EP1656223A1

EP1656223A1 - Coilbox located between the roughing train and the finishing train in a hot-rolling mill

Info

Publication number: EP1656223A1
Application number: EP04741156A
Authority: EP
Inventors: Klaus Bäumer; Bernhard Ehls; Matthias Beuter; Thomas Runkel; Matthias Krüger; Peter Schmitz
Original assignee: SMS Demag AG
Current assignee: SMS Siemag AG
Priority date: 2003-08-22
Filing date: 2004-07-19
Publication date: 2006-05-17
Anticipated expiration: 2024-07-19
Also published as: CN1839002B; JP2007503310A; WO2005028136A1; JP4833842B2; CA2536423C; CA2536423A1; DE10339191A1; ATE372837T1; UA90248C2; US7942029B2; RU2006109009A; CN1839002A; US20070012082A1; DE502004004974D1; EP1656223B1; RU2353453C2

Abstract

Extending the use of a coil box between pre-train and a finishing train for rolled material in a hot rolling mill comprises applying a pressing force (F) to the coil to treat smaller coil weights in a mandrel-less coil box, placing the coil in a roller table sink. An independent claim is also included for a device for carrying out the process.

Description

Coil box between roughing and finishing mill in the hot rolling mill

The invention relates to a method and a plant for expanding the use of a winding and unwinding station (coil box) between roughing and finishing mill for rolled material in hot rolling mills.

The use of a coil box in hot rolling mills is known. The technology of the coil box requires a certain minimum weight of the strip for processing. The minimum weight essentially depends on the material strength, the strip thickness and the design of the coil box. If the weight falls below the minimum, the coiled tape can no longer be unwound due to insufficient frictional forces between the unwinding rolls and the strip material. This means that the coil box cannot be used for strips below the minimum weight.

In the case of a coil box, the first station is used to wind up the coil. The subsequent unwinding of the coil is also carried out at the first station. At the same time as unwinding, the coil is transferred from the first to the second station. As long as the coil is still being unwound at the first station, no further tape can be taken up in the coil box; there must be a minimum break between two belts. The minimum break essentially depends on the construction and the control of the coil box.

The occupancy time of the first station also depends on the speeds of the material inlet and the material outlet. The maximum speeds are determined by the possibilities of the equipment in front of and behind the coil box and by the production program and can only be changed within limits. By the minimum break and the maximum speeds the material throughput in a hot strip mill is limited and a coil box can only be used to a limited extent in hot rolling mills with a high material throughput.

In the known coil boxes, a transfer from the first to the second station is carried out with supporting mechanisms. This can be a mandrel engaging centrally in the coil or, according to document US Pat. No. 5,987,955 B, a method with a weighing movement. Other mechanisms are also known, e.g. Rollers can be swiveled via levers, which rest on the outer circumference of the coil. This type of handover is referred to below as so-called active handover, which in the case of tapes with high coil weights represents the process with the shortest time for the handover.

In the case of a thornless transfer, there is another method of transferring the coil from the first to the second winding station by means of a strip tension acting on the outlet side onto the coil to be unwound. This belt tension is typically built up from the first scaffolding, but can also be built up in whole or in part by other facilities. The document DE 1 038 857 A1 describes necessary precautions which prevent the coil from moving against fixed stops and being damaged. This type of transfer is referred to below as so-called passive transfer. Passive transfer is always carried out for coils below a defined weight limit, unless this is prevented by retention mechanisms. The occupancy time of the first winding station depends on the bundle weight and can be shorter or longer than when the handover is active.

In the known methods with active handover, it is not possible to permit or force a passive handover during an active handover. In the weighing method described in document EP 0 933 147 A1, gaps arise in the roller table due to the displacement of the unwinding station against the direction of belt travel, into which a passively transferring coil would sink during active transfer and thereby damage would take place on the coil and the coil box. If gaps are closed with rollers that can be swiveled in, these rollers must be swung out before the rollers are moved; then, however, a roller table gap arises again.

In most applications, the use of a coil box achieves a significantly higher and more uniform temperature level across the strip length. Nevertheless, even if a coil box is used, the ideal temperature profile in a band will not be achieved. Heat is also extracted from the strip inside the coil box by radiation and roller contacts, especially on the outer turns. , , -,. .

Different temperatures and an additional inconsistent temperature curve over the length of the strip are disadvantageous. Especially in the case of missing or inadequate strip thickness control, the temperature differences lead to different rolling forces in the finishing train and thus to different strip thicknesses over the strip length. However, the uniformity of the strip thickness over the strip length is an important quality feature.

Against the background of the prior art described above, the object of the invention is to provide technical measures with which significantly smaller coil weights can be treated in a coil box. The invention is also intended to provide measures with which the material throughput in a coil box can be significantly increased. This also and especially applies to continuous lines with low speed of the roll stands in front of and behind the coil box and possibly short distances between the last roll stand in front of the coil box and the inlet of the coil box. Measures to increase the material throughput are particularly important when using a coil box with small coil weights.

Furthermore, the object of the invention is to provide measures with which a higher and more uniform temperature level of the strip can be achieved in connection with a coil box. The aforementioned task is solved with the following measures:

, To reduce the minimum weight of the strip, the use of a pressing device in a thornless coil box is proposed, which on the one hand increases the frictional forces between the coil and unwinding rollers with the force acting on the coil from above and on the other hand an unwanted transfer of the with a special geometric arrangement Prevents coils.

,. When the coil is unwound according to sketch A1, a height-adjustable pressing device 1 with a pressing force F is used until immediately before and at the start of a transfer of the coil from the first winding station 2a and 2b to the second winding station 4.

With rollers of the pressing device 1 a and 1 b, or with the bottom rollers of the winding station 2a and 2b or in combination, a pocket can be formed in which the coil C or C is held by the outlet-side driver T even when it is pulled. This prevents a coil from being pulled against the coil opener 3, even with a very low weight. After lifting the coil opener 3, the bag is opened again by lifting and lowering the corresponding rollers.

Furthermore, the pressing device can be designed with one or more rollers 1 a and 1 b. Rollers 1 a and 2b can also be designed with two rolls and a medium bearing, transversely to the material direction. The roll edges are rounded to prevent rolling in.

According to sketch A2, the earliest possible passive transfer of the coil C or C in the direction of the drive rollers T can be initiated by lowering the roller 2a and lifting the roller 2b. The method for dynamically raising and lowering the pressing device in accordance with the out-of-roundness of the coil is described as follows: The inertia of the pressing device is compensated for by a corresponding control of the pressing force, with the result that the pressing force F acting on the coil is largely constant regardless of a non-roundness of the coil remains. The compensation of the pressing force takes into account the vertical velocities of the pressing device due to the coil runout. The pressing force is increased or decreased by the amount of the resulting acceleration forces.

The level of the maximum pressing force for different material properties and operating modes is determined by tests, stored in a control system and called up again for further use.

With this measure of the invention, strips with significantly lower weights can be processed in a coil box compared to the previous solutions. The area of application of the coil box is expanded for a minimum necessary specific coil weight (coil weight to coil width) from 2 kg / mm.

2. To increase the material throughput in a coil box, the combination of active and passive transfer in a mandrelless coil box is proposed according to the invention. This means that a passive transfer can take place at any time during an active transfer. This can reduce the occupancy time of the first station and the necessary minimum break between two belts and increase the material throughput in a coil box. According to diagram B1, the occupancy time of the first station applies - For the active handover, a fixed period of time in diagram area A. This area applies to larger coil weights. - For the passive handover, a variable duration depending on the bundle weight. The time period increases from a minimum value in the diagram area P (smaller coil weights) to the value of the upper line in the diagram area AP (medium coil weights). Up to now, an active handover has not been possible in the AP area because an unwanted passive handover can take place due to the reduction in weight during unwinding and due to material tolerances.

The arrangement and movement of the rolls lying horizontally one behind the other in the strip running direction corresponds to sketch B2. The coil C or C rests on the pivotable rollers 2 and is unwound in the direction of the driver rollers T. The coil is transferred to the pivotable and displaceable rollers 3 up to one or more rollers G. After the holding mandrel D has been inserted, the coil is completely unwound.

The advantage of the method according to the invention is to combine an active and passive handover and thus to allow or force a passive handover even during an active, thornless handover. This shortens the transfer time in the AP diagram area for medium strip weights to the lower line. The now possible combination of the two methods shortens the occupancy time of the first station for strips with medium coil weights.

The roller spacing of the rollers 3, 4 and 5 (as well as additional rollers in some cases) can be reduced, so that the coil can move up to the rollers G at any time during a transfer without falling into a roller table gap.

Furthermore, one or more rollers 4 can be arranged to be horizontally displaceable in the tape running direction in order to to close the gap. In contrast to pivoting rollers, there are no roller table gaps in the case of displaceable rollers 4.

The process of active transfer can be developed in such a way that the rollers 2, 3, 4 and 5 are always at approximately the same height. This means that the coil can be passively transferred at any time during the active transfer without any major height movement. ,

One or more rollers G are used to brake the coil. The rollers G can be adjustable in height and thus adjust to the height of the coil center in the technically necessary range. The remaining coil to be unwound is held with at least one of the rolls G and the last turns of the coil are opened with the dome D inserted into the central axis of the coil.

With the use of the pressing device 1, the use of the diagram area P and the lower line of AP (diagram B1) is made possible for certain, lighter coil weights. Because of their coil weight, these coils would not be able to be processed without a pressing device.

A procedure for predicting the handover procedure and the minimum break is also used. The practical results from already processed strip material flow into this process and serve to reliably predict the minimum break.

Finally, the timing of the inlet of the raw material in ^'is controlled roll stands in front of the coil box for the advance calculation of the minimum pause. This is particularly important for the main lines in order to take advantage of the minimum break and to achieve an increased material throughput, because before the current strip is processed in the coil box, the following strip should run into the main strip with a predetermined minimum break. box the next volume should enter the Kontistrasse with a predetermined minimum break.

A modified control of the driver on the outlet side enables the transfer process to be started early. As soon as the tape to be unwound has reached the driver and the drive rollers are frictionally closed, the transfer from the first to the second station is initiated.

Ultimately, a third winding station can be used, thus further reducing the occupancy times of the first station. The tape is wound up at the first station. After that

The coil is transferred to the second station. The unwinding process begins there. During the unwinding process, the coil is handed over to the third station. Since there is no longer any time required for unwinding at the first station, the first station is free again for the subsequent belt faster.

The combination of three winding stations with a transfer without a mandrel from the first to the second and from the second to the third station is particularly advantageous. The transfer can be carried out by weighing methods or with a sliding roller acting approximately at the height of the central axis or a combination of these methods.

The disadvantages known from the prior art of a coil rotating on the mandrel and the loss of the position of the tape head in the event of a mandrelless transfer from the first to the second station are avoided.

The measures according to the invention can be compared to previous

Solutions in a coil box can achieve a significantly higher material throughput. Depending on the production process, the invention enables an annual production output of the coil box of approx. 3 million tons per year and higher, even with small coil weights.

3. According to the invention, the coil box has devices for passive and active, variable increase and equalization of the strip temperature, in particular by means of a strip heater (e.g. an induction heater or a continuous gas furnace). The temperature of colder band areas (such as the band head, band foot and outside of the band) can also be increased in a targeted manner compared to other areas. The existing tempera- door difference is reduced and at the same time the average temperature is increased.

When a coil box is combined with a heating system, the speed of the conveyor belt passing through the heating system can be reduced, thus increasing the heating effect for the colder belt areas. The strip speed can be selected independently of the speed of the roll stands in front of and behind the coil box, specifically for the strip base with a heating system arranged behind and for the strip head with a heating system in front of the coil box. The heating power can be increased lengthwise or crosswise to the strip running direction for colder strip areas and reduced for warmer strip areas. Devices for lateral guidance and for dividing the strip material can be arranged between the heating device and the coil box.

Furthermore, the operational safety of the heating system can be increased by a directional driver on the outlet side of the coil box or by an independent directional driver in front of the heating system. The straightening driver reduces band misalignment and band ripples in the coil box or other devices and band duplications are recognized. To avoid scale rolling and thus to increase the strip quality, descaling is carried out in front of or within the directional driver. Devices such as spray bars used. Cleaning devices can be attached to the straightening rollers of the straightening driver in order to avoid and remove the rolling of foreign material, for example scale. Furthermore, the heat radiation inside the coil box can be reduced by using width-adjustable thermal insulation hoods. Shortening the coil box due to shorter transport times and thus the shorter time for heat radiation means that less heat is extracted from the material. Thermal insulation hoods can also be used on the roller table or / or or behind or in front of and behind a coil box.

Furthermore, with increased winding and unwinding speeds in front of and behind the coil box compared to the rolling speeds of the roll stands, the transport time on the roller table can be reduced and thus the heat radiation can be reduced.

As a result of the measures according to the invention, a significantly higher and more uniform material temperature is achieved over the length of the strip. This creates an important prerequisite for rolling with a final strip thickness between 0.5 and 2.0 mm.

4. The individual measures according to the invention, described under numbers 1 to 3 above, can also be combined with one another. The previous operating range of a coil box (see diagram C1) lies within the diagram area O. This range is also covered after the measures of the invention have been introduced. Through a sensible combination of the measures described under numbers 1 to 3 above, a significantly larger expansion of the application area of a coil box can be achieved than with the individual measures. If only the measures to reduce the minimum weight of the strip according to number 1 are applied, the production spectrum to be processed is increased by strips with lower coil weights (diagram C1, diagram area A). However, since the achievable material throughput in a coil box decreases with lower coil weights, this results in a lower material throughput as an inevitable disadvantage.

If only the measures to increase the material throughput according to number 2 above are applied, the benefit of the invention can only be achieved in the range of medium minimum coil weights (diagram C1, diagram surface B).

By combining the measure according to the invention for reducing the minimum weight of the federal government with the measures for increasing the material throughput, strips with a lower bundle weight with high material throughput can be processed in a coil box (diagram C1, diagram areas A, B and additionally AB).

It should be noted here that only a part of the measures according to the invention under numbers 1 to 3 in their partial combination offer a meaningful expansion of the area of use of the coil box, depending on the specific technical requirement.

5. In summary, the following advantages can be achieved with the measures according to the invention:

The minimum weight of the tapes to be processed is significantly reduced. This means that a coil box can now also be used with low coil weights. The achievable throughput of a coil box is significantly increased. This means that a coil box can now be used in rolling mills with a high material throughput.

Temperature differences and inconsistent temperature profiles in the strip are further reduced. The heat losses through radiation are reduced and, if necessary, compensated. This creates the conditions for hot rolling with a final strip thickness between 0.5 and 2.0 mm.

By combining individual measures according to the invention to reduce the minimum weight or to increase the material throughput, the field of use of the coil box is expanded again, particularly for production programs with small coil weights and high material throughput.

Claims

claims

1. A method for expanding the use of a winding and unwinding station (coil box) between roughing mill and finishing train for rolled strip material in hot rolling mills, characterized by the fact that for the treatment of smaller coil weights in a mandrelless coil box, the coil to be unwound has a pressing force directed towards the roller conveyor (4) (F) is forced on and / or the coil is placed in a roller table sink, and / or in order to increase the material throughput in a mandrelless coil box, the active transfer and the passive transfer of a coil from a first winding station to a second winding station are combined in terms of time and weight are, and / or that the strip is supplied with heat and / or strip or coil box to be insulated in order to variably increase and even out the strip temperature in front of or behind the mandrelless coil box.

2. The method according to claim 1, characterized by the fact that the pressing force increases the frictional forces between the coil and the unwinding rollers and / or that an unwanted transfer of the coil is prevented with a predetermined geometric design of the roller table sink.

3. The method according to claim 1 or 2, d ad u rch geken nzeich net, that the size of the pressure force (F) takes into account the coil runout, the material properties, operating modes and other operating parameters.

4. The method according to claim 1, characterized in that the arrangement and movement of the rollers lying one behind the other in the belt direction (2, 3, 4, 5) is selected such that first a passive transfer of the coil (C, C) takes place, followed by one Braking the coil by means of at least one roller (G) and holding the coil after inserting a holding mandrel (D) into the coil. (C "). -.,

5. The method according to claim 4, characterized in that the earliest possible passive transfer of the coil (C, or C) is initiated in the direction of the pulleys (T) by lowering the roller (2a) and lifting the roller (2b).

6. The method according to one or more of the preceding claims, characterized in that for the calculation of the transfer process and the minimum pause of the coil treatment, the practical results from the strip material already processed are incorporated.

7. The method according to one or more of the preceding claims, characterized in that, before the start of the transfer process from the first to the second winding station, an output-side driver (T) is controlled in order to apply a specific strip tension.

8. The method according to claim 1, characterized in that the supply of heat is increased or reduced in a controlled manner along or across the strip running direction.

9.Device for expanding the use of a winding and unwinding station (coil box) between the roughing train and finishing train for rolled strip material in hot rolling mills, so that a pressure device is assigned to the coil to be unwound in order to treat smaller coil weights in a mandrelless coil box. or the coil is in a roller table sink, and / or that in order to increase the material throughput or to reduce the occupancy time in a mandrelless coil box, the support rollers for the coil can be pivoted (2, 3), moved horizontally in the longitudinal direction (3, 4) or in Distance (4) are arranged, and / or that, in order to increase and even out the strip temperature, adjustable or adjustable strip heating devices and / or roller table thermal insulation hoods are arranged in front of or behind the coil box and / or width-adjustable thermal insulation hoods are preferably provided within the coil box ,

10. The device according to claim 9, dad u rch geken marked that the pressure device is provided with pressure rollers (1a, 1b), and / or the roller table sink is formed by adjustable floor rollers (2a, 2b).

11. The device according to claim 9 or 10, dad u rch geken marked that means for pivoting the rollers (2a, 2b) and means for adjusting the distances or the height of the rollers (3, 4, 5) are provided.

12. The apparatus according to claim 9, characterized in that the rest coil (C ") is assigned a Haltedom (D) for opening and unwinding the last coil turns.

13. The device according to one or more of the preceding claims 9 to 12, characterized in that a controllable driver (T) is arranged downstream of the coil box.

14. The device according to one or more of the preceding claims 9 to 13, characterized in that a directional driver or a directional driver is arranged on the outlet side of the coil box or in front of the strip heating devices.

15. The device according to one or more of the preceding claims 9 to 14, characterized in that at least one descaling device is provided in front of or within the directional driver.

16. The device according to one or more of the preceding claims 9 to 15, characterized in that the straightening driver is formed with at least one cleaning device for the straightening rollers.

17. The device according to one or more of the preceding claims 9 characterized in that the device has three winding stations for thornless transfer of the coils.