The present invention relates to an apparatus and to a method for the expansion of elongated metal elements which move in the longitudinal direction and are areal at least regionally. In particular areal metal elements such as are described in German patent application 102 59 307.8 should be expanded using the apparatus and the method in accordance with the invention.
The areal metal elements described in this prepublished German patent application are used, for example, for the manufacture of sectional elements, in particular of upright sections or plaster sections. The metal elements in this connection have incisions in their mid regions which are shaped such that, when the metal elements are drawn apart, metal regions present between the incisions are folded over so that ultimately a widening of the metal element takes place. Wider metal elements can thus be produced with a reduced metal consumption by this folding procedure. The cutting patterns required for the folding procedure can be of the most varied type. A plurality of such different cutting patterns are described in German patent application 102 59 307.8 and are in particular shown in
It is, however, problematic to carry out the expansion of such elongated metal elements which are areal at least regionally with an economically justifiable effort and so to achieve an economically sensible manufacture of the sectional elements. Since the costs of such sectional elements are mainly determined by the material costs, a widening of the metal element is admittedly generally desired with a reduced material requirement, but the gains recorded by the material saving many not be cancelled out again by increased costs in the production of the sectional elements. An economically worthwhile manufacture is the more difficult in this connection since corresponding sectional elements represent a mass produced article of which thousands of kilometers are produced annually and which is produced at a very high speed (for example 100 to 150 m/min). An apparatus for the expansion of corresponding areal metal elements must therefore be capable of ensuring a correspondingly high throughput with a simultaneous high reliability.
It is therefore an object of the invention to provide an apparatus and a method for the expansion of elongated metal elements which move in the longitudinal direction, which are areal at least regionally and which ensure a large throughput with a simultaneously simple and reliable design. The apparatus and the method should in particular be usable in continuous operation.
This object is satisfied in accordance with the invention by an apparatus of the initially named kind which comprises at least two mutually oppositely disposed clamping portions of which one is arranged and configured for the holding by clamping of a first longitudinal side of the metal element and the other is arranged and configured for the holding by clamping of a second longitudinal side disposed opposite the first longitudinal side of the metal element, with the clamping portions each being provided at a carrier unit by which the clamping portions are moved apart automatically substantially perpendicular to the direction of movement of the metal element during the forward movement of the metal element. In the method in accordance with the invention, a first longitudinal side of the metal element is clamped in a holding manner into a first clamping portion and a second longitudinal side of the metal element is clamped in a holding manner into a second clamping portion disposed opposite the first clamping portion, with the clamping portions each being provided at a support unit by which the clamping portions are moved apart automatically substantially perpendicular to the direction of movement of the metal element during the forward movement of the metal element.
The mutually oppositely disposed clamping portions thus form an expansion region for the metal element between them in which the spacing between the mutually oppositely disposed clamping portions increases. The expansion of the metal element takes place in the expansion region by enlarging the lateral spacing between the mutually oppositely disposed clamping portions which each draw the mutually oppositely disposed longitudinal sides of the metal element apart.
The apparatus in accordance with the invention is very robust thanks to its simple design and thereby also suitable for a high throughput. It is furthermore achieved by the clamping portions that the expansion of the moving metal element can take place in continuous operation so that the required throughput is ensured. It is generally, however, also possible for the expansion to take place in intermittent operation, for example also in a progressive tool. It is thus not absolutely necessary in the sense of the present application for the metal element to move forward simultaneously with the expansion. The forward movement of the metal element in intermittent operation, for example, includes repeating stationary phases in which the expansion can take place. The expansion during a stationary phase in intermittent operation is thus also to be understood as an expansion during the forward movement in the sense of the present invention since the individual stationary phases also represent parts of the total forward movement of the metal element. With a correspondingly short length of the metal element, it can also be expanded simultaneously over its total length, i.e. in plate production. In this case, the forward movement includes the infeed, the stationary phase during which the metal element is expanded and the outfeed of the metal element.
A preworking of the longitudinal sides of the metal element is not necessary due to the use of clamping portions. The longitudinal sides of the metal element do not need to have any folds or other engagement elements into which, for example, drawing elements engage for the drawing apart of the metal element. The longitudinal sides can be made completely smooth due to the clamping in accordance with the invention of the longitudinal sides of the metal element, whereby the application possibilities of the expanded metal elements are very wide and complex pre-treatments of the metal element associated with additional costs for the production of engagement points can be dispensed with. The clamping portions can be made such that a free longitudinal strip of 0.5 to 5 mm (for example approximately 1, 1.5, 2 or 3 mm) is already sufficient at both longitudinal sides of the metal element to clamp them in each case into the clamping portions and to draw the metal element apart.
In accordance with an advantageous embodiment of the invention, the clamping portions each comprise a contact region and a clamping region, with the longitudinal sides of the metal element being able to be clamped between the contact region and the clamping region. The clamping region can advantageously be formed by an eccentric member. The formation of the clamping region by an eccentric member also makes the whole apparatus very robust and simultaneously simple since the eccentric member can be supported at a supporting section of the clamping portion such that the clamping force generated by the eccentric member automatically increases on the moving apart of the clamping portions. The higher the force acting on the metal element thus is on the moving apart, the more firmly the metal element is clamped in the clamping portion.
It is generally also possible for the clamping portion to be pre-tensioned with respect to the contact region by spring bias. Any possible suitable type of spring can be used, for example helical springs, gas compression springs or other springs. A hydraulic, pneumatic, electric, magnetic or other mechanical pre-tensioning of the clamping portion with respect to the contact region and any other suitable type of pre-tensioning are also generally conceivable. Such a pre-tensioning is also sensible in connection with an eccentric design of the clamping region when the eccentric member does not yet unfold the full clamping force by the pre-tensioning, for example on the gripping of the metal element. Due to the pre-tensioning, the eccentric member can automatically be brought so far into the clamping position that ultimately the holding of the metal element is achieved only on the basis of the clamping force.
In accordance with a further preferred embodiment of the invention, the clamping portions each comprise a plurality of clamping elements. The development of the expansion of the metal element can be set in a simple manner by the division of the clamping portions into a plurality of clamping elements.
In accordance with a further advantageous embodiment of the invention, a control section, in particular in the form of a cam track guide, is provided with which the clamping elements can be brought automatically from a release position into a clamping position on the movement of the metal element. In a similar manner, a further control section can be provided with which the clamping elements can automatically be brought back from the clamping position into the release position on the further movement of the metal element after the expansion of the metal element. After the release of the metal element, the clamping elements can remain in their release position or can again be brought into the clamping position, but without a metal element clamped in. It must only be ensured that the clamping elements are in the release position shortly before the clamping elements again come into contact with the metal element. Said release position can be achieved again by corresponding control sections.
In particular the control sections made for the movement of the clamping elements into the clamping position can be made so movable that different positions of the clamping elements can be compensated which are produced, for example, by different thicknesses of the metal elements or by a penetration of the metal elements into the clamping elements of different amounts. The control sections can, for example, be movably supported hydraulically or against a spring force.
The carrier unit is preferably made as a circulating carrier unit, in particular as an endless circulating carrier unit. It is ensured by the configuration of the carrier unit as a circulating carrier unit that a metal element of any desired length can be expanded using the apparatus in accordance with the invention.
In accordance with a further advantageous embodiment of the invention, at least two circulating carrier units are arranged at each longitudinal side of the metal element, with each longitudinal side of the metal element being respectively clamped between at least two carrier units. With a horizontally arranged metal element, each longitudinal side of the metal element can thus be clamped, for example, between a carrier unit arranged above the metal element and a carrier unit arranged beneath the metal element. The clamping portions can thus preferably be made integrally with the carrier unit in this case. Generally, however, a separate configuration of the clamping portions is also possible.
In accordance with a further preferred embodiment of the invention, at least one circulating carrier unit is arranged at each longitudinal side of the metal element, with each longitudinal side of the metal element being respectively clamped in the clamping portions provided at the circulating carrier units. In this case, the longitudinal sides of the metal element are thus not clamped between two different carrier units, but each longitudinal side is rather respectively clamped in clamping portions which are, for example, arranged extending at carrier units to the side of the metal elements along its longitudinal sides.
The carrier units are preferably made as a track conveyor. It can, for example, be made as a steel tread. Generally, a design as a band, as a belt or as another peripheral unit, in particular suitable for clamping, is also conceivable.
In accordance with a further advantageous embodiment, a run-in region is provided for the metal element in which the mutually oppositely disposed clamping portions have substantially a constant spacing from one another, with an expansion region adjoining the run-in region in which the spacing between the mutually oppositely disposed clamping portions increases. It is ensured by the constant spacing of the clamping portions in the run-in region that the metal element can first be securely gripped by the clamping portions without any other forces acting on the metal element, in particular in the lateral expansion direction. Only after the metal element has been securely gripped by the clamping portions after running through the run-in region does the expansion of the metal element take place in the expansion region by enlarging the lateral spacing between the mutually oppositely disposed clamping portions which each draw apart the oppositely disposed longitudinal sides of the metal element. The spacing of the mutually oppositely disposed clamping portions preferably increases substantially continuously in the expansion region so that a continuous strain on the metal element is ensured which results in a uniform expansion of the metal element.
In accordance with a further preferred embodiment of the invention, the carrier units are configured as rotating disks, tires or wheels inclined with respect to one another. The clamping portions can each be formed in the outer marginal region of the rotating disks, tires or wheels. With this embodiment, in particular the contact regions of the clamping portions can be formed by the peripheral surfaces of the rotating disks, tires or wheels.
In this embodiment, the expansion of the metal element takes place by the angular position of the rotating disks, tires or wheels in that the metal element is clamped tight by the clamping portions in the region of the marginal regions of the carrier units inclined toward one another, is drawn apart by the peripheral surfaces of the rotating carrier units running apart and is released by the clamping portions again before the maximum spacing between the mutually inclined rotating carrier units is exceeded.
Further advantageous embodiments of the invention are recited in the dependent claims.
The invention will be described in more detail in the following with reference to embodiments and to the drawings; there are shown in these:
The metal element 1 is already described in the German patent application 102 59 307.8 to which reference is explicitly made.
The sections 3 are arranged such that the halves 4, 5 of the metal element 1 shown above or beneath the sections 3 in
Correspondingly expanded metal elements can be used, for example, for the manufacture of sections such as are used e.g. as edge protection (
To be able to expand metal elements 1 known per se at high speed, as shown in
The metal element 11 is provided with cuts in accordance with
The apparatus 13 shown in
The track conveyors 15 are made as endless track conveyors and are guided rotatably around deflection rollers 18 in accordance with arrows 17. Two or more deflection rollers can be provided in dependence on the design.
Generally, the deflection rollers 18 can be driven or only rotate freely around their respective axes.
Clamping elements 19 are in each case arranged at the outwardly facing sides of the conveyor members 16 and move in the arrow direction 17 together with the conveyor members 16. The track conveyors 15 thus form carrier units for the clamping elements 19, whereas the clamping elements 19 respectively provided at a track conveyor form a clamping portion of this track conveyor.
The two track conveyors 15 are arranged such that a run-in region 20 and an expansion region 21 adjoining it are formed. In the run-in region 20, respectively mutually oppositely disposed clamping elements 19 facing toward the longitudinal axis 14 of the metal element 11 have the same spacing from one another which corresponds approximately to the width of the metal elements 11 not yet expanded. In the expansion region 21, the spacing of mutually oppositely disposed clamping elements 19 enlarges continuously, as can be recognized from
The metal element 11 shown in
In the expansion region 21, the metal element 11 is expanded by the clamping elements 19 moving apart in accordance with arrows 24 in a direction substantially perpendicular to the longitudinal axis 14 until it has the desired width at the discharge end of the expansion region 21. After the expansion has taken place, the metal element can, for example, be rolled or pressed flat in a rolling process, whereby it receives its final width and the folding points produced in the metal element on the expansion are leveled. Generally, this can also take place by an otherwise suitable pressing process (e.g. in a stroke press).
Both the holding tight of the longitudinal sides 22, 23 of the metal element at the start of the run-in region 20 and the release of the widened metal element at the end of the expansion region 21 is effected by control sections, not shown, which cause an automatic closing and opening of the clamping elements 19. Corresponding control sections, which bring the possibly closed clamping elements 19 into the release position so that the metal element can penetrate securely into the clamping elements 19 in the run-in region 20 and can be gripped by them, can also be provided before the start of the run-in region 20. For example, the corresponding control sections can be formed by cam track guides which are provided before and at the start of the run-in region 20 or at the end of the expansion region 21 and cooperate with the clamping elements 19 in a corresponding manner. Generally, the control could also take place, for example, by limit switches or in another suitable manner. If the run-in region 20 is omitted, the control sections at the inlet side can accordingly be provided at the inlet of the expansion region 21.
The track conveyors 15 form carrier units for the clamping elements 19 and effect a movement apart of the clamping elements 19 in the expansion region 21 due to their shape shown in
A special embodiment of the clamping elements 19 is shown in more detail in
The clamping element 19 comprises a base element 25 which is fastened to the outer side of the conveyor member 16, as can be recognized from
Furthermore, the clamping element 19 comprises an eccentric member 27 which is rotatably supported around an axis 28 at the limb of the U-shaped base element 25 shown at the top in
The eccentric member 27 is rotatably supported off-center around the axis 28 such that, on a rotation of the eccentric member counter-clockwise in accordance with
As can be recognized from
By the use of an endless carrier unit with automatic clamping elements, the expansion apparatus in accordance with the invention is very simple and robust in design and can in particular expand metal elements moving at high speed from a first width to an enlarged second width.
A modified embodiment of the invention is described in
In the embodiment in accordance with
The conveyor members 16 are guided around horizontally arranged deflection rollers 37 which are either drivable or freely rotatable.
The longitudinal sides 22, 23 of the areal metal element 11 are each arranged between the upper and lower track conveyors 35, 36 which are arranged at both sides and which are arranged so close to one another that the longitudinal sides 22, 23 of the metal element 11 are clamped between the upper and lower track conveyors 35, 36. In this embodiment, the outer sides of the conveyor members 16 thus directly form clamping portions 38 for the metal element 11.
As can in particular be recognized from
As in the embodiment in accordance with
The embodiment in accordance with
The respective outer marginal regions of the disks 39, 40 are configured as clamping portions 43, 44, with the peripheral surfaces of the disks 39, 40 forming contact regions 45, 46 for the areal metal element 11.
The longitudinal sides 22, 23 of the metal element 11 contact the contact regions 45, 46 of the disks 39, 40 and said metal element is guided around the disks 39, 40 in accordance with arrows 47, 48.
The metal element 11 is pressed toward the contact regions 45, 46 via clamping elements 49, 50 provided at the marginal regions of the rotating disks 39, 40 and is thereby clamped tight between the clamping elements 49, 50 and the contact regions 45, 46.
Due to the mutually inclined arrangement of the rotating disks 39, 40 and to the expanding spacing of the edges of the rotating disks 39, 40 shown at the top in
In a similar manner as with the previously described embodiments, the clamping elements 49, 50 can be adjusted automatically via cam track guides from their release position into the clamping position and back. Corresponding cam track guides can, for example, be provided between the metal element 11 and the rotating disks 39, 40 in the region of the starting contact points and end contact points disposed at the top and at the bottom respectively in
The clamping element 49 (as well as the clamping element 50 not described any further in the following) has a base part 51 which is fastened to the outer side of the rotating disk 39. A displaceably and pivotably supported clamping lever 52 is provided at the radially outwardly disposed side of the base part 51 and is located in the clamping position in
The clamping lever 52 is pressed upwardly in accordance with an arrow 54 in
The clamping lever 52 is furthermore displaceably supported in accordance with two arrows 56, 57, with the displacement being able to take place, for example, by a cam track guide which engages into a groove 58 provided at the upper side of the clamping lever 53. On a displacement of the clamping lever 52 into the release position in accordance with
A specific aspect of the clamping element 49 is shown again in detail in
If, in contrast, the intermediate lever 58 is pivoted downwardly against the gas compression spring 55 via a cam track guide engaging at its free end 61, the clamping lever 52 is released for a horizontal displacement which can be controlled via a cam track guide engaging into the groove 58.
To prevent a kinking of the metal element 11, it is guided in each case in a loop-like manner via guide pulleys 62 in the run-in and run-out regions so that the metal element 11 comes into contact with the peripheral surfaces of the disks 39, 40 forming the contact regions 45, 46 and also leaves them again substantially tangentially.
After the clamping elements 19 defined by the second control section 72 have been brought into their clamping position, the metal element 11 is drawn apart during the running through of the expansion region 21. At the end of the expansion region 21, the cam spigots 33 run toward the radially outwardly disposed cam surface of the third control section 73 by which they are again tilted radially outwardly so that the clamping elements 19 are moved into their release position and the metal element 11 is automatically released by the clamping elements 19. On the return to the start of the expansion region 21, the clamping elements 19 can be either in their release position or in the clamping position.
Number | Date | Country | Kind |
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10 2006 010 795.0 | Mar 2006 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP07/01734 | 2/28/2007 | WO | 00 | 2/5/2009 |