge 30 electrolytic cell unit 60 mounting member 61 second bearing member 61a second flange 62 elastic member 63 fixing member 100 electrolytic purification Equipment A Anode plate F ₁ Cathode hook F ₂ Anode hook K Cathode plate R Rod

Claims (5)

In the rod mounting structure of the electrode plate transport device for detachably mounting the rod having the hook for supporting the electrode plate in a suspended manner to the frame of the electrode plate transport device,
Wherein the frame includes storage portion has an opening bored at the edge of the frame is formed for mounting the rod,
The rod has a flange having a larger diameter than the accommodating portion and a diameter larger than the opening width of the opening, and a bearing member movable along the rod is attached thereto .
A rod mounting structure for an electrode plate transport device, wherein the rod is detachable from a lateral direction of the frame by fixing the bearing member with a fixing member in a state where the bearing member is interposed in the housing portion. . In the rod mounting structure of the electrode plate transport device according to claim 1,
The hook is pivotable at least 90 ° around the rod by attaching a pinion gear screwed to a rack gear arranged to be horizontally movable along the frame to the upper end portion side of the rod. Rod mounting structure for electrode plate transfer device. In the rod mounting structure of the electrode plate transport device according to claim 1 or 2,
The frame includes an upper frame projecting in the horizontal direction, and a lower frame projecting in the horizontal direction in parallel with the upper frame on the lower side of the upper frame,
The edge of the upper frame the first housing portion is formed drilled with a first opening,
The edge of the lower frame the second housing portion is formed drilled with a second opening,
The rod has a first bearing member having a first flange portion having a diameter larger than that of the first housing portion on the upper side and a diameter larger than an opening width of the first opening portion, and a lower portion. A second bearing having a second flange portion having a diameter larger than that of the second accommodating portion on the side and having a diameter larger than an opening width of the second opening portion and movable along the rod member is attached,
Fixing the second bearing member with a fixing member in a state where the first bearing member is interposed in the first receiving portion and the second bearing member is further interposed in the second receiving portion. The rod mounting structure of the electrode plate transport apparatus, wherein the rod is attachable and detachable from the lateral direction of the frame. In the rod mounting structure of the electrode plate transport device according to claim 1,
A rod mounting structure for an electrode plate transport apparatus, wherein an elastic member is interposed between the fixed member and the bearing member or the second bearing member. In the rod mounting structure of the electrode plate transport apparatus according to any one of claims 1 to 4,
The rod mounting structure for an electrode plate transport device, wherein the fixing member is a set collar.

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