ROLLING PLANT FOR ROLLING BILLETS OR BLOOMS

Abstract

A rolling plant for rolling billets or blooms, the plant defining a longitudinal feeding axis X of said billets or blooms and comprising a feeding area for feeding said billets or blooms; a rolling train; a longitudinal roller table to transport the billets or blooms from said feeding area to said rolling train along said longitudinal feeding axis X; a welding machine adapted to move forwards and backwards along said longitudinal roller table to weld billets or blooms to one another when moving from said feeding area to said rolling train;
characterized in that said welding machine is slidingly suspended from a bridge and is adapted to translate parallel to said longitudinal feeding axis X, and said bridge is arranged at the longitudinal roller table and is adapted to translate transversely to said longitudinal feeding axis X, whereby in a first operating position of the bridge the welding machine occupies part of the longitudinal roller table and can move forwards and backwards along said longitudinal feeding axis X, whereas in a second operating position of the bridge the welding machine makes said longitudinal roller table clear.

Claims

1. A billet or bloom rolling plant for rolling billets or blooms, the plant defining a longitudinal feeding axis X of said billets or blooms and comprising a feeding area for feeding said billets or blooms; a rolling train; a longitudinal roller table to transport the billets or blooms from said feeding area to said rolling train along said longitudinal feeding axis X; a welding machine adapted to move along said longitudinal roller table to weld billets or blooms to one another when moving from said feeding area to said rolling train; characterized in that said welding machine is slidingly suspended from a bridge and is adapted to translate parallel to said longitudinal feeding axis X, and said bridge is arranged at the longitudinal roller table and is adapted to translate transversely to said longitudinal feeding axis X, whereby in a first operating position of the bridge the welding machine occupies part of the longitudinal roller table and can move forwards and backwards along said longitudinal feeding axis X, whereas in a second operating position of the bridge the welding machine makes said longitudinal roller table clear.

2. The plant according to claim 1, wherein said bridge is a bridge suspended on a fixed structure of the plant.

3. The plant according to claim 2, wherein said suspended bridge is a bridge with two beams, parallel to the longitudinal feeding axis X, and the welding machine is adapted to slide on first guides, each first guide being arranged on a respective beam of the bridge.

4. The plant according to claim 3, wherein said suspended bridge is adapted to slide on second guides, orthogonal to the beams and provided on said fixed structure.

5. The plant according to claim 1, wherein a maintenance area of the welding machine is provided at said second operating position of the bridge.

6. The plant according to claim 1, wherein the longitudinal roller table comprises a plurality of first, preferably motorized, rollers, each first roller being mounted on a respective pivoting support, preferably in a number less than or equal to five.

7. The plant according to claim 6, wherein the welding machine is provided at the bottom with at least two second rollers, preferably only two second rollers which are possibly idle, and with at least one cam element adapted to lower at least two first rollers from a supporting position, in which said at least two first rollers support the billets or blooms, to a retractable position during a movement of the welding machine along said longitudinal feeding axis X, so that said at least two second rollers replace said at least two first rollers in said supporting position.

8. The plant according to claim 6, wherein at least some of said first rollers are provided with respective actuation means to lower the corresponding first roller before the bridge passes from the first operating position to the second operating position.

9. The plant according to claim 7, wherein said first rollers are cantilevered with respect to the respective pivoting support and/or said second rollers are cantilevered with respect to a base of the welding machine.

10. The plant according to claim 7, wherein said first rollers and/or said second rollers are provided with side edges for containing the billet or bloom along the longitudinal feeding axis X.

11. The plant according to claim 7, wherein the first rollers are provided with an idle wheel on a side thereof and said at least one cam element is adapted to act on said idle wheel to lower the respective first roller.

12. The plant according to claim 1, wherein the welding machine is suspended from a carriage slidingly fastened to the bridge so as to translate parallel to said longitudinal feeding axis X, preferably wherein said carriage and said bridge are components of a bridge crane or overhead crane.

13. The plant according to claim 1, wherein said feeding area or said billets or blooms comprises a heating furnace and/or a movement bed, or comprises a continuous casting machine.

14. The plant according to claim 1, wherein said welding machine is a flash welding machine entirely suspended from the bridge or from an overhead crane.

15. The plant according to claim 14, wherein said flash welding machine is a welding assembly comprising a first fixed structure or frame; first clamping means, placed on said first structure, for clamping a tail of a first billet or a head of a second billet; a second sliding structure or frame, connected to said first structure and sliding, parallel to the longitudinal feeding axis X, with respect to the first structure; second clamping means, placed on said second structure, for clamping the head of the second billet or the tail of the first billet; at least two upsetting cylinders for adjusting the position of the second structure with respect to the first structure along a direction parallel to the longitudinal feeding axis X, in order to press the head of the second billet on the tail of the first billet, or vice versa, during welding; and wherein the whole welding assembly is slidingly suspended from the bridge or from the overhead crane.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0042] In the description of the invention, reference is made to the attached drawings, provided by way of explanation and not by way of limitation, in which:

[0043] FIG. 1 shows a diagram of the rolling plant in accordance with the invention;

[0044] FIG. 2 shows a perspective view of part of the plant of FIG. 1;

[0045] FIG. 3 shows a detail of the plant of the invention;

[0046] FIG. 4 shows a perspective view of the welding machine of the plant of the invention.

DESCRIPTION OF EXEMPLARY EMBODIMENTS OF THE INVENTION

[0047] With reference to FIG. 1, an example of a rolling plant 1 is shown for rolling thick metal products, in particular billets or blooms, in accordance with the invention.

[0048] The rolling plant 1, defining a longitudinal feeding axis X of the metal products, comprises the following components: [0049] a feeding area 2 of the metal products for feeding the metal products one at a time along axis X; [0050] a rolling train 3, of which only a first rolling stand is shown; [0051] a longitudinal roller table 4 to transport the metal products from the feeding area 2 to the rolling train 3 along the longitudinal feeding axis X; [0052] a welding machine 5 adapted to move forwards and backwards along the longitudinal roller table 4 to weld metal products to one another when moving from the feeding area 2 to the rolling train 3.

[0053] The welding machine 5 is a flash welding machine for a flash welding of billets or blooms. The flash welding machine is not suitable for welding thin metal products, such as strips or sheets, because the strip or sheet would be damaged; as well as the laser welding machine for welding strips or sheets is not suitable for a flash welding of thick metal products, such as billets or blooms, because the laser power is not sufficient for appropriately welding billets or blooms.

[0054] Preferably the flash welding machine 5, designed for welding a tail of a first billet or bloom with a head of a second billet or bloom along the longitudinal feeding axis X, is a welding assembly comprising (FIG. 1) [0055] a first fixed structure or frame 30; [0056] first clamping means, placed on said first structure 30, for clamping the tail of the first billet or the head of the second billet; [0057] a second sliding structure or frame 31, connected to said first structure 30 and sliding, parallel to the feeding axis, with respect to the first structure 30; [0058] second clamping means, placed on said second structure 31, for clamping the head of the second billet or the tail of the first billet; [0059] at least two upsetting cylinders 32 for adjusting the position of the second structure 31 with respect to the first structure 30 in order to press head and tail of the billets during the welding.

[0060] Welding is achieved by means of an electric discharge produced by electrical power supplies which supply electric current the billets to be welded. The billets must be effectively blocked during welding. To this end, there are provided clamping means which serve to hold the billets in position during welding and to transmit the electric current to the billets to be welded.

[0061] These clamping means typically comprise elements, in particular wear pads, which go directly into contact with the billets to be welded. As the welding is carried out, the clamps that hold the head and tail of the billets to be welded are approached by means of said upsetting cylinders 32. This operation is necessary to allow the effective adhesion between the two components in welding, which form a welded joint. However, around the joint a burr is produced, due to the expulsion of the molten material towards the outside during welding. This burr must be removed (or reduced) if it is excessive, so as not to cause problems during rolling.

[0062] Advantageously, the welding machine 5 is slidingly suspended, for example by means of a carriage 8, from a bridge 7 and is adapted to slide parallel to the longitudinal feeding axis X. Alternatively, the welding machine 5 can be equipped to be directly suspended from the bridge 7, without the need to provide for the carriage 8, and to slide parallel to the longitudinal feeding axis X.

[0063] The bridge 7 is arranged at the longitudinal roller table 4 and is adapted to translate transversely to the longitudinal feeding axis X, whereby, in a first operating position of the bridge 7, the welding machine 5 occupies part of the longitudinal roller table 4 and can move forwards and backwards along the longitudinal axis X, whereas, in a second operating position of the bridge 7, the welding machine 5 leaves the longitudinal roller table 4 completely clear (FIG. 2).

[0064] For example, the bridge 7 can translate orthogonally to the longitudinal feeding axis X or it can translate transversely to the longitudinal feeding axis X along a slightly curved surface, for example by means of a lifting system of the bridge 7 of the parallelogram type. Carriage 8 and bridge 7 can be components of a bridge crane or overhead crane 6.

[0065] Advantageously, the whole flash welding machine is suspended from the bridge 7 or from the bridge crane 6. This means that the welding machine does not have parts fixed on the ground and that the whole welding assembly, above disclosed, is suspended from the bridge 7 or bridge crane 6.

[0066] The feeding area 2 of the metal products can comprise a heating furnace, if the heating of the product before the rolling is required, or a movement bed, if the products already reach a suitable temperature on said bed. Alternatively, the feeding area 2 can coincide with a continuous casting machine in the case of an endless production process.

[0067] Preferably, the bridge 7 is a bridge suspended on a fixed structure 9 of the plant.

[0068] For example, the bridge 7 is a bridge with two beams 10, parallel to the longitudinal feeding axis X, and the carriage 8 can slide on two first guides 11, each first guide 11 being arranged on a respective beam 10 of the bridge 7. The bridge 7, instead, can slide on two second guides 12, orthogonal to the beams 10 and arranged on the fixed structure 9.

[0069] Advantageously, at the second operating position of the bridge 7, i.e. the one in which the welding machine 5 leaves the longitudinal roller table 4 completely clear, a maintenance area 13 of the welding machine itself is provided, which allows the operators to have an easy access also to the parts inside the machine (FIG. 2).

[0070] The longitudinal roller table 4 is of the single-channel type and comprises, or consists of, a plurality of rollers 14, preferably motorized, each roller 14 being mounted on a respective pivoting support 15. The rollers 14 are therefore oscillating rollers, i.e. retractable rollers. Advantageously, by virtue of the configuration of the welding machine of the plant of the invention, the number of rollers 14 can be less than or equal to five, preferably less than or equal to four.

[0071] The welding machine 5 is provided at the bottom with at least two preferably idle and non-motorized rollers 16, and with at least one cam element 17 adapted to lower at least two rollers 14 of the roller table 4 from a working position thereof, i.e., supporting the metal products when moving, to a retracted position during a movement of the welding machine 5 along the longitudinal feeding axis X, so that said at least two rollers 16 temporarily replace said at least two rollers 14 in the working or supporting position.

[0072] In a variant, the welding machine 5 is provided at the bottom with only two rollers 16, one input roller and one output roller, adapted to support the billet during the welding.

[0073] The rollers 16, preferably idle and non-motorized, are fixed rollers of the welding machine 5; therefore the rollers 16 do not oscillate like the retractable rollers 14.

[0074] Further rollers are not advantageously provided, in addition to the rollers 16, on board the welding machine 5.

[0075] Preferably, the rollers 14 are provided on one side thereof with an idle wheel 20 and the cam element 17 is configured to act on one or more idle wheels 20, during the movement of the welding machine along axis X, in order to lower the respective one or more rollers 14.

[0076] Preferably, in order to avoid interference between the lower part of the welding machine 5 and the roller table 4 when the welding machine has to be moved away from the axis X, translating together with the bridge 7 transversely to said axis X, at least some of the rollers 14 can be provided with a respective actuation means 18, for example a pneumatic cylinder, to lower the corresponding roller 14 before the bridge 7 passes from the first operating position along the axis X to the second operating position spaced from the axis X.

[0077] A further advantage can be obtained by providing the rollers 14 as rollers cantilevered with respect to the respective pivoting support 15 and also providing the rollers 16 of the welding machine as rollers cantilevered with respect to a base of the welding machine 5. In fact, below the rollers 16 and 14 an empty space can be provided, without any other components of the plant. This allows to reduce the dirt caused on the other components of the longitudinal roller table 4 during the welding.

[0078] It is also possible to properly contain the metal product along the axis X and avoid dirt accumulation points by making the rollers 14 and/or the rollers 16 provided with lateral edges or flaps 19 (FIG. 3).

[0079] With particular reference to the example of FIG. 1, a stretch of the rolling plant 1 of the invention is shown which extends from a heating furnace 2, only partially shown, to an emergency shears 21 placed before the entrance to the rolling train 3, served by a pinch roll 22 located upstream of said emergency shears 21.

[0080] The emergency shears 21 intervene in case of an obstruction in the rolling train 3 to divide the billet or part of billet already rolled from that still to be rolled. The pinch roll 22 is used to move the billet towards the rolling train.

[0081] Between the pinch roll 22 and the emergency shears 21 one or more deburring devices 23 are provided to eliminate the burrs at the welding joints of the metal products.

[0082] The heating furnace is of the type designed for the accumulation of metal products, also coming from several casting lines, and/or for the mixed feeding of hot and cold products and cooperates upstream with known transport and feeding means.

[0083] Downstream of the heating furnace 2, a descaler 24 can be present, fixed to the foundation plane, for example equipped with nozzles both of the fixed type and of the rotating type.

[0084] Downstream of said descaler 24 there is provided the fixed structure 9 comprising the bridge 7, and possibly also the carriage 8, on which the welding machine 5 is hanging. The fixed structure 9 is arranged above the roller table 4 and also extends along a direction transverse to the axis X.

[0085] Preferably, at the two ends of the fixed structure 9 along the axis X, i.e. at the two ends of the bridge crane 6 along the feeding direction of the metal products, there is provided a respective support unit 25 provided with at least two fixed cantilevered rollers 26, arranged along the axis X aligned to the rollers 14 of the roller table 4 when said rollers 14 are in the working or metal product support position.

[0086] When exiting the roller table 4 and downstream of the end-of-stroke of the welding machine 5, a heating system can also be provided which is adapted to uniform the temperature, in particular at the edges and/or the junction area between the metal products. Such heating system can be of the induction type.

[0087] Considering the example of the billets as a metal product to be rolled, in the plant of the invention, during the welding cycle, the welding machine 5 moves in a manner coordinated to the billet in order to carry out, during the movement, the welding between the tail of the billet directed to the rolling mill and the head of the next billet moving along the axis X.

[0088] The possible carriage 8 supporting the welding machine 5 is provided with wheels which run on the guides 11 of the beams 10 and moves with an alternating rectilinear motion, in relation to the movement of the billets to be welded, on said guides 11, for example in the form of rails. The carriage 8, and therefore the welding machine 5, has, in relation to the welding cycle, a advancement stroke correlated to the movement of the billets from an initial position to an end-of-stroke position. Similarly, in a further construction variant, the welding machine 5 can be equipped with wheels adapted to slide directly on the guides 11 of the beams 10.

[0089] The advancement of the welding machine 5 causes the lowering of at least two of the rollers 14, which constitute the motorized roller table 4 for supporting and moving the billets, and of the respective pivoting supports 15.

[0090] Such lowering in this embodiment is carried out by the cooperation between the cam element 17, integral with the welding machine during the advancement, and the idle wheels 20 of at least two rollers 14 so that the relative rollers 14 and pivoting supports 15 are lowered below the feeding axis X, and are raised again, by virtue of a counterweight 27 thereof or of a raising system, once the welding machine 5 has passed over them to constitute again a support for the advancing billets. With the lowering of the at least two rollers 14, the working or billet support position thereof is occupied by the at least two rollers 16 of the welding machine 5 itself.

[0091] Advantageously, if any billet is to be removed from the roller table 4, preferably some pneumatic cylinders 18 allow the lowering of the respective rollers 14 (FIGS. 1 and 3) so that interference between the lower part of the welding machine 5 and the roller table 4 is avoided when the welding machine 5 is moved away from the axis X, translating together with the bridge 7 transversely to said axis X, passing from the first operating position along the axis X to the second operating position spaced from the axis X.