DE4209649C2 - Multi-stage hydraulic pressure cylinder - Google Patents

Description

The invention relates to a multi-stage hydraulic Pressure cylinder and a method of moving loads with different degrees of loading and travel, in particular to push out and lift a bottom electrode the furnace of a DC arc furnace, where the hydraulic pressure cylinder with three pressure levels Media ports for moving the cylinder tubes and the telescopic cylinder tubes.

Multi-stage hydraulic cylinders for moving Loads are generally known. Telescopic cylinder Known types, however, have the disadvantage that in addition to the cylinder length, there is still room for need the necessary supporting structure. About that In addition, all components of the telescopic cylinder must be so be designed so that they can absorb the forces generated by each cylinder stage. At a big difference in strength between the individual This unique feature of the telescopic Cylinder inevitably leads to an elaborate construct tive design of the cylinder.

A pressure cylinder known from DE 26 26 606 A1 is characterized in that a first outer Printing cylinder, which is designed as a hollow piston cylinder is, as stationary, d. H. fixed cylinder in is attached to a housing. In the stationary A first piston moves with a cylinder tube piston rod attached to it.  

This piston rod is also a cylinder tube for formed the second pressure cylinder in which a another piston moves the second piston rod, which in a flange ring with a guide flange. The load is exclusive to this pressure cylinder carried by the second piston rod.

DE 36 22 424 A1 describes a two-stage telescopic Cylinder known from a first basic cylinder with pressure chamber and annulus, a first piston with the Pressure chamber of the first stage and another piston with the interior of the second stage. The ring space of the first stage and the interior of the second The levels are equal in volume.

Although this two-stage telescopic cylinder any driving style depending on the version allowed with this telescopic cylinder task can not be solved. Neither can different pressures generated in the two stages to handle loads with different levels of loading and moving stroke paths, this still stands out Telescopic cylinder due to a compact design or low overall height.

From US-4,726,281 is a multi-stage hydraulic Printing cylinder with three pressure levels known from a first outer cylinder tube with closed Bottom flask and media connections for this first Level exists. The cylinder pistons are in this piston the second and third stage, the inner, third piston with pressure media connections for the second and third stages are connected.  

The multi-stage pressure cylinder is replaced by a Hydraulic pump supplied with two outputs, whereby between the media ports on the outer, first Cylinder tube and the pressure media connections of the inner, third cylinder tube each a three-way Valve is arranged.

Due to the different length of the three cylinders piston and through the attached to the cylinder ends End rings can be the cylinder pistons of the three stages cannot be fully intertwined, they Rather, only reach a so-called staircase shaped final state, in which the loads once on the one side of the first outer cylinder in one Towing eye and on the opposite side of the attack the inner, third cylinder piston.

With this multi-stage printing cylinder, too task can not be solved, although under different pressures in the first or second and third stage can be generated. The load attack point lies only on the inner, narrowest, third cylinder tube.

The object of the invention is a multi-stage hydraulic cylinders of the type too create loads with different load levels and moves stroke paths, which has a compact design and has the smallest possible height.

The problem is solved by the features as described in claims 1 and 3 are specified.

Claim 2 represents an advantageous embodiment of the Invention.  

According to the invention, this is a multi-stage hydraulic cylinder created in the first Generate a high pressure with a short stroke can. This first stroke level is based on the known principle of the hollow piston cylinder, the Load is supported on a hollow piston. This Hollow piston is designed according to the invention so that it at the same time the cylinder tube of the inside arranged arranged multi-stage telescopic cylinder.

In the operating state, pressurization moves on Connection piece of the first lifting stage at an initial lifting movement a large load. This burden persists from a dead weight, increased by a certain one Breakaway torque from a firmly connected association, the Refractory lining in the base of an arc oven. After the short stroke within the The breakaway torque is overcome in the first stroke stage. In the next or the next stage of the lifting movement only the load, i.e. H. the weight, alone emotional. For this purpose, the corresponding lifting stages II and III pressurized at the pressure medium connection. Then the piston of stroke level III moves up to Load and takes this from the cylinder barrel first stroke level. Levels II and III extend and finally move the load into theirs End position.

When retracting or lowering the invention three-stage lift cylinders are only low back pressures or to take loads to the desired To move back to the end position.  

Such a multi-stage hydraulic cylinder can as a three-stage lifting system, for example on one DC arc furnace can be used to create a approx. 26.0 tons heavy ground electrode corresponding wear and tear from the with Refractory lined hearth of the Push out the furnace and thus into the interior of the To move the furnace space.

The pressure of the first stroke of the a total of three-stage lifting system can weigh up to approx. 100 t amount to the sintered with the stove floor and loosened stamped bottom electrode and by approx. 300 mm to raise. In the second and third stroke stages, the detached bottom electrode through the two inner ones Lift cylinders (stroke levels II and III) by approx. 2000 mm to be lifted by another hoist, for example, an indoor crane, picked up and closed a parking or repair area in the hall of the Steelworks to be driven and dropped there.

In the figures, the invention is based on schematic embodiments explained.

Show it:

Fig. 1 shows a section of the three-stage lifting cylinder in the retracted state,

Fig. 2 shows a section of the three-stage lifting cylinder with extended stage I,

Fig. 3 shows a section of the three-stage lifting cylinder in the extended state and

Fig. 4 shows the arrangement of the three-stage lifting cylinder below the bottom electrode of a DC arc furnace.

Wherein up to 3 shown in FIGS. 1 multistage hydraulic pressure cylinder is a three-stage cylinder, which consists of a first cylindrical tube stage I, the second as a hollow piston cylinder having a first cylinder tube (1), a piston disk (2) and with a Cylinder tube ( 3 ) is designed as a hollow piston rod.

A first cylinder tube ( 4 ) and a second cylinder tube ( 6 ) are arranged as telescopic cylinders in the second cylinder tube ( 3 ).

The second cylinder tube (3) has a stroke limiter (5) for the first telescopic cylinder tube (4) of the stage stroke II to this first telescopic cylinder tube (4) in turn has a stroke limitation (7) for the second telescopic cylinder (6) of the Lift level III on.

On the first cylinder tube ( 1 ) Druckmedienan connections ( 8 ) for lifting and ( 9 ) for lowering the lifting stage I are provided. The corresponding pressure medium connections ( 10 ), ( 11 ) for the pressure medium for the lifting stages II and III are for lifting ( 10 ) below the second cylinder tube ( 3 ) and for lowering ( 11 ) laterally in the upper area of the second cylinder tube ( 3 ).

( 13 ) denotes a stationary support on the lower part of the direct-current arc furnace, on which the first cylinder tube of lifting stage I is supported.

Fig. 1 shows the multi-stage pressure cylinder in the retracted state, the piston disc ( 2 ) is in the lower part of the first cylinder tube ( 1 ), the second cylinder tube ( 3 ) is directly under the load ( 12 ).

The first telescopic cylinder tube ( 4 ) and the second telescopic cylinder tube ( 6 ) are depressurized and are located on the bottom of the cylinder tubes ( 3 ) and ( 4 ) surrounding them.

In Fig. 2 it can be seen that the multi-stage pressure cylinder is extended upwards in stroke level I, the piston disc ( 2 ) is in the upper part of the first cylinder tube ( 1 ), the load ( 12 ) finally rests on the second cylinder tube ( 3rd ). The two inner telescopic cylinder tubes ( 4 ) and ( 6 ) are in the rest position.

Fig. 3 shows the three-stage lifting cylinder in the fully extended state, ie here are all telescopic cylinder tubes ( 3 , 4 , 6 ) up to their stroke limits ( 5 , 7 ) and extended to the upper edge of ( 1 ). The load now rests exclusively on the telescopic cylinder ( 6 ) of lifting stage III.

In FIGS. 1 to 3, the application of the hydraulic cylinder according to the invention is shown as a lift cylinder for breakaway (stage stroke I), for raising (stage stroke II and III) and lower (stage stroke I-III) of a load (12) generally. In principle, the device according to the invention can also be used for moving loads in other directions.

Fig. 4 shows the use of a series of three-stage hydraulic pressure cylinders using a practical example, namely for pushing out a bottom electrode ( 14 ) from the furnace hearth ( 17 ) of a DC arc furnace ( 18 ) as indicated in the introduction to the description.

The bottom electrode ( 14 ) is in the hearth of a direct current arc furnace ( 18 ) and should be replaced by a new or reconditioned bottom electrode ( 14 ) after the refractory material and the metal rods have worn out. With the help of the multi-stage hydraulic pressure cylinder ( 16 ) arranged below the furnace vessel on the circumference of the bottom electrode ( 14 ), which press from below against the bottom plate ( 15 ) of the bottom electrode ( 14 ), the bottom electrode is initially under high back pressure (weight of Bottom electrode approx. 26 t) only in lifting stage I within the first cylinder tube ( 1 ) with pressure medium through the pressure medium connections ( 8 ) and ( 9 ). It is thereby achieved that the bottom electrode (14) with which it is broken loose from the composite surrounding refractory material of the furnace hearth (17). Then, as described in FIG. 3, the long-stroke telescopic cylinders raise the bottom electrode ( 14 ) into the interior of the furnace vessel of the direct-current arc furnace ( 18 ) under a lower counterpressure. The worn-out bottom electrode ( 14 ) can then be removed from the direct-current arc furnace ( 18 ) by a lifting device (not shown).

Reference list

1

First cylinder tube, stroke level I

2nd

Piston disc of the second cylinder tube

3rd

Second cylinder tube, stroke level I

4th

First telescopic cylinder tube, stroke level II

5

Stroke limitation from stroke level II

6

Second telescopic cylinder tube, lifting stage III

7

Stroke limitation from stroke level III

8th

Pressure medium connection for lifting, lifting level I

9

Pressure medium connection for sinks, stroke level I

10th

Pressure medium connection for lifting, lifting stages II and III

11

Pressure medium connection for sinks, lifting stages II and III

12th

load

13

Support

14

Bottom electrode of a DC arc furnace

15

Floor panel from

14

16

Multi-stage hydraulic pressure cylinder

17th

Stove

18th

DC arc furnace

Claims (3)

1.Multi-stage hydraulic pressure cylinder for moving loads with different load levels and stroke paths, in particular for pushing out and lifting a bottom electrode from the furnace of a DC arc furnace, the hydraulic pressure cylinder having three pressure stages with pressure media connections for moving the cylinder tube and the telescopic cylinder has tubes, characterized ,

• 1. that a piston disk ( 2 ) of a second cylinder tube ( 3 ) is hydraulically movable in a first cylinder tube ( 1 ) attached to a support ( 12 ),
• 2. that a first telescopic cylinder tube ( 4 ) can be moved in a second cylinder tube ( 3 ),
• 3. that this first telescopic cylinder tube ( 4 ) is also the cylinder for a second telescopic cylinder tube ( 6 ),
• 4. that in the first stroke stage the load ( 12 ) rests on the head end of the second cylinder tube ( 3 ) and is lifted exclusively by this cylinder tube ( 3 ),
• 5. that the telescopic cylinder tubes ( 4 , 6 ) for the second and third lifting stage are in the retracted, unloaded state within the second cylinder tube ( 3 ) and
• 6. that in the second and third lifting stages the load ( 12 ) rests on the head end of the first telescope cylinder tube ( 4 ) or the second telescope cylinder tube ( 6 ) and exclusively from the respective telescopic cylinder tube ( 4 or 6 ) is raised,
• 7. that pressure media connections ( 8 , 9 ) for moving the piston disc ( 2 ) of the cylinder tube ( 3 ) and
• 8. that pressure media connections ( 10 , 11 ) for moving the telescopic cylinder tubes ( 4 , 6 ) are arranged.

2. A multi-stage hydraulic pressure cylinder according to claim 1, characterized in that the ratio of the effective area of the short-stroke piston disk (2) to the effective area of the first long hubigen telescopic cylinder tube (4) or the first and second long-stroke telescopic cylinder pipes (4, 6 ) Is 2: 1 to a maximum of 5: 1. 3. A method for moving a load, in particular the bottom electrode of a DC arc furnace, with different load levels and under different stroke paths with the help of a three-stage hydraulic pressure cylinder according to one of claims 1 to 3, characterized in that for moving the load ( 12 ) under Initially high back pressure, stroke level I, - break-off of the bottom electrode ( 14 ) from the oven - first only the short-stroke pressure cylinder ( 1 , 2 , 3 ) attached to a support ( 13 ) is pressurized with pressure medium via the pressure medium connections ( 8 , 9 ) , and that afterwards to move the load ( 12 ) under lower counter pressure, lifting stage II, - lifting the bottom electrode ( 14 ) inside the furnace vessel - the long-stroke first telescopic cylinder tube ( 4 ) or the long-stroke first and second telescopic cylinder tubes ( 4 , 6 ), stroke levels II and III, with pressure medium through the pressure medium connections ( 10 , 11 ).