DE4003717A1 - Side guidance for rolled strip material - pushing guides in controlled manner against edges of strip material - Google Patents

Abstract

Rolled strip material (2) is fed by rollers (13) along a linear path. Edge guidance is provided by elements (3,4) that can be moved into contact with the edges of the strip. Each element has a pair of linear hydraulic actuators (8,14) that receive inputs from valves coupled into position and force regulating loops. Each loop has a position regulator (30) and a force regulator (32). Position signals are fed back from sensors for correction control. The force is limited to a set value. A process control computer (15) is coupled to the system. ADVANTAGE - Reduces wear of guides.

Description

The invention relates to a side guide for on a Roll conveyor transported roller conveyor according to the generic term of Claim 1.

Such side guides have a shaft which can be driven in rotation on the ends of which there are gears that sit in racks intervention. Between the racks and the ends of the Guide rulers are arranged over pneumatic cylinders a mechanical forced synchronization connected are and via a controller either in a withdrawn or can be moved into a pressure position.

The guide ruler is located in the first step can be moved and prepositioned in parallel. In the second step, the synchronized tires cause matik cylinder a pressing of the guide ruler on the band edge.

A disadvantage of this structure is that there is always a contact pressure acts on the belt edges. This will be next to the belt edge the guide rulers are also unduly used. Short Change intervals for the guide rulers, long standstill times and damage to the belt edges are the result.  

In addition, an exact guidance of the tape, such as. B. required for wrapping that is flush with the belt edge, with pneumatics cylinders is not possible. Because there is indeed Possibility that the balance is on Side guide working with pneumatic cylinders on both sides system due to external influences, e.g. B. by off the line caused side forces runs out of the middle position. The Structure of such a side guide with different nested drives is also very connected with great effort.

The invention has for its object a genus appropriate side guide for transported on a roller table Form the rolled strip in such a way that defined positions of the Guide rulers and defined forces of the guide rulers are adjustable on the rolled strip so that, for example, an edge flush reeling of the tape is possible.

This task is characterized by the characteristics of the Claim 1 solved. Hydraulic cylinder related the regulation according to the invention ensure an exact Approaching the belt edge position. The additional force rule allows the setting of defined forces.

It is advantageous if each guide ruler has two hydraulics cylinders are assigned, each with a control loop exhibit. However, good results can also be obtained achieve when two hydraulic cylinders form a control loop is assigned or if only one hydraulic cylinder with a Control loop per guide ruler is used.  

If the force control is subordinate to the position control, so is due to the limitation of strength and the constant comparison between the actual force and the predetermined target force Gentle, damage-free approach to the guide rulers reached the belt edges.

On the other hand, the position control over the force control the guide line is approached quickly ale to the belt edge. The superimposed force control loop works the position control loop only when the pressure in the piston-cylinder unit rises and the necessary Force goes against the target force. With this type of regulation however, care should be taken to ensure that starting off on the band edge is not too abrupt, otherwise damage to the Band edge can occur.

In the claims 9 to 12 possibilities are proposed against the parallel movement of the guide rulers work, namely mechanically and on technical control by synchronous control of the Posi tion control loops or by a combination of equals running control of the position control loops and the force control circles. Are the two hydraulic cylinders of a guide mechanically compulsorily synchronized, so very much fast synchronization times achieved. Just a game in the Gearing and torsion of the shafts can be unequal to cause moderation. The electronic synchronization This is achieved by constantly querying the actual values, the subsequent comparison with target values and by the Signal propagation times slower than the mechanical forced syn chronization. However, freedom from maintenance is an advantage of electronic regulation.

The invention is explained in more detail with reference to a drawing. Show:

Fig. 1 is a front view of the inventive guide sides in the strip running direction,

Fig. 2 shows a control scheme for the four cylinders of the side guides,

Fig. 3 of the Darge easily control loops in a simplified development depicting the structure of a schematically in Fig. 2,

Fig. 4 shows the structure of a control loop in a simplified representation, which can be assigned to the piston-cylinder units and instead of the control loop shown in Fig. 3 Darge

Fig. 5 is a control circuit for synchronous control of the posi tion and force-controlled piston-cylinder units.

In Fig. 1, a roller table 1 is indicated, on which rolled strip 2 is transported. Guide rulers 3 and 4 are arranged on both sides of the roller table 1 . The guide rulers 3 , 4 are mounted on guide blocks 5 , 6 so that they can be moved towards and away from one another. At a shoulder 7 of the guide ruler 3 engages a piston-cylinder unit 8 , 8 '(see also Fig. 2), which is firmly connected to the base 10 via the bracket 9 , 9 '. The piston-cylinder units 8 , 8 'are net angeord at the two ends of the guide ruler. The piston-cylinder unit 8 'is covered by the piston-cylinder unit 8 in Fig. 1.

With the approach 7 racks 11 , 11 'are connected ver, which are positively coupled to each other via a fixed, rotatably mounted, toothed balance shaft 12 . About the rack 11 , 11 'and the balance shaft 12 , both sides of the guide ruler 3 are coupled together so that both sides can only be moved by the same way; ie the guide ruler can only be moved in parallel.

For the guide ruler 4 are the same, not shown to provide drives. The synchronization of both sides of the guide ruler 4 can either also be mechanically enforced or accomplished by one of the rules described below.

In FIG. 2, the rolled strip 2 is shown, which is run by a driver 13 to a not shown reel. The guide rulers 3 and 4 rest on the edges of the rolled strip 2 . Fig. 2 shows the arrangement of all piston-cylinder units 8 , 8 '; 14 , 14 'on one side of the roller table. Such an arrangement can be appropriate for reasons of space. However, there is, as shown in Fig. 1, the possibility of the piston-cylinder units 8 , 8 'of a guide ruler 3 on one side of the roller table 1 and the piston-cylinder units 14 , 14 ' of the second guide ruler 4 the second side of the roller table 1 .

The piston-cylinder units 8 , 8 'attack on the guide ruler 3 and are mechanically synchronized via the balance shaft 12 . The piston rods of the piston-cylinder units 14 , 14 'are guided under the roller table and engage the guide ruler 4 .

Fig. 2 shows that all four piston-cylinder units 8 , 8 '; 14 , 14 'are assigned their own control loops, all of which have the same structure. The position control loops 30 , 30 ', 30 '', 30 ''' position setpoints can be specified. The position control loops 30 , 30 ', 30 '', 30 ''' work on force limiters 31 , 31 ', 31 '', 31 ''', which in turn act on force controllers 32 , 32 ', 32 '', 32 ''' . Position setpoints, the setpoints for the force controllers and the maximum force values can be entered via the process computer 15 . The actual position values are tapped via sensors 16 to 16 '''and given to the position control loops 30 to 30 '''. The pressure representing the force in the supply lines of the double-acting piston-cylinder unit 8 , 8 '; 14 , 14 'is also determined and the force control circuits 32 to 32 ''' applied.

Between the position control loops 30 '' and 30 '''a synchronous control loop 33 is provided, which ensures the parallel displacement of the guide ruler 4 . The average position values of the piston-cylinder units 8 , 8 'for the guide ruler 3 are formed in the mean value circle 34 while the mean position values of the piston-cylinder unit 14 , 14 ' for the guide ruler 4 are formed in the mean value circuit 35 . The mean values of the mean value circuits 34 and 35 are applied to the synchronous control loop, which can regulate the synchronous running of the guide rulers 3 and 4 . The regulation can be started e.g. B. via a light barrier 17 and a device for tape tip detection 18 on the driver 13th

Fig. 3 shows the control circuit 19 for one of the piston-cylinder units 8 , 8 '; 14 , 14 '. It is a position control loop with subordinate force control. The control circuit 19 corresponds to the four control circuits shown in FIG. 2 and is formed from a position control circuit 21 , a force limiter 22 and a force control circuit 23 . The output of the force control circuit 23 is guided to a valve 24 , on the pressure line of which an actual value transmitter 25 for the actual force is arranged. The position setpoint is e.g. B. tapped on the piston-cylinder unit 8 via an actual value sensor 26 and leads back to the position control loop 21 .

Fig. 4 shows the control circuit 20 , instead of the Regelkrei ses 19 the piston-cylinder units 8 , 8 '; 14 , 14 'can be assigned net. The control circuit 20 is a position control with a superimposed force control.

A setpoint force and a setpoint position value are predefined for the control circuit 20 . The force setpoint and the actual force value are applied to a force control circuit 27 . After appropriate conversion of the force signals, these are guided to the position control loop 28 with the position setpoint and the actual position value. The position control loop 28 ar works on the valve 24 .

Fig. 5 shows a circuit by means of which the synchronization of the piston-cylinder units 8 , 8 'and 14 , 14 ' can be accomplished by electrical or electronic means.

The upper half of Fig. 5 shows a circuit, as it is removed already in Fig. 3 and the loop from a posi tion control circuit 21 _1, a force limiter 22 _1, a motor 23 ₁ as well as a valve 24 ₁ and the receivers 25 ₁ and 26 ₁ exists. The actual position value of the transducer 26 ₁ is not only applied to the position control loop 21 ₁ but also to the position control loop 21 ₂ as a position setpoint for the cylinder of the 8 '.

The lower part of the control circuit is constructed similarly to the control circuit shown in FIG. 3. The position control circuit 21 ₂ is followed by a force limiter 22 ₂ , a force control circuit 23 ₂ and a valve 24 ₂ . The force transducer 25 ₂ is, as shown in FIG. 3, guided on the one hand to the force control circuit 23 ₂ and additionally, together with an overall specification of the force setpoint, to a summation force controller 29 which can influence the force limiter 22 ₁ .

Characterized in that the actual position of the piston-cylinder A unit 8 as a position target value for the piston-cylinder unit 8 'is used, it is ensured that the two piston-cylinder units 8, 8' is run, so that the guide straightedge only parallel is movable. By coupling the actual force on the piston-cylinder unit 8 'on the total force controller 29 for the piston-cylinder unit 8 , a predeterminable total maximum force is not exceeded.

List of reference numerals:

1 roller table
2 rolled strip
3 guide rulers
4 guide rulers
5 guide block
6 guide block
7 approach
8 piston-cylinder unit
9 bracket
10 bases
11 rack
12 balance shaft
13 drivers
14 piston-cylinder unit
15 process computers
16 sensors
17 light barrier
18 Band tip detection
19 control loop
20 control loop
21 position control loop
22 force limiters
23 force control loop
24 valve
25 actual sensors
26 Actual value sensors
27 Force control loop
28 position control loop
29 summation force controller
30 position control loops
31 force limiters
32 power transmitters
33 synchronous control loop
34 Average circle
35 Average circle
36 synchronous control loop

Claims (12)

1. Side guide for rolled strip transported on a roller table, preferably for hot strip in front of a reel, with parallel rulers provided on both sides of the rolled strip that can be moved towards and away from each other, which can be roughly positioned in a first step and pressed onto the strip in a second step are,
with pressure medium cylinders, which are able to apply the contact pressure in the second step,
with a control for the pressure medium cylinders,
as well as means that ensure the parallel displacement of the guide rulers,
that hydraulic cylinders ( 8 , 8 '; 14 , 14 ') are provided as pressure medium cylinders, which cause the guide rulers ( 3 , 4 ) to be displaced both during the first and during the second step,
that for the control of the hydraulic cylinders ( 8 , 8 '; 14 , 14 ') a control device ( 19 , 20 ) is provided which, via the hydraulic cylinders ( 8 , 8 '; 14 , 14 ') downstream of it as actuators, during the first step advance the guide rulers ( 3 , 4 ) from a retracted starting position to a predefinable position,
and that during the second step at least one of the hydraulic cylinders ( 8 , 8 '; 14 , 14 ') is both position and force controllable. 2. Lateral guide according to claim 1, characterized in that each guide ruler ( 3 , 4 ) two hydraulic cylinders ( 8 , 8 '; 14 , 14 ') are assigned and that each hydraulic cylinder has a control circuit ( 19 , 20 ). 3. Lateral guide according to claim 1 or 2, characterized in that the control ( 19 ) is formed during the second step as position control with subordinate force control. 4. Lateral guide according to claim 1 or 2, characterized in that the control ( 20 ) is performed during the second step as position control with superimposed force control. 5. Lateral guide according to at least one of claims 1 to 4, characterized in that the control circuits ( 19 , 20 ) of the hydraulic cylinder ( 8 , 8 '; 14 , 14 ') at least one guide ruler ( 3 , 4 ) during the position control process in the second step bring about a premature termination of the advancement when a prescribable contact force is reached or a further advancement ben beyond the prescribable position setpoint until a presettable contact force is reached. 6. Lateral guide according to at least one of claims 1 to 5, characterized in that the control circuits ( 19 , 20 ) of the hydraulic cylinder ( 8, 8 '; 14, 14' ) at least one guide ruler ( 3 , 4 ) during the second step a retraction of the guide ruler ( 3 , 4 ) when the pressure force exceeds a predeterminable threshold value. 7. Lateral guide according to at least one of claims 1 to 6, characterized in that the control circuits ( 19 , 20 ) of the hydraulic cylinder ( 8 , 8 '; 14 , 14 ') at least one guide ruler ( 3 , 4 ) during the second step a periodic , cause a retractable retraction of the guide ruler ( 3 , 4 ), which is followed by a new defined pressing after a predeterminable time interval. 8. lateral guide according to at least one of claims 1 to 7, characterized in that the control circuits ( 19 , 20 ) of the hydraulic cylinder ( 8 , 8 '; 14 , 14 ') one of the guide rulers ( 3 , 4 ) both during the first and effect position control during the second step. 9. lateral guide according to at least one of claims 1 to 8, characterized in that as a means for ensuring the parallel displacement at least one guide ruler ( 3 , 4 ) whose two hydraulic cylinders ( 8 , 8 '; 14 , 14 ') by a mechanical forced synchronization ( 11 , 12 ) are interconnected. 10. Side guide according to claim 9, characterized in that the forced synchronization ( 11 , 12 ) from each piston of the hydraulic cylinder ( 8 , 8 '; 14 , 14 ') of a guide bar ( 3 , 4 ) arranged racks ( 11 , 11 ') there is, which are arranged parallel to each other and are longitudinally displaceable with the two pistons, and that the toothed rods ( 11 , 11 ') are connected via a fixed-mounted balance shaft ( 12 ) having gears at their ends. 11. Lateral guide according to at least one of claims 1 to 10, characterized in that at least one of the guide rulers ( 3 , 4 ), the two position control loops ( 30 '', 30 ''') of a guiding ruler ( 4 ) a synchronous control loop ( 33 ) is assigned. 12. Lateral guide according to at least one of claims 1 to 11, characterized in
that as a means to ensure the parallel displacement environment of at least one guide rule (3, 4) the control circuit (19, 20) of the hydraulic cylinder (8, 14) of a guide rule (3, 4) is assigned a force control loop,
that the control loop ( 19 , 20 ) of the second hydraulic cylinder ( 8 ', 14 ') of the guide ruler ( 3 , 4 ) is position-controlled as a function of the first hydraulic cylinder ( 8 , 14 ),
and that the contact pressure of the second hydraulic cylinder ( 8 ', 14 ') is fed back to the force control circuit of the first hydraulic cylinder ( 8 , 14 ) such that an adjustable total force of both hydraulic cylinders ( 8 , 8 '; 14 , 14 ') cannot be exceeded.