• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a bent bending tool (1) for a bending machine, in particular a die bending machine, comprising a tool body (3), which at least one tool shank (4) for at least partially receiving the bending tool (1) in a bending direction (20) in a designated Receiving shaft (15) has a tool head (9) adjoining the tool shank (4) in the bending direction (20), which has a tool center of gravity (10) outside a vertical plane of symmetry (17) of the receiving shaft (15) and in a transverse direction (21) at least on one side a tool shoulder (11), and at least one on the tool shank (4) for moving the bending tool (1) in the longitudinal direction (22) of the bending machine for receiving in a groove (16) provided movement means (8) which at least one side of the tool shank (4 ) is designed to be outstanding relative to a respective tool shank surface (7), and at least one spacer element for application a support force (23) counteracting a tilting moment (13) caused by deviation of the center of gravity of the tool (10) from the plane of symmetry (17) in the transverse direction (21) on at least one surface (18, 19) of the tool holder (14) at least one spacer element (2), at least one with a biasing force (24) mounted roller body (25) which is mounted on or at least partially within the tool body (3) at least in the direction of the biasing force (24) and at least partially relative to a , Preferably, the at least one rolling body (25) adjacent, surface (18, 19) of the tool body (3) is excellently arranged.
    公开号:AT521173A4
    申请号:T505282018
    申请日:2018-06-27
    公开日:2019-11-15
    发明作者:
    申请人:Trumpf Maschinen Austria Gmbh & Co Kg;
    IPC主号:
    专利说明:

    Summary
    The invention relates to a cranked bending tool (1) for a bending machine, in particular a die bending machine, comprising a tool body (3) which has at least one tool shank (4) for at least partially receiving the bending tool (1) in a bending direction (20) in a direction provided for this purpose Receiving shaft (15) has a tool head (9) adjoining the tool shaft (4) in the bending direction (20), which has a center of gravity (10) outside a vertical plane of symmetry (17) of the receiving shaft (15) and in a transverse direction (21) at least on one side has a tool shoulder (11), and at least one movement means (8), which is provided on the tool shaft (4) for moving the bending tool (1) in the longitudinal direction (22) of the bending machine for receiving in a groove (16) and which is at least on one side on the tool shaft (4 ) is excellent in relation to a respective tool shank surface (7), and at least one spacer element for application a counteracting supporting force (23) on at least one surface (18, 19) of the tool holder (14), caused by a deviation of the tool center of gravity (10) from the plane of symmetry (17) in the transverse direction (21), counteracting supporting force (23), the comprises at least one spacer element (2), at least one rolling element (25) mounted with a biasing force (24), which is movably mounted on or at least partially within the tool body (3) at least in the direction of the biasing force (24) and at least partially relative to one , preferably the at least one roller body (25) adjacent surface (18, 19) of the tool body (3) is outstandingly arranged.
    Fig. 5a
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    The invention relates to a cranked bending tool for a bending machine, in particular a die bending machine, which comprises a spacer element that is pretensioned with a pretensioning force to compensate for a tilting moment.
    Bending tools, which are used as the upper tool in a bending machine for forming a sheet metal part, can often have a tool body with a complicated geometry. It can happen that the tool body is cranked, that is, deviating from the bending direction, is at least simply angled. With tool geometries of this type, the center of gravity of the tool is often no longer offset in a vertical plane of symmetry of the tool holder or the tool shank, but laterally offset in a transverse direction.
    The lateral offset of the tool center of gravity from the plane of symmetry causes a tilting moment of the cranked tool on and / or in the tool holder. When changing the bending tool, this tilting moment can lead to increased wear of the bending tool and / or the tool holder on the contact surfaces, and even jamming of the bending tool in the tool holder.
    In order to prevent damage to the tool, it was proposed in W02014 / 007640A1 to mount a rigidly arranged roller in the tool shaft or on the tool shoulder of a bending tool, which roller should facilitate the movement of the bending tool in the receiving shaft. The rigidly mounted roller should be made very rigid in order to be able to support the bending tool on the tool holder.
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    In future, ever lower manufacturing tolerances and / or very high fitting accuracy of the tool holder and the tool body will be required. This means that storage and / or movement of the tool shank in the receiving shaft of the tool holder must be as free of play as possible. Systems known from the prior art, as disclosed, for example, in W02014 / 007640A1, are only of limited practical use, since they have the disadvantage that the rollers can wear out to some extent and can be damaged by a conventional clamping of the bending tool in the tool holder. In addition, an automated changing process of a bending tool by external manipulators and / or robots is very difficult.
    The object of the present invention was to overcome the disadvantages of the prior art and to provide a cranked bending tool which enables wear on the bending tool and / or the tool holder to be reduced. Another object of the invention is that the displacement resistance of a bending tool in the tool holder is reduced and jamming of the bending tool in or on the tool holder is prevented. Furthermore, the bending tool according to the invention serves to make it usable on both sides, that is to say essentially independently of the direction of insertion.
    This object is achieved by a bending tool according to the claims.
    The cranked bending tool according to the invention for a bending machine, in particular a die bending machine, comprises a tool body, at least one movement means and at least one spacer element. The tool body has at least one tool shaft for at least partially receiving the bending tool in a bending direction in a receiving shaft of the tool holder provided therefor, the tool body having a tool head adjoining the tool shaft in the bending direction, which has a tool center of gravity outside a vertical plane of symmetry of the receiving shaft and / or of the tool shank and has a tool shoulder at least on one side in a transverse direction. On the tool shank for moving the bending tool in the longitudinal direction of the bending machine for receiving
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    N2018 / 07900-AT-00, at least one movement means is formed in a groove, which movement means is outstandingly configured at least on one side on the tool shank relative to a respective tool shank surface. At least one spacer element is designed to apply a supporting force that counteracts a tilting moment caused in the transverse direction by a deviation of the tool center of gravity from the plane of symmetry on at least one surface of the tool holder. The at least one spacer element comprises at least one rolling element mounted with a prestressing force, which is movably supported on or at least partially within the tool body at least in the direction of the prestressing force and is at least partially excellently arranged relative to a surface of the tool body, preferably adjacent to the at least one rolling element ,
    In simple terms, the tilting moment acts around the longitudinal axis of the bending tool or the tool holder and causes the bending tool to be pressed against at least one contact point. By designing the at least one spacer element by means of at least one rolling element, which is directly or indirectly pretensioned with a pretensioning force, the at least one spacer element can compensate the tilting moment by transmitting a supporting force from the bending tool to the tool holder. As a result, the friction between the receiving shaft and the tool shank and / or between the underside of the tool holder and a tool shoulder or the tool shoulder plane can be reduced when the bending tool moves in the tool holder. The reduction in friction enables wear on the contact surfaces mentioned to be reduced. In addition, jamming of the bending tool on and / or within the tool holder can be avoided.
    Furthermore, the flexible mounting or pretensioning of the at least one rolling body in the direction of the pretensioning force makes it easier to insert the bending tool shank into the holding chute of the tool holder provided for this purpose. As a result, a change of such a bending tool can be relative
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    N2018 / 07900-AT-00 can be done easily and quickly, whereby the compensation of the tilting moment can lead to an increase in safety and reduced wear.
    Furthermore, it can be expedient if the at least one rolling body for applying the supporting force, normal to the bending direction or transverse direction, is arranged on and / or at least partially in the tool body on an inside of the receiving shaft and / or in the bending direction on an underside of the tool holder.
    The movable mounting or pretensioning of the at least one rolling element in the direction of the pretensioning force thus brings about an automatic coupling of the rolling element to a corresponding surface of the tool holder. This is particularly advantageous in the case of an automated change of a bending tool, since a robot or the like does not have to operate any additional mechanics and the at least one spacer element or the rolling body can at least temporarily withdraw completely behind a surface of the tool body.
    In addition, by means of the suitable positioning of the at least one spacer element on the tool body, an optimum can be found with regard to the required supporting or prestressing force and the space requirement on and / or within the tool body. For example, the relatively short lever arm when positioning a spacer element on or within the tool shank requires a higher pretensioning force in order to apply the required supporting force to the inside of the receiving shaft than if the spacer element is arranged on or within a tool shoulder, since a larger lever arm may be used here can.
    More than one spacer element can also be provided on the tool body, in particular in the longitudinal direction. It is also conceivable that a spacer element for applying a part of the supporting force on the tool shaft relative to the inner surface of the receiving shaft, as well as a further spacing element for a part of the supporting force on the tool head in the direction of the underside of the tool holder. In such a way, the required
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    Partial prestressing forces are selected to be relatively low, which makes insertion of the bending tool particularly easy to accomplish.
    It can further be provided that the at least one spacer element has an adjusting device for adjusting the amount of the pretensioning force.
    The advantage of an adjustment device is that it can be easily adapted to different tool geometries and / or tool weights and the associated supporting forces or pretensioning forces. This can e.g. after repairing a bending tool can be used to adjust the supporting force to a changed position of the tool center of gravity.
    Such an adjustment device can e.g. be formed by a spring element, preferably a helical spring, which can apply a predeterminable spring force or pretensioning force by means of an adjustable spring travel. Likewise, an adjustment device e.g. be formed by an adjustable support device of a spring element, such as a bending rod, and comprise adjusting screw. An adjusting device is advantageously accessible from the outside, so that in the limit case, even with a bending tool accommodated in the tool holder, the pretensioning force can be adjusted or adjusted.
    In addition, it can be provided that the spacer element comprises at least two rolling elements, which are preferably arranged next to one another in a rolling element receptacle.
    In this way, an improved transmission of the supporting force can take place at several contact points, which enables a lower local surface pressure of the respective rolling bodies in contact with a surface of the tool holder. On the one hand, this lowers the resistance or exertion of force when inserting the bending tool into the receiving shaft and, on the other hand, it can reduce wear.
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    Also advantageous is a configuration according to which it can be provided that the at least one spacer element comprises a rolling element receptacle and at least one limiting element, which delimiting element for limiting a deflection of the rolling element receptacle or the rolling element is movably connected to the tool body in the direction of the prestressing force by means of at least one fastening means is trained.
    At least one rolling element is rotatably supported in the rolling element receptacle, the limiting element on the rolling element receptacle being able to be arranged laterally and internally in such a way that a limited movement of the rolling element receptacle and thus of the rolling element is made possible. Such a limiting element can e.g. be movably connected on and / or in the tool body or in a spacer housing, whereby the respective spacer against loss by e.g. Falling out and / or falling is secured. In addition, such a delimitation element serves to ensure that the spacer element or the rolling body does not protrude beyond the surface of the tool body by a predeterminable height, which is particularly advantageous for easier insertion.
    A limiting element can be e.g. a groove or an appropriately designed extension of the rolling body receptacle can be formed in order to at least partially accommodate the fastening means. In the simplest case, the fastening means can be a screw, the head of which serves as loss protection and whose thread and / or shaft or threadless part serves as a guide and stop for the limiting element in the direction of the pretensioning force.
    According to a further development, it is possible for the at least one spacer element to be arranged in a spacer element housing which is designed at least to accommodate the rolling element receptacle and the at least one delimiting element and to support the adjusting device with respect to the rolling element receptacle.
    A spacer element designed in this way can be regarded as a functional unit which is relatively simple to manufacture and which also enables
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    N2018 / 07900-AT-00 the adjustment device is supported within the spacer housing and not necessarily on the tool body. In this way, a kind of “retrofit element” can be created in a simple manner, which can be attached and / or exchanged relatively easily on and / or within an existing tool body.
    Furthermore, it can be expedient if the at least one spacer element is arranged on the outside of the tool head for supporting the bending tool on the underside of the tool holder.
    Such an arrangement is advantageous because good external accessibility for e.g. the setting of the preload is given. In addition, a comparatively large lever arm between the rolling body and the plane of symmetry is used, as a result of which the required supporting force or pretensioning force can be selected to be relatively low.
    In addition, it can be provided that the spacer element is designed as a bending rod such that the at least one rolling body is arranged at a free end of the bending rod and a fixed end of the bending rod is fastened in the tool body, preferably the tool head, normal to the bending direction and / or in the bending direction ,
    The bending rod has a predeterminable flexibility in at least one direction, as a result of which the prestressing force can be adjusted essentially by the geometry of the bending rod, in particular the local cross section of the bending rod, the rolling body diameter and the available bending length. A bending rod is relatively simple and inexpensive to manufacture. The bending bar can be in a designated opening, which e.g. can also be designed as a bore can be accommodated within the tool body. The receiving opening advantageously does not penetrate the tool body and has a larger diameter than the bending rod or the rolling body in order to allow the spacer element to move at least in the direction of the prestressing force. The fixed end is advantageously screwed into the tool body and the at least one rolling body is rotatably attached to the free end.
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    Furthermore, it can be provided that the at least one rolling body is at least partially arranged opposite to a tool shoulder top and the rolling body for applying the supporting force in the bending direction with respect to the tool holder is fixed with the fixed end of the bending rod normal to the bending direction in the tool head.
    In this way, a particularly large bending length of the bending rod can be realized with stiffness or flexibility that can be easily set or predefined. The rolling element can be arranged in such a way that it protrudes transversely over the surface of the tool shoulder. The free end and / or the rolling element is preferably aligned in the transverse direction or even set back behind the surface of the tool head which is adjacent in the longitudinal direction. In this way, protruding elements over the tool body are avoided, which can hinder handling of the bending tool. Among other things, this favors the use of automated tool changing devices.
    According to a particular embodiment, it is possible that the bending rod comprises at least one threaded section for receiving the bending rod in the tool head and / or tool shank, a bending section with a predeterminable bending length, and a rolling body section, and the adjusting device for adjusting the pretensioning force by adjusting a predeterminable support distance between Threaded section and rolling body section, the bending section is arranged at least partially supporting.
    The threaded section is provided as a fixed end for receiving in the tool body, while the rolling body section for receiving the at least one rolling body is arranged at the free end of the bending rod. Between these sections, the bending length available for exerting and / or adjusting the pretensioning force extends along the bending section. The adjusting device of this embodiment preferably comprises an adjusting screw and / or a spindle drive which is rotatably mounted in the tool body. The adjusting device can furthermore have a support element which is movable parallel to the bending rod and which interacts with the set screw or the spindle drive. In this way, a two-point can be set by means of the adjusting device
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    Storage of the bending rod are formed. The free bending length of the bending rod can be set relatively easily by adjusting the support distance from the threaded section, as a result of which the prestressing force can be adjusted. The support element can e.g. be a sleeve or a C- or V-shaped profile in order to support the bending rod at least on one side, preferably with a covering.
    According to an advantageous development, it can be provided that the bending bar is designed as a waisted bending bar, the bending section being designed as a first waist section and the rolling body section being designed as a second waist section and at least one waist section diameter of the first and / or second waist section being smaller than a threaded section diameter is.
    It has been shown that a decrease in cross section of the bending rod from the threaded section to the free end, preferably as two waist sections, can increase the fatigue strength of the bending rod. In addition, the smaller diameter of the bending section and / or rolling body section enables a lighter construction of the bending rod. The smaller waist section diameters can also be used to optimize the rigidity or the prestressing force of the bending rod in a relatively simple manner.
    The waist section diameters, in particular of the first waist section or of the bending section, can also not be designed to be continuous, that is to say following a mathematical function. This can be used by the person skilled in the art to provide different local waist section diameters which optimize the rigidity requirements along the bending rod with regard to the necessary prestressing force and / or fatigue strength.
    In particular, it can be advantageous if the adjusting device for adjusting a predeterminable supporting distance comprises a preferably sleeve-shaped supporting element that is at least partially encasing the bending section.
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    This measure allows a two-point mounting of the bending rod at the fixed end and on the support element of the adjusting device to be designed in a relatively simple and stable manner. The at least partial sheathing and in particular a sleeve-shaped support element can prevent local bending of the bending rod in the direction of the prestressing force to be applied to the support element, as a result of which improved and more stable storage can be achieved.
    Furthermore, it can be provided that at least two movement means in the longitudinal direction are formed side by side as a sliding element or preferably as a rolling element.
    This measure allows the local friction and / or the local surface pressure to be reduced to the respective movement means, as a result of which the risk of wear and the tendency to wedge the bending tool in the tool holder can be reduced. The sliding elements are advantageously made of a material with a low coefficient of friction compared to the tool holder and high mechanical strength. Polymers such as PTFE, PEEK, PPSU, PAEK or the like are preferably used, since they can moreover have a high resistance to solvents and / or lubricants. The use of rolling elements, which are similar to the rolling element as e.g. ball-bearing rollers can be formed. The advantage of the rolling elements is the very low rolling friction and high mechanical stability.
    In addition, it can be provided that at least two movement means in the transverse direction are formed on opposite sides of the tool shank, preferably symmetrically opposite one another.
    This allows an improved load transfer of the weight of the bending tool into the tool holder and, particularly in combination with at least one spacer element to compensate for the tilting moment, can bring about a significant reduction in the wear of the movement means.
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    In a special embodiment, the at least one movement means can be formed in one piece with the tool shaft as an extension.
    Such a movement means acts as a sliding element and is designed as an integral extension of the tool shank. Such sliding elements can be taken into account in the manufacture or machining of the tool shank and can therefore be easily manufactured. It is particularly advantageous here if at least this movement means, which is designed as an extension of the tool shank, is coated and / or coated with a surface layer with a low coefficient of friction, such as PTFE. Carbon-based low friction layers, such as amorphous carbon (DLC), are particularly suitable as the surface layer, as a result of which the friction of the at least one extension can be efficiently reduced.
    All of the design options according to the invention also have the effect that the tool shank or the bending tool can be inserted into the tool holder on both sides, since the compensation of the tilting moment by the at least one spacer element can be carried out essentially without additional changes to the tool holder.
    Furthermore, for the temporary fastening of the bending tool in the tool holder, clamping or clamping systems are generally used, which clamp the bending tool on the tool shaft in one or more clamping grooves provided for this purpose. Ideally, the top of the tool shank is pressed against the receiving shaft and any existing tool shoulders are pressed against the underside of the tool holder. According to the invention, in the case of a tool clamping or clamping, the at least one spacer element moves back behind the respective surface of the tool body, as a result of which the clamping process can take place without hindrance and a skewed "clamping" of the bending tool can be efficiently avoided. In addition, damage to the clamping or clamping systems, the tool holder and / or the bending tool can be avoided.
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    The present invention can also be applied analogously to bending tools with a center of gravity in the plane of symmetry. It is in the sense of the present invention that the above-mentioned embodiments of cranked bending tools with spacer elements designed according to the invention can also be used to compensate for tilting moments also in the transverse and / or longitudinal direction in the case of non-cranked bending tools or cranked tools whose tool center of gravity lies in the plane of symmetry. The tilting moments of such bending tools can occur due to a displacement of the bending tools in the longitudinal direction and can cause oscillating movements and / or jamming. The spacer elements can e.g. be arranged on both sides in the transverse direction on the tool body in order to minimize oscillating movements and / or jamming during the insertion process into the tool holder, as a result of which the running-in speed can be increased and the set-up time reduced.
    For a better understanding of the invention, this will be explained in more detail with reference to the following figures.
    Each show in a highly simplified, schematic representation:
    Fig. 1 schematic overview representation in an oblique view of a cranked bending tool in the tool holder;
    2 shows schematic sectional views of a bending tool with differently arranged spacer elements on or inside the tool body (a-f);
    3 shows a schematic illustration of an exemplary embodiment of a bending tool with a spacer element on or in the tool shank with a rolling element (a) or two rolling elements (b);
    4 shows a schematic sectional illustration of an exemplary embodiment of a bending tool with a spacer element with a spacer element housing;
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    5 shows a schematic sectional illustration of an exemplary embodiment of a bending tool with a spacer element which is designed as a bending bar (a) or a waisted bending bar and adjusting device (b).
    In the introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, and the disclosures contained in the entire description can be applied analogously to the same parts with the same reference numerals or the same component names. The location information selected in the description, e.g. above, below, to the side, etc., referring to the figure described and illustrated immediately, and if the position is changed, these are to be applied accordingly to the new position.
    1 shows a schematic illustration of a cranked bending tool 1. The bending tool 1 comprises a tool body 3, which has at least one tool shank 4 and a tool head 9. The tool shank 4 is provided for receiving in a receiving shaft 15 of the tool holder 14. The tool head 9 is then formed on the tool shank 4 in the bending direction. As can be seen from FIG. 1, the tool center of gravity 10 lies outside or laterally offset from a vertical plane of symmetry 17 of the receiving shaft 15. The eccentric tool center of gravity 10 results in a tilting moment 13. A situation is shown schematically in FIG. in which the bending tool 1 is supported with its tool shaft 4 via a movement means 8 in the tool holder 14 in a groove 16. Through this support on the movement means 8, the tilting moment 13 causes the tool body 3 to contact the tool holder 14 at at least one contact position. In the illustrated case, such contact positions can occur between the tool shank surface 7 and an inside 18 of the receiving shaft 15 or also between a top side of the tool shoulder 12 and an underside 19 of the tool holder 14. Contact positions between the movement means 8 and the groove 16 are also formed. When the bending tool 1 is displaced in the longitudinal direction 22, increased wear can occur at these contact positions.
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    It can also be seen from FIG. 1 that at least one clamping groove 6 is formed on the tool shaft 4, which is provided for tensioning the bending tool 1 by means of a clamping or clamping system, not shown.
    2 to 5 different embodiments of spacer elements 2 are presented and shown schematically. The spacer elements 2 shown exert a supporting force 23 on at least one surface, such as an inside 18 and / or underside 19, of the tool holder 14, as a result of which the tilting moment 13 is compensated for. According to the invention, the at least one spacer element 2 comprises a rolling body 25 which is mounted with a preload force 24 and which is arranged on or at least partially within the tool body 3. The spacer element 2 and / or the rolling element 25 are movably supported at least in the direction of the prestressing force 24. The at least one rolling element 25 is at least partially arranged in an outstanding manner relative to a surface of the tool element 3 that is adjacent to the at least one rolling element, such as the tool shank surface 7 or the tool shoulder top 12.
    In Fig. 2 different arrangements and possible positions of a spacer 2 on and / or within a tool body 3 are shown schematically.
    2a, 2b and 2f show exemplary embodiments in which the spacer element 2 transmits the supporting force 23 in the transverse direction 21 to the tool holder 14. The respective spacer elements 2 are arranged on or within the tool shank 4 of the tool body 3. In FIG. 2a, the spacer element 2 is arranged in the tool shank 4 such that it is flush with the top 5 of the tool shank 4. 2b, the spacer element 2 is accommodated within the tool shank 4 in such a way that the upper side 5 of the tool shank 4 can be designed to be essentially continuous in the longitudinal direction 22 and transverse direction 21. Analogously, these arrangements are to be transferred to the spacer element 2, which is shown schematically in FIG. 2f as a bending rod 31.
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    2c, 2d and 2e show examples in which the spacer element 2 is arranged on or within the tool head 9 or the tool shoulder 11. The application of the support force 23 takes place essentially in or opposite to the bending direction 20. In FIG. 2c, the spacer element 2 is positioned in the tool shoulder 11 in such a way that the at least one rolling element 25 can at least partially protrude beyond the upper side of the tool shoulder. Analogously to this, the arrangement of a spacer element 2 is indicated schematically in FIG. 2d, the spacer element 2 being fastened laterally to the tool shoulder 11 in the transverse direction 21 by means of a spacer element housing 30. 2e shows an exemplary embodiment, wherein the spacer element 2 comprises a bending rod 31 and is received within the tool head 9 in such a way that a rolling body 25 can at least partially protrude above the tool shoulder top 12.
    The arrangements shown schematically in FIGS. 2a to f can be combined with one another or can also be used individually.
    3a and 3b and FIG. 4 show examples of spacer elements 2 in which the at least one rolling element 25 is arranged in a rolling element receptacle 27. The application of the prestressing force 24 can be formed directly between the tool body 3 and the rolling body receptacle 27 by, for example, one or more spring elements. The spring elements are shown by way of example as coil springs, although plate springs, leaf springs and the like can also be suitable for carrying out the invention. This direct support of the rolling body receptacle 27 on the tool body 3 is not shown since such an embodiment is easily imaginable for the person skilled in the art. In the following, the description of an adjusting device 26 for the adjustable amount of the preload force 24 is discussed in more detail.
    As can be seen in FIG. 3a, the rolling body 25 is arranged rotatably in the rolling body receptacle 27. The supporting force 23 is applied by transferring the pretensioning force 24 to the rolling body receptacle 27. The rolling body receptacle 27 can have at least one limiting element 28. The fastening means 29 shown as screws are connected to the tool body 3 or tool shank 4. The limiting element 28 can be a recess or
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    Have groove, which allows a limited deflection of the rolling body receptacle 27 or the spacer 2 in the direction of the biasing force 24. The fastening means 29 thus serves on the one hand as a stop in the transverse direction 21 and projects beyond at least parts of the limiting element 28 in the longitudinal and / or transverse direction 22, 21, as a result of which the spacer element 2 can be prevented from accidentally falling out. An adjustment device 26 can also be seen from FIG. 3a. The illustrated embodiment of the adjusting device 26 comprises at least one spring element for applying the prestressing force 24, which consists of e.g. two coil springs and a supporting counter plate is formed. Furthermore, the spring travel of the spring element can be set by, for example, an adjusting screw 47 or the like. Such an adjusting screw 47 can be rotatably mounted in the tool body 3 or the tool shank 4 and is designed for easy adjustment of the counter plate, and thus the spring travel. Advantageously, the adjusting device 26 is arranged within the tool shank 4 in such a way that no component protrudes over the tool shank surface 7.
    With reference to the description of FIGS. 2 and 3a, a further exemplary embodiment is shown schematically in FIG. 3b, the spacer element 2 having two rolling elements 25 arranged next to one another in the longitudinal direction 22. The mode of operation is not repeated, in particular with reference to the description of FIG. 3a.
    FIG. 4 shows a further and possibly independent embodiment of a spacer element 2, the same reference numerals being used for the same parts as in the previous FIGS. 1 to 3. The mode of operation for applying the supporting force 23 while exerting a predeterminable prestressing force 24 on the rolling body 25 is carried out analogously to the description of FIGS. 3a and 3b. 4a shows a spacer element 2 which is arranged in a spacer element housing 30. The spacer housing 30 serves to receive the rolling body receptacle 27 of the at least one limiting element 28 and to support the adjusting device 26 relative to the rolling body
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    N2018 / 07900-AT-00 peraufnahme 27. As a result, the rolling body holder 27 and the adjusting device 26 are protected against contamination and / or mechanical action from the outside. In the selected illustration, two delimiting elements 28 are formed in the rolling body receptacle 27 as partial recesses. For this purpose, the spacer element housing 30 has complementary openings that are not visible in the sectional view, but allow the fastening means 29 to be installed from the outside. The fastening means 29 in turn enable a limited deflection of the rolling body receptacle 27 in the direction of the prestressing force 24. This arrangement is particularly space-saving. Likewise, the adjusting device 26 or the adjusting screw 47 can be reached very easily from the outside.
    The illustrated exemplary embodiments of the spacer element 2 in FIGS. 3a, 3b and 4 can also be arranged differently on or at least partially within the tool body 3 when viewed together with FIG. 2. A detailed description of alternative positioning and / or combinations of such spacer elements 2 is clearly evident to the person skilled in the art and is therefore not explained in more detail.
    5 shows exemplary embodiments schematically, the spacer element 2 being designed as a bending rod 31 such that the at least one rolling element 25 is arranged at a free end 32 and a fixed end 33 is fastened in the tool head 9 in the normal and / or bending direction 20 ,
    5a, the bending rod 31 is screwed to a threaded section 34 in the tool head 9. It is also conceivable that the bending rod 31 is fastened at its fixed end 33 outside the tool head 9. As can be seen in FIG. 5a, the bending rod 31 is deflected in the bending direction 20 when the bending tool 1 is received in the tool holder 14, as indicated schematically by a movement arrow. The rigidity of the bending rod 31 can be adjusted by the material and the diameter and / or the bending length 36 of the bending rod 31. When the rolling body 25 comes into contact with the underside 19 of the tool holder 14, the bending rod 31 is bent, as a result of which the prestressing force 24 is applied to the rolling body 25. To a limited deflection of the free
    18/34
    N2018 / 07900 AT-00
    To allow end 32 of the bending rod 31, a receiving opening 46 is provided in the tool body 3. In such an embodiment, the rolling body 25 is thus at least partially movable in the bending direction 20 and / or longitudinal direction 22.
    Another possibility for executing a spacer element 2 as a bending rod 31 is shown schematically in FIG. 5b. An adjusting device 26 is indicated in the illustration shown. The adjusting device 26 corresponding to a bending rod 31 can comprise an externally accessible adjusting screw 47, which is designed to adjust the supporting distance 42 between the threaded section 34 and a supporting element 43 movably mounted transverse to the bending direction 20. In this way, the available bending length 36 can be adjusted by means of the adjusting device 26, whereby the prestressing force 24 or supporting force 23 can be adjusted. It can also be seen from FIG. 5b that the support element 43 supports the bending section 35 to form a two-point support. The support element 43 is preferably designed as a sleeve which at least partially surrounds the bending rod 31 on part of the bending section 35.
    Furthermore, a further exemplary embodiment can be seen from FIG. 5b, in which the bending rod 31 is designed as a waisted bending rod 31. Here, the bending section 35 is indicated as a first waist section 38 and the rolling body section 37 as a second waist section 39. At least one waist section diameter 40 of the first and / or second waist section 38, 39 is smaller than a thread section diameter 41. Analogous to the description of FIG. 5a, the rigidity of the waisted bending rod 31 can be set relatively easily by the local diameter and / or material etc. of the bending rod 31.
    1 to 5 also show the formation of at least one movement means 8 which is of outstanding design at least on one side on the tool shank 4 relative to a respective tool shank surface 7. Such movement means 8 are used for receiving in a groove 16 of the tool
    19/34
    N2018 / 07900-AT-00 take 14 and enable a movement of the bending tool 1 in the longitudinal direction 22. It has proven to be particularly advantageous to design at least two movement means 8 in the longitudinal direction 22 next to one another as a sliding element 44 or rolling element 45. Such a sliding element 44 is preferably connected to the tool shank 4 as an elongated sliding body and is arranged at least on the side of the bending tool on which the tool center of gravity 10 is mounted. Analogously, the at least one movement means 8 can be designed as a rolling element 45. Schematic representations for this are shown in FIGS. 1 to 5.
    In a further embodiment, at least two movement means 8 are formed in the transverse direction 21 on opposite sides of the tool shank 4, as can be easily deduced from the overview and discussions of FIGS. 1 to 5.
    In a special embodiment, the movement means 8 or sliding element 44 can also be designed as an integral extension of the tool shank 4 and thus be produced in one piece with the tool shank 4. Such movement means can preferably have a greater extension in the longitudinal direction 22 than in the bending direction 20, as a result of which a good load transfer can be achieved. A movement means 8 designed as an extension of the tool shank 4 is preferably provided with a surface layer, not shown, with a low coefficient of friction.
    The exemplary embodiments show possible design variants, it being noted at this point that the invention is not limited to the specially illustrated design variants of the same, but rather also various combinations of the individual design variants with one another are possible and this variation possibility is based on the teaching of technical action through the present invention Ability of the specialist working in this technical field.
    20/34
    N2018 / 07900 AT-00
    The scope of protection is determined by the claims. However, the description and drawings are to be used to interpret the claims. Individual features or combinations of features from the different exemplary embodiments shown and described can represent independent inventive solutions. The object on which the independent inventive solutions are based can be found in the description.
    All information on value ranges in the objective description is to be understood so that it includes any and all sub-areas, e.g. the information 1 to 10 is to be understood so that all sub-areas, starting from the lower limit 1 and the upper limit 10, are included, i.e. all sections start with a lower limit of 1 or greater and end with an upper limit of 10 or less, e.g. 1 to 1.7, or 3.2 to 8.1, or
    5.5 to 10.
    For the sake of order, it should finally be pointed out that, for a better understanding of the structure, elements have sometimes been shown to scale and / or enlarged and / or reduced.
    21/34
    N2018 / 07900 AT-00
    LIST OF REFERENCE NUMBERS
    1 bending tool 28 limiting element 2 spacer 29 fastener 3 Tool body 30 Spacer housing 4 tool shank 31 bending Beam 5 Top of the tool 32 free endnomic 33 firm end 6 clamping groove 34 threaded portion 7 Tool shank surface 35 bending section 8th means 36 bending length 9 Tool head 37 Roll body section 10 Tool focus 38 first waist section 11 tool shoulder 39 second waist section 12 Tool shoulder top 40 Waist section diameter 13 overturning moment 41 Gewindeabschnittsdurchmes- 14 tool holderser 15 receiving shaft 42 supporting distance 16 groove 43 supporting 17 plane of symmetry 44 Slide 18 Inside of the 45 rolling elementmeschachts 46 receiving opening 19 Underside of tool holder 47 adjustingacceptance 20 bending direction 21 transversely 22 longitudinal direction 23 supporting force 24 preload force 25 roll body 26 adjustment 27 Roll Length
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    N2018 / 07900 AT-00
    权利要求:
    Claims (15)
    [1]
    claims
    1. Cranked bending tool (1) for a bending machine, in particular a die bending machine, comprising
    - A tool body (3) which has at least one tool shaft (4) for at least partially receiving the bending tool (1) in a bending direction (20) in a receiving shaft (15) provided for this purpose, a tool head adjoining the tool shaft (4) in the bending direction (20) (9), which has a tool center of gravity (10) outside a vertical plane of symmetry (17) of the receiving shaft (15) and has a tool shoulder (11) at least on one side in a transverse direction (21),
    - And at least one on the tool shaft (4) for moving the bending tool (1) in the longitudinal direction (22) of the bending machine for receiving in a groove (16) provided movement means (8), which is at least on one side of the tool shaft (4) relative to a respective tool shaft surface (7) is excellently trained,
    - And at least one spacer element, for applying a counteracting supporting force (23) to at least one surface (18, 19) of the tilting moment (13) caused by deviation of the tool center of gravity (10) from the plane of symmetry (17) in the transverse direction (21) Tool holder (14), characterized in that the at least one spacer element (2) comprises at least one rolling body (25) mounted with a pretensioning force (24), which on or at least partially within the tool body (3) at least in the direction of the pretensioning force (24 ) is movably mounted and is at least partially excellently arranged relative to a surface (18, 19) of the tool body (3), preferably adjacent to the at least one rolling body (25).
    [2]
    2. cranked bending tool (1) according to claim 1, characterized in that the at least one rolling element (25) for applying the supporting force (23), normal to the bending direction (20) or transverse direction (21) on an inside (18) of the receiving shaft ( 15) and / or in the bending direction (20) on an underside (19)
    23/34
    N2018 / 07900-AT-00 of the tool holder (14), is arranged on and / or at least partially in the tool body (3).
    [3]
    3. cranked bending tool (1) according to one of the preceding claims, characterized in that the at least one spacer element (2) has an adjusting device (26) for adjusting the amount of the biasing force (24).
    [4]
    4. cranked bending tool (1) according to one of the preceding claims, characterized in that the spacer element (2) comprises at least two rolling elements (25), which are preferably arranged side by side in a rolling element holder (27).
    [5]
    5. cranked bending tool (1) according to one of the preceding claims, characterized in that the at least one spacer element (2) comprises a rolling element holder (27) and at least one limiting element (28), which limiting element (28) for limiting deflection of the rolling element holder (27 ) or the rolling body (25) by means of at least one fastening means (29) with the tool body (3) in the direction of the biasing force (24) is movably connected.
    [6]
    6. cranked bending tool (1) according to one of the preceding claims, characterized in that the at least one spacer element (2) is arranged in a spacer element housing (30) which at least for receiving the rolling body receptacle (27) and the at least one limiting element (28), and is designed to support the adjusting device (26) with respect to the rolling body receptacle (27).
    [7]
    7. cranked bending tool (1) according to claim 6, characterized in that the at least one spacer element (2) on the outside of the tool head (9)
    24/34
    N2018 / 07900 AT-00
    Support of the bending tool (1) on the underside (19) of the tool holder (14) is arranged.
    [8]
    8. cranked bending tool (1) according to one of claims 1 to 5, characterized in that the spacer element (2) is designed as a bending rod (31) such that the at least one rolling element (25) at a free end (32) of the bending rod ( 31) is arranged and a fixed end (33) of the bending rod (31) normal to the bending direction (20) and / or in the bending direction (20) in the tool body (3), preferably tool head (9), is attached.
    [9]
    9. cranked bending tool (1) according to claim 8, characterized in that the at least one rolling body (25) is at least partially arranged opposite an upper side of the tool shoulder (12) and the rolling body (25) for applying the supporting force (23) in the bending direction (20) opposite the tool holder (14) with the fixed end (33) of the bending rod (31) normal to the bending direction (20) in the tool head (9).
    [10]
    10. cranked bending tool (1) according to one of claims 8 or 9, characterized in that the bending rod (31) at least one threaded portion (34) for receiving the bending rod (31) in the tool head (9) and / or tool shank (4), one Bending section (35) with a predeterminable bending length (36) and a rolling body section (37), and the adjusting device (26) for adjusting the pretensioning force (24) by adjusting a predeterminable support distance (42) between the threaded section (34) and rolling body section (37 ), the bending section (35) is arranged at least partially supporting.
    [11]
    11. cranked bending tool (1) according to one of claims 8 to 10, characterized in that the bending rod (31) is designed as a waisted bending rod (31), the bending section (35) as a first waist section (38) and the rolling body section (37 ) is designed as a second waist section (39) and at least one waist section diameter (40) of the first and / or
    25/34
    N2018 / 07900-AT-00 second waist section (38, 39) is smaller than a threaded section diameter (41).
    [12]
    12. cranked bending tool (1) according to one of claims 8 to 11, characterized in that the adjusting device (26) for adjusting a predetermined support distance (42), the bending section (35) at least partially encasing, preferably sleeve-shaped support element (43) ,
    [13]
    13. cranked bending tool (1) according to any one of the preceding claims, characterized in that at least two movement means (8) in the longitudinal direction (37) side by side as a sliding element (44) or preferably as a rolling element (45) are formed.
    [14]
    14. cranked bending tool (1) according to one of the preceding claims, characterized in that at least two movement means (8) in the transverse direction (21) on opposite sides of the tool shaft (4), preferably symmetrically opposite, are formed.
    [15]
    15. cranked bending tool (1) according to one of the preceding claims, characterized in that at least movement means (8) is formed in one piece with the tool shaft (4) as an extension.
    26/34
    N2018 / 07900 AT-00
    -— 17th

    TRUMPF Maschinen Austria GmbH & Co. KG.
    27/34


    TRUMPF Maschinen Austria GmbH & Co. KG.
    28/34

    TRUMPF Maschinen Austria GmbH & Co. KG.
    29/34


    TRUMPF Maschinen Austria GmbH & Co. KG.
    30/34


    8.44
    TRUMPF Maschinen Austria GmbH & Co. KG.
    31/34

    TRUMPF Maschinen Austria GmbH & Co. KG.
    32/34

    TRUMPF Maschinen Austria GmbH & Co. KG.
    33/34

    TRUMPF Maschinen Austria GmbH & Co. KG.
    34/34
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    同族专利:
    公开号 | 公开日
    EP3814032A1|2021-05-05|
    CN112165997A|2021-01-01|
    WO2020000003A1|2020-01-02|
    AT521173B1|2019-11-15|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    AT505282018A|AT521173B1|2018-06-27|2018-06-27|Bending tool with spacer element|AT505282018A| AT521173B1|2018-06-27|2018-06-27|Bending tool with spacer element|
    CN201980033286.4A| CN112165997A|2018-06-27|2019-05-29|Bending mould with spacer elements|
    EP19736290.8A| EP3814032A1|2018-06-27|2019-05-29|Bending tool comprising a spacer element|
    PCT/AT2019/060180| WO2020000003A1|2018-06-27|2019-05-29|Bending tool comprising a spacer element|
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