This application claims priority to PCT/FR04/00430 filed Feb. 26, 2004, which in turn claims priority from FR 03/2500 filed Feb. 28, 2003.
The invention relates to factories for producing aluminium by igneous electrolysis using the Hall-Héroult process. It relates more particularly to the handling equipment used in the said factories.
The metal aluminium is produced industrially by igneous electrolysis, which is to say electrolysis of alumina in solution in a molten cryolite bath, called an electrolyte bath, according to the well known Hall-Héroult process. The electrolyte bath is contained in pots, called “electrolysis pots”, comprising a steel shell, which is lined with refractory and/or insulating materials inside, and a cathode assembly positioned at the bottom of the pot. Anodes, typically made of a carbonaceous material, are partially immersed in the electrolyte bath. The assembly formed by an electrolysis pot, its anodes and the electrolyte bath is called an electrolytic cell.
The factories contain a large number of electrolytic cells positioned in line, in buildings called halls or electrolysis rooms, and electrically connected in series using joining conductors, in order to optimise the use of the floor space of the factories. The cells are generally positioned so as to form two or more parallel lines that are electrically connected to one another by end conductors. The electrolysis current therefore passes in cascade from one cell to the next.
In operation, an electrolysis factory requires work to be carried out on the electrolytic cells, including in particular the replacement of worn anodes by new anodes, tapping of liquid metal of the cells and extracting or adding electrolyte. The most modern factories are equipped with a lifting and handling unit comprising a travelling crane, which can be moved in a translation movement above the electrolytic cells and along them, and a carriage equipped with several handling and working elements (often called “tools”), such as shovels and hoists.
The handling element designed to handle and move loads such as anodes comprises a clamp capable of gripping the load, called “handling clamp”. For example, when handling the anodes, this clamp is positioned close to the stem of the anode that is to be clamped, then closed around the stem such that it allows the anode to be lifted. The anode is then moved and then positioned or placed at the desired location.
However, it is possible that the load may accidentally be dropped, usually because it has been accidentally released during handling, for example due to untimely opening of the clamp (typically arising from an incorrect open command).
The applicant has therefore sought to make handling clamps which permit these drawbacks to be overcome, whilst remaining reliable, simple and compact.
An object of the invention is a handling clamp designed for the industrial production of aluminium by igneous electrolysis, capable of gripping a load by a gripping element (called “stem” hereafter) attached to the said load, and comprising locking means capable of preventing the clamp from opening when the load is suspended from it.
More specifically, the handling clamp of the invention, which is designed to grab a load equipped with a stem, comprises:
The applicant had the idea of fitting the clamp with a locking system that is locked or unlocked by the sole movement of the stem in the clamp. When it is locked, the locking system locks the gripping element(s) in the closed position, thus preventing the clamp from opening and the stem from being freed. The locking is therefore controlled by the presence and the position of the stem in the clamp, which avoids the untimely release of the load in the event of the actuating means of the mobile gripping element(s) of the clamp failing.
Another object of the invention is the use of the clamp of the invention in a factory for producing aluminium by igneous electrolysis, in particular for handling the anodes made of carbonaceous or other materials.
Another object of the invention is a lifting and handling unit comprising at least one load (typically anodes) handling element, equipped with a handling clamp according to the invention.
The invention will be easier to understand with the help of the detailed description of its preferred embodiments, which are described below and which are illustrated with the aid of the appended figures.
The electrolysis factories designed for the production of aluminium include a zone for producing liquid aluminium, which comprises one or more electrolysis rooms (1). As illustrated in
The lifting and handling unit (6, 7, 8, 9, 10) is used to perform operations on the cells such as changing an anode or filling the feed hoppers of the electrolytic cells with crushed bath and AIF3. It can also be used to handle various loads, such as pot elements, ladles of liquid metal or anodes. The said unit (6, 7, 8, 9, 10) typically comprises a travelling crane (6), a carriage (7) capable of moving on the travelling crane (6), and handling and work elements (often called “tools)) (8, 9, 10), such as a cabin (8) for the operator, a crust shovel (not illustrated), a crust breaker (not illustrated) or a handling element (9) equipped with a gripping or handling clamp (10). The latter element is particularly designed for handling anodes (3), even though it may also be used for handling other loads.
The travelling crane (6) is seated and moves on running tracks (11, 12) positioned parallel to one another and to the main axis—and typically longitudinally—from the hall (and the line of cells). The travelling crane (6) can therefore be moved along the electrolysis room (1).
In the invention, the handling clamp (10), which is designed to grasp a stem (4) attached to a load (3)—typically an anode—and equipped with at least one attachment means (5, 5a, 5b), typically a cavity, comprises:
In the open position, the gripping element(s) create enough space to allow the stem to be inserted in the clamp.
The/each gripping element (100a, 100b) is advantageously capable of pivoting around an axis (105).
The clamp (10) typically comprises two gripping elements (100a, 100b), which are advantageously capable of pivoting around an axis (105) specific to each gripping element or common to both gripping elements. The clamp (10) is then typically symmetrical with respect to an axis C, called the “central axis”, which may also coincide with the axis of the stem (4). The axis/axes (105) are preferably substantially perpendicular to the axis C, so that they are substantially in a horizontal position during use.
The attachment means (101a, 101b) of the clamp (10) typically comprise a protrusion on the/each gripping element (100a, 100b) and the corresponding attachment element(s) (5, 5a, 5b) of the stem (4) comprising at least one cavity. The protrusion(s) (101a, 101b) of the/each gripping element (100a, 100b) are capable of cooperating with the corresponding cavity(ies) (5, 5a, 5b) of the stem (4) so as to limit the axial movements of the stem (4) between the said lower and upper positions when the/each gripping element (100a, 100b) is in the closed position. The dimensions of the attachment means (101a, 101b, 5, 5a, 5b) are such that, when they are engaged, the stem (4) can still be moved between the upper position, in which the locking system (120) is unlocked (as illustrated in FIG. 5(E)), and the lower position, in which the locking system (120) is locked (as illustrated in
The attachment means (101a, 101b) of the clamp (10) and the one or more corresponding attachment means (5, 5a, 5b) of the stem (4) are advantageously such that they substantially limit—and possibly prevent—the rotation of the stem (4) around its axis A, which ensures precise positioning of the load fixed to the stem, in general an anode.
Typically, the clamp comprises among others a clamp body (109) and a means of attachment (108). The latter especially permits the clamp (10) to be fixed to a handling element (9).
In one preferred embodiment of the invention, the locking system (120) comprises at least one locking element (102a, 102b), such as a tooth or a hook, fixed to each gripping element (100a, 100b), and at least one moving lock (121) with at least one first position called “locking” and a second position called “release” or “unlocking”, the said lock (121) being:
In this embodiment, the locking system (120) of the clamp (10) is locked (or “engaged”) when, at the same time, the gripping element(s) (100a, 100b) are in the closed position and the stem (4) is in the lower position, which typically occurs when the load is suspended from the clamp (10), and it is unlocked when the stem (4) is in the upper position, which typically occurs when the clamp (10) exerts pressure on the stem (4). The clamp (10) of the invention thus permits locking or unlocking of the said locking system (120) by a simple relative movement of the stem (4) with respect to the clamp (and typically in the clamp).
In use, the locking position of the lock (121) is typically a lower position and the release position is typically an upper position, which permits the locking system (120) to be locked by the effect of gravity. In this case, the lock (121) is advantageously capable of being moved along a central symmetrical axis C of the clamp (10).
In order to make locking possible, the lock (121) is typically equipped with at least one cavity (126a, 126b), such as a notch or a mortise, capable of cooperating with the/each locking element (102a, 102b) so as to prevent the movement of the/each gripping element (100a, 100b) from the closed position to the open position.
Preferably, the lock (121) has a wait position—which is typically the said locking position but which may be different—and is situated in the clamp such that the stem (4) can move it from the wait position to the release position when it is inserted into the clamp. To this end, the lock (121) may feature a thrust element (124), such as a nipple, and is capable of being moved from the wait position to the said release position by a thrust of the stem (4)- and more precisely the end (4′) of the stem (4) on the said thrust element (124). The said thrust element (124) is typically situated close to the end (127) of the lock (121) located on the opening side of the clamp.
The clamp (10) may also include at least one guide part (122, 123) capable of guiding the movement of the lock (121) when it moves between its different positions. In the embodiment illustrated in
In one preferred embodiment of the invention, the locking system (120) further comprises at least one return means, such as an elastic element for example, (125) capable of causing the lock (121) to move from the release position to the locking position, and capable of maintaining it in this latter position, when each or the gripping element (100a, 100b) is in the closed position and the stem (4) is in the lower position. The return means (125), which is typically a spring, is advantageously incorporated into the lock (121) in order to isolate it form the surrounding environment and, possibly, to lubricate it, in order to maintain its elasticity and avoid it being damaged. To this end, the return means (125) is advantageously situated in a cavity inside the lock (121) and/or in a cavity inside one of the guide parts (122) of the lock. In the example shown in
In one advantageous variant of the invention, the locking system (120) further comprises at least one means, called locking means, capable of maintaining the/each gripping element (100a, 100b) in the open position when the lock (121) is in the locking position or in the wait position, as illustrated in
As illustrated in
The gripping elements (100a, 100b) and/or the guide parts (103, 104) preferably define a cavity which matches the form of the stem in order to limit or even prevent it from rotating.
The gripping elements (100a, 100b) of the clamp may be actuated by different means.
The clamp of the invention advantageously comprises two mobile gripping elements (100a, 100b) and the lock (121) is preferably situated between these two gripping elements. This configuration makes possible a compact construction and protects the lock from collisions with external elements.
The locking system (120) is preferably entirely mechanical, such as that illustrated in
The operation of the locking system (120) of the clamp (10) of the invention is illustrated with the aid of the specific example of
When the lock (121) is in the release position (FIG. 5(D)), the gripping elements (100a, 100b) can pivot freely around their respective (or common) axis (105) and permit, in particular, the positioning of the locking element(s) (102a, 102b) aligned with each corresponding cavity (126a, 126b) and the engagement of the attachment means (101a, 101b, 5, 5a, 5b), typically by inserting the protrusions (101a, 101b) into the corresponding cavities (5, 5a, 5b) of the stem (4). The gripping elements (100a, 100b) are locked when the clamp (10) is pulled upwards and the stem (4) drops down under the effect of its own weight and that of the load (
In the example illustrated in
Another object of the invention is a lifting and handling unit (6, 7, 8, 9, 10) comprising at least one load handling element (for loads such as anodes) (9) equipped with a handling clamp (10) according to the invention.
The invention permits double command systems to be avoided. It also has the advantage of being practically unaffected by accelerations during handling.
Number | Date | Country | Kind |
---|---|---|---|
03 02500 | Feb 2003 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/FR2004/000430 | 2/26/2004 | WO | 00 | 3/3/2006 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/079046 | 9/16/2004 | WO | A |
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3012811 | Sandrock | Dec 1961 | A |
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3945514 | Dose | Mar 1976 | A |
4032020 | Kato | Jun 1977 | A |
4279699 | Kuhn | Jul 1981 | A |
20050101172 | Shi et al. | May 2005 | A1 |
Number | Date | Country |
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1182405 | Nov 1964 | DE |
1190100 | Oct 1959 | FR |
1363432 | Jun 1964 | FR |
1437541 | May 1966 | FR |
2282580 | Mar 1976 | FR |
1300759 | Dec 1972 | GB |
2018220 | Oct 1979 | GB |
Number | Date | Country | |
---|---|---|---|
20060290153 A1 | Dec 2006 | US |