CN218880083U - Cathode titanium plate assembly of electrolytic bath - Google Patents

Abstract

The utility model discloses an electrolysis trough negative pole titanium plate assembly, including a plurality of intervals and parallel arrangement's titanium plate body, the welding of the upper end of every titanium plate body has the compound stick of titanium copper, and the tip level of the compound stick of titanium copper extends titanium plate body, its characterized in that: and the same side of each titanium-copper composite rod is provided with a conducting bar together, and the conducting bar is detachably connected with the titanium-copper composite rods. The conducting bar is of a split structure and comprises a fixing piece and a connecting piece, wherein the fixing piece is located between two adjacent titanium-copper composite rods, the connecting piece is located on the outermost side, the fixing piece and the two connected titanium-copper composite rods are detachably connected and are connected with each other, the two adjacent titanium-copper composite rods are connected, and the connecting piece and the titanium-copper composite rod on the outermost side are detachably connected and are connected with an external electrode. The modularized design can be flexibly installed according to actual needs.

Description

Cathode titanium plate assembly of electrolytic bath

Technical Field

The utility model relates to the technical field of electrolytic bath equipment, in particular to a cathode titanium plate component of an electrolytic bath.

Background

The electrolytic bath consists of a bath body, an anode and a cathode, when direct current passes through the electrolytic bath, oxidation reaction occurs at the interface of the anode and the solution, and reduction reaction occurs at the interface of the cathode and the solution, so as to prepare the required product. Electrolytic cells are widely used in various fields due to their superior energy consumption. The titanium plate is usually used as the cathode plate in a large-scale electrolytic tank, and the cathode titanium plate has good corrosion resistance and light weight, so that the service life of the cathode titanium plate can be effectively prolonged. However, for the electrolytic cells with different volumes, cathode titanium plates with different numbers or different intervals may be needed, and the cathode titanium plates are finally welded on a copper bar and are electrically conducted through the copper bar. The copper bars are generally in an integral rod-shaped structure, and the copper bars with different sizes are selected for different electrolytic tanks, so that inconvenience is brought to use.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects, the utility model aims to provide an electrolytic bath cathode titanium plate component which is designed in a modularized way and can be flexibly installed according to actual needs.

In order to achieve the above purpose, the utility model discloses a technical scheme is: electrolytic bath negative pole titanium board subassembly, including a plurality of intervals and parallel arrangement's titanium board body, every the upper end welding of titanium board body has the compound stick of titanium copper, the tip level of the compound stick of titanium copper extends titanium board body, its characterized in that: and the same side of each titanium-copper composite rod is provided with a conductive bar together, and the conductive bars are detachably connected with the titanium-copper composite rods. The conducting bar is of a split structure and comprises fixing pieces and a connecting piece, wherein the fixing pieces are positioned between every two adjacent titanium-copper composite rods, the connecting piece is positioned on the outermost side, the fixing pieces and the two connected titanium-copper composite rods are detachably connected and are communicated with the adjacent two titanium-copper composite rods, and the connecting piece and the titanium-copper composite rod on the outermost side are detachably connected and are communicated with an external electrode.

The beneficial effects of the utility model reside in that: 1) The conducting bar is detachably connected with the titanium-copper composite rod, so that the conducting bar can be conveniently replaced according to actual needs. 2) Each titanium plate body is connected to the external electrode in parallel through the conducting bar, the conducting bar is of a split structure, the fixing pieces and the connecting pieces form a standard structure, and when the titanium plate bodies need to be increased or decreased, the fixing pieces only need to be increased or decreased.

Further, the fixing piece is of a door-shaped structure and comprises two vertical portions and a connecting portion which is arranged above the vertical portions, the vertical portions are abutted to the side wall of the titanium-copper composite rod, and the vertical portions are connected with the titanium-copper composite rod through at least one fixing assembly. The vertical portion is connected with the titanium-copper composite rod, and on the one hand, two adjacent titanium-copper composite rods are connected, and on the other hand, two adjacent fixing pieces are electrified and conducted through the fixing pieces.

Further, the height position of the connecting part is higher than that of the titanium-copper composite rod, and the vertical distance from the connecting part to the titanium-copper composite rod is not less than 5 cm. In the use process, an anode plate is inserted between two adjacent titanium plate bodies, so that the connecting part is arranged above the titanium-copper composite rod, and the inserted anode plate is not interfered.

Further, each fixing assembly comprises a screw and nuts positioned at two ends of the screw, through holes for the screw to pass through are formed in the vertical portion and the titanium-copper composite rod, and the vertical portion and the titanium-copper composite rod are clamped between the two nuts. The structure of screw rod and nut is convenient for install fast and dismantle, when needs are demolishd, loosens nut and screw rod, takes out the screw rod in the follow through-hole can.

Furthermore, the screw, the nut and the conductive bar are made of copper materials, so that the conductive performance is good.

Further, a boss extends from the upper end of the titanium plate body, the boss is welded with the titanium-copper composite rod, and a groove is formed between the titanium-copper composite rod and the titanium plate body. Because the titanium plate body and the titanium-copper composite rod are welded, the grooves can effectively dissipate heat in the welding process of the titanium plate body and the titanium-copper composite rod, thereby preventing the titanium-copper composite rod and the titanium plate body from generating thermal deformation in the welding process and ensuring the flatness of the titanium plate body.

Furthermore, the left end and the right end of the titanium plate body are also provided with fixed seats, and the fixed seats are abutted with an external electrolytic cell. The arrangement of the fixing seat is convenient for fixing the titanium plate body in the electrolytic bath.

Further, the method is as follows. The fixing seat comprises a transverse plate which is abutted and fixed with the electrolytic cell. The diaphragm is convenient for the fixed of fixing base. The transverse plate is fixed with a lifting lug, and the lifting lug is provided with a jack convenient to hoist.

Furthermore, a plurality of insulating columns are arranged on the same side face of the titanium plate body, and the insulating columns are distributed on the titanium plate body in an array mode. Because the anode plate is inserted between two adjacent titanium plate bodies and the insulating column is arranged, the anode plate only can be in contact with the insulation in the installation or disassembly process, and the short circuit caused by the contact with the titanium plate bodies is avoided.

Drawings

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

fig. 2 is a side view of an embodiment of the present invention;

fig. 3 is a schematic view of the connection state of the titanium plate body and the titanium-copper composite rod in the embodiment of the present invention.

In the figure:

1. a titanium plate body; 11. a boss; 12. a groove; 2. a titanium copper composite rod; 3. a fixing member; 31. a vertical portion; 32. a connecting portion; 4. a connecting member; 5. a fixing assembly; 6. a fixed seat; 61. a transverse plate; 62. lifting lugs; 7. and an insulating column.

Detailed Description

The following detailed description of the preferred embodiments of the present invention will be provided in conjunction with the accompanying drawings, so as to enable those skilled in the art to more easily understand the advantages and features of the present invention, and thereby define the scope of the invention more clearly and clearly.

Referring to the attached drawing 1, the utility model discloses an electrolysis trough negative pole titanium board subassembly, including a plurality of intervals and parallel arrangement's titanium board body 1, every the welding of the upper end of titanium board body 1 has compound stick 2 of titanium copper, the tip level of compound stick 2 of titanium copper extends titanium board body 1, every compound stick 2 of titanium copper is provided with the conducting bar jointly with one side, the conducting bar can be dismantled with compound stick 2 of titanium copper and be connected. The conducting bar is detachably connected with the titanium-copper composite rod 2, so that the conducting bar can be conveniently replaced according to actual needs.

The conducting bar is of a split structure and comprises fixing pieces 3 located between two adjacent titanium-copper composite rods 2 and a connecting piece 4 located on the outermost side, the fixing pieces 3 are detachably connected with the two connected titanium-copper composite rods 2 and conduct the two adjacent titanium-copper composite rods 2, and the connecting piece 4 is detachably connected with the titanium-copper composite rod 2 on the outermost side and conducts the titanium-copper composite rod 2 on the outermost side and an external electrode. Each titanium plate body 1 is connected to the external electrode in parallel through the conducting bar, the conducting bar is of a split structure, the fixing pieces 3 and the connecting pieces 4 form a standard structure, and when the titanium plate bodies 1 need to be increased or decreased, the fixing pieces 3 only need to be increased or decreased.

The titanium-copper composite rod 2 is of a square structure, a cylinder is arranged in the titanium-copper composite rod 2, titanium is arranged outside the titanium-copper composite rod, the titanium outside the titanium-copper composite rod 2 is stripped at the part where the titanium-copper composite rod 2 is connected with the fixing piece 3, and the copper inside the titanium-copper composite rod is abutted to the fixing piece 3, so that the electric conductivity is improved. Wherein the connecting piece 4 is also made of copper material with good conductive effect.

Referring to fig. 2, the fixing member 3 is a door-shaped structure and includes two vertical portions 31 and a connecting portion 32 disposed above the vertical portions 31, the vertical portions 31 abut against the side walls of the titanium-copper composite rod 2, and the vertical portions 31 and the titanium-copper composite rod 2 are connected by at least one fixing assembly 5. The vertical portion 31 is connected with the titanium copper composite rod 2, on one hand, connects two adjacent titanium copper composite rods 2, and on the other hand, electrically connects two adjacent fixing pieces 3 through the fixing pieces 3.

The height position of the connecting part 32 is higher than that of the titanium-copper composite rod 2, and the vertical distance from the connecting part 32 to the titanium-copper composite rod 2 is not less than 5 cm. In the using process, an anode plate is inserted between two adjacent titanium plate bodies 1, so that the connecting part 32 is arranged above the titanium-copper composite rod 2, and the inserted anode plate cannot be interfered.

Each fixing component 5 comprises a screw and nuts positioned at two ends of the screw, through holes for the screw to pass through are formed in the vertical portion 31 and the titanium-copper composite rod 2, and the vertical portion 31 and the titanium-copper composite rod 2 are clamped between the two nuts. Two nuts are evenly in threaded connection with the screw, or one nut is fixed with the screw, and the other nut is in threaded connection with the screw, so long as the fixing piece 3 and the titanium copper composite rod 2 can be fixed. When the screw needs to be detached, the nut and the screw are loosened, and the screw is taken out from the through hole.

The screw, the nut and the conductive bar are all made of copper materials, and the conductivity is not affected.

The overlapping portions of the titanium-copper composite rod 2 and the vertical portion 31 are rectangular, so that the four fixing assemblies 5 are arranged and distributed at four corners of the rectangle respectively, and the connection stability is improved.

The connecting element 4 is L-shaped and comprises a second vertical part 31 parallel to the vertical part 31 and a second connecting part 32 parallel to and at the same height as the connecting part 32, i.e. the connecting element 4 removes one vertical part 31 for the fixing element 3, because the connecting element 4 only needs to be connected with one titanium-copper composite rod 2. The connecting member 4 is equivalent to a lead wire for leading out the cathode titanium plate assembly, and is connected with an external electrode for conducting electricity.

Referring to fig. 3, a boss 11 extends from the upper end of the titanium plate body 1, the boss 11 is welded to the titanium-copper composite rod 2, and a groove 12 is formed between the titanium-copper composite rod 2 and the titanium plate body 1. Because titanium plate body 1 and titanium copper composite rod 2 are welded, recess 12 can effectively dispel the heat at both welding processes, has prevented titanium copper composite rod 2 and titanium plate body 1 produced thermal deformation in welding process, guarantees titanium plate body 1's roughness.

Fixing seats 6 are further arranged at the left end and the right end of the titanium plate body 1, and the fixing seats 6 are abutted to an external electrolytic tank. Is fixed with a titanium plate body 1 by welding or adopting bolts for fixing. The arrangement of the fixing seat 6 is convenient for fixing the titanium plate body in an electrolytic tank (not shown in the figure), and the electrolytic tank comprises a cross rod for placing the fixing seat 6.

Referring to fig. 3, the fixing seat 6 comprises a transverse plate 61, and the transverse plate 61 is abutted and fixed with the electrolytic cell. The transverse plate 61 is provided with bolt holes for bolts to pass through. A lifting lug 62 is fixed on the transverse plate 61, and a jack convenient for lifting is arranged on the lifting lug 62. The lifting lugs 62 are arranged to facilitate the hoisting and transportation of the titanium plate body 1.

Referring to fig. 2, a plurality of insulating columns 7 are arranged on the same side surface of the titanium plate body 1, and the insulating columns 7 are distributed on the titanium plate body 1 in an array manner. The titanium plate body 1 is provided with an embedded groove, part of the insulating column 7 is embedded into the embedded groove, and the insulating column 7 protrudes out of the side surface of the titanium plate body 1. The insulating column 7 is made of an insulating material such as PTFE (polytetrafluoroethylene), PEEK (polyetheretherketone) and the like, and the insulating column 7 is adhered in the embedded groove through glue. Because the anode plate is inserted between two adjacent titanium plate bodies 1 and the insulating column 7 is arranged, the anode plate only can be in contact with the insulation in the installation or disassembly process, and the short circuit caused by the contact with the titanium plate bodies 1 is avoided.

The specific working process of this embodiment is as follows: after the titanium plate body 1 and the titanium copper composite rod 2 are welded, the titanium plate body and the titanium copper composite rod are sequentially placed at the designated position of the electrolytic tank by passing through a lifting lug 62 crane. Selecting the fixing pieces 3 according to the number of the final titanium plate bodies 1, fixing the titanium-copper composite rods 2 and the fixing pieces 3 through the fixing assemblies 5, connecting the titanium plate bodies 1 in parallel, and finally fixing one connecting piece 4 to form a cathode titanium plate assembly whole.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, so as not to limit the protection scope of the present invention, and all equivalent changes or modifications made according to the spirit of the present invention should be covered in the protection scope of the present invention.

Claims (9)

1. Electrolytic bath negative pole titanium board subassembly, including a plurality of intervals and parallel arrangement's titanium board body, every the upper end welding of titanium board body has the compound stick of titanium copper, the tip level of the compound stick of titanium copper extends titanium board body, its characterized in that: the same side of each titanium-copper composite rod is provided with a conductive bar together, and the conductive bars are detachably connected with the titanium-copper composite rods;

the conducting bar is of a split structure and comprises a fixing piece and a connecting piece, wherein the fixing piece is positioned between two adjacent titanium-copper composite rods, the connecting piece is positioned on the outermost side, the fixing piece and the two connected titanium-copper composite rods are detachably connected and are communicated with the two adjacent titanium-copper composite rods, and the connecting piece and the titanium-copper composite rod on the outermost side are detachably connected and are communicated with an external electrode.

2. The cell cathode titanium plate assembly according to claim 1, wherein: the fixing piece is a door-shaped structure and comprises two vertical portions and a connecting portion which is arranged above the vertical portions, the vertical portions are abutted to the side wall of the titanium-copper composite rod, and the vertical portions are connected with the titanium-copper composite rod through at least one fixing component.

3. The cell cathode titanium plate assembly of claim 2, wherein: the height position of the connecting part is higher than that of the titanium-copper composite rod, and the vertical distance from the connecting part to the titanium-copper composite rod is not less than 5 cm.

4. The cell cathode titanium plate assembly of claim 2, wherein: each fixing component comprises a screw and nuts positioned at two ends of the screw, through holes for the screw to pass through are formed in the vertical portion and the titanium-copper composite rod, and the vertical portion and the titanium-copper composite rod are clamped between the two nuts.

5. The cell cathode titanium plate assembly according to claim 4, wherein: the screw, the nut and the conductive bar are all made of copper materials.

6. The cell cathode titanium plate assembly of claim 1, wherein: the upper end of the titanium plate body extends to form a boss, the boss is welded with the titanium-copper composite rod, and a groove is formed between the titanium-copper composite rod and the titanium plate body.

7. The cell cathode titanium plate assembly of claim 1, wherein: the left end and the right end of the titanium plate body are also provided with fixing seats, and the fixing seats are abutted to an external electrolytic tank.

8. The cell cathode titanium plate assembly according to claim 7, wherein: the fixing seat comprises a transverse plate, the transverse plate is abutted against and fixed with the electrolytic cell, a lifting lug is fixed on the transverse plate, and a jack convenient to hoist is formed in the lifting lug.

9. The cell cathode titanium plate assembly according to claim 1, wherein: and a plurality of insulating columns are arranged on the same side surface of the titanium plate body, and the insulating columns are distributed on the titanium plate body in an array manner.

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