CN210237798U - Emergency crossover bus of electrolytic cell - Google Patents

Abstract

The utility model provides an emergent cross-over connection generating line of electrolysis trough, is including the upper portion generating line and the lower part generating line two parts that the electricity is connected together, and the upper end of upper portion generating line has last crimping piece through upper portion flexible coupling, goes up the crimping piece and is connected with electrolysis trough anode bus through last anchor clamps, the lower part generating line erect the top at electrolysis trough electricity inlet/outlet end generating line through supporting mechanism, be equipped with lower part flexible coupling respectively in the both sides of the bottom of lower part generating line, the lower part flexible coupling of both sides surrounds electrolysis trough electricity inlet/outlet end generating line from both sides to through the terminal lower crimping piece of lower part flexible coupling and electrolysis trough electricity inlet/outlet end generating line be connected. The lower part generating line of emergent cross-over connection generating line erects in the electrolysis trough and advances the top of electricity or going out the electricity end generating line, through the lower part flexible coupling of both sides, can utilize the bolt hole on the former generating line to realize the quick connection of emergent cross-over connection generating line and electrolysis trough electricity or going out the electricity end generating line. The structure has good connection stability, simple and reliable equipment and can realize quick power restoration.

Description

Emergency crossover bus of electrolytic cell

Technical Field

The utility model relates to an aluminum electrolysis cell fault emergency device, in particular to an electrolysis cell emergency crossover bus.

Background

The aluminum electrolysis production line is operated by hundreds of electrolytic cells in series and is supplied with power in a centralized way. When any one electrolytic cell in the production line has accidents, such as bus damage, short circuit port damage and the like, and current cannot pass through a certain electrolytic cell, the whole production line stops production. The recovery of the accident needs a longer time, which causes great loss to the electrolytic production. The emergency bus device is used for temporary short circuit bridging in the case of an electrolytic cell accident. At present, various emergency bridging buses for an electrolytic cell are available, but the structure is generally complex, the number of application components is large, the installation speed is low, and the rapid recovery of power supply of the electrolytic cell is not facilitated.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of overcoming the defects and providing an emergency crossover bus of an electrolytic cell.

The utility model discloses a solve the technical scheme that above-mentioned technical problem adopted and be: the utility model provides an emergent cross-over connection generating line of electrolysis trough, is including the upper portion generating line and the lower part generating line two parts that the electricity is connected together, and the upper end of upper portion generating line has last crimping piece through upper portion flexible coupling, goes up the crimping piece and is connected with electrolysis trough anode bus through last anchor clamps, the lower part generating line erect the top at electrolysis trough electricity inlet/outlet end generating line through supporting mechanism, be equipped with lower part flexible coupling respectively in the both sides of the bottom of lower part generating line, the lower part flexible coupling of both sides surrounds electrolysis trough electricity inlet/outlet end generating line from both sides to through the terminal lower crimping piece of lower part flexible coupling and electrolysis trough electricity inlet/outlet end generating line be connected.

The lower pressure welding block is fixedly connected with the electrolytic cell electricity inlet/outlet end bus through a lower pressure welding bolt and a bolt hole on the electrolytic cell electricity inlet/outlet end bus.

The upper crimping block is arranged between the supporting plates on two sides of the upper bus in a sliding mode, and a primary regulator used for adjusting the sliding position and angle of the upper crimping block is connected between the upper crimping block and the supporting plates.

The primary regulator is a screw rod, and a group of the primary regulator is arranged above and below the upper pressure joint block respectively.

The lower end of the upper bus is rotatably connected with the upper end of the lower bus through a rotating shaft, and a secondary regulator for regulating the connection angle of the upper bus and the lower bus is connected between the upper bus and the lower bus.

The secondary regulator is a screw rod, and two groups of secondary regulators are respectively arranged on two sides of the lower bus.

The lower bus bar is supported and arranged on the top of the bus bar at the electricity inlet/outlet end of the electrolytic cell through a supporting mechanism.

The lower bus is erected on the support frame and/or the edge plate of the electrolytic cell trough through the support mechanism.

The utility model has the advantages that: the lower part generating line of emergent cross-over connection generating line erects in the electrolysis trough and advances the top of electricity or going out the electricity end generating line, through the lower part flexible coupling of both sides, can utilize the bolt hole on the former generating line to realize the quick connection of emergent cross-over connection generating line and electrolysis trough electricity or going out the electricity end generating line. The structure has good connection stability, simple and reliable equipment and can realize quick power restoration.

Drawings

Fig. 1 is a schematic view of the connection structure of the emergency jumper bus of the present invention.

Fig. 2 is a schematic side view of the emergency jumper bus of the present invention.

The labels in the figure are: 1. the electrolytic cell comprises a lower bus, 2, a lower flexible connection, 3, a support plate, 4, an upper clamp, 5, a primary regulator, 6, a secondary regulator, 7, a rotating shaft, 8, a lower pressure joint block, 9, a lower pressure joint bolt, 10, an electrolytic cell anode bus, 11, an electrolytic cell inlet/outlet end bus, 12, an electrolytic cell edge plate, 13, an upper bus, 14, an upper flexible connection, 15, a support mechanism, 16 and an upper pressure joint block.

Detailed Description

The technical solution of the present invention will be described in detail and fully with reference to the accompanying drawings and the detailed description. The specific contents listed in the following examples are not limited to the technical features necessary for solving the technical problems to be solved by the technical solutions described in the claims. Meanwhile, the list is only a part of the present invention, and not all of the embodiments.

As shown in figures 1 and 2, the emergency crossover bus of the electrolytic cell comprises an upper bus 13 and a lower bus 1 which are electrically connected together. The upper end of the upper bus bar 13 is horizontal and the lower end extends obliquely. The upper end of the lower bus bar 1 extends obliquely and is connected to the upper bus bar 13, and the lower end extends vertically downward. The lower end of the upper bus bar 13 and the upper end of the lower bus bar 1 are rotatably connected by a rotating shaft 7, and a secondary regulator 6 is connected between the upper bus bar 13 and the lower bus bar 1. The secondary regulator 6 may take the form of a screw or the like and is provided with one set on each side of the lower busbar 1. The upper bus bar 13 can be rotated around the rotating shaft 7 by adjusting the screw rod, so that the connection angle of the upper bus bar 13 and the lower bus bar 1 can be adjusted.

The upper end of the upper bus 13 is connected with an upper pressure joint block 16 through an upper soft connection 14, and the upper pressure joint block 16 is connected with the anode bus 10 of the electrolytic cell through an upper clamp 4. The upper pressure welding block 16 is arranged between the supporting plates 3 fixed on two sides of the upper bus 13 in a sliding mode, and a primary regulator 5 used for regulating the sliding position and the sliding angle of the upper pressure welding block 16 is connected between the upper pressure welding block 16 and the supporting plates 3. The primary regulator 5 can also adopt a screw rod, and a group is respectively arranged above and below the upper pressure joint block 16. The pitch angle of the upper pressure joint block 16 can be adjusted and controlled to move forwards or backwards along the support plate 3 through the upper and lower groups of screw rods, and the two groups of screw rods are combined with the adjustment of the secondary regulator 6 between the upper bus 13 and the lower bus 1, so that the two groups of screw rods can adapt to the position and the height of the anode bus 10 of the electrolytic cell.

The lower bus 1 is erected above the electrolytic cell electricity inlet/outlet end bus 11 through a supporting mechanism 15, lower flexible connections 2 are respectively arranged on two sides of the bottom end of the lower bus 1, the lower flexible connections 2 on the two sides surround the electrolytic cell electricity inlet/outlet end bus 11 from the two sides, and are connected with the electrolytic cell electricity inlet/outlet end bus 11 through a lower pressure connecting block 8 at the tail end of the lower flexible connections 2. In this way, the original electrolytic cell inlet/outlet end bus 11 can be utilized to be well electrically connected with the lower flexible connection 2 arranged on two sides, and the strength and the stability of the whole connection structure are ensured.

When the electrolytic cell inlet/outlet end bus 11 is connected, the lower pressure-connecting block 8 and the electrolytic cell inlet/outlet end bus 11 can be fixedly connected through the lower pressure-connecting bolt 9 and the bolt hole on the electrolytic cell inlet/outlet end bus 11 by using the original bolt hole on the electrolytic cell inlet/outlet end bus 11.

When the emergency crossover bus is fixed, the lower bus bar 1 can be supported and arranged on the top of the electrolysis cell power inlet/outlet end bus bar 11 through a supporting mechanism 15 as shown in fig. 1 and 2. A support frame can be additionally arranged to support and fix, or a support mechanism is used for fixing the lower bus-bar groove opening edge plate 12.

The above description of the specific embodiments is only for the purpose of helping understanding the technical idea of the present invention and the core idea thereof, and although the technical solution is described and illustrated using the specific preferred embodiments, it should not be construed as limiting the present invention itself. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention. Such modifications and substitutions are intended to be included within the scope of the present invention.

Claims (8)

1. The utility model provides an emergent crossover bus of electrolysis trough, is including the upper portion generating line (13) and lower part generating line (1) two parts that are connected together of electricity, and the upper end of upper portion generating line (13) has connect through upper portion flexible coupling (14) and has gone up crimping piece (16), goes up crimping piece (16) and is connected with electrolysis trough anode bus (10) through last anchor clamps (4), its characterized in that: the lower bus (1) is erected above the electrolytic cell electricity inlet/outlet end bus (11) through a supporting mechanism (15), lower flexible connections (2) are respectively arranged on two sides of the bottom end of the lower bus (1), the lower flexible connections (2) on the two sides surround the electrolytic cell electricity inlet/outlet end bus (11) from the two sides, and the lower flexible connections (2) on the two sides are connected with the electrolytic cell electricity inlet/outlet end bus (11) through a lower pressure connection block (8) at the tail end of the lower flexible connections (2).

2. An electrolysis cell emergency crossover bus as defined in claim 1, wherein: the lower pressure joint block (8) and the electrolytic cell electricity inlet/outlet end bus (11) are fixedly connected through a lower pressure joint bolt (9) and a bolt hole on the electrolytic cell electricity inlet/outlet end bus (11).

3. An electrolysis cell emergency crossover bus as defined in claim 1, wherein: the upper pressure joint block (16) is arranged between the support plates (3) on two sides of the upper bus (13) in a sliding mode, and a primary regulator (5) used for regulating the sliding position and the sliding angle of the upper pressure joint block (16) is connected between the upper pressure joint block (16) and the support plates (3).

4. An electrolysis cell emergency crossover bus as defined in claim 3, wherein: the primary regulator (5) is a screw rod, and a group of the primary regulator is respectively arranged above and below the upper pressure joint block (16).

5. An electrolysis cell emergency crossover bus as defined in claim 1, wherein: the lower end of the upper bus (13) is rotatably connected with the upper end of the lower bus (1) through a rotating shaft (7), and a secondary regulator (6) for regulating the connection angle of the upper bus (13) and the lower bus (1) is connected between the upper bus (13) and the lower bus (1).

6. An electrolysis cell emergency crossover bus as defined in claim 5, wherein: the two-stage regulator (6) is a screw rod, and two groups of the two-stage regulator are respectively arranged on two sides of the lower bus (1).

7. An electrolysis cell emergency crossover bus as defined in claim 1, wherein: the lower bus bar (1) is supported and arranged on the top of the electrolytic cell electricity inlet/outlet end bus bar (11) through a supporting mechanism (15).

8. An electrolysis cell emergency crossover bus as defined in claim 1, wherein: the lower bus bar (1) is fixed on a support frame and/or an edge plate (12) of the electrolytic cell trough through a support mechanism.

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