RU2601018C2 - Device to extract short-circuiting wedges at connecting electrolyzer for aluminium production - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to a device for extracting a short-circuiting wedge inserted between two conductors for disconnecting an electrolyzer in a row of electrolytic cells for aluminium production. Device comprises a means of gripping the wedge and at least one bearing cylinder oriented vertically and having a housing and a piston with a rod, herewith the housing or the rod is rigidly connected with at least one horizontal support surface directed downward and arranged to allow the wedge extraction when the extraction device is installed above the wedge, the upper horizontal surface of each conductor is located at the same level with the horizontal support surface, as well as with the wedge gripping means to allow the wedge extraction by the bearing cylinder providing opposite forces on the conductors and the wedge for their separation.

EFFECT: provided is higher reliability and safety of operation with the possibility of controlling the trajectory of pushing the wedges.

15 cl, 3 dwg

Description

The invention relates to the field of producing aluminum by fire electrolysis according to the Hall-Hero method. It relates to devices for electrically connecting electrolysis cells to produce aluminum by flame electrolysis. More specifically, it relates to equipment that is used in the process of restarting a temporarily stopped electrolyzer, an operation also called “turning on”, which allows you to remove shorting wedges located between the cathode assembly of the specified cell and the cathode assembly of a previous neighboring cell. Such equipment will hereinafter be referred to as a "wedge extraction device" or as an "extraction device".

Aluminum is produced industrially in electrolyzers by firing electrolysis according to the well-known Hall-Eru method. Factories contain a large number of electrolyzers installed in a row in buildings called workshops or halls of electrolysis and electrically connected in series using connecting conductors in order to optimize the occupied floor space of the plants. Each cell contains a bath equipped with a cathode assembly and an anode system. The bath contains a steel casing, cladding elements made of refractory materials and a cathode assembly located at the bottom of the bath, formed by a dense arrangement of carbon-containing blocks in which metal rods are inserted, the ends of which extend from the casing. Each bath also contains an anode system formed by at least one rigid beam that supports one or more horizontal conductive rods, called an “anode frame”, on which rods are mounted to hang anodes of carbon-containing material, which are partially immersed in the electrolyte bath.

The cells are typically arranged to form two or more parallel rows that are electrically connected to each other by end conductors. Typically, an electric current flows from the cathode of the preceding cell to the anode of the next cell. The connection diagram between two successive electrolysis cells contains an electrolysis current transmission circuit consisting of cathode collectors connected on the one hand to the cathode outputs of the electrolyzer of this row (n) and, on the other hand, to “anode risers”, which, in turn, are connected to a rigid beam and anode frames of the next neighboring cell, row (n + 1).

From time to time, one or more row electrolysers must stop. This stop is made by connecting the cathode collector of a given cell to a connecting conductor that connects the cathode outputs of a previous neighboring cell to the “anode risers” that feed the anode frame of the cell. The connection is made by a plurality of conductive wedges, usually made of aluminum, which are disclosed in patent FR 2583069 (see FIG. 8, item 12): in this configuration, the cathode collector of the electrolyzer and the connecting conductor between the cathode of the previous electrolyzer and the anode of the indicated electrolyzer are locally in the form of two conductors with a substantially rectangular cross-section, each of which has at least one upper horizontal surface and one essentially vertical surface, and essentially vertical The surface of one conductor is opposite the substantially vertical surface of the other, so these two essentially vertical surfaces limit the gap for receiving the shorting wedge, which in turn contains two essentially parallel surfaces, slightly converging downwards when the wedge is placed in order to occupy the specified gap.

To shut off the cell, wedges must be inserted between the conductors to provide a contact surface giving as little electrical resistance as possible. In practice, in order to ensure good electrical contact, these wedges are inserted into the gap existing between the conductors, while they themselves are held by bolt clamps.

To turn on the electrolyzer, these wedges must be removed to isolate these conductors from each other, and the current flowing from the previous electrolyzer again passes through the anode risers to feed the anode frame of the next electrolyzer. To remove the wedges without exerting too much force, it is usually necessary to unscrew, at least partially, the indicated clips. Then the wedges are pulled upward so that they come out of the gap arranged between the conductors.

Until now, the installation and removal of these wedges required complex human interventions, which either entails stopping the cell line for the time necessary for the intervention, which reduces the productivity of the line, or, preferably, entails intervention for a very limited time. Indeed, if the extraction is carried out without stopping the line, then, since the removal of all the wedges cannot be done at the same time, the current flowing in the remaining wedges in place gradually increases, due to which they noticeably heat up, so that the wedges removed last can reach high temperatures. Increased temperature of the wedges can have detrimental effects, for example, require more significant force to extract due to their expansion, or lead to a significant deterioration of the contact surfaces. Thus, the intervention should be as short as possible in order to limit the heating of the wedges removed last.

In addition, safety restrictions require operators to remain at floor level, in particular when they are operating on specified wedges. Around modern electrolyzers, passages are arranged to facilitate various operations on electrolyzers. These passages are approximately at the same level as the surface of the liquid bath. For safety reasons, cathodic collectors and connecting conductors are located below these passages. Conductors and gaps for receiving wedges are located below these passages, but they must be accessible from these passages during operations necessary to temporarily stop the cell or turn it on.

To save time during these operations, they tried to remove the wedges using a chain hoist mounted on a bridge crane moving along the electrolysis shop, above the electrolyzers. To do this, shorting wedges equipped with trunnions were used, and the chain hoist was equipped with a U-shaped sling designed to mesh with the wedge trunnions. Polyspast allowed to develop significant efforts, usually of the order of 10 tons, but these efforts remained insufficient if the scrapers were not previously unscrewed, at least partially. This led to a big loss of time, since the unscrewing of the clamps could only be carried out at ground level, with a tool with a large handle, the rotation capabilities of which were low. In addition, when, despite the applied effort, the wedge still stuck to the conductors, the case ended up with the chain hoist lifting, grabbing and damaging the conductors. Finally, this practice caused serious security problems, since wedges that have a certain mass, usually several tens of kilograms, were often pushed along a more or less controlled upward path that could pass near operators.

The authors of the application have developed a method of extracting wedges that does not have the above-mentioned disadvantages, in which an extraction device is applied that acts on the wedges without having to unscrew the clamps, which exerts considerable force when removing the wedges, without causing the slightest risk of damage to said conductors and, finally, which allows control the trajectory of the ejection of these wedges.

A first object of the invention is an extraction device for removing a shorting wedge, said wedge being inserted between two conductors to turn off the cell, each conductor having at least one upper horizontal surface and one substantially vertical surface, the substantially vertical surface of one conductor is opposite the substantially vertical surface of the other, so these two essentially vertical surfaces are bounding and a gap for receiving said shorting wedge, which, in turn, contains two substantially parallel surfaces that converge slightly downward when said wedge is set to occupy said gap, said device comprising means for gripping said wedge that it also contains at least one ram cylinder oriented vertically, comprising a housing and a piston with a corresponding piston rod,

a) the specified housing (or the specified rod) is rigidly connected to at least one horizontal supporting surface, which is oriented downward and which is located so that when the specified extraction device was above the specified wedge to remove it, the upper horizontal surface of each conductor was at the same level with the specified horizontal abutment surface,

b) said rod (or said case) is connected to said means of gripping said wedge, so that when said power cylinder is actuated to extract the wedge, said power cylinder exerts opposite forces on said conductors and said wedge, trying to push them apart.

Using the wedge extraction device according to the invention, it is possible to turn on the electrolyzer, isolating from each other, without damaging them, conductors connected to the cathode elements of two adjacent electrolyzers: the force balancing the force that tends to separate the wedge from the conductor is the result of the forces that act directly on the upper horizontal surface of each conductor, which avoids the raising of the conductors and their damage, in the case when the extracting force is insufficient to separate the wedge from the conductors. This device is capable of applying forces higher than possible according to the prior art, without damaging the conductors, all the more advisable that the wedge is firmly held between two conductors held by the clamps.

As indicated earlier, both conductors opposite each other are:

- the first conductor, which is a connecting conductor between the cathode output of the electrolyzer directly in front and the anode riser, which feeds the anode frame of the specified cell,

- the second conductor, which is an element of the cathode collector of the specified cell.

The extraction device according to the invention comprises at least one ram which is mounted so that it can, when actuated, exert opposing forces on the wedge and at least one conductor. Each of the two parts of the power cylinder, which are movable relative to each other (body and rod), can be connected either with a wedge or with conductors. The first part of the power cylinder (body or rod) is rigidly connected to at least one horizontal supporting surface, designed to be at the same level with the upper horizontal surface of the conductor. The second part of the ram (the rod or the housing) is connected to the wedge gripping means, at least temporarily, when the ram is actuated to remove the wedge. In other words, this second part of the master cylinder may be movable relative to said gripping means at some stages of using the extraction device, but it is necessary that it comes into contact with this gripping means and carries it into its motion when the master cylinder is actuated in order to render parting efforts.

The wedge gripping means preferably comprises an engaging part on which engagement means are fixed, acting together with additional engagement means made on the wedge, preferably on the upper part of the wedge, which is provided to remain above the gap between the conductors when the wedge is inserted into them, and which thus more easily accessible. For example, at least one substantially horizontal, drilled hole is provided in the upper part of the wedge to allow the passage of a blocking axis rigidly connected to the engagement part. The blocking axis or axes are driven by one or more auxiliary drives, which, in turn, are mounted on said engagement part and which drive said axes so that they can slide into said holes to capture the wedge.

In practice, the conductors are arranged opposite each other so that the wedge is placed vertically, and thus the extraction device can be installed at the level of the wedge to be removed using a moving and lifting device, such as a combination of an overhead crane, trolley and tackle. But the invention is still of interest if a pair of these horizontal and vertical directions is replaced by any pair of perpendicular directions, each wedge should have an upper side perpendicular to the direction of the gap that separates them, and the moving device designed to install the specified device at the same level with wedges, of course, adapted to such a coordinate system.

The extraction device according to the invention comprises at least one ram cylinder having the above characteristics. This power cylinder can be an electric power cylinder, usually powered by a circuit containing a switch, but preferably, it is a hydraulic power cylinder, since with the same dimensions the latter can exert more significant forces. Preferably, the hydraulic ram or rams are powered from the same hydraulic installation as is preferably installed on said extraction device or on a moving device of said extraction device.

In one preferred embodiment of the invention, said extraction device also comprises a drive for lifting the assembly comprising the wedge, the wedge gripping means and the power cylinder or force cylinders after the wedge has been removed, that is, after it is no longer held by the conductors. This drive plays the role of an ejector: the assembly containing the wedge and the wedge gripping means must be removed so that the wedge can completely completely exit the gap between the opposing conductors as fast as the speed of the rod of the hydraulic ram. Indeed, they strive for the highest possible pushing speed of the assembly containing the wedge and the gripping means, as this limits the risk of the appearance of an electric arc during the lifting of the wedge.

Preferably, said drive, also called an ejector, is a pneumatic ram. Preferably, the wedge gripping means is rigidly connected to the rod (or housing) of said ejector, and the stroke of said ejector is large enough to allow said wedge to completely exit the gap between the conductors.

In one preferred embodiment, the power cylinder or power cylinders and the ejector act simultaneously. In this case, there is no need to synchronize the actions of the power cylinder (s) and the ejector: the extracting force exerted on the wedge by the power cylinder or power cylinders, being significantly higher than the force exerted by the ejector, is applied only until the wedge will not separate from the conductors, from this moment only the lifting force of the ejector acts.

Preferably, said extraction device comprises a frame on which said ejector is fixed. The specified frame contains means of engagement so that it can be moved by a transport and lifting device. Typically, the device used for transporting and lifting said extracting device is a combination of an overhead crane, trolley, and tackle. To carry out the extraction of the wedge, the device, using the specified transportation and lifting device, is placed on the same level with the conductors and positioned so that at least one horizontal supporting surface rests on the upper horizontal surface of the conductor. During the extraction, the extracting device may or may not be supported by the conveying and lifting device.

Preferably, said frame is equipped with centering means that allow the said extracting device to be guided during its vertical reduction to a predetermined position with respect to said conductors, the bearing surfaces being at the same level with the upper horizontal sides of said conductors.

Preferably, said frame also comprises a cowl that limits the volume in which the assembly containing the wedge and the wedge gripping device must move after removing said wedge, and which protects operators working in the vicinity of the extractor device face-to-face with movable extractable parts.

Another object of the invention is a method for extracting shorting wedges used in the operation of turning on the electrolyzer, consisting in removing shorting wedges that were inserted between two conductors to turn off the indicated cell, the first conductor being connected to the cathode assembly of said electrolyzer, and the second conductor connected to the cathode assembly of the previous one an adjacent cell, each conductor having at least one upper horizontal surface and one substantially vertical a surface, wherein the substantially vertical surface of one conductor is opposite the substantially vertical surface of the other, so these two essentially vertical surfaces define a gap for receiving said short wedge, which in turn contains two substantially parallel surfaces, slightly converging downward when the specified wedge is inserted to occupy the specified gap, moreover, the specified method is different in that to extract the specified wedge I use device according to the invention.

Preferably, since the intervention should be as quick as possible in order to limit the heating of the wedges to be removed last, several devices according to the invention are used to simultaneously remove all or part of the wedges that were installed to turn off the cell.

FIG. 1 schematically shows a service machine in a typical electrolysis workshop for producing aluminum, a sectional view.

FIG. 2 schematically shows the location of the connecting conductors between two adjacent cells.

FIG. 3a and 3b schematically illustrate one particular embodiment of a wedge retrieval device according to the invention. FIG. 3a shows the indicated extraction device, when it is mounted on the conductors, at the level of the wedge to be removed. FIG. 3b shows the indicated extraction device when the wedge is removed, and which is still in place, resting on the conductors, at the level of the wedge that has just been removed.

Electrolysis plants designed to produce aluminum contain one or more electrolysis shops. The electrolysis shop (1) shown in FIG. 1, contains electrolyzers (2) and a service machine (5). The cells (2) are usually arranged in a line or in rows, with each line or row typically containing more than a hundred cells. The electrolyzers (2) are arranged so as to provide a passage for movement along the electrolysis shop (1). The electrolysers (2) contain a number of anodes (3) equipped with a metal rod (4) intended for fastening and electrical connection of the anodes with a metal anode frame (27). Each electrolyzer (2) contains a cell equipped with a cathode assembly (22) and an anode system (26). The cell has a steel casing with lining elements made of refractory materials. The cathode assembly (22), located at the bottom of the cell, is formed by a dense arrangement of carbon-containing blocks into which metal rods are embedded, the ends (21) of which exit from the housing and are connected to each other by means of a cathode collector (23). The connection diagram between two series electrolysers (2. (n-1) and 2.n) contains an electrolysis current transmission circuit, where the cathode collector (23. (n-1)) is connected on one side to the cathode outputs (21. (n- 1)) of the electrolyzer of this series (2. (n-1)), and on the other hand, with the anode risers (28.n), which, in turn, are connected to the anode frames (27.n) of the next electrolyzer (2. n).

From time to time, one or more row electrolysers must be stopped. This stop is accomplished by connecting the cathode collector (23.n) of this electrolyzer (2.n) to a connecting conductor that connects the cathode collector (23 (n-1)) of the adjacent preceding electrolyzer (2. (n-1)) to the anode risers (28.n) that feed the anode frame of the specified cell. The connection is carried out by means of a plurality of conductive wedges (20), usually made of aluminum, forcibly inserted into different places where two conductors have two essentially vertical surfaces that are opposite each other. To turn on the electrolyzer, you need to remove all the wedges in the shortest possible time. The device according to the invention allows to remove the wedges one after another. It can quickly shift at the same level with each wedge and can exert significant extracting force, allowing each wedge to be separated from the conductors.

EXAMPLE OF IMPLEMENTATION (FIG. 3A AND 3B)

The extraction device (30) shown in FIG. 3a and 3b, is designed to remove the shorting wedge (20), which was inserted between the two conductors (24 and 25) to turn off the cell. The first conductor (24) is a connecting conductor between the cathode output (23. (n-1)) of the adjacent preceding electrode and the anode riser (28.n), which feeds the anode frame (27) of the indicated next cell (2.n). The second conductor (25) is part of the cathode collector (23.n) of the indicated next cell (2.n). Each conductor (24, 25) has at least one upper horizontal surface (240, 250) and a substantially vertical surface (241, 251). Essentially vertical surfaces (241, 251) are opposed to each other, thus setting a gap that is designed to receive the specified shorting wedge, which, in turn, has two essentially parallel surfaces (204, 205), slightly converging downwards .

The extracting device (30) comprises gripping means (31) of said wedge and a ram (32) oriented vertically, comprising a housing (320) and a rod (321). The housing (320) is rigidly connected, through an intermediate hollow part (33), to a horizontal abutment surface (335), which is oriented downward and which is positioned so that when the said extracting device is placed above the indicated wedge to remove it, the upper horizontal surface (240, 250) of each conductor (24, 25) was flush with the horizontal supporting surface (335). The rod (321) is connected to the gripping means (31) of the wedge (20), so that when the power cylinder (32) is actuated in order to extract the wedge, this power cylinder exerts on the conductors (24, 25) and on the wedge (20) opposing efforts, trying to push them apart. The master cylinder (32) is a double-acting hydraulic master cylinder, fed from the hydraulic unit through a circuit arranged so that extraction is carried out when power is supplied to the chamber from the piston (322).

In this embodiment, the housing (320) of the master cylinder (32) has a lower horizontal side (325) that is in contact with the upper horizontal surface (331) of the intermediate part (33) when the extraction device is on the conductors in order to remove the wedge. When the power cylinder (32) is activated, the vertical force is exerted on the upper horizontal surface (331) of the intermediate part (33), which is transmitted to the conductors by means of the lower horizontal surface, which plays the role of a horizontal supporting surface (335), and it, in turn, is located in contact with the upper horizontal surfaces (240, 250) of the conductors (24, 25).

The rod (321) is hollow, through it passes a longitudinal hole (3211), through which the axis (40), rigidly connected to the gripping means (31) of the wedge, can slide. The specified axis (40), rigidly connected to the gripping means, is equipped with a protrusion (41), which serves as a limiter of the axial movement of the rod (321): when the power cylinder is activated, oil under pressure fills the chamber from the piston (322), which entrains the rod (321) up. The end (3210) of the rod (321) comes into contact with the protrusion (41) of the axis (40) so that the power cylinder (32) acts on the axis and exerts an upward force on said gripper (31).

To facilitate the extraction of the wedge (20), the wedge and said extraction device (30) are equipped with gripping means interacting with each other. The extraction device (30) comprises, as a means of gripping the wedge, an engagement part (313) having a generally inverted U shape, the two side sides U provided with openings being placed in order to remove the wedge from both sides of the upper end of the wedge, and two trunnions (311, 312), placed so that they are on the same line horizontally, on both sides of the wedge (20). The wedge (20) has in its upper part, which, as provided, will remain above the gap between the conductors, a horizontal (201) hole extending over the entire thickness of the wedge. Each pin (311, 312) can be driven by a power cylinder (315, 316), which allows, using a suitable connecting rod and crank mechanism, to enter the specified pin into the hole (201) of the wedge and the hole of the side of the engagement part corresponding to the specified pin in order to capture the wedge. The engagement part (313) is fixed to the lower end of the vertical axis (40).

The intermediate part (33) also plays the role of a fairing, which protects operators working in the vicinity of the extraction device opposite the movable extracted parts.

The extracting device (30) also includes a drive (50) designed to lift the assembly containing the wedge, the wedge gripping means and the power cylinder or power cylinders after the wedge has been removed, that is, after it is no longer held by the conductors. This drive is a pneumatic power cylinder (51). The wedge gripper (31) is fixed to the lower end of the axis (40), which, in turn, is a continuation of the rod (52) of the actuator (50). When removing the power cylinder (32) and the drive (50) act simultaneously: the extracting force exerted on the wedge provided by the power cylinder (32) is significantly higher than the force exerted by the drive (50) is applied only before the wedge is disconnected from conductors, and from this moment only the lifting force of the drive (50) is valid.

The extracting device (30) also contains a frame (60) on which the specified drive (50) is fixed. The frame is presented here schematically, forming a block with an intermediate part (33), which represents its lower part. The specified frame contains means of engagement (not shown) so that it can be moved by a transport and lifting device.

Claims (15)

1. A device for extracting a shorting wedge before switching on a temporarily disconnected electrolyzer in a series of electrolysis cells for producing aluminum, while a shorting wedge is installed between the down conductors of the cathode nodes of the temporarily disconnected electrolyzer and the preceding electrolyzer, each down conductor has at least one upper horizontal surface and one vertical surface, and the vertical surface of one down conductor is opposite the vertical surface of the other with images a gap intended for receiving said shorting wedge containing two surfaces that converge downward when it is inserted into said gap containing means for gripping said wedge and a drive, characterized in that the drive is made in the form of at least one vertically oriented power cylinder containing housing and piston with a rod, moreover
a) said housing or said rod is rigidly connected to at least one horizontal supporting surface (325) facing downward so as to be placed flush with the upper horizontal surface of each collector when installing said device for extracting a shorting wedge above said wedge to remove it,
b) said rod or said housing is connected to said gripping means of said wedge to exert opposed forces on said down conductors and said wedge so that they move apart when said power cylinder is actuated to extract said wedge. 2. The device according to claim 1, characterized in that said gripping means comprises an engagement part on which engagement means are fixed, acting together with the engagement means formed in the upper part of the wedge remaining above the gap between the down conductors when the wedge is inserted there. 3. The device according to p. 1, characterized in that the said power cylinder is a hydraulic power cylinder. 4. The device according to any one of paragraphs. 1-3, characterized in that it comprises a drive for lifting the node containing the wedge, means for gripping said wedge, and said power cylinder for withdrawing said node from said gap existing between said down conductors after the wedge is no longer held by them. 5. The device according to p. 4, characterized in that the said drive is a pneumatic power cylinder. 6. The device according to p. 4, characterized in that the said power cylinder and said drive are made with the possibility of simultaneous action during the extraction of the said wedge. 7. The device according to p. 4, characterized in that it contains a frame to which the aforementioned drive is attached, said frame containing means of engagement to enable its movement by a lifting and transport device. 8. The device according to p. 7, characterized in that the said frame is equipped with centering means for guiding the said device for retrieval during its lowering vertically to a predetermined position relative to the down conductors, the supporting surfaces being at the same level with the upper horizontal surfaces of the down conductors. 9. The device according to p. 7, characterized in that the said frame contains a fairing, limiting the volume for moving in it a node containing a wedge and means for capturing the wedge, after removing the wedge to protect operators. 10. The device according to any one of paragraphs. 1-3, characterized in that it contains a hollow intermediate part having a horizontal supporting surface facing downward, while the housing of the power cylinder is rigidly connected through said intermediate hollow part with said horizontal supporting surface, ensuring that the upper horizontal surface of each collector is placed at the same level with said horizontal abutment surface while positioning said device for extracting said wedge. 11. The device according to p. 10, characterized in that the housing of the power cylinder has a lower horizontal surface in contact with the upper horizontal surface of the said intermediate part when installing the device for extraction on the said down conductors to remove the said wedge. 12. The device according to p. 10, characterized in that the rod of the power cylinder is made hollow with an axial hole drilled through through to slide through it rigidly connected to the mentioned means of capturing the wedge axis. 13. The device according to p. 12, characterized in that said axis rigidly connected to the gripping means is made with a protrusion, which is a limiter of the axial movement of the rod to move the rod upward, while when the actuator is actuated, the end of the rod comes into contact with the axis protrusion for ensure that the power cylinder exerts an upward force on said gripping device. 14. The device according to p. 12, characterized in that it comprises a drive for lifting the node containing the wedge, means for gripping the said wedge and a power cylinder for withdrawing the said node out of the gap between the down conductors after the wedge is no longer held by them, while said wedge gripping means is fixed on the lower end of the axis, which is a continuation of the actuator stem. 15. A method of extracting a shorting wedge before switching on a temporarily disconnected electrolyzer in a series of electrolytic cells to produce aluminum, comprising removing a shorting wedge inserted between two down conductors to turn off the electrolyzer using an extraction device according to any one of claims. 1-14, the first collector connected to the cathode assembly of said electrolyzer, and the second collector connected to the cathode assembly of a previous neighboring cell.

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