RU2439208C2 - Connector for mechanical and electrical connection of anode with anode frame of electrolytic bath for purpose of aluminium production and device to grip, clamp and release such connector - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: connector consists of two brackets or grips acting as levers, which are fixed at common axis by joints; respective continuations of the axis are taken by anode frame hooks operating together with connector and are actuated by the opposed tightening screw with two areas and pitch in opposite directions, which operate together at beam level connecting free ends of brackets. Hold-down surface of connector, that is the area purposed for operation with anode rod, is formed by hold-down device separated from brackets or beans connecting them; at that this hold-down device is fixed at the connector isostatically. Device for gripping/releasing of the connector with anode frame is also described.

EFFECT: it provides isostatic fixing of the device and reduction of anode falls at replacement and limitation of voltage drop at contacts when big current value is fed through anode.

11 cl, 16 dwg

Description

FIELD OF THE INVENTION

The device is used in the field of aluminum production using a technology known as fire electrolysis.

According to this technology, aluminum is produced in bathtubs or standard electrolyzers for aluminum production, each of which has a bath for melting, in particular, cryolite and aluminum, through which a large electric current is passed. For this, the baths have anodes that have undergone preliminary heat treatment, which are consumed during the electrolysis reaction, so that they need periodic replacement, usually the replacement frequency is from 22 to 28 days.

Thus, the problem arises of replacing the anodes in these electrolytic cells for aluminum production. They are connected through a connector mechanically and electrically to a conductive anode frame connected to each of the aforementioned electrolyzers.

This anode frame is lowered vertically to compensate for the wear of the anodes, and it is necessary to maintain a constant distance between the poles of the anode and the electrolyzer that acts as a cathode. Thus, the anodes are fixed on the anode frame by means of connectors that provide both mechanical connection of the above-mentioned anodes with the anode frame and, on the other hand, electrical conductivity, which allows for an electrolysis reaction. More precisely, this mechanical connection is carried out at the level of the anode rod formed by an aluminum rod of square cross section, designed in such a way as to withstand the weight of the anode.

This fastening should be especially effective in order to avoid falling anodes into the bath, on the other hand, to optimize the electrical connection in order to limit the voltage drop across the contacts, due to the high current flow through each of the anodes.

State of the art

Among the various types of connectors known today, there are movable connectors that do not remain on the anode frame when the anode is consumed and can be used when replacing and installing a new anode.

Such a connector is described in document FR 2039543. It consists of two articulated levers on a common axis, on the continuation of which hooks are fixed on one side and the other, which, in turn, are attached to the anode frame. The free ends of these levers can come closer or be removed under the influence of a two-way opposite clamping screw.

The rod of the anode is inserted between the anode frame and the ends of the levers located at the level of the common axis. Effective fastening results from the aforementioned movement of the ends of the levers with respect to the hooks. Thus, the pressure area of the levers located near the common axis is such that when the opposite ends of the aforementioned levers approach each other, by means of a clamping screw, a clamping force is created corresponding to the application under consideration, or, on the contrary, when breeding, the aforementioned ends deflect the clamping surface leverage with respect to the neutral position determined by the hooks, thereby freeing the aforementioned anode shaft.

According to this documentation, this connector is driven by a moving device designed to perform various operations to change the anode, but does not allow the anode frame to be lifted, keeping the height of the anode under consideration constant. This moving device is equipped with a grip for the connector associated with the clamping and expanding device of the connector. Such a tool works simultaneously with the tool of the anode rod itself, performing, among other things, the function of lifting and removing the anode from the electrolysis bath, it is also called the "puller".

However, one of the technical problems that occurs during this operation, in particular the replacement of the anode, is a risk that cannot be neglected, namely, the risk of the connector falling after being expanded. Indeed, the grips of the connectors known today are equipped with an additional protrusion element on the aforementioned connector.

So, it was demonstrated and even experimentally shown that, first of all, due to the weight of the connector and, on the other hand, taking into account the means used to capture, the connector fell several times with significant consequences for the puller, namely:

- if the connector falls into the electrolysis bath, it damages the electrolysis bath and, in addition, creates problems in its recovery,

- if the connector falls outside the electrolysis bath, then due to the relatively large weight of the connector, personnel may be injured.

Such connectors are described, for example, in document FR A 2854906. In it, the upper arm of this connector has a gripping flange for working together with a puller, which is fixed to the moving device.

Whatever the types of connectors previously used in the technique, all of them are statically indeterminable between the geometric axis defined by the position of the hooks, which take the common axis of the articulation of the levers forming the connector, and the plane defined by the parallelism of the anode clamping surfaces.

Thus, since the connector — the anode — is a cylindrical-type connection in plan and, moreover, the compression force is uneven, due to the statically indeterminate nature of the device, the anode rods are deformed by sponges or levers, reducing the compression effect and thereby causing a drop voltage between the rod of the anode and the anode frame.

Disclosure of invention

An object of the present invention is to remedy these various disadvantages. First, the goal was to create a device devoid of the statically indeterminate nature described above, and, in addition, equipped with such means that the risk of falls no longer exists.

Thus, this connector for mechanical and electrical connection of the anode with the anode frame of the electrolytic cell for the production of aluminum by the method of fire electrolysis, with a frame equipped with mounting hooks designed to work with the connector, consists of two brackets or jaws that act as levers pivotally articulated on a common axis, the corresponding extensions of which fall into these hooks and are driven in opposite directions by means of a two-way opposite clamping screw, which unites the free ends of brackets on a traverse axis.

In accordance with the invention, the pressure surface of the connector, that is, the area intended to work together with the anode rod and the anode frame, is an additional clamping device, spatially separated from the brackets and traverses, which connects them to each other and is fixed statically definable on the connector or elements forming it.

In other words, the novelty of the device consists, first of all, in that an additional device is installed on the traditional connector, which is statically determined with respect to the connector. The statically determinate nature of this additional clamping device allows, on the one hand, to eliminate the classical types of deformation of the anode rods, and, on the other hand, to increase the surface of the clamp and, therefore, the effectiveness of the clamping of the anode rod to the anode frame, which increases the optimization of the electrical contact of these two elements.

The statically determinate nature of this connector makes it insensitive to the position of the hooks and anode rod.

In accordance with the present invention, the clamping device has two flat surfaces located vertically from the middle zone of the connector, and these surfaces are fixed with spherical trunnions at the level of the traverses connecting the connecting brackets of the connector. In addition, these surfaces are rigidly connected to each other using a section in the form of a loop surrounding the hinge axis of the bracket. Due to the relative mobility of this clamping device with respect to the connector itself, the mobility caused by the movement of the clamping surfaces together of the ball pins, the connector has excellent static definability.

In accordance with the characteristic of the invention, the clamping device has the form in the form of Ω (omega), the omega loop is wrapped around the common hinge axis of the two jaw levers forming the connection.

In accordance with another characteristic of the invention, in the rear part of the pressing device there is a blade located also vertically, fixed relatively movably in tool holders equipped for this purpose with the rear part of the front traverses connecting the brackets.

The advantage is that the assembly, consisting of the clamping surfaces, the blade and the portion in the form of a loop called omega, is one block and is made of pressed steel.

Secondly, the invention relates to a device for gripping, clamping and expanding such an anode connection.

The device includes, first of all:

• connector capture device equipped with:

- two forks, parallel to one another, mounted oscillatory with respect to the hinge axis, mounted on the hinge axis of the connector and connected to the fixing hooks of the anode frame;

- and a device for supporting the contact joint and holding it with forks while in the expanding position;

• a clamping / expanding device for the contact joint, which in the working position secures the connector using clamping means, and is designed as a double-acting opposing screw head for securing the forks when the forks are at the level of the common axis of the connector.

In accordance with the invention, the device for supporting the contact joint is a grip mounted oscillatingly on the same hinge axis as the forks, and works together with the clamping device of this connector, in particular with the lower end of the vertical blades of the clamping device.

When such an interaction takes place, there is no longer any risk that the connector will jump out of the gripping device, since the interaction between the support device and the connector itself is carried out in the vertical direction, since from now on the clamp holds the connector under the influence of gravity, on the other hand, it is held by forks with the help of the same clamp and sent to them.

Obviously, the corresponding dimensions of the forks and clamps are selected so as to correspond to the height difference between the common hinge axis of the forming levers of the connector and the position of the lower end of the lower blade of the pressing device with which it is equipped.

It is interesting that the device for capturing and clamping the contact connector is equipped with a guide for the anode rod, which facilitates its lowering upon contact with the connector, moreover, this guide consists of a cylinder with side plates, the diameter of which is larger than the diameter of the cylinder, and the distance between which practically corresponds to the size of the square side of the anode the rod.

According to another characteristic of the invention, the forks are hinged to the clamping safety device, but their deflection angle is limited.

Finally, the device is equipped with elastic stops designed to work together with the rear upper traverse of the connection, and they are designed and installed in such a way as to ensure freedom of the clamping device outside the clamp when the connector is in the closed position, optimizing the safety of the system in excess.

Brief Description of the Drawings

The method of implementation of the invention and the advantages arising from this are better seen in the above example, given solely for the purpose of illustration and not of an exhaustive nature, using the accompanying drawings.

Figure 1 is a schematic illustration of an electrolyzer for the production of aluminum using fire electrolysis technology, which shows various types of anodes mounted on an anode frame.

Figures 2 and 3 are a schematic view in projection of the anode connector of the invention in the clamping and expanding positions.

Figures 4 and 5 are a vertical section of the anode connector in the clamping and expanding positions.

6, 7 and 8 are a schematic view of the device for moving and clamping the anode connector in different directions.

Figures 9 and 10 are a schematic representation of two positions of the present device: a grip position and a release position of a connector.

Finally, FIG. 11A through 11F schematically show the different steps of expanding the connector and gripping it with the present device.

The implementation of the invention

Figure 1 shows the electrolysis bath (1) for the production of aluminum by a technology called fire electrolysis. Several pre-dried anodes (2), usually carbon ones, are successively immersed in a bath or electrolyzer, which are individually attached to the anode frame (3) using a vertical conductive rod (4).

As already indicated, the anode frame (3) is made of metal and is a conductor of electricity, it is movable with respect to the fixed support (5) located above the electrolysis bath (1). Thus, the anode frame (3) can move vertically with respect to the fixed support (5).

Figure 1 also shows the rods (4) of the anodes (2), allowing them to be fixed on the anode frame (3) using a connector (10), described in more detail below, each of which has a hinge axis falling into the hooks (6), fixed on the anode frame (3).

Figure 2 and 3 shows the anode connector (10), proposed in the invention, respectively, in the expanding and clamping positions.

As you know, the connector (10) consists of two levers or jaws, respectively (11) and (12), each of which is formed by two side plates, respectively (13, 13 ') and (14, 14'), these plates are identical between by myself.

The side plates (13, 13 '), and accordingly (14, 14') of each of these two levers are interconnected by two traverses, respectively, the front traverse (15, 16) and the rear (17, 18).

Both of these levers (11) and (12) are pivotally interconnected with respect to the axis (19), which is usually a cylindrical metal rod protruding from one and the other side of the above levers. These protrusions are intended for hooks (6) mounted on the anode frame (3), which also allow, on the one hand, to accept the connectors, and, on the other hand, to provide the function of clamping the rods (4) of the anodes on the anode frame.

In the rear part of the device on the rear traverses (17) and (18), holes (20) and (21) are provided for the clamping screw (22), which consists of two linear parts (23) and (24), the characteristic of which is that they have the opposite pitch of the screw.

Accordingly, the holes (20) and (21) have an additional thread corresponding to the reverse stroke of the screw.

This screw (22) has a square head and is designed to work together with a clamping device, which will be described in detail below.

In addition, it is necessary to clarify that the traverses (17, 18) are not stationary, but are mounted rotating on the side plates (13, 13 '), and accordingly (14, 14'), to ensure that the clamp screw (22) is held in a linear position. during clamping and expanding operations of the connector.

In accordance with the invention, the connector (10) has a clamping device (26), spaced (spatially separated) from the clamp by the front end of the levers or the free end of the front traverses (15, 16). Indeed, this pressing device (26) is formed by two flat surfaces, respectively, of the upper (27) and lower (28), interconnected by a connecting zone (29) around the axis (19), as, for example, shown in Fig. 4 and 5.

In other words, the clamping device is made in the form of Ω (omega).

Each of the surfaces, the upper (27) and lower (28), is located on the ball joint (30) located on the free end (31) of the traverse, respectively, of the front (15) and rear (16). This support (30) is connected to a cylindrical profile (32) on the inner part (33) of said surfaces (27) and (28).

Due to the fact that the front traverses (15) and (16) are relatively thin, the spherical bearing (30) is a hollow spherical part providing the above-mentioned surfaces (27) and (28) with easy movement in the horizontal and vertical directions, regardless of the connecting zone (29).

In addition, in the back of the connecting zone (29), the clamping device (26) has a vertical blade (34), which is mounted in the grooves (35, 36) of the rear edge, respectively (37, 38) of the front traverses (15) and (16) )

The role of this vertical scapula (34) will later become clearer.

However, it must be emphasized that the blade is a special non-linear profile (see Figs. 4 and 5) that allows it to rest on the trailing edge (35, 36) of the traverse (15) and (16) and maintain this support during clamping operations and expandable connector.

It is clear that with this method of fastening the clamping device (26), it is not fixed stationary on the connector (10), but has some freedom of movement, limited, of course, by the special configuration described above.

This particular configuration, giving the connector of the present invention a statically determinate character, allows, on the one hand, to increase the efficiency of pressing the anode rod (4) against the anode frame (3) and, therefore, the electrical contact of this frame with the anode rod.

Moreover, if in this example the working area of flat surfaces (27) and (28) represents only a third of the width of the connector, then in practice it is possible to use other types of clamping devices of various sizes, depending on practical needs.

In FIG. 6 to 8 show a connector moving and clamping device in accordance with the invention.

Basically, it is mounted on a special device connected to a bridge, which is thus able to move above electrolysis cells for aluminum production.

It functions during anode replacement operations along with an anode rod grip device, commonly referred to as an “extraction device”, and is secured to the holder.

In accordance with the invention, this device (40), primarily consists of a capture member of the connector (10). This capture member primarily consists of a side fork (41, 42) fixed to the axis (43), but its deflection is limited by a protrusion (44) in a hole with a limited length (45) connected to the structure of the aforementioned capture member. At the opposite end of the axis (43), the aforementioned forks (41, 42) have a groove (46) for the pivot axis (19) of the connector (10).

The gripping body also has a guiding device (47), designed to facilitate its movement forward at the stage of approaching the connector in position on the hooks (6) of the anode frame (3). This guide device (47) is a cylinder pivotally mounted on an axis (43), with side guides (48), the distance between which is slightly larger than the standard width of the anode rod (4).

In addition, in accordance with one of the characteristics of the invention, the gripper is equipped with a clamp (49), working in the same direction as the forks (41, 42), but at a distance from them. This clamp (49) is provided with a protrusion (50), intended, as will be described below, to work together with the clamping device (26) of the connector (10), in particular, with a vertical blade (34).

Finally, the gripper has elastic stops (51) and (52) with coil springs resting on the rear yokes (17) and (18) of the connector (10) in order to ensure the release of the catch limiter (50) (49) and the pressing device of the aforementioned connector, when the latter is in the clamping position, it will be described later.

The device according to the invention is also equipped with a clamping device (53) usually driven by a hydraulic actuator, but it is also sometimes possible to use a pneumatic and electric actuator. The clamping device (53) works together with the head (25) of the clamping screw (22) of the connector (10).

The corresponding dimensions of the clamp (49), forks (41, 42) and the location of the clamp device (53) are determined depending on the size of the connector and its possible deviation.

Figures 9 and 10 show the positions of the gripping and clamping device in accordance with the present invention, together with the proposed connector, respectively, in the lifting and clamping position.

When the device in question is omitted to lift the connector, it rests on the anode rod (4) and is guided by a guiding device (47, 48).

When the grooves (46) of the forks (41, 42) are lowered in the direction of the axis (19) of the connector (10), the clamp (49) is adjusted so that it rests on the rear vertical blade (34) of the clamping device (26) of the connector until it passes below the lower end (55) of the aforementioned blade in order to capture this lower edge with a stop (50). The clamping device (51) is activated, causing a weakened mode of the connector, which cannot be weakened due to the joint operation of the limiter (50) with the lower end of the blade (34), on the one hand, and the lower edge of the grooves (46) of the forks ( 41, 42) on the hinge axis (19).

The connector is thus ideally supported by this double grip, virtually eliminating the risk of it falling.

When it becomes necessary to rearrange the connector (10) on the hooks (6) of the anode frame (3), i.e. rearrange the axis (19) of the connector on the hooks (6), it is necessary to fight against the tendency of the clamp (49) to orient in such a way as to systematically support the lower end (55) of the blade (34), ensuring the safety of the device.

To this end, the safety spring stops (51) and (52) are supported on one and the other side of the clamping head (25) of the clamping screw (22) on the rear crosshead (17). Thus, until a sufficient number of revolutions has been achieved for clamping, three in this case, the spring safety devices (51) and (52) do not rely on the aforementioned rear crosshead and do not carry out a resistance reaction to reverse the clamp (49) on the hinge axis (43) . Therefore, there is no separation of the lower end (55) and the vertical blade (34) of the clamping device (26) of the connector in question, as well as its release.

On the contrary, as soon as the clamp of the connector becomes sufficient, and assuming that the rear yoke (17) has risen sufficiently, it puts pressure on the aforementioned stops and, thereby, tilting the clamp (49).

Due to the special design of the gripping and clamping device, the connector, by accident or by mistake, cannot be loosened until it is clamped at the level of the hooks (6) to the anode rod (4), which ensures greater safety during replacement operations anode.

FIG. 11A through 11F show the various steps of the anode replacement operation.

FIG. 11A: The extraction device (56) that the aluminum production plant is equipped with is fixed on the upper free end of the anode rod (4) and holds and supports the aforementioned anode with clips or special support devices before releasing the connector. In this case, the connector is in the closed operating position.

FIG. 11B: The device for gripping and clamping the connector is lowered along the anode rod, guided, as previously indicated, by a cylindrical guide (47, 48). Consequently, the clip (49, 50) slides along the support to the rear blade (34) of the pressing device (26) with which the aforementioned connector is equipped.

FIG. 11C: The lowering of the device stops when the lateral forks (41, 42) are fixed on the axis (19) of the connector with hooks (6). Therefore, the clamping device (53) is in the operating position at the level of the head (25) of the clamping screw (22). At the first revolutions, the clamp (49) tilts under the lower end (55) of the blade (34) and provides a joint operation with the locking protrusion (50) (Fig. 11D) while lifting the device.

11E: Simultaneously with the expansion of the connector, the axis (19) connected to the hooks (6) is released, and since, ultimately, the device presses in the direction of the anode rod, it becomes possible to release the axis (19) from the grooves of the hooks (6 ) and raising the connector to the parking position. The clamp (49, 50) becomes engaged in the vertical blade (34) of the pressing device (26) of the aforementioned connector.

Thus, the advantages of the connector and the moving and clamping device of the present invention are demonstrated.

First of all, you should again insist on optimizing the clamping force of such a connector on the anode rod to the anode frame.

Indeed, in view of the statically determinate type of pressure device (26), on the one hand, the anode rods themselves are not damaged, on the other hand, a stronger mechanical pressure is achieved. And, in addition, conductivity is improved.

Studies have shown savings for classic anode rods of 10-20% due to a decrease in the number of voltage drops compared to similar pairs of pressure devices, but on a connector of a statically indeterminate type.

In addition, it is necessary to emphasize the high level of security of this device.

Claims (11)

1. A connector for mechanical and electrical connection of the anode (2, 4) with the anode frame (3) of the electrolyzer (1) for the production of aluminum by the method of fire electrolysis, and the anode frame is equipped with hooks for fastening (6) designed to work with the connector (10) consisting of two brackets or jaws (11, 12), acting as levers pivotally mounted on a common axis (19), the corresponding ends of which reach the aforementioned hooks (6), and their free edges are actuated in a counteracting manner using an opposite clampingInta (22) with two zones (23, 24) interacting at the level of the traverse (17, 18), touching the above-mentioned free ends of the brackets (11, 12), characterized in that the clamping surface of the connector (10), which is the zone of contact with the rod the anode (4), providing the possibility of connecting this rod with the anode frame, is formed by a clamping device (26) separate from the brackets (11, 12) or traverse (15, 16), combining them with each other, while the aforementioned clamping device (26) isostatically fixed on the connector (10). 2. The connector according to claim 1, characterized in that the clamping device (26) has two flat surfaces (27, 28) located vertically from the middle zone of the connector, and these flat surfaces are located on ball trunnions (30) mounted at the front traverse (15, 16) connecting the brackets (11, 12), which are components of the connector. 3. The connector according to claim 2, characterized in that the flat surfaces (27, 28) forming the clamping device (26) are connected to each other by means of a connecting zone (29) surrounding the hinge axis (19) of the brackets (11, 12 ) 4. The connector according to claim 3, characterized in that the clamping device (26) is made in the form of Ω (omega), the omega loop covers the hinge axis (19) of both brackets (11, 12) of the connector (10). 5. The connector according to one of claims 2 to 4, characterized in that in the rear zone of the pressing device (26) there is a blade (34) located vertically. 6. The connector according to claim 5, characterized in that the vertical blade (34) is movably mounted in the grooves (35, 36) located for this in the rear of the front traverses (15, 16), reaching the brackets (11, 12). 7. The connector according to claim 6, characterized in that the assembly formed by flat surfaces (27, 28), a vertical blade (34) and a connecting zone (29) defining an omega is one block. 8. A device for capturing and clamping / releasing an anode connector (10) for mechanically and electrically connecting a conductive rod (4) of an anode (2) with an anode frame (3) of an electrolyzer (1) for producing aluminum by a fire electrolysis method, comprising a device for capturing the aforementioned connector, equipped with a double forks (41, 42), in which the forks are parallel to each other, mounted with the possibility of swinging relative to the hinge axis (43), resting on the hinge axis (19) of the connector and received by the fixing hooks (6) on the one frame (3), a device for supporting the aforementioned connector and holding it in the aforementioned forks when it is in the unlocked position, a clamping and releasing device (53) of the connector, designed to be placed in the working situation at the level of the clamping device (22, 25) of the connector , in particular the head or threaded sleeve of a two-way opposing screw, for fixing the forks on the common axis of the connector, while the connector support device is a clamp (49) mounted to swing on the same the hinge axis (43) on which are fixed forks (41, 42) and works together with the clamping device (26) of the connector, particularly with the lower end (55) of the vertical blades (34) above the compression unit (26). 9. The device according to claim 8, characterized in that the clamp (49) has a locking protrusion (50), designed to perform the lifting operation of the lower end (55) of the vertical blade (34) of the clamping device (26). 10. The device according to claims 8 and 9, characterized in that it is equipped with a guide device (47, 48) of the anode rod (4), which ensures its descent to contact with the connector. 11. The device according to claim 8, characterized in that it is equipped with elastic stops (51, 52) designed to work together with the rear traverse (17) of the connector, which are designed and positioned so as to release the clamp (49, 50) of the pressure devices when the connector is in the clamped position.

Images