La présente invention se rapporte à une machine de cambrage de fils métalliques, caractérisée par le fait qu'elle comporte des unités de cambrage (3, 4) équipées chacune d'une tête rotative (32, 42) de cambrage du fil tournant autour d'un axe (35, 45) orthogonal à l'axe d'alimentation (51) du fil (5).

A bending machine for bending wire, tubing, or other elongate material (24), comprising a support structure (10) and a bending head (20) which is mounted on the support structure (10) and which is capable of bending such material in a given plane which is fixed relative to the bending head (20). A feed unit (14) is mounted on the support structure (10) and is arranged to feed such material (24) along a feed axis of the machine to the bending head (20). The bending head (20) is rotatable about the said feed axis of the machine thereby to enable the machine to bend the material (24) into more than one plane. Furthermore, substantially the whole of the bending head (20) is positioned to one side of the said feed axis of the machine.

A bending apparatus wherein a long material (3) to be bent is inserted into an axial guide hole (24) of a cylindrical material guide (23), the bending direction of the long material (3) being determined by a bending direction setting body (26) which is provided rotatably on the outer periphery of the material guide (23) and set in any desired rotational position, and the long material (3) is bent by a bending operation body (35) which is provided in front of the bending direction setting body (26) rotatably around a support shaft (38) set to be perpendicular to the material (3) to be bent and has a material insertion portion (39) formed facing the fore end of the material guide (23).

An apparatus and method for calibrating an automated wire bending machine is provided that includes a camera system comprising a camera and a lens configured with a focal plane fixedly positioned relative to a bending surface provided on the automated wire bending machine. The disclosed apparatus and method further includes a processor device configured to interpret images captured by the camera system. The apparatus and method measures an actual angle formed in a wire while a bent portion of the wire is substantially within the focal plane of the camera system, and a memory device stores values generated during a calibration sequence of the automated wire bending machine. The values correspond to the actual angle and a target angle provided for the calibrating of the automated wire bending machine.

Die Erfindung betrifft eine Materialbearbeitungsvorrichtung, insbesondere Umformmaschine, die mindestens ein Materialbearbeitungsaggregat (15), vorzugsweise mehrere Materialbearbeitungsaggregate (15) aufweist, deren jedes entlang einer Linearführung (204) linear verschiebbar angeordnet ist, wobei jedes Materialbearbeitungsaggregat (15) mittels eines von einer Maschinensteuerung steuerbaren Antriebsmechanismus (200) automatisiert linear verschiebbar ist, um es in einer jeweiligen Soll-Arbeitsposition zu positionieren, wobei der Antriebsmechanismus (200) eine Gewindespindel (201) zum Verschieben des Materialbearbeitungsaggregates (15) aufweist, und wobei jedem linear verschiebbaren Materialbearbeitungsaggregat (15) eine jeweilige von der Gewindespindel (201) durchsetzte Spindelmutter (214) zugeordnet ist, die mittels einer Kupplungsvorrichtung (223) wechselweise in einen Leerlaufbetriebszustand und in einen Kopplungsbetriebszustand versetzbar ist, wobei sie in dem Leerlaufbetriebszustand mit der Gewindespindel (201) drehbar ist, so dass sie keine Linearbewegung längs der Gewindespindel (201) ausführt, wohingegen sie in dem Kopplungsbetriebszustand verdrehfest mit dem betreffenden Materialbearbeitungsaggregat (15) gekoppelt ist, so dass sie bei Drehung der Gewindespindel (201) eine Linearbewegung entlang der Gewindespindel (201) unter Mitnahme des Materialbearbeitungsaggregates (15) längs der Linearführung (204) ausführen kann.

Parallel zur Vorschubachse (34) des Drahtes (4) ist ein Biegetisch (7) angeordnet, der um die Vorschubachse (34) drehbar ist. Der Biegetisch trägt einen Revolverkopf (8), der um eine Achse (35) drehbar ist, die zur Vorschubachse (34) im rechten Winkel steht. Im Revolverkopf sind einzelne Biegewerkzeuge (9) drehantreibbar gelagert. Jedes Biegewerkzeug kann mit Hilfe einer pneumatischen Hubvorrichtung in die Biegeebene angehoben werden. Auf diese Weise können innerhalb eines Bearbeitungsvorgangs an einem Biegestück unterschiedliche Biegewerkzeuge sequentiell eingesetzt werden.

The currently existing automatic wire / rod sraightening and bending machines create planar wire or rod shapes which normally lie within a fixed and standard plane (ABΓΔ), which contains the imaginary line x-x of the straightened wire.

This invention has concentrated on the construction of an extra bending mechanism 7 which by appearing at the right moment, creates wire / rod bends always in relation with the above mentioned line x-x, but within other planes (EZHϑ), also containing line x-x 15 but distinctly different than plane (ABΓΔ).

In this manner it is possible to achieve the construction of wire shapes in three dimensions.

The currently existing automatic wire / rod sraightening and bending machines create planar wire or rod shapes which normally lie within a fixed and standard plane (ABΓΔ), which contains the imaginary line x-x of the straightened wire.

This invention has concentrated on the construction of an extra bending mechanism 7 which by appearing at the right moment, creates wire / rod bends always in relation with the above mentioned line x-x, but within other planes (EZHϑ), also containing line x-x 15 but distinctly different than plane (ABΓΔ).

In this manner it is possible to achieve the construction of wire shapes in three dimensions.

Orientable bending assembly of a type capable of being temporarily retracted below the upper edge of a work platform (15) of a bending-shaping machine for sections, the bending assembly being provided with clockwise and anticlockwise rotation of a bending pin (18) and contrast roll (12), a bending means (11) cooperating with and being supported by an orientable slide block (14) pivoted on an orientation pivot (16) lying in the neighbourhood of a plane comprising the axis of the contrast roll (12), this plane being substantially parallel to the axis of the section or sections being bent and shaped.

La présente invention se rapporte à une machine de cambrage de fils métalliques, caractérisée par le fait qu'elle comporte des unités de cambrage (3, 4) équipées chacune d'une tête rotative (32, 42) de cambrage du fil tournant autour d'un axe (35, 45) orthogonal à l'axe d'alimentation (51) du fil (5).

A fluid flow or fluid pressure transmission device comprising a fixed block (103) and a rotary shaft (94) mounted in relation to the fixed block (103) so as to be rotatable relative thereto. The fixed block (103) has a at least one passageway (110) through it extending to the rotary shaft (94), and the rotary shaft (94) has at least one annular groove (100) or other recess in registration with the fixed block passageway (110) and at least one axially extending passageway (98) in communication with the annular groove (100) or other recess. As a result, the axial passageway (98) is in communication with the fixed block passageway (110) independently of the angular position of the rotary shaft (94) relative to the fixed block (103). Such a device is particularly useful in supplying fluid flow or pressure to a rotary bending head (20) of a wire bending machine for example.

A bending apparatus wherein a long material (3) to be bent is inserted into an axial guide hole (24) of a cylindrical material guide (23), the bending direction of the long material (3) being determined by a bending direction setting body (26) which is provided rotatably on the outer periphery of the material guide (23) and set in any desired rotational position, and the long material (3) is bent by a bending operation body (35) which is provided in front of the bending direction setting body (26) rotatably around a support shaft (38) set to be perpendicular to the material (3) to be bent and has a material insertion portion (39) formed facing the fore end of the material guide (23).

La présente invention concerne une machine automatique pour cambrer des éléments métalliques minces et rectilignes d'épaisseur constante du genre fils, feuillards ou tubes.

Cette machine comprend un organe distributeur (13) à travers lequel un élément métallique à cambrer (1) peut être déplacé selon un mouvement d'avance par pas, un organe de pliage (14) qui est situé en aval et à proximité de la sortie de l'organe distributeur (13) et qui peut, d'une part, être animé d'un mouvement de rotation angulaire autour d'un axe (Y) perpendiculaire à la direction d'avance de l'élément métallique et, d'autre part, être déplacé selon un mouvement de va-et-vient sur une trajectoire rectiligne (X) parallèle à cet axe (Y),

Selon l'invention, cette machine comprend en outre des moyens pour engendrer un mouvement de rotation angulaire relatif entre l'organe de pliage (14) et l'élément métallique (1), autour d'un deuxième axe (Z) confondu avec la direction d'avance de l'élément métallique. De préférence, ces moyens font tourner l'organe de pliage (14) autour de l'élément métallique (1) qui est immobile en rotation.

Cette machine permet de produire des articles pliés selon n'importe quelle configuration spatiale à partir d'un fil, d'un feuillard ou d'un tube métallique.

A servo-rotating all-function tool module is provided for use with a spring forming machine and includes an axle rotating tool module and a servo transmission module assembly (19, 29, 39). The axle rotating tool module is mounted, together with an axle (81, 91), to a front wall board (70, 80, 90) and includes a tool (11, 21) and an axle slide base (12, 22) mounted to the axle (81, 91), so that the axle slide base (12, 22) is acted upon by a force to slide along the axle (81, 91), the tool (11, 21) is caused to press downward or return upward. The servo transmission module assembly (19, 29, 39) is mounted to the spring forming machine to provide a driving force for causing the axle slide base (12, 22) to slide along the axle (81, 91). Since the tool module is mounted, together with the axle (81, 91), to a front wall board (70, 80, 90) of the spring forming machine, the direction in which the tool (11, 21) approaches a wire can be varied by rotating the axle (81, 91) in order to conduct operations of bending at different angles and twisting/looping.