CN214458378U - Manganese electrodeposition conductive cross beam - Google Patents

Manganese electrodeposition conductive cross beam Download PDF

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Publication number
CN214458378U
CN214458378U CN202120364673.0U CN202120364673U CN214458378U CN 214458378 U CN214458378 U CN 214458378U CN 202120364673 U CN202120364673 U CN 202120364673U CN 214458378 U CN214458378 U CN 214458378U
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conductive
stainless steel
welding
head
copper
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CN202120364673.0U
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欧阳鹏
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Abstract

The utility model discloses a manganese electrodeposition conductive beam, manganese electrodeposition conductive beam is made by leading electrical head, stainless steel band steel and busbar triplex welding, and electrically conductive head and stainless steel band steel adopt the welding to make the roof beam, and the welding of at least one side of making the crossbeam side at electrically conductive head and stainless steel band steel has electrically conductive copper bar. The utility model is formed by welding the conductive head and the stainless steel flat steel into a beam and then welding the conductive strips on one side or two sides of the beam, thereby saving a large amount of copper materials, and reducing the raw materials and the processing cost of the conductive beam by 10-20 percent. Meanwhile, the bearing capacity of the conductive beam is improved, and the requirements of the manganese electrodeposition production on the development now and in the future are met. The conductive beam is welded, so that the corrosion looseness of copper and stainless steel and the heating expansion deformation looseness are avoided, the service life of the conductive rod is effectively prolonged, the maintenance cost is greatly reduced, the conductive efficiency of the conductive beam is improved, and the energy waste is reduced.

Description

Manganese electrodeposition conductive cross beam
Technical Field
The utility model relates to the technical field of electrolysis equipment, in particular to a manganese electrodeposition conductive beam in the electrolysis equipment.
Background
The plate conductive beams (bars) used in the manganese electrolysis production process at present are in the following modes: firstly, the copper bar folded U-shaped clamping stainless steel plate is anchored by bolts (ground anchors); and secondly, adopting composite steel clad copper. The method has the following defects: 1. the method comprises the steps of 1, increasing the specification size of a copper bar to reduce the influence of deflection deformation of the continuously produced copper bar on production, and causing the increase of manufacturing cost, 2, causing the heating caused by poor contact between the copper bar and a stainless steel plate due to the corrosion and the loosening of an anchoring bolt in a long-term acid-base environment of an electrolytic cathode plate, namely causing the energy waste and increasing the maintenance cost, and 3, causing the loosening and the heating of the copper and the stainless steel due to the difference of expansion coefficients of the copper and the stainless steel, namely causing the energy waste, and being incapable of maintaining and increasing the recovery cost of nonferrous metals.
Therefore, there is a need for an improved conductive beam for manganese electrolysis to reduce the cost and avoid the waste of materials.
Disclosure of Invention
Therefore, for solving the above problems, an object of the present invention is to provide a manganese electrodeposition conductive beam, which has less copper material, less thermal deformation and less acid-base corrosion, and thus has a long service life.
In order to achieve the above object, the technical solution of the present invention is as follows.
The manganese electrodeposition conductive beam is characterized in that the manganese electrodeposition conductive beam is formed by welding a conductive head, stainless steel flat steel and a conductive strip, the conductive head and the stainless steel flat steel are welded to form a beam, and a conductive copper strip is welded on at least one side of the side face of the beam formed by welding the conductive head and the stainless steel flat steel.
The bottom surface of the conductive copper bar is flush with the bottom surfaces of the beams which are welded with the conductive heads and the stainless steel flat steel, so that a good conductive effect is achieved.
The conductive head and the stainless steel flat steel are welded into a rectangular beam.
Furthermore, the conductive head adopts red copper with the component of T2, is rectangular, and has the thickness of 6-12mm, the length of 100-200mm and the width of 40-80 mm.
Furthermore, the stainless steel flat steel is 304 stainless steel with the thickness of 6-12mm, the length of 700-1000mm and the width of 40-80mm, and the stainless steel flat steel is connected with the tail end of the conductive head.
Furthermore, the conductive copper bar component adopts T2 red copper, the thickness is 0.5-4mm, the width is 10-40mm, and the length is 700-1000 mm.
The utility model is formed by welding the conductive head and the stainless steel flat steel into a beam and then welding the conductive strips on one side or two sides of the beam, thereby saving a large amount of copper materials, and reducing the raw materials and the processing cost of the conductive beam by 10-20 percent. Meanwhile, the bearing capacity of the conductive beam is improved, and the requirements of the manganese electrodeposition production on the development now and in the future are met. The conductive beam is welded, so that the corrosion looseness of copper and stainless steel and the heating expansion deformation looseness are avoided, the service life of the conductive rod is effectively prolonged, and the conductive efficiency of the conductive beam is improved.
Drawings
Fig. 1 is a schematic structural diagram implemented by the present invention.
Fig. 2 is a bottom view of the present invention.
Fig. 3 is a left side view of the practice of the invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
As shown in fig. 1-3, for the utility model discloses the electrically conductive crossbeam of manganese electrodeposition, the electrically conductive crossbeam of manganese electrodeposition is made by conductive head 1, stainless steel band steel 2 and 3 triplexs of busbar welding, wherein, conductive head 1 and stainless steel band steel 2 adopt the welding to make the roof beam, make one side or both sides welding electrically conductive copper bar 3 of crossbeam side at conductive head and band steel welding, electrically conductive copper bar 3 is from the both sides welding that conductive head and band steel welding made the crossbeam side in the mode shown in fig. 1 to electrically conduct. Fig. 2 is a bottom view, just verifying this.
As can be seen from fig. 1, the bottom surface of the conductive copper bar 3 is flush with the bottom surfaces of the conductive head and the beam made of stainless steel flat steel by welding, so as to have good conductive effect. In other words, the bottom surface of the conductive copper bar 3 is located on the same horizontal plane as the bottom surfaces of the conductive head 1 and the stainless steel flat bar 2. This is also evident from fig. 2.
Usually, the conductive head 1 and the stainless steel flat bar 2 are welded to form a rectangular beam.
As shown in connection with fig. 3. The conductive head 1 adopts red copper with the component of T2, the conductive head 1 is rectangular, the thickness is 6-12mm, and the length is 100-200 mm. The width is 40-80 mm.
The stainless steel flat steel 2 adopts 304 or 316 stainless steel, the thickness is 6-12mm, and the length is 700-1000 mm. The width is 40-80 mm.
The conductive copper strip 3 adopts T2 red copper as the component, is consistent with the conductive head, has the thickness of 0.5-4mm, the width of 10-40mm and the length of 700-1000mm, and the actual specification size of the conductive strip is calculated and selected according to the current of not more than 5 amperes per square millimeter.
In a word, the utility model is formed by welding the conductive head and the stainless steel flat steel into the beam and then welding the conductive strips on one side or two sides of the beam, thereby saving a large amount of copper materials and reducing the raw materials and the processing cost of the conductive beam by 10-20 percent. Meanwhile, the bearing capacity of the conductive beam is improved, and the requirements of the manganese electrodeposition production on the development now and in the future are met. The conductive beam is welded, so that the corrosion looseness of copper and stainless steel and the heating expansion deformation looseness are avoided, the service life of the conductive rod is effectively prolonged, and the conductive efficiency of the conductive beam is improved.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. The manganese electrodeposition conductive beam is characterized in that the manganese electrodeposition conductive beam is formed by welding a conductive head, stainless steel flat steel and a conductive strip, the conductive head and the stainless steel flat steel are welded to form a beam, and a conductive copper strip is welded on at least one side of the side face of the beam formed by welding the conductive head and the stainless steel flat steel.
2. The mn-electrodepositable conductive beam of claim 1, wherein the bottom surface of the conductive copper bar is flush with the bottom surface of the beam formed by welding the conductive head to the stainless steel flat.
3. The mn-electrodepositable conductive beam of claim 1, wherein the beam formed by welding the conductive head and the flat stainless steel is rectangular.
4. The Mn electrodeposition conductive beam as in claim 3, wherein the conductive head is made of red copper with the composition of T2, the conductive head is rectangular, the thickness is 6-12mm, the length is 100-200mm, and the width is 40-80 mm.
5. The Mn electrodeposition conductive beam as in claim 4, wherein the stainless steel flat steel component is 304 stainless steel, the thickness is 6-12mm, the length is 700-1000mm, the width is 40-80mm, and the stainless steel flat steel is connected to the tail end of the conductive head.
6. The Mn electrodeposition conductive beam as in claim 5, wherein the conductive copper bar is made of T2 red copper, and has a thickness of 0.5-4mm, a width of 10-40mm, and a length of 700-1000 mm.
CN202120364673.0U 2021-02-07 2021-02-07 Manganese electrodeposition conductive cross beam Active CN214458378U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202120364673.0U CN214458378U (en) 2021-02-07 2021-02-07 Manganese electrodeposition conductive cross beam

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202120364673.0U CN214458378U (en) 2021-02-07 2021-02-07 Manganese electrodeposition conductive cross beam

Publications (1)

Publication Number Publication Date
CN214458378U true CN214458378U (en) 2021-10-22

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CN202120364673.0U Active CN214458378U (en) 2021-02-07 2021-02-07 Manganese electrodeposition conductive cross beam

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CN (1) CN214458378U (en)

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