RU2690903C1 - Aluminum electrolyser anode frame overwind machine - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to self-propelled machine for constriction of anode frames of electrolysers for aluminum production. Proposed machine comprises self-propelled wheeled truck with frame, cabin, motor installation and manipulator with hydraulic wrench for opening and closing locks of anode pins at anode frame overwind, manipulator consists of telescopic column arranged with the possibility of lifting upwards by means of lifting hydraulic cylinder, fixed by means of vertical axis of rotation on upper part of telescopic column, telescopic boom consisting of external section and internal section, made with possibility of telescopic extension from external section by means of hydraulic cylinder of extension, and said hydraulic wrench fixed on inner section of telescopic boom on horizontal axis of swinging by means of end beam, with possibility of swinging in vertical plane with restriction downwards by means of stop.EFFECT: higher efficiency and reliability of the machine for the augmentation of the anode frames overwind.8 cl, 3 dwg

Description

Technical field

The invention relates to non-ferrous metallurgy, in particular to self-propelled machines for the waist of the anode frames of aluminum production electrolyzers.

The level of technology

The technological process of processing of electrolyzers provides for periodic waist of the anode frames. In some enterprises, the anode frame is tightened either by unscrewing the anode pin fasteners with special cap wrenches manually, or using a workshop crane, on which the hydraulic key is vertically secured to unscrew the anode pin fasteners. The main disadvantage of manual unscrewing the locks is hard physical labor and dangerous working conditions. The disadvantages of using a workshop crane include a significant energy intensity of the process due to the use of a large mass of the crane and the diversion of the crane from the performance of other technological operations.

The safest way to anode frames is to use self-propelled machines for anodic frames.

Closest to the proposed machine is a machine for waist anodic frames (RF patent No. 146460, S25S 3/10, publ. 10.10.2014,). The analog is made in the form of a four-wheeled self-propelled chassis, contains a longitudinal platform made of steel profile, on which beams are placed, a cabin is located in the front part of the chassis, and a power plant is located in the rear part of the chassis. The machine contains a sliding forklift, on which is located a two-section multi-hinged manipulator with a hydraulic key, each section of the manipulator has the ability to turn the cylinders relative to each other in a horizontal plane due to vertical hinges. The chassis frame at the bottom corners has no bevels. The main disadvantages of the known machine are its low productivity and insufficient reliability. The performance of the analog is reduced due to the fact that the leading of the hydraulic key to the anode rod fastening locks must be performed by two successively installed sections of the rotary manipulator, which rotate along the radius in the horizontal plane, each section having its own drive for turning, because of which the operator must control several drives alternately, because due to the complex trajectory of the hydraulic wrench, it is difficult to perform simultaneously. In addition, the performance of the machine is reduced due to the danger of hitting the bottom corners of the chassis frame on the flanging of the electrolyzer protruding above the floor of the housing, which causes difficulty in maneuvering in the electrolysis housing. The lack of reliability of the machine is caused by the rapid deterioration of the parts of the vertical hinges of the sections of the manipulator, which are experiencing significant loads at maximum departure of the sections of the manipulator. In addition, due to the rigid mounting of the hydraulic key on the manipulator section, there is a high probability of damage to the mechanisms of the machine if the axis of the hydraulic key does not coincide with the axis of the anode rod mounting locks.

Disclosure of the invention

The technical result of the invention is to increase productivity and increase the reliability of the machine for waist anode frames.

The technical result is achieved by the fact that in the machine for tightening the anode frames of an aluminum electrolysis cell containing a self-propelled wheeled cart with a frame, a cabin located on it, a motor unit and a manipulator with a hydraulic key for opening and closing anode frame locks when the anode frame is over-tightened, that the manipulator consists of a telescopic column, made with the possibility of lifting upward by means of a lift hydraulic cylinder, fixed by means of a vertical axis of rotation on the upper part of the telescopic column, telescopic boom, consisting of the outer section and the inner section, made with the possibility of telescopic extension from the outer section by means of the extension hydraulic cylinder, and the said hydraulic wrench fixed on the inner section of the telescopic boom on the horizontal swing axis by means of an end beam, vertical plane with the restriction down by the stop.

The invention is complemented by particular features. So, the frame is made of U-shaped sheet metal in plan with separate platforms - front and rear, the lower corners of the frame of the self-propelled carriage are made with bevels. The cab on the front platform and the engine installation on the rear platform are located along the left side of the frame. The axis of rotation of the hydraulic key is located vertically. Telescopic boom is made with the possibility of rotation about the vertical axis in the horizontal plane. The manipulator in the transport position is installed in the frame dimension along the starboard side of the frame.

Brief Description of the Drawings

The invention is illustrated by drawings, where in FIG. 1 shows a general view of a machine with a manipulator in the working, extended position. FIG. 2 shows a general view of the machine from the top with the manipulator in the transport position. FIG. 3 shows an enlarged fragment of the end beam with the hydraulic key of the manipulator in the extended position with the elevated line up (the dash line 2 is shown) and the end beam installed on the stop with a hydraulic key and fitted on the anode pin fastener lock.

List of structural elements:

1 - self-propelled truck;

2 - frame;

3 - the front frame of the frame;

4 - rear frame frame;

5 - bevels of the lower corners of the frame;

6 - the left side of the machine;

7 - cab;

8 - engine installation;

9 - manipulator;

10 - hydraulic wrench;

11 - lift cylinder;

12 - telescopic column;

13 - the axis of rotation of the telescopic boom;

14 - telescopic boom;

15 - outer section of the boom;

16 - hydraulic cylinder extension;

17 —internal boom section;

18 - axis swing hydraulic key

19 - end beam;

20 - end of the end beam;

21 - axis of rotation of the hydraulic key;

22 - rotation cylinder;

23 - boom transport position;

24 - right side of the machine;

25 - lock fastening anode pins;

26 - working position of the boom.

The inventive machine contains a self-propelled wheeled cart 1, which includes a U-shaped frame made of sheet metal in plan 2 with separate platforms — the front frame frame 3 and the rear frame frame 4. At the corners of the machine, the bottom corners of the frame 2 are made with bevels 5. On The front frame of the frame 3 along the port side 6 is located cab 7, on the rear platform of the frame 4 along the port side 6 is a motor installation 8. A telescopic manipulator 9 with a hydraulic key 10 is located between the front platform of the frame 3 and the rear platform of the frame 4. The puller consists of a telescopically rising up from the frame 2 of the column 12. Lifting the telescopic column 12 is done by lifting hydraulic cylinder 11. At the top of the column 12 using a vertical axis of rotation 13 a telescopic boom 14 is fixed. Telescopic boom 14 consists of an outer boom section 15, from which telescopically extend the extension by the hydraulic cylinder 16, the inner section of the boom 17. On the outer end of the inner section of the boom 17 on the horizontal swing axis of the hydraulic key 18 is fixed on the end beam 19. The end beam 19 with a hydraulic key 10 has the ability to swing freely on the swing axis 18 in a vertical plane. Swing end of the beam 19 is limited to the stop 20. The axis of rotation of the hydraulic key 21 is located vertically. Telescopic boom 14 has the ability to rotate relative to the vertical axis 13 in the horizontal plane using the hydraulic cylinder rotation 22 and in transport position 23 is installed in the envelope of the machine along the right side of the frame 24. Along the right side of the machine 24 on the front 3 and rear 4 of the frame under the boom 23 of the manipulator anode frame beams can be installed if they are to be transported (not shown in the figures). The hydraulic key 10 serves to unscrew or tighten the locks securing the anode pins 25. When unscrewing or twisting the hydraulic key 10 is put on the anchorage pin fastener lock 25.

The machine works as follows.

The machine, moving along the electrolyzer, stops, the boom 14 from the transport position 23 is rotated to the working position 26 away from the machine and positioned along one of the anode rod locks 25. The hydraulic key 10 is telescoped by boom sections 15 and 17 and extended by telescopic boom 14 to one of the locks attaching the anode pins 25 from above, is positioned until the axis of the hydraulic key 21 and the axis of the fastening lock of the anode pin 25 coincide and the manipulator 9 is lowered by telescoping olons 12 down, and after fully fitting the hydraulic key 10 to the anode pin 25 lock, the locks 25 are opened or closed with a hydraulic key 10. Next, the hydraulic key 10 rises up by telescoping the column 12 by means of a hydraulic cylinder 11 up, the car moves to the next anode lock pins 25 and further the process of opening and closing of all locks for fastening the anode pins 25 is repeated according to the workshop technological instruction.

In case of inaccuracy of positioning the hydraulic key 10 above the anode pin 25 fastening lock, when the hydraulic key 10 is lowered, the end beam 19 deviates together with the hydraulic key 10 on the swing axis 18. At the same time, due to the flexible hinge mounting of the hydraulic key 10 on the axis 18 does not occur damage to the machine mechanisms due to the mismatch of the axis of the hydraulic key 21 with the axis of the locks securing the anode pins 25 (the dash line is shown in FIG. 3). In the working position, the end beam 19 with the hydraulic key 10 does not fall down due to the fact that its downward movement is limited by the stop 20.

The specifics of work when the anode frame is over-tightened require that multiple maneuvers be performed on the machine. Due to the presence of bevels 5 at the lower corners of the frame 2, the magnitude of the external turning radius of the lower part of the machine is reduced, which makes it more convenient to maneuver in the electrolysis housing.

Positive results of the proposed technical solution:

The design of the telescopic boom of the machine with a hydraulic key freely fixed with the possibility of swinging up and down on the manipulator, as compared with the analog, reduces errors during operation, provides greater convenience during operation and, consequently, provides greater productivity and greater reliability.

The presence of bevels on the lower corners of the frame reduces errors during operation, expands the possibility of maneuvering in electrolysis housings and, consequently, increases the performance of the anode frame waist.

The presented positive results are confirmed by production tests of the machine carried out in the electrolysis housings of the aluminum plant, made in accordance with the claims.

Claims (8)

1. The machine for the waist of the anodic frames of the aluminum electrolysis cell, containing a self-propelled wheeled cart with a frame, a cabin located on it, a motor unit and a manipulator with a hydraulic key for opening and closing the anode rod locks when the anodic frame waist is, characterized in that the manipulator consists of a telescopic column , made with the possibility of raising up through the hydraulic lift cylinder, fixed by means of a vertical axis of rotation on the upper part of the telescopic column, telescopic boom, with standing from the outer section and the inner section, made with the possibility of telescopic extension from the outer section by means of the extension hydraulic cylinder, and the above-mentioned hydraulic key fixed on the inner section of the telescopic boom on the horizontal axis of swing by means of an end beam, with the possibility of swing in a vertical plane with limitation down by means of an emphasis . 2. Machine under item 1, characterized in that the frame is made U-shaped in plan with separate platforms - front and rear. 3. The machine under item 1, characterized in that the frame is made of sheet metal. 4. The machine under item 1, characterized in that the lower corners of the frame of the self-propelled truck are made with bevels. 5. The machine under item 1, characterized in that the cab on the front platform and the motor installation on the rear platform are located along the left side of the frame. 6. The machine under item 1, characterized in that the axis of rotation of the hydraulic key is located vertically. 7. The machine under item 1, characterized in that the telescopic boom is configured to rotate about a vertical axis in the horizontal plane. 8. The machine under item 1, characterized in that the manipulator in the transport position is installed in the envelope of the frame along the starboard side of the frame.

Images