EP1704940A1 - Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis - Google Patents

Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis Download PDF

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Publication number
EP1704940A1
EP1704940A1 EP05405255A EP05405255A EP1704940A1 EP 1704940 A1 EP1704940 A1 EP 1704940A1 EP 05405255 A EP05405255 A EP 05405255A EP 05405255 A EP05405255 A EP 05405255A EP 1704940 A1 EP1704940 A1 EP 1704940A1
Authority
EP
European Patent Office
Prior art keywords
transverse
wire
guide
wires
positioning
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP05405255A
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German (de)
English (en)
Inventor
Hansjörg Müller
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
HA Schlatter AG
Original Assignee
HA Schlatter AG
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by HA Schlatter AG filed Critical HA Schlatter AG
Priority to EP05405255A priority Critical patent/EP1704940A1/fr
Priority to ES06405111T priority patent/ES2306408T3/es
Priority to EP06405111A priority patent/EP1704941B1/fr
Priority to DK06405111T priority patent/DK1704941T3/da
Priority to AT06405111T priority patent/ATE390970T1/de
Priority to DE502006000544T priority patent/DE502006000544D1/de
Priority to US11/384,560 priority patent/US20060226127A1/en
Publication of EP1704940A1 publication Critical patent/EP1704940A1/fr
Withdrawn legal-status Critical Current

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21FWORKING OR PROCESSING OF METAL WIRE
    • B21F27/00Making wire network, i.e. wire nets
    • B21F27/08Making wire network, i.e. wire nets with additional connecting elements or material at crossings
    • B21F27/10Making wire network, i.e. wire nets with additional connecting elements or material at crossings with soldered or welded crossings
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21FWORKING OR PROCESSING OF METAL WIRE
    • B21F23/00Feeding wire in wire-working machines or apparatus
    • B21F23/005Feeding discrete lengths of wire or rod

Definitions

  • the invention relates to a positioning device for positioning transverse wires for a mesh welding machine.
  • the invention further relates to a method for inserting transverse wires in a mesh welding machine, a control device for a mesh welding machine and a computer program product for such a control device.
  • transverse wires which are successively fed transverse wires to be welded to a series of spaced longitudinal wires, are well known. Often, the transverse wires should be positioned in a predetermined transverse position (relative to the longitudinal wires) prior to welding. By an exact positioning can be achieved, for example, that all transverse wires have a predetermined lateral projection over the longitudinal wires or flush with the longitudinal wires. A cutting of transverse wire ends with too much supernatant subsequent to the welding process is thus unnecessary.
  • a transverse positioning is also necessary if the transverse wires are conveyed with different transverse positions or in the manufacture of complex grids, if different lengths of transverse wires and / or transverse wires are to be welded with different transverse positions with the longitudinal wires.
  • the disclosed device With this device, only protruding ends of successive transverse wires can be aligned on one side; further positioning is not planned.
  • the disclosed device is thus less flexible. In addition, it can only achieve a low positioning speed.
  • the DE-OS 2,133,845 shows a mesh welding machine, which transverse wires of different lengths can be supplied.
  • driven transport rollers are provided for feeding the transverse wires, wherein the drive with a Actuator for the cross wire feed length is connected, so that when the desired cross wire welding position, the transport rollers can be stopped.
  • the position accuracy achievable with this device and the possible speed of positioning are limited.
  • the device is also structurally complex.
  • the EP 0 241 449 A1 (ECG) describes a multi-point resistance welding machine, with which also grids can be produced, which have transverse wires of different lengths and which are arranged in any transverse position.
  • ECG electrowetting-on-strength
  • two feeders for transverse wires are provided, of which at least one in a guide transversely to the feed path of the longitudinal wires is displaceable.
  • This device allows the positioning of transverse wires of different lengths. But if successive transverse wires of the same length to be welded in different transverse positions, a shift of the entire displaceable feeder is necessary, whereby the achievable speed is severely limited.
  • This device is structurally complex and also not suitable for a larger number of different cross-wire lengths.
  • the DE 30 25 320 C2 shows an apparatus for feeding bars with a feed member which abuts against one end of the bars and is movable along the conveying direction. At the other end, the rods abut against a likewise movable in the conveying direction stop, which is held by a restoring force in an initial position and is coupled to a device for measuring the position of the wire.
  • the stopper is coupled to a piston rod which slides in a cylinder of a pneumatic piston-cylinder unit. The supply of the unit with compressed air is controlled so that a constant bias is applied to the stop.
  • This device is expensive. It is also less flexible, because the bars can only move in one direction, and in a change in the grid geometry conversions are necessary. Complex grids can not be manufactured with it.
  • the object of the invention is to provide a the aforementioned technical field associated positioning for positioning of cross wires for a mesh welding machine, which is simple in construction and allows precise and fast positioning of the cross wire and a high flexibility in the production of lattice.
  • the positioning device has a guide for receiving one of the transverse wires and two freely movable slides for contacting the transverse wire received in the guide on two opposite end sides.
  • the slides are designed in such a way that the transverse wire stored in any desired position in the guide can be moved by the slides along the guide into any predetermined delivery position.
  • the slides are preferably freely movable at least along substantially half the length of the guide. A maximum Flexibility is achieved when the slides are free to move along the entire length of the guide.
  • Such a device can be easily converted to a two-lane operation. If two grids with widths are to be produced in an existing mesh welding machine, which at most add up to the maximum grating width of the machine, then two grids can be produced in parallel next to each other.
  • the inventive device can be modified for this purpose in a simple manner by a fixed two-sided stop is mounted at the corresponding position of the guide between the bars to be produced. The cross bars of the two grids can then be moved by the two lateral slides each to the fixed stop.
  • cross-wire is intended in the context of this description rod-like, d. H. comprise substantially straight elements with a substantially constant cross-section, which are welded in the mesh welding machine with a plurality of longitudinal wires, regardless of their cross-section (ie, in particular transverse wires of larger cross-section includes, which are also referred to as cross bars).
  • the device is controlled such that both slides are moved to lateral initial positions prior to the introduction of the transverse wire in the guide.
  • the distance between the slides in these initial positions is a length of the transverse wire to be introduced plus a maximum expected positional tolerance of the transverse wire.
  • the slides are thus positioned so that the transverse wire is securely inserted between the two slides in the guide.
  • the necessary displacement of the slide is minimized, which on the one hand reduces the time required and on the other hand, the mechanical load on the slide and its actuating mechanism.
  • a maximum expected cross-wire length is used, ie the predetermined cross-wire length plus a maximum expected length tolerance.
  • the device according to the invention can be operated such that the slides are moved to the opposite lateral ends of the guide prior to the introduction of the transverse wire, so that each transverse wire which is introduced into the guide at any receiving position moves to the predetermined dispensing position can be.
  • the control of the device is performed by a control device, which is integrated, for example, in the machine control of the mesh welding machine.
  • the control device is controlled in particular by a computer program product, which brings the described here, the inventive method for inserting transverse wires to expiration.
  • the slides are each coupled to a servo axis. This allows a simple, fast and extremely precise control of the positioning. Servo axes can be easily operated by computer controls.
  • the coupling of the slides to the servo axes preferably takes place via endless coupling means, in particular toothed belts. These are lightweight, cost-effective and allow large displacement paths with high dynamics. Alternatively, other coupling means are provided, for example spindles.
  • one of the slides has a spring-mounted stop to compensate for length tolerances of the transverse wires.
  • the length tolerances of the transverse wires can be accommodated by increasing the initial slider spacing by the expected maximum tolerance.
  • the slides are moved inwards, ie toward each other, to contact the transverse wire and then move it to the predetermined position. If the transverse wire has a greater length than specified due to length tolerances, then at least one of the slides can no longer be moved further in the case of fixed stops before it reaches its predetermined target position.
  • the spring-mounted stop can record this residual path, so that both slides can reach the predetermined end position.
  • the slides do not hit on the cross wire, but it is only the weak retroactive spring force transmitted to the drives. These are therefore not burdened excessively.
  • the end positions of the slides are preferably set so that they correspond to the predetermined cross-wire length minus the maximum expected length tolerance.
  • the spring travel of the spring-mounted stop corresponds then (at least) twice the maximum length tolerance. When positioning a crosswire of correct length, exactly half the spring travel of the stop is thus used up. Both slightly longer and slightly shorter cross wires can be precisely positioned without the need for adjustment of the control.
  • one of the slides may have the spring-loaded stop or both slides, depending on whether the wire center or a specific wire end should come to rest in a predetermined position for wires with undersize or excess length.
  • both slides are preferably equipped with a sprung stop.
  • the slides are thus designed to be replaceable, so that when changing over to the two-lane operation of the slide can be replaced without sprung stop.
  • the stops of the slide are fixed, and the length tolerances are taken into account in other ways.
  • the slide drive itself or coupling means between the drive and the slides can, for. B. be able to compensate for the tolerance.
  • the force increase upon contacting the crosswire can be detected and the sliders stopped accordingly, or the effective length of the crosswire is determined by sensors prior to performing the slider movement and taken into account in moving the sliders.
  • one of the slides on a trigger mechanism which is designed such that at a predetermined release force on the slide a cross-wire contacting element triggered, ie mechanically separated from the slider, z. B. notched, is.
  • a cross-wire contacting element triggered ie mechanically separated from the slider, z. B. notched
  • the release mechanism with a spring-mounted Stop (as described above) combined.
  • the spring-mounted stop may be repelled regularly, while the triggering of the trigger mechanism may only occur in very rare cases, namely, if the length of the introduced cross-wire smooth further operation of the welding machine would be impossible anyway.
  • a trigger mechanism may be provided, which is arranged at a different location of the positioning device.
  • the increase in force when contacting the transverse wire can be detected and the process run can be stopped accordingly, or the effective length of the cross-wire is determined by sensors prior to carrying out the slide movement, so that the process can be interrupted.
  • the guide is advantageously designed as a transverse trough.
  • the cross wire is securely held and can be easily moved, for example, by slide with adapted to the trough attacks in the transverse direction.
  • the trough defines by its shape a deployment position, which - regardless of the cross wire diameter - is given by the area of lowest possible positional energy. As a result, certain tolerances in the introduction of the transverse wire are allowed by this automatically passes into this deepest region of the trough due to gravity.
  • the trough does not have to be formed continuously, but may be formed for example by a plurality of trough-like support elements.
  • the guide is formed as a flat, horizontal or inclined surface.
  • a device for inserting transverse wires into a mesh welding machine preferably comprises a positioning device as described above, which is arranged at a distance from a welding position of the mesh welding machine.
  • the final transverse positioning of the control wires only takes place at the welding position.
  • the welding process can thus take place only when the transverse positioning has taken place.
  • the duration of a cross-wire welding cycle is thus determined by the required welding time and additionally the time required for the transverse positioning. This reduces in conventional Mesh welding machines the throughput.
  • the known solutions also require a complex and unwieldy construction, because in a small space both the welding tools and the means for the transverse positioning of the transverse wire must be accommodated.
  • the introduction of the transverse wire into the positioning device which is distanced from the welding position and the subsequent transverse positioning of the transverse wire in the guide can take place parallel to the welding process of a preceding transverse wire and do not lead to an extension of the welding cycle. Only after the transverse positioning of the transverse wire is transported to the welding position. Immediately after inserting the cross wire in the welding position, d. H. after contacting the longitudinal wires to be welded to the transverse wire, the welding operation can be carried out. This increases the possible throughput of the welding machine.
  • transverse wire can thus be stored in principle with any position on the guide, after which he is moved to the predetermined position.
  • no high demands are placed on the upstream feeder for the transverse wires.
  • the device for inserting transverse wires also advantageously comprises a transport device for transporting the positioned transverse wire from the guide into the welding position, which is designed such that the transverse position of the transverse wire is maintained during transport.
  • a precise positioning of the cross wire in the guide is maintained even during transport.
  • the combination of the positioning device according to the invention with such a transport device thus enables a flexible and extremely precise positioning of the transverse wires, without the throughput of the mesh welding machine being impaired.
  • the transport device comprises a movable gripper for gripping, transporting and depositing the transverse wire.
  • a movable gripper for gripping, transporting and depositing the transverse wire.
  • This is preferably in a vertical Plane movable, which is parallel to the longitudinal direction of the mesh machine, and is not moved during the transport process out of this plane.
  • the gripping mechanism of the gripper is also designed so that the cross wire with respect to the gripper can not be moved transversely, as long as it is detected by the gripper. This ensures that the transverse position of the cross wire is maintained during the gripping, transporting and depositing of the cross wire.
  • a further device is provided for the insertion of the transverse wires.
  • the next transverse wire of the guide can be supplied as soon as the gripper has taken a guide wire located in the positioned cross-wire and removed from the guide.
  • a plurality of grippers are provided, which can detect the transverse wire along its axis.
  • the transverse wire is transported out of the guide, for example, along an inclined plane to the welding position, wherein the positioning device comprises lateral inclinations for the inclined plane, which ensure that during the sliding down of the transverse wire no displacement in the transverse direction can take place.
  • the transport device may comprise, for example, a conveyor belt.
  • the transverse wire positioned in the guide can be brought into the welding position in another way. For example, it may fall freely from the guide along an obliquely downwardly extending plane into the weld line.
  • transverse positions can be specified for successive cluer wires.
  • This allows the production of gratings, which comprise transverse wires of different lengths and / or with a different transverse positioning.
  • the initial position of the slider is determined in such a case, for example, by starting from a predetermined position of the center of the transverse wire, the slider on both sides each half the cross-wire length (with length tolerance, see above) plus half the maximum expected position tolerance from the center position are.
  • the device is controlled so that the transverse position of the wires is constant during a production run.
  • a mesh welding machine with a positioning device may comprise two or more devices arranged for the insertion of the transverse wires upstream of devices for providing transverse wires, wherein the transverse positions of these devices are different. Thanks to the flexible positioning device introduced by the facilities in the leadership of the positioning transverse wires can be moved regardless of their receiving position in any predetermined dispensing positions. This allows many configurations of a plurality of devices, they can be arranged not only one behind the other but also for example in the transverse direction next to each other, whereby the space requirement of the cross wire feeds can be reduced in the machine longitudinal direction.
  • the requirements for the transverse positioning of the transverse wires and thus to the position of devices for providing transverse wires compared to known solutions are significantly reduced, so that in particular accounts for a precise adjustment of the transverse position-giving elements of the means for providing the transverse wires can.
  • a mesh welding machine with a positioning device may further comprise a system for producing the transverse wires from a wire supply.
  • This is the device for inserting the cross wires upstream.
  • the system for generating the transverse wires is capable of producing a sequence of transverse wires of arbitrary lengths.
  • round grids eg grill grids
  • the length of cross wire to cross wire first increases and then decreases can be manufactured easily and without material loss.
  • the system for generating the transverse wires is arranged such that cut transverse wires are deposited directly from the system in the guide for positioning.
  • the positioning device can be controlled so that the transverse wires are always "picked up” regardless of their length at the same location and then moved to the predetermined transverse position.
  • a cutting device (shears) of the system for generating the transverse wires can thus remain stationary even at different predetermined discharge positions of successive transverse wires.
  • transverse wires for use with the inventive mesh welding machine is suitable, for example, the wire straightening and cutting Syrocut the H. A. Schlatter AG, Schlieren, Switzerland.
  • FIG. 1 is an oblique view of the positioning device according to the invention for positioning transverse wires for a mesh welding machine.
  • FIG. 2 shows a vertical cross section through the positioning device 100 with the guide 101 parallel to the longitudinal axis of the mesh welding machine. The longest extent of the guide 101 extends in the transverse direction (with respect to the mesh welding machine).
  • the guide 101 is formed by a plurality of well elements 102.1... 102.16, which together form a transversely extending well 103 in which a transverse wire can be received.
  • the trough parts 106 and the guide parts 107 of the trough elements 102.1... 102.16 are screwed to a transversely extending carrier 108.
  • the trough has a V-shaped cross-section, ie it is formed by two tapered walls 104, 105 formed, of which the rear wall 104 is approximately vertical and the front wall 105 is inclined at an angle of approximately 40 ° to the vertical.
  • housings 111, 112 of the positioning device 100 are arranged.
  • Each of the housings 111, 112 comprises a servomotor 113, 114. These are coupled via drive shafts rotatable about vertical axes, each with a circulating toothed belt 115, 116.
  • the deflection pulleys for the toothed belts 115, 116 are arranged rotatably about a vertical axis in the housing 111, 112 opposite the servo motor 113, 114.
  • a rail 117 is fastened between the housings 111, 112. This has an H-shaped profile with recesses on the top and bottom.
  • Two slides 120, 140 are movable on the rail 117 in the transverse direction.
  • the slides 120, 140 (as shown diagrammatically in FIG. 2 by means of the slide 120) have two opposite rollers 121, 122 which run in the recesses of the rail 117.
  • the first slider 120 is attached to the first toothed belt 115, the second slider 140 on the second toothed belt 116.
  • the slides 120, 140 are disposed obliquely below in front of the trough 103, d. H. between the guide 101 and the welding position.
  • a stop member 124 Starting from the main part 123 of the slide 120, 140 extends (again shown with reference to the slider 120) a stop member 124 upwards and backwards.
  • a stop 125 At the end of the abutment part 124, a stop 125 is formed, whose cross section fits into the trough 103 and thus can contact the transverse wire 300 located in the deepest region of the trough 103.
  • FIG. 3 is an oblique view of a slider of the positioning device with a spring-mounted stop and a triggering device.
  • the slider 120 includes, as mentioned, a main part 123 and a stopper part 124 with a stopper 125.
  • the stopper part 124 is resiliently supported on the main part 123.
  • the main part 123 on a connecting part on two guide pins 126, 127, which are oriented with mounted slide 120 in the transverse direction.
  • the stop member 124 slides on the two guide pins 126, 127.
  • it has sliding guides 128, 129, which are executed in a foot region of the stop member 124.
  • a further pin 130 is arranged, which is held in a fixed to the main part 123 clamping ring and passes through a corresponding opening 131 of the stop member 124.
  • the pin 130 On the outside of the stop member 124 and spaced therefrom, the pin 130 has a head 132. Between the head 132 and the stopper member 124, a coil spring 133 is held on the pin 130.
  • the stop member 124 may continue to slide on the guide pin 126, 127 outwardly until it releases from the pins 126, 127 and thus from the main body 123.
  • the stop member 124 is thus disengaged at large forces, so that the forces do not act on the main part 123 of the slider 120 and thus not on the coupling means on the drive for the slider 120.
  • FIG. 4 shows a vertical cross section through the positioning device 100 and a transport device 200 of a device according to the invention for inserting transverse wires parallel to the longitudinal axis of the mesh welding machine.
  • the transport device 200 comprises a plurality of grippers 201 with two mutually movable, tong-like gripping jaws 202, 203, which are designed such that the transverse wire 300 between the gripping jaws 202, 203 grasped, held during transport and can be released at the destination again. All grippers 201 are attached to a transversely extending tube 204. This is held by a plurality of parallel and synchronously operated articulated arm mechanisms (not shown). The illustrated gripper 201 can thus be moved parallel to the machine longitudinal direction in the vertical plane shown in FIG.
  • articulated arm mechanisms will be at this No further details.
  • a transport of the gripper 201 and optionally a rotation of the gripper 201 about a horizontal axis transverse to the transport plane For example, articulated-arm robots (with two or more parallel axes of rotation, eg conventional SCARA robots) or even Cartesian robots can be used.
  • the number of articulated arm mechanisms arranged transversely along the tube 204 is selected depending on the width of the mesh welding machine and thus the length of the tube 204. In typical mesh welding machines, three parallel mechanisms are sufficient. For narrow machines, two are enough; for wide machines four or more mechanisms are necessary.
  • the gripper 201 has a small extent in the transverse direction and can therefore intervene between the trough elements 102.1... 102.16 (see FIG. 1) and capture the transverse wire inserted in the trough 103 of the guide 101 as shown in FIG.
  • at least two, but preferably up to 8 or more synchronously controlled grippers 201 are provided, depending on the transverse wire length.
  • the cross wire 300 After gripping the cross wire 300 by the grippers 201, it is transported along a transport path 210 without changing the transverse position to the welding position 220. There it is deposited on the longitudinal wires 310. Immediately thereafter, the welding process can take place by moving the upper electrode 221 downwards to the intersections between the transverse wire 300 and the longitudinal wires 310 and to the counterelectrodes 222 arranged below the welding position 220, after which a welding current is conducted through the intersection points until a desired welding is made. The transverse wire 300 is further transported along with the longitudinal wires in the further course.
  • the gripper 201 returns to the position shown in FIG. 4 to grasp the next cross wire, which has meanwhile been positioned in the trough 103 in the transverse direction.
  • FIGS. 5A-5D are schematic representations of the method sequence during the positioning of a transverse wire.
  • FIG. 5A shows the predetermined positioning of a transverse wire 301 of the correct length and the initial position of the slides 120, 140.
  • the feeding device is designed such that the transverse wire 301 is deposited with a maximum positional error ⁇ x next to the predetermined position in the depression 103.
  • the possible wire positions are indicated by dashed lines.
  • the maximum expected deviation in the length of the cross wire is ⁇ L. It should be noted that for clarity, the expected length error of the transverse wires is greatly exaggerated.
  • the sliders 120, 140 are now positioned so that a maximum length wire with the maximum expected position error still comes to lie between the sliders 120, 140, i. H. their distance from the predetermined center of the transverse wire 301 to be positioned is (L + ⁇ L) / 2 + ⁇ x.
  • the sprung stop 125 of the slider 120 is closer to the corresponding end of the transverse wire 301 by half the spring travel than the unsprung stop of the other slider 140 the opposite transverse wire end.
  • FIG. 5B now shows a transverse wire 302 that has not yet been positioned in the depression 103. It is slightly longer (within the length tolerance) than specified and is located to the left of the predetermined position. Once the transverse wire 302 has been inserted into the trough 103, the sliders 120, 140 will simultaneously move inward toward the transverse wire ends at the same speed.
  • the abutment of the slider 140 first reaches the transverse wire end facing it, whereupon the transverse wire 302 is displaced to the right by the slider 140.
  • the end position of the unsprung slider 140 is given by the predetermined position of the corresponding end of a correct length cross wire.
  • the slider 120 with the sprung stop 125 compensates for the excess length of the transverse wire 302 by compressing the spring means by more than half the spring travel ( Figure 5D).
  • the transverse wire 302 is removed by the gripper and then fed without changing the transverse position of the welding device.
  • the slides 120, 140 can after positioning, before or after the Grasping the cross wire 302 by the gripper to be moved outward again. So that the compressed spring of the spring-mounted stop 125 does not lead to a change in position of the transverse wire 302, first the slider 120 is retracted with the spring-loaded stopper 125 and only with a certain delay of the other slider 140th
  • FIGS. 6A-F are schematic representations of the method sequence during the positioning of transverse wires of different lengths.
  • three clear wire magazines 401, 402, 403 for providing transverse wires of different lengths and a feed device 500 arranged upstream of the guide 101 are shown schematically.
  • the feed device 500 is formed by a conveyor belt with ribs 502.1... 502.9 arranged transversely to the transport direction 501.
  • the transverse wire magazines 401, 402, 403 are arranged above the feed device 500, wherein the two transverse wire magazines 401, 402 are arranged side by side for small transverse wire lengths transversely to the transport direction.
  • the third cross wire magazine 403 for long transverse wires is located behind the other magazines 401, 402.
  • various transverse wires 303, 304, 305, 306, 307 from the transverse wire magazines 401, 402, 403 have already been deposited in the feed device 500. These are in this order a short cross-wire 303, two middle transverse wires 304, 305, again a short cross-wire 306 and a long cross-wire 307.
  • the transverse position of the cross wires 303 ... 307 in the feeder 500 corresponds to the transverse position of the respective cross-wire magazines 401, 402, 403 with respect to the feeding device 500.
  • the transverse wire 303 is deposited in the guide 101, the slides 120, 140 are moved into corresponding initial positions (see above).
  • the slides 120, 140 are moved so that the cross wire 303 is transported in the guide 101 in the predetermined dispensing position; the feeder 500 continues to run (see Figure 6C).
  • the Slider 120, 140 in one of the length and the position of the next cross-wire 304 adapted starting position moves ( Figure 6D).
  • the slides 120, 140 are again moved in such a way that this transverse wire 304 is also transported to its predetermined dispensing position (see FIG. 6F), from which it is removed by the transport device and the welding device 223 can be supplied.
  • FIG. 6A-F The configuration shown in Figures 6A-F is intended to be merely an example.
  • the number and arrangement of the magazines can be adapted to the geometry of the grid to be produced as well as the construction of the feeder.
  • Several magazines can also be arranged one above the other; because the slides can detect and position any cross-wire introduced into the guide, no high demands are placed on the accuracy of the insertion position.
  • FIGS 7A-D are schematic representations of the process flow in positioning transverse wires deposited directly in a system for producing transverse wires in the guide.
  • the system 600 for producing cross wires from a wire supply is arranged laterally next to the guide 101, wherein the cutting device 601 of the system 600 for cutting the cross wires is positioned so that cut transverse wires can be deposited directly from the system 600 into the guide 101.
  • the transverse wires are first injected into a discharge channel of the system 600, which is arranged vertically above the guide 101 and parallel to the guide 101. After opening a flap in the bottom of the discharge channel of the transverse wire located therein falls directly into the guide 101st
  • the sliders 120, 140 are first moved to initial positions near both ends of the guide 101 regardless of the length of the transverse wires to be cut off.
  • the cut cross-wire 308 falls after cutting off the discharge channel in the guide 101 between the slides 120, 140. It can thus be detected at its end faces and moved to a predetermined discharge position ( Figure 7B). From this Dispensing position he is again taken from the transport device (not shown) and fed to the welding device 223.
  • the sliders 120, 140 are again moved to their initial position at the ends of the guide 101 ( Figure 7C), so that the next cross wire 309 can be cut off. Also this falls after cutting off the discharge channel directly into the guide 101 and is then moved by the slide 120, 140 to the predetermined discharge position. If the positioning process is to be accelerated, also in the context of the embodiment shown here, the first slide 120 arranged on the side opposite the cutting device 600 can only be moved outwardly to the extent that the transverse wire to be cut off can be deposited between the slides 120, 140.
  • the invention is not limited to the illustrated embodiment. Details of the guide, the positioning and the transport device can be changed in many different ways and adapted to the particular needs. The positioning and control of the slide (or other positioning) can be done in other ways.
  • a device for inserting transverse wires in a mesh welding machine is provided by the invention, which allows a high efficiency of the welding machine and is structurally simple.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Wire Processing (AREA)
EP05405255A 2005-03-21 2005-03-21 Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis Withdrawn EP1704940A1 (fr)

Priority Applications (7)

Application Number Priority Date Filing Date Title
EP05405255A EP1704940A1 (fr) 2005-03-21 2005-03-21 Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis
ES06405111T ES2306408T3 (es) 2005-03-21 2006-03-13 Dispositivo posicionador para el posicionamiento de alambres transversales en una maquina soldadora de rejillas y procedimiento para posicionamiento de alambres transversales en una maquina soldadora de rejillas.
EP06405111A EP1704941B1 (fr) 2005-03-21 2006-03-13 Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis
DK06405111T DK1704941T3 (da) 2005-03-21 2006-03-13 Positioneringsindretning til positionering af tværtråde til en gittersvejsemaskine og fremgangsmåde til indlægning af tværtråde i en gittersvejsemaskine
AT06405111T ATE390970T1 (de) 2005-03-21 2006-03-13 Positioniereinrichtung zum positionieren von querdrähten für eine gitterschweissmaschine und verfahren zum einlegen von querdrähten in eine gitterschweissmaschine
DE502006000544T DE502006000544D1 (de) 2005-03-21 2006-03-13 Positioniereinrichtung zum Positionieren von Querdrähten für eine Gitterschweissmaschine und Verfahren zum Einlegen von Querdrähten in eine Gitterschweissmaschine
US11/384,560 US20060226127A1 (en) 2005-03-21 2006-03-21 Positioning device for positioning transverse wires for a mesh-welding machine

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
EP05405255A EP1704940A1 (fr) 2005-03-21 2005-03-21 Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis

Publications (1)

Publication Number Publication Date
EP1704940A1 true EP1704940A1 (fr) 2006-09-27

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Family Applications (2)

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EP05405255A Withdrawn EP1704940A1 (fr) 2005-03-21 2005-03-21 Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis
EP06405111A Not-in-force EP1704941B1 (fr) 2005-03-21 2006-03-13 Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis

Family Applications After (1)

Application Number Title Priority Date Filing Date
EP06405111A Not-in-force EP1704941B1 (fr) 2005-03-21 2006-03-13 Dispositif de positionnement pour positionner des fils transversaux dans une soudeuse de treillis et méthode de positionnement des fils transversaux dans une soudeuse de treillis

Country Status (6)

Country Link
US (1) US20060226127A1 (fr)
EP (2) EP1704940A1 (fr)
AT (1) ATE390970T1 (fr)
DE (1) DE502006000544D1 (fr)
DK (1) DK1704941T3 (fr)
ES (1) ES2306408T3 (fr)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN117901255A (zh) * 2024-03-19 2024-04-19 中铁四局集团有限公司 一种预制小箱梁钢筋网片纵筋标准化供料机构及其方法

Families Citing this family (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
ITUD20080067A1 (it) * 2008-03-28 2009-09-29 Beta Systems Srl Testa di saldatura per una macchina per la formazione di rete metallica, relativo procedimento di saldatura e macchina per la formazione di rete metallica utilizzante detta testa di saldatura
CN107081630B (zh) * 2017-06-20 2023-09-08 君联自动化设备(深圳)有限公司 上料机
CN107322228B (zh) * 2017-09-07 2023-05-26 河北骄阳焊工有限公司 焊机用双工位无级横丝定位装置及定位的方法
EP3715009A1 (fr) * 2019-03-28 2020-09-30 apilion Machines + Services GmbH Installation de soudage destinée à la fabrication de grillage formant armature
CN113038679B (zh) * 2021-03-16 2023-08-22 中国科学院近代物理研究所 用于加速器束流剖面测量的弹性多丝探针靶头

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EP0241449A1 (fr) * 1986-04-02 1987-10-14 EVG Entwicklungs- u. Verwertungs- Gesellschaft m.b.H. Machine à souder par résistance par points nombreuses
EP0622136A1 (fr) * 1993-04-26 1994-11-02 Michael R. Koch Dispositif pour la fabrication de treillis d'armature pour panneaux en béton
DE29621385U1 (de) * 1996-12-10 1997-03-06 Jaeger Emil Gmbh Co Kg Positioniereinrichtung für Querdrähte
DE29703872U1 (de) * 1997-03-04 1997-04-30 Theis Klaus Dr Puffer- und Positioniereinrichtung für Stäbe

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DE204606C (fr) * 1900-01-01
AT395229B (de) * 1989-05-24 1992-10-27 Evg Entwicklung Verwert Ges Gitterschweissmaschine
AT402033B (de) * 1992-02-20 1997-01-27 Evg Entwicklung Verwert Ges Verfahren und anlage zum herstellen von bewehrungsgittermatten
AT407501B (de) * 1996-06-13 2001-04-25 Evg Entwicklung Verwert Ges Verfahren und vorrichtung zum herstellen von drahtgittermatten
ITUD20020135A1 (it) * 2002-06-18 2003-12-18 Beta Systems Srl Macchina per la formazione di rete metallica e relativo procedimento

Patent Citations (4)

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Publication number Priority date Publication date Assignee Title
EP0241449A1 (fr) * 1986-04-02 1987-10-14 EVG Entwicklungs- u. Verwertungs- Gesellschaft m.b.H. Machine à souder par résistance par points nombreuses
EP0622136A1 (fr) * 1993-04-26 1994-11-02 Michael R. Koch Dispositif pour la fabrication de treillis d'armature pour panneaux en béton
DE29621385U1 (de) * 1996-12-10 1997-03-06 Jaeger Emil Gmbh Co Kg Positioniereinrichtung für Querdrähte
DE29703872U1 (de) * 1997-03-04 1997-04-30 Theis Klaus Dr Puffer- und Positioniereinrichtung für Stäbe

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN117901255A (zh) * 2024-03-19 2024-04-19 中铁四局集团有限公司 一种预制小箱梁钢筋网片纵筋标准化供料机构及其方法

Also Published As

Publication number Publication date
DK1704941T3 (da) 2008-07-28
ES2306408T3 (es) 2008-11-01
DE502006000544D1 (de) 2008-05-15
EP1704941A1 (fr) 2006-09-27
ATE390970T1 (de) 2008-04-15
EP1704941B1 (fr) 2008-04-02
US20060226127A1 (en) 2006-10-12

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