DE19837632C2 - upsetting press - Google Patents

Description

The invention relates to an upsetting press for reducing the width of flat slabs according to the preamble of patent claim 1 .

The as a block for the production of sheet metal by hot rolling Zen slab is used by a continuous casting produced. In the continuous casting machine the Bram width can only be changed with difficulty as desired. To reduce the width of the cast flat membranes 3 immersion presses are used to cover the width of the bra adjust. Typical examples of such a calibration press are for example from JP 2-165803-A, the JP 5-123701-A, JP 3-77704-A and JP 61023543 A known.

To increase the width of a slab using an upsetting press reduce, two mechanisms are necessary, one of which a tool for reducing the slab width and moved and the other the starting positions of the Tool for the slab width. The in the  have the calibration presses disclosed above also these two types of functions.

With the upsetting press according to JP 2-165803-A that is Tool to reduce the slab width on a cross attached to the front end of a connecting rod which is reciprocated by a rotating crankshaft becomes. The tool is due to the rotation of the crank wave moved back and forth. An initial position of the work material for reducing the slab width is set, by screwing a screw / nut mechanism in Slab width direction is moved back and forth. This Mechanism is arranged in a housing that the includes rotating crankshaft and the like. Since the The crankshaft is moved in this way, it requires associated drive system a universal joint. However, since the drive motor used has a capacity of 3000 to 4000 kW is a large dimension drive unit required.

JP 5-153701-A is an improved device known in which a support section of a cure belwelle is attached to a housing to this After to eliminate part. Furthermore, in a crosshead, that is moved back and forth by a connecting rod individual screw / nut mechanism for adjustment the position of a tool. This mechanism mus eliminates the need to use the above mentioned universal joint for driving the crankshaft, so that both a size reduction and a Ge weight reduction can be achieved. The tool, to which the pressing force in a transverse pressing process is exercised, but has a great length, so that with only one screw, the center of the pressure force the screw center is often offset, which is why  Screw system falling to the right or to the left can.

In order to eliminate this disadvantage, a sliding mechanism must be provided which prevents the crosshead containing the screw from falling in the transverse direction. However, since the press load is 2,500 to 3,000 tons, a guide mechanism that prevents the crosshead from falling due to a large eccentric press load is often damaged, and the repair of the damaged guide mechanism is time-consuming and therefore the productivity is deteriorated.

In the upsetting press known from JP 3-77704-A is a swaging tool, also known as an anvil carried by two screws. If in this state two screws, one serving as a crosshead Block and a crankshaft arranged in the same plane net, the anvil is essentially stable below supports.

However, if the drive shafts of the two screws and cut the crankshaft in the same plane themselves, which is why they interfere with each other. Around To avoid mutual interference, a screw must be drive universal joint can be inclined. The crankshaft usually has a diameter of 1000 mm and performs an eccentric rotation with a Eccentric radius of approximately 100 mm. So that the Univer bypassing the crankshaft, the screws and crank the crankshaft from each other by approximately 10 m stands up. However, this is impractical. Therefore open bears the JP 3-77704-A only schematically different Drive mechanisms, without real drive mechanisms to describe.  

All of the disadvantages mentioned above are overcome by the Calibration press, which is known from JP 61023543 A, eliminated. In this publication there is a support section of a crankshaft attached to a housing, without the need for a universal joint. In one Crosshead that back and forth through a connecting rod four screws / nut mecha are moved nisms arranged, of which on each side of the verb extension bar are two each for a cutting and to avoid mutual interference with the crankshaft the. At the front ends of these screws / nuts Mechanisms are arranged on anvil attachment sliders. There the upsetting tools or anvils in the space between between the four screws acts on the screw ben no drop moment, which is why stable press machining can be executed.

However, because of the large press load, the screws and a Link rod on the back of each anvil is practiced, is not transmitted in a straight line, affects the Glider and the crosshead, in which the screws / nuts Mechanisms are arranged, a large bending moment, so that a sufficiently high rigidity can be ensured must, which resists this great bending moment, why the plant in question large dimensions and a compli adorned structure must have.

Therefore, the use of a universal joint must ver be avoided by placing the crankshaft directly on the housing is supported, also a fall of the Screws due to an eccentric load on the in the screw / nut mechanisms arranged on the crosshead must be avoided and that from the anvil to the cross the main load of the screw is transferred to the press load linig are transferred, the structure of the press load Transmission elements is simplified.  

EP 0 798 056 A1 describes a squeezing press Reduction of flat slabs known to be two to two The flat slab synchronously, horizontally movable upsetting includes tools, each on a stand the guided tool slide is attached. For one serve the starting positions of the upsetting tools Positioning devices, the two on the respective carriage attacking screw spindles with axially movable on them Nuts and a worm gear for the axial movement of the Have screw spindles. For each of the two screw spins Each lateral positioning device becomes its own ner worm gear used, which is an increased techni means effort and also a synchronization of this two worm drives to maintain the same axial movements of the two spindle nuts.

The invention has for its object a falling of screws due to an eccentric press load avoid and the structure of the pressing load transmissionab simplify cut.

According to the invention, this object is achieved by a compression press with the features of claim 1. The Unteran Sayings are on practical embodiments of the inven directed.

The compression press according to the invention contains a pair Upsetting tools that apply a pressing force to a flat slab exercise to reduce their width, be position adjusting devices for setting the starting positions of the two also referred to below as anvils Upsetting tools and reciprocating devices, the two anvils over the position adjuster approximation and distance from each other.

In the upsetting press according to the invention there are rotating ones Crankshafts over bearings in both inner walls of one closed housing arranged in such a way that it face each other and have one in between Slab located. There are connections with the crankshafts rods connected. Furthermore, the front ends of the Connecting rods connected to crossheads that procured so fen are that they are perpendicular to a side surface in Can move the slab back and forth. In a total of two screws are arranged on each crosshead net that their longitudinal axes are a horizontal center line cut the side surface of the slab vertically and that they are on either side of the longitudinal center of a die Slab width reduction section using anvils are located. The two screws are with an on drive unit that the screws normally  forward at the same time towards the slab face and can move backwards. As a drive unit for the Both screws become an orthogonal drive converter used, which is arranged between the anvil and crankshaft is and a change of direction of 90 ° with respect to the Screw shafts causes. At the front ends of the forward and backward moving screws is a Slider provided on which a slab width reduction anvil can be attached.

In an expedient embodiment of the Orthogo nal drive converters are on the shafts of the two screws worms on each side, worm gears attached, is also between the two respective Worm gears turned a snail shaft in the way sets that the respective serrations in opposite Directions are engaged. There is also an actuator provided for rotating the worm shaft.

In a further embodiment of a device to move the screws forward and backward fen floating shafts of screws on which snails wheels are attached longitudinally by a crosshead, with a snail between these two worm gears shaft is inserted and an actuator for rotating the Snail shaft is provided.

Each glider and each crosshead are each means two rows of two guide rollers each, d. H. about a total of eight guide rollers on the upper surfaces suspended from two housing supports surrounding them.

Because the crankshafts for the reciprocation of the Slab width reduction anvils on both inner walls of the housing are attached via bearings, is the use  JP 2-165803-A because of vibrations of the crankshafts were necessary, not necessary here. Because the slabs width reduction anvils each with two screws are supported, the axes of which are horizontal never perpendicular to the side surface in the transverse direction of the slab cut and the both sides of the longitudinal center of the slab width reducing section are, has the pressing force that in each anvil to When the slab width is reduced, their load center within the two screws in longitudinal direction of the slab. It also lies in the transverse Slab side surface essentially the press load center in the middle plane of the two screws. Therefore one occurs eccentric load that causes the screws to fall might not evoke on why it is possible to support the pressing load stably. Furthermore, since the press load by the screws essentially in the same The rigidity of the glider and Crossheads are not raised as in JP 610235431 A, which enables weight reduction.

Because the forward and backward movement of the screws in with respect to the transverse slab plane using a Orthogonal drive converter is executed, the one Change of direction of 90 ° in relation to the screw between each anvil and the associated crankshaft causes, the screw / crankshaft distance does not have to be made extremely long, rather a pressing force Transfer unit provided with a small footprint his. In an expedient embodiment of the Drive procedure is a snail shaft between Worm wheels used, which are attached to the two screws are attached to one side, so that the teeth of the snail shaft with the teeth of the worm wheels are in opposite engagement and the worm wheels when the screw shaft turns into the same  Direction. In this embodiment can drive two screws with one actuator be why the space can be reduced and the Drive mechanism can be simplified.

In addition, if the screw shafts like floating Waves extend longitudinally through the crosshead the worm wheels attached to the floating shafts, with a worm shaft between the worm wheels in the way is used that his teeth with the the respective toothing of both worm wheels is engaged, whereby the floating waves are made thinner can. As a result, the diameter of each worm gear can be reduced and two screws with one Low torque drive forwards and backwards be moved.

If these mechanisms are arranged in one plane, extend the slider with one attached to it Anvil and the crosshead holding the two screws are arranged upwards, two rows of feet roll in the longitudinal direction on both sides of each Extensions are arranged. That way the dead weight of the glider and that of the cross mainly through the upper surfaces of housing supports in hung up.

Because the glider and the crosshead each through A total of four guide rollers can be hung Float horizontally without descending falling stable.

Further details of the invention emerge from the Be writing referring to the accompanying drawings; show it:  

FIG. 1 is a plan view and sectional view taken along the line BB in Figure 2 of a sizing press according to an embodiment of the invention.

FIG. 2 shows a side view or sectional view along the line AA in FIG. 1;

Fig. 3 is a top view of a sizing press according to another embodiment of the invention;

Fig. 4 is a sectional view taken along line CC in Fig. 3;

Fig. 5 is a plan view of a calibration press according to yet another embodiment of the inven tion; and

Fig. 6 is a sectional view taken along line CC in Fig. 5.

Appropriate embodiments of the invention will now be described with reference to FIGS. 1 to 6. First, the description is directed to an embodiment shown in FIGS . 1 and 2.

Fig. 1 is a view of a compression or calibration press with two screws according to an embodiment of the invention, the side to the left of the center is a plan view, while the side to the right of the center is a central sectional view. More specifically, Fig. 2 is a sectional view taken along line AA in Fig. 1, while Fig. 1 is a view along the line BB in Fig. 2.

In the upsetting or calibration press according to this embodiment, a slab 1 is transported in the X direction by means of rollers 40 and 41 of a slab conveying device and then subjected to a slab width reduction process by means of the press and finally moved in the outward direction in the direction of the arrow X. The width reduction operation for the slab 1 is carried out by anvils 2 a and 2 b, which press the slab 1 from both sides. The anvils 2 a and 2 b each have an inclined surface in an input section and a surface parallel to the slab press axis in the output section. The anvils 2 a, 2 b move back and forth relative to the transverse plane of the slab 1 . The slab 1 can also be pressed on the fly while it is being transported at a constant speed. For the sake of simplicity, however, the slab is stopped in this exemplary embodiment during the press working and then transported by a predetermined distance when the anvils 2 a and 2 b have been moved away from the slab 1 .

The back and forth movement of the anvils 2 a and 2 b is carried out by rotating input shafts 19 a and 19 b of crank shafts 9 via a motor, not shown, and a reduction gear, not shown. Support shafts 15 are supported in bearing boxes 17 via bearings 16 , the crankshafts 9 each being supported by housings 18 a and 18 b. With each crankshaft 9 two connecting rods 8 a and 8 b are connected via bearings 14 . The two connecting rods 8 a and 8 b are connected at their end sections with shafts 26 which are supported on one side and which are arranged on both sides of crossheads 6 , via bearings 7 . Since the crankshaft 9 and the cross heads are 6 a and 6 b are connected in this way with each other, the cross-heads can 6 a, 6 b move in the transverse direction of the slab 1 9 upon rotation of the crank shafts.

An initial position of each anvil is set by screws 4 a and 4 b, which are arranged in each of the crossheads 6 a, 6 b. This spatial setting will now be described. In each of the crossheads 6 a and 6 b, two screws 4 a and 4 b are arranged, on which nuts 5 a and 5 b are fastened. The front end portions 22 a and 22 b of the screws 4 a and 4 b are connected to sliders 3 a and 3 b, to which the anvils 2 a and 2 b are attached. As shown in Fig. 2, the axes of the two screws 4 a and 4 b, which are arranged in each of the crossheads 6 a and 6 b, perpendicular to the side surface in the transverse direction of the slab 1 and lie in the same plane as the center line this side surface, which prevents that an eccentric load is generated by the pressing load in the vertical direction. Furthermore, the two screws 4 a and 4 b are arranged on both sides of the longitudinal center Y of the slab width reduction section in each of the anvils 2 a and 2 b. This means that the two screws are arranged so that the press load center Y lies between the two screws, thereby preventing the anvils 2 a and 2 b from tilting to the right or to the left. The initial positions of the screws 4 a and 4 b relative to the width of the slab 1 are set in the following manner. The shanks of the screws 4 a and 4 b extend as floating shafts longitudinally through the crosshead 6 a ( 6 b), spline grooves 13 a and 13 b being formed in end sections of the floating shafts extending in this way. At the keyway sections worm wheels 10 a and 10 b are attached and covered with a cover 12 so that they are rotatable on the back of the crosshead 6 a ( 6 b). A worm shaft 11 is inserted between the two worm wheels 10 a and 10 b, its teeth being in engagement with the teeth of the worm wheels in the opposite direction. The worm shaft 11 is rotated by a motor 23 attached to a base plate 26 'via a spindle 27 , by a support 29 under bevel gears 25 and a spindle 24 . The starting positions of the anvils 2 a and 2 b are set by forward and backward rotations of the motor 23 . In the position adjusting device for producing the initial position of the anvil 2 a ( 2 b), its drive mechanism is arranged in a direction perpendicular to the axial direction (slab width direction) of the screws 4 a and 4 b. More specifically, the axial direction of the screw shaft 11 and the spindle 27 , which form components of the drive mechanism, is perpendicular to the axial direction of the screws 4 a and 4 b. In this game Ausführungsbei the screw shaft 11 and the spindle 27 are arranged vertically. Thus, in the position adjustment device for the anvil 2 a (2 b) a Orthogonalantriebs converter for changing the direction of the drive shaft into a to the axial direction of the screw 4 a and 4 b perpendicular direction arranged, and therefore the drive shaft (drive unit) is the position adjusting device be introduced can without being an obstacle to the anvil reciprocating device including the crankshaft 19 and the like. As a result, the anvil 2 a ( 2 b) can be moved back and forth by means of the Positioneinstellvor direction, so that a simplification of the system and a reduction in weight are possible. After producing the starting positions of the anvils 2 a and 2 b, the crankshafts 9 are rotated, whereby both anvils 2 a and 2 b press against the slab 1 and move away from it, so that a slab width reduction process is carried out.

The slider 3 a, 3 b and the crossheads 6 a, 6 b extend upwards and are each on the top of the upper stand of the housing 18 a and 18 b over two rows each of a pair of guide rollers 20 and 21 , respectively, on both Sides of each of the sliders 3 a and 3 b or the crossheads 6 a and 6 b are arranged, suspended. The slider 3 a, 3 b and the crossheads 6 a, 6 b can roll 20 and 21 evenly through the guide.

In FIGS. 3 and 4 there is shown a further embodiment of the invention, wherein the sake of simplicity only one side is shown. From the exemplary embodiment shown in FIGS . 1 and 2, this exemplary embodiment differs only in the mechanism with which the screws 36 are moved to and withdrawn from the slab 1 , the screws 36 being accommodated in a crosshead 34 . More specifically, two screws 36 a and 36 b are arranged along a side surface in the transverse direction of the slab 1 , while in a direction perpendicular to the axial direction of the screws (vertical direction), an adjusting mechanism (spindle 24 and the like) for the screws 36 a and 36 b is arranged. The two screws 36 a and 36 b are located on both sides of the center Y of the width reduction section for the anvil 2 a at substantially the same distance. Furthermore, the screws 36 a and 36 b are arranged so that their axes lie in the central plane in the thickness direction (vertical direction) of the slab 1 , as shown in Fig. 4.

In this embodiment, the worm gear teeth 42 a and 42 b are formed as parts of the outer surfaces of nuts 37 a and 37 b, threads on a worm shaft 39 are in engagement with the worm gear teeth. Front ends 44 of the screws 36 a and 36 b are rotatably connected to a slider 32 . In such a mechanism, the screw shaft 39 is moved forwards and backwards by a motor 23 , whereby the anvil 2 a ( 2 b) is driven to move towards and away from the slab 1 . This rotation of the motor 23 takes place via a spindle 24 a, bevel gears 25 supported by a carrier 31 and a spindle 24 .

The motor 23 is supported by a base plate 30 which is attached to a housing 18 .

The nuts 37 a and 37 b are housed in the crosshead 34 so that they can be rotated using a cover 33 .

In the same way as in the system shown in FIGS . 1 and 2, the slider 32 and the crosshead 34 are each suspended on the top of housing stands 18 a, 18 b over two rows of two guide rollers each and can crosswise the slab 1 move evenly.

Although the above description has been directed to the construction of the plant on the side of the anvil 2 a, the above description can be found in the same manner to the construction of the plant on the side of the anvil 2 b application.

Yet another embodiment of the invention will now be described with reference to FIGS. 5 and 6. This embodiment differs from the above embodiments in the structure of a connecting rod 51 , the structure of a crosshead 50 and the method with which they are connected. More specifically, a front end portion 55 of the connecting rod 51 and the corresponding end portion of the crosshead 50 , which have a semi-cylindrical shape, are rotatably supported by a bearing 53 and are held by a displacement preventing member 54 . In between, a compensation cylinder, as is known from JP 2-31619-A, is arranged, which has been omitted here for the sake of simple Dar position. The connecting rod 51 is supported by a bearing 52 which is mounted on a crank shaft 9 . According to this procedure, in which the crosshead is supported by the front end section 55 of the connecting rod 51 , the anvil 2 a ( 2 b) developed press load on the crankshaft 9 without the detour via the one-sided under supported shaft in the As shown Fig. 1 and 3, transmitted straight. Therefore, the rigidity of the crosshead 50 can be low, that is, a weight reduction can be achieved.

Of course stand for the connection of the verbin different methods such as such as those available in the above-mentioned publications publications are disclosed.

More specifically, JP 61023543 A is a support ver drive known that use two semi-cylindrical bearings det, while from JP 5-123701-A and from JP 2-165803-A a support method is known that uses a spherical bearing. Of course can use any of these methods for the calibration press can be used according to the invention. The latter ver driving that uses a single spherical bearing causes a bend, however, so it is desirable that two bearings in a longitudinal plane of the slabs broad as provided in the former procedure.

Although expedient embodiments of the invention that have been described on the shafts of the two screws attached worm wheels each independently from each other by a snail shaft be driven backwards and forwards. However, since the Forward movement and withdrawal of the two screws ben must be done synchronously is a difficult process necessary, namely the direct connection of two Schnec or the mechanical connection of this type drive mechanisms or even an electrical connection  during the operation of the two motors. Although in the above embodiments of the screw shaft for Rotating the worm wheels is arranged vertically it also horizontal, d. H. perpendicular to the screws create, be arranged. In this case, too Snail shafts can be connected directly or through each be driven by a motor.

As far as the bearings 14 , 16 and 7 in FIGS. 1 and 2 and the bearings 52 and 53 in Fig. 5 are concerned, plain bearings have been used for the sake of simplicity, but of course ball or roller bearings can also be used, to reduce the frictional resistance when sliding.

The slab that is a double press subjected to screw calibration press according to the invention usually has a thickness of 150 to 270 mm, a width of 600 to 2200 mm and a length of 13 m. If the slab is a flat steel, its tempera lies tur in the press processing in the range of 1050 ° C to 1200 ° C.

In the press processing, the slab is transported at an average speed of 15 to 20 m / min. With the above embodiments, the following effects can be obtained:

• 1. In the calibrating press for reducing the width of a slab, two screws are arranged in a crosshead, which reciprocates after converting a rotary motion of a crankshaft. The axes of the two screws are perpendicular to a side surface in the transverse direction of the slab, the width of which is to be reduced by anvils, and lie in the same plane as the middle part of this slab side surface. In addition, the two screws are arranged on both sides of the longitudinal center of the slab width reduction section, in which the slab width is reduced by means of the anvils. Therefore, the screws that receive the press load are subject to an eccentric load, neither in the vertical nor in the transverse direction, which is why, despite the minimal number of only two screws, the press load can be absorbed stably.
  In addition, since the pressing load is transferred from each anvil to the screws in the same plane, the rigidity of the slider and the crosshead need not be increased. Weight reduction can thereby be achieved.
• 2. As the forward movement and the retreat movement of the two screws enclosed in the crosshead are done by an orthogonal drive converter that is perpendicular to the screw shank and between each Anvil and the crankshaft is arranged, the Ab stood shortened between the screws and the crankshaft become what favors a compact plant construction.
• 3. According to an appropriate embodiment Drive unit for moving forward and retracting the two screws enclosed in the crosshead between worm wheels attached to the two screws shafts are arranged, a screw shaft arranged, its teeth with the teeth of the worm wheels in engaging in opposite directions. Therefore, the two screws on either side of the System with only one motor forwards and backwards are moved, which is why the structure of the drive unit can be simplified.  
• 4. Since the two screw shafts that are in the crosshead are included as floating shafts longitudinally run through the crosshead and the worm wheels on the floating shafts are attached so that they the Moving screws back and forth can floating shafts be thin, which is why the worm wheel diameter can be reduced. Consequently, that can Drive torque can be reduced.
• 5. Each slider, to which an anvil is attached, and each crosshead, which encloses the two screws, are extended upwards, with two rows of four guide rollers are arranged overhanging on both sides of each such elongated section, the weight of each concerned Component on the upper side of housing stands in a suspended manner is supported by these guide rollers. There is therefore no risk of the components falling down, which is why a stable back and forth movement is possible.
  According to the invention, not only the falling of screws due to an eccentric press load can be prevented, but it is also possible to simplify the press load transfer section.

Claims (7)

1. Upset press for reducing the width of flat slabs with
two compression tools ( 2 a, 2 b) which can be moved horizontally in opposite directions on both sides of the flat slab ( 1 ) and which are fastened to a tool slide ( 3 a, 3 b) guided on housing stands ( 18 ),
Drive devices ( 8 , 9 ) for moving the upsetting tools ( 2 a, 2 b) back and forth,
Positioning means (4 a, 4 b, 11, 13 a, 13 b) for adjusting the initial position of the upsetting tools, the two time on jewei carriage (3 a, 3 b) engaging screw spindles (4 a, 4 b) with it, axially movable nuts ( 5 a, 5 b) and a worm gear ( 11 ) for axially moving the screw spindles ( 4 a, 4 b),
characterized in that
the worm ( 11 ) of the worm drive is arranged vertically between two worm wheels ( 10 a, 10 b) seated on the screw spindles ( 4 a, 4 b) and is in engagement with both worm wheels ( 10 a, 10 b). 2. Upset press according to claim 1, characterized in that the respective two screw spindles ( 4 a, 4 b) are arranged rotatably and axially movable in a common crosshead ( 6 ). 3. Compression press according to claim 2, characterized in that the crosshead ( 6 ) via connecting rods ( 8 a, 8 b; 55 ) is connected to a rotatably driven crankshaft ( 9 ). 4. Upset press according to claim 2 or 3, characterized in that the tool slide ( 3 a, 3 b) and the crossheads ( 6 a, 6 b) by means of rollers ( 20 , 21 ) on longitudinal members of the housing stand ( 18 a, 18 b) are movable. 5. Compression press according to one of the preceding claims, characterized in that the screw ( 11 ) on a vertical spin del ( 27 ) of a bevel gear ( 25 ) is attached. 6. Compression press according to one of the preceding claims, characterized in that the worm wheels ( 10 a, 10 b) by means of a spline and axially displaceable on the screw spindles ( 4 a, 4 b) are arranged. 7. Compression press according to one of claims 1 to 5, characterized in that the nuts on the screw spindles ( 4 a, 4 b) are designed as worm wheels ( 37 a, 37 b).