EP1554066A2 - Device for free three-dimensional profile forming - Google Patents

Abstract

The appliance has a profile advance unit (3), a guide element (1) engaging on the profile, and a bending sleeve (5) in a retainer element (4). The profile (7) is turned in or with the guide element, and in/with the bending sleeve, about a longitudinal axis (L). The bending sleeve is born pivoted via the retainer element about a first hinge point of a rocker arm, which in turn is pivoted about a second hinge point. The retainer element is held in a guide groove, so that the inner surface of the sleeve acting in a bending manner on the outside of the profile, is permanently tangential to an arc of a circle corresponding to the desired bending radius, when the position of the retainer element in the groove changes.

Description

 Device for 3D free-form bending of profiles

The invention relates to a device for SD free-form bending of profiles with constant external dimensions over their length, in particular with a circular shape, with a feed device for moving the profile with a longitudinal axis, which has a rotary drive for rotating the profile about its longitudinal axis, in one to this Longitudinal axis parallel feed direction by a guide element having a passage opening, which rests on the surface of the profile, and a bending sleeve arranged in the feed direction behind the guide element and at least partially enclosing the profile to be bent, which is held in a carrier element with which it can be turned perpendicular to the The direction of advance of the profile lying axis can be tilted and displaced perpendicular to the longitudinal axis and tilting axis, such that the bending sleeve acts on the profile in a bending manner.

Such 3D free-form bending devices are known from the prior art. For example, a 3D profile bending device is known from JP 08 257 643 A, in which a profile is pushed by means of a feed device through a stationary guide element and a bending sleeve arranged behind it in the feed direction and integrated into a carrier element. The carrier element is rotatable in one around a first axis running perpendicular to the longitudinal axis of the profile to be bent through the center of the bending sleeve Holding rack held. The receiving frame itself is rotatably mounted about a second axis of rotation, which runs both perpendicular to the profile axis and perpendicular to the first axis through the center of the bending sleeve. Furthermore, the mounting frame can be moved along both axes. The profile can be bent three-dimensionally by coordinated rotation and displacement of the receiving frame or twisting of the support element in the receiving frame.

A disadvantage of this bending device is that the different rotary and sliding movements of the carrier element and the receiving part have to be coordinated exactly with one another in order to produce the desired profile shape. On the one hand, this entails high investment costs and, on the other hand, a complex CNC control of the bending device.

Another bending device, which works on the same principle as the aforementioned device, is known from EP 0 928 646 AI. In addition to the pivotability or displaceability about or along the mutually orthogonal axes arranged perpendicular to the profile axis, in this device the support element can be rotated about the longitudinal axis of the profile in order to achieve a desired torsion of the profile during bending. In this device, all degrees of freedom of the bending process are recorded, but in addition to the feed device, a total of five individual rotary or linear drives to be coordinated are required. This places the highest demands on precision and Synchronism of the drives and can not be realized inexpensively.

EP 0 928 645 AI describes a bending device for 3D free-form bending of profiles with a simplified structure. As in the prior art described above, in this device the profile is pushed by a feed device through a non-rotatable guide element and a U-shaped, open bending sleeve arranged behind it. The guide element is inserted into a sleeve which is connected to the machine frame in a manner fixed against relative rotation, about which sleeve in turn an outer sleeve is rotatably mounted. The axis of rotation of the outer sleeve coincides with the longitudinal axis of the profile. The outer sleeve has a cantilever extending in the feed direction, at the end of which a support element supporting the bending sleeve is pivotally mounted about an axis running perpendicular to the feed device and laterally offset to it. The position of this axis relative to the bending sleeve is chosen so that the rotation and displacement of the bending sleeve required to set the desired bending radius is accomplished by a single pivoting movement. A three-dimensional bending of the profile is achieved in that the outer sleeve and with it the open bending sleeve connected to the outer sleeve via the support element and the extension arm are rotated about the profile axis by a certain angle which corresponds to the desired change in the position of the bending plane becomes. Then the bending sleeve is again pivoted accordingly to set the desired bending radius and the bending continues in a new bending plane. Compared to the other bending devices described above, this device is characterized by a greatly simplified structure which, in addition to the feed device, only requires two further drives. However, the complex mechanism for rotating the bending sleeve via the rotatably mounted outer sleeve is disadvantageous. This is contrary to a compact design of the device. Also, in the transition phase from one bend to the other bend, an extended straight transition section that is often not desired is created. Furthermore, the use is limited to profiles with a circular cross-section, since the profile must be kept axially rotatable in the bending sleeve.

In practice, a 3D bending device for bending profiles with a circular cross-sectional shape is also known, in which the profile is pushed through a non-rotatable guide sleeve enclosing the profile and a bending sleeve arranged behind it and held in a carrier element and also enclosing the profile with a positive fit. The rotation and displacement of the bending sleeve required to set the desired bending radius is achieved in that the bending sleeve is rotatably held in a rocker arm via the carrier element perpendicular to the feed direction and is pivoted via a cantilever arm by means of an actuating cylinder. For the purpose of changing the bending plane, in contrast to the aforementioned prior art, instead of pivoting the bending sleeve about the longitudinal axis of the profile, the profile is changed by a drive integrated in the feed device twisted its longitudinal axis. As a result, the relative movement between the bending sleeve and the profile to be bent is unchanged.

As a result, a more compact construction of the bending device is possible based on the prior art described above. Nevertheless, this device is also not suitable for bending a profile with a cross-sectional shape that deviates from the circular shape, since the profile must be rotatably mounted both in the guide sleeve and in the bending sleeve.

In addition, the drawing and bending machines for hollow profiles, which are meanwhile very common in the automotive industry, are known from the prior art, but can only be used to implement bends in one plane, that is to say 2D bends. DE 100 20 727 Cl describes a drawing bending machine for thin-walled metal pipes. Here, the tube is clamped at its front end in a clamping device between clamping jaws. In the case of thin-walled tubes, it is necessary to support the tube from the inside in the area of the clamping by a clamping head and in the area of the bending deformation by a bending mandrel. In order to initiate the bending of the clamped tube, a bending table, which has a circular shape in the area of the bend, which defines the achievable bending radius, is pivoted about its axis of rotation. The tube is pulled forward and at the same time bent over the bending table. In addition to the limitation to bending in one plane, the central disadvantage of such drawing bending machines is that it is not possible to implement variable radii and bends around the longitudinal axis of the profile.

The invention is therefore based on the object of providing a device which, with a simple structure, allows the SD free-form bending of profiles with an outer shape which is constant over its length, such as that of a circle, but also that of an oval or regular polygon, etc.

This object is achieved in a device of the type mentioned in the invention in that

a) the profile is rotatably mounted in or with the guide element about the longitudinal axis, b) the profile is rotatably mounted in or with the bending sleeve about the longitudinal axis, c) the bending sleeve is pivotally mounted off-center about a first articulation point of a rocker, wherein the rocker is in turn pivoted about a second articulation point arranged on the same profile side as the first articulation point, eccentrically to the profile longitudinal axis, d) the support element is held in a guide groove on the profile side opposite the articulation points, in such a way that it bends on the outside of the profile acting area of the inner surface of the bending sleeve when changing the position of the part of the support element mounted in the guide groove minus the resilience of the profile always tangential to a bending radius that is desired in each case Circular arc is aligned.

The 3D free-form bending of a profile with constant external dimensions over its length is achieved in that the profile can be rotated about its longitudinal axis relative to the stationary position of the bending sleeve by means of the rotary drive acting on it. In the case of profiles with a cross-sectional shape deviating from the circular shape, the guide element in its receiving unit and the bending sleeve in the carrier element are rotated axially in particular by positive locking, while in the case of a profile with a circular cross-sectional shape the guide sleeve and the bending sleeve can also be firmly connected to their respective receptacles , Due to the twisting of the profile, the bending plane remains unchanged even after changing the bending direction. Therefore, the construction of the device can be structurally comparatively simple in that the device can be designed as an extension of a 2D drawing bending machine. The adjustment movement of the bending sleeve for setting the bending radius takes place in one plane and can thus be coupled, for example, to the movement of the bending table of a drawing bending machine. As a result, important components of a conventional draw bending machine can continue to be used. It is therefore possible for users who already have drawing bending machines for 2D bending to carry out 3D bending of profiles by suitably expanding their machines without having to invest in completely new machines. Due to the eccentrically pivotable mounting of the support element with the bending sleeve around a pivot point of a rocker arm, the positioning drive for the bending sleeve can be implemented inexpensively while minimizing the number of moving parts. Installation and control of linear axes to move the carrier element in two spatial directions is completely eliminated.

A compact construction of the device according to the invention can be realized in that the Füh approximately member ^'is formed as one about the longitudinal axis of the profile rotatably mounted guide sleeve. It proves to be particularly advantageous if the guide sleeve is divided lengthways. By dividing the guide sleeve, for example in two halves, it is achieved that the play between the profile and the guide sleeve, and thus also between the profile and the bending sleeve, can be completely eliminated. This enables bending with a particularly small bending radius compared to the prior art.

If the passage opening of the guide element has a cross-sectional shape that changes substantially continuously in the feed direction, so that the guide element acts on the profile as a shaping die, the profile cross section can additionally be specifically changed before the bending process. For this purpose, the guide element can be provided, for example, with shaped elements inserted into its passage opening. Small changes in the cross-sectional shape can take place in the cold state, while in the case of major changes in shape it is advisable that the Guide element has a heating device for heating the profile. It goes without saying that the heating device supports the bending process with a small selected bending radius even when the cross-sectional shape is kept constant.

In an advantageous embodiment of the invention it is provided that the edges of the passage opening of the guide sleeve are rounded on the input and / or output side. This makes it easier to insert the profile into the bending sleeve when preparing the bending process.

The device according to the invention is also particularly suitable for bending hollow profiles with variable bending radii. In the case of small bending radii, the device has a bending mandrel that supports the hollow profile from the inside during bending. This effectively prevents the hollow profile from collapsing, particularly when bending with a small bending radius, and reduces the formation of folds in the bent region.

A prerequisite for a uniform bending result while observing the set bending radius and minimizing the stresses occurring in the profile to be bent is the tangential alignment of the area of the inner surface of the bending sleeve which acts on the outside of the profile to form a circular arc corresponding to the bending radius. If no mandrel is used to internally support the profile to be bent, depending on the cross-sectional geometry and the wall thickness of the profile, the bending does not start at the exit of the guide element, but relative to the enclosed cross-sectional area already in the guide element, so that consequently there is a displacement of the circular arc in the direction opposite to the feed direction. A further tangential alignment of the bending sleeve to the shifted circular arc is then achieved in that the course of the guide groove is adjustable relative to the longitudinal axis of the profile.

In addition to the bending, a plastic torsion of the profile about its longitudinal axis can be achieved in that the bending sleeve has a rotary drive. In this case, the bending sleeve and with it the profile to be bent are rotated about the longitudinal axis of the profile by means of the rotary drive, while the corresponding rotation of the guide sleeve is prevented by a suitable blocking. The rotary drive can be integrated into the carrier element, for example.

For the bending sleeve, there are various design options with regard to adapting the sleeve opening to the cross section of the profile to be bent. This allows the bending sleeve to completely enclose the profile. A particularly variable use is also possible with a U-shaped bending sleeve.

As in the case of the guide sleeve, the introduction of the profile into the bending sleeve is facilitated in that the edges of the bending sleeve are rounded on the input and / or output side. It must be adequately secured against axial thrust exerted by the profile when inserting the profile and during operation. This also results in a bending result that corresponds exactly to the specifications supports that the inner surface of the bending sleeve has a linear or slightly concave curved area in the direction of the stroke. If the profile to be bent is a hollow profile with a circular outer shape, this area should be> 1/5 of the profile diameter.

To further minimize the formation of wrinkles during the bending process, it is expedient if a shaped element with an adapted passage opening, which corresponds in sections to the cross section of the profile, is arranged between the guide element and the bending sleeve in such a way that it acts as a wrinkle smoother on the profile. This element, which supplements the use of the above-mentioned bending mandrel in the case of the bending of hollow profiles, thus enables a further reduction in the bending radius. Depending on the application, it can be designed to be flexible or rigid. In the case of a profile with an outer circular shape, it expediently has a ring shape. According to a particularly advantageous embodiment of the invention, it can be designed as an extension of the guide element in the direction of the bending sleeve. An extension of the bending sleeve in the direction of the guide element is also possible. In these cases, a U-shaped configuration of the shaped element is expedient so that the side flanks of the profile are supported during the bending process. In the case of a flexible molded element, it can be designed as a spiral spring or made of an elastomeric material, for example an elastomeric plastic. The invention is explained in more detail below with the aid of a drawing representing an exemplary embodiment. In detail show:

1 is a side view of a device for 3D free-form bending of profiles with an inserted hollow profile immediately before the start of bending,

2 shows the device of FIG. 1 in longitudinal section,

Fig. 3 shows the device of Fig. 1 in perspective view

Fig. 4 shows the device of Fig. 1 in cross section I-I of Fig. 2 in detail.

The bending device has a guide element 1 designed as a guide sleeve, which is rotatably mounted about its longitudinal axis L in a stationary receiving block 2 via two bearings 2a. This rotation can be prevented by a blocking device, not shown. Furthermore, the guide element 1 is longitudinally divided into two sleeve halves la, lb. Together they form a passage opening lc adapted to the shape of the profile with a rounded edge Id on the input side. In the feed direction V of a profile 7 to be bent with a longitudinal axis L, in particular a hollow profile, behind the sleeve halves la, lb there is also a sleeve-shaped one made of a rubber-elastic material existing shaped element le arranged (see. Fig. 2), which also adapted to the cross-sectional shape of the profile 7 and is firmly connected to the lower sleeve half 1b. Furthermore, the bending device has a feed device 3 designed as a profile collet for clamping the profile 7 at its front end 7a in the feed direction V. The feed device 3 is in turn displaceable in a feed direction V by a linear drive, not shown. Furthermore, the feed device 3 is provided with a rotary drive, also not shown, which allows the feed device 3 and with it the profile 7 to be rotated about its longitudinal axis L.

A carrier element 4 designed as a carrier plate is arranged in the feed direction V behind the guide element 1 and the molded element le and is connected to the stationary receiving block 2 via two parallel rockers 4a (see FIG. 3). Both the carrier element 4 in the rockers 4a and the rockers 4a themselves are rotatably mounted in the receiving block 2. The carrier element 4 and the rockers 4a thus together form a coupling gear. A round opening 4b is formed in the carrier element 4, in which an inserted bending sleeve 5 is rotatably mounted by means of a bearing 4c (see FIG. 4). In addition, the bending sleeve 5 is pivotally mounted off-center via the carrier element 4 about two first articulation points P _{x of} the rockers 4a arranged on an axis running perpendicular to the longitudinal axis L of the profile. The rockers 4a are in turn pivoted about a second articulation point P ₂ arranged on the same profile side off-center to the longitudinal axis L of the profile. In the carrier element 4 A rotary drive, not shown, is integrated for rotating the bending sleeve. The inner cross section 5a of the bending sleeve 5 is also adapted to the shape of the profile 7 to be bent, in particular square or circular, but dimensioned larger than the passage opening 1c of the guide element 1. The edges 5b of the passage opening of the bending sleeve 5 are rounded on the entry and exit sides for easier handling , In addition, the inner surface of the bending sleeve 5 has a linear region 5c in the feed direction V (see FIG. 4).

A fork-shaped arm 2b is fastened to the receiving block 2, in each of which two branches 2c a curved guide groove 2d is formed. In the guide grooves 2d of the arm 2b, the carrier element 4 is slidably supported by guide pins 4c pointing outwards. Furthermore, an actuating arm 4d which is guided around the extended axis of rotation 6a of a disk-shaped bending table 6 is rigidly connected to the carrier element 4. The bending table 6 can be part of a conventional draw bending device. At the end of the actuating arm 4d, two outwardly facing guide pins 4e are also arranged. These engage in guide grooves 6c, which are formed in two cantilever arms 6b aligned in parallel. The cantilever arms 6b are firmly connected at one end to the axis of rotation 6a of the bending table 6 and are therefore adjustable together with the bending table 6 via its rotary drive, not shown. The operation of the bending device according to the invention is as follows:

The hollow profile 7 to be bent is firmly clamped with its one end 7a in the feed device 3. A bending mandrel 8 is inserted into the hollow profile 7 and is guided through the feed device 3 and fastened behind it by means of a fixed fastening element, not shown. This consists of a flexible front mandrel part 8a, in particular a ball chain for a tube with a circular cross-sectional shape, and a rear clamping head, not shown, via which the mandrel 8 is held axially. The bending mandrel 8 serves to prevent collapse or excessive wrinkling of the profile 7 in the course of the bending process. Therefore, its mandrel part 8a is supported on the inside of the hollow profile 7. It goes without saying that with a hollow profile with an angular shape, e.g. a tube with a square cross-sectional shape, the mandrel part must have a corresponding cross-sectional shape.

To prepare for the bending, the hollow profile 7 is inserted into the guide element 1 by the linear drive of the feed device 3 which grips the hollow profile 7 at its rear end 7a. This is facilitated by the rounded edge ld of the passage opening lc of the guide element 1 1 on the input side. Due to the correspondingly selected inner cross-sectional shape of the passage opening 1c, the guide element 1 bears in a form-fitting manner on the hollow profile 7. Before the initiation of bending, the carrier element 4 is in one Starting position I, in which the bending sleeve 5 is aligned with the guide element 1. The hollow profile 7 is now pushed so far through the guide element 1 and the shaped element le that its from

Feed device 3 facing away from end 7b, at the level of which the mandrel part 8a of the inserted mandrel 8 protrudes slightly beyond the bending sleeve 5.

To initiate bending in a first plane (2D bending) with constant feed of the hollow profile 7 and axially fixed bending mandrel 8, the extension arms 6b together with the bending table 6 are rotated clockwise by an angle α. The carrier element 4 is also moved via its actuating arm 4d, the guide pins 4e moving radially outward in the guide grooves 6c assigned to them. The carrier element 4 performs a pivoting movement relative to the feed direction V of the hollow profile 7, which is composed of a tilting movement and a translatory movement with at least a portion perpendicular to the profile axis L. When the pivoting movement of the cantilever arms 6b is completed by the angle α, the carrier element 4 is in a position II pivoted further clockwise than in FIGS. 1 and 2, which, like any other possible position, is unambiguously indicated by the respective position of the guide pins 4c, 4e in the guide grooves 2c formed in the cantilever ends 2b and by the position of the carrier element 4 relative to the rockers 4a. Each position of the carrier element 4 clearly corresponds to a bending radius, so that by a suitable choice of Adjustment angle α the desired bending radius can be easily adjusted.

For the transition to 3D freeform bending, i.e. a change in the direction of the bending or a change in the bending plane, the feed is stopped and the hollow profile 7 is rotated by the desired angle by the rotary drive connected to the profile collet 3. Both the guide element 1, which is rotatably mounted in the receiving block 2, and the bending sleeve 5, which is rotatably mounted in the carrier element 4, are also rotated in the process. It can be seen from this that, in contrast to the prior art, a strict rotational symmetry of the profile 7 to be bent is no longer required in the device according to the invention for performing the 3D free-form bending.

When the hollow profile 7 is rotated by the feed device 3, the portion of the hollow profile 7 which has already been bent is rotated out of the defined bending plane B of the bending device and the hollow profile 7 which is fed in again when the feed starts again is bent spatially unchanged in the bending plane B. The profile section located at the level of the bending sleeve 5 during the rotation of the hollow profile 7 is also moved out of the bending plane B. This is possible without adjusting the bending sleeve 5, since the passage opening 5a of the bending sleeve 5, which is dimensioned for the external dimensions of the profile 7 with lateral play, offers the profile 7 sufficient space. If a torsion of a profile with a cross-sectional shape deviating from the circular shape is required, the guide element 1 is blocked by the blocking device and the bending sleeve 5 is rotated in a defined manner. In this case, however, the bending plane cannot be changed.

If the bending radius is also to be changed, the position of the carrier element 4 holding the bending sleeve 5 is also adjusted in the manner described by rotating the extension arms 6b together with the bending table 6.

Claims

P A T E N T AN S P RÜ C H E

Device for 3D free-form bending of profiles (7) with external dimensions that are constant over their length, in particular with a circular shape, with a feed device (3) for moving the profile (7) with a longitudinal axis (L), which has a rotary drive for rotating the profile ( 7) around its longitudinal axis (L), in a feed direction (V) parallel to this longitudinal axis (L) through a guide element (1) which has a passage opening (lc) and which lies against the surface of the profile (7), and an in Feed direction (V) behind the guide element (1), which at least partially surrounds the profile (7) to be bent, is held in a support element (4) with which it rotates perpendicular to the feed direction (V) of the profile (7) horizontal axis can be tilted and displaced perpendicular to the longitudinal axis (L) and tilting axis, in such a way that the bending sleeve (5) acts on the profile (7) in a bending manner since you are marked, since ß a) the profile (7) in od it is rotatably supported with the guide element (1) about the longitudinal axis (L), b) the profile (7) is rotatably supported in or with the bending sleeve (5) around the longitudinal axis (L), c) the bending sleeve (5) the carrier element (4) around a first pivot point (P of a rocker (4a) is pivotally mounted eccentrically, the rocker (4a) in turn being pivotally mounted about a second articulation point (P ₂ ) arranged on the same profile side as the first articulation point (P _x ) eccentrically to the profile longitudinal axis (L), d) the support element on the articulation points (P _X , P ₂ ) opposite side of the profile is held in a guide groove (2d) such that the area of the inner surface of the bending sleeve (5) which acts on the outside of the profile (7) when the position of the in the guide groove ( 2d) of the mounted part of the carrier element (4) minus the resilience of the profile (7) is always oriented tangentially to a circular arc corresponding to the respectively desired bending radius.

2. Apparatus according to claim 1, because of which the rotatably mounted guide element (1) is designed as a guide sleeve (1).

3. Apparatus according to claim 2, d a d u r c h g e k e n n z e i c h n e t, that the guide sleeve (1) is divided longitudinally.

4. Device according to one of claims 1 to 3, characterized in that the passage opening (lc) of the guide element (1) has a substantially continuously changing cross-sectional shape in the feed direction (V), so that the guide element (1) as a shaping die the profile (7) acts.

5. Device according to one of claims 1 to 4, d a d u r c h g e k e n n z e i c h n e t, d a ß the guide element has a heating device for heating the profile (7).

6. Device according to one of claims 1 to 5, d a d u r c h g e k e n n z e i c h n e t, d a ß the edges (ld) of the passage opening (lc) of the guide sleeve (1) are rounded on the input and / or output side.

7. Device according to one of claims 1 to 6, d a d u r c h g e k e n n z e i c h n e t, d a ß in the case of a hollow profile to be bent (7) has a bending mandrel (8) which supports the hollow profile (7) during bending from the inside.

8. Device according to one of claims 1 to 7, d a d u r c h g e k e n n z e i c h n e t, d a ß the course of the guide groove (2d) relative to the profile longitudinal axis (L) is adjustable.

9. Device according to one of claims 1 to 8, d a d u r c h g e k e n n z e i c h n e t, that the bending sleeve (5) has a rotary drive.

10. Device according to one of claims 1 to 9, characterized in that ß the bending sleeve (5), the profile (7) completely encloses.

11. The device according to one of claims 1 to 9, d a d u r c h g e k e nn z e i c hn e t, that the bending sleeve (5) is U-shaped.

12. The device according to any one of claims 1 to 11, d a d u r c h g e k e n n e e c h n e t, that the edges (5b) of the bending sleeve (5) are rounded on the input and / or output side.

13. The device according to claim 1, wherein the inner surface of the bending sleeve (5) has a linear or slightly concave curved area (5c) in the longitudinal direction of the profile (L).

14. The apparatus of claim 13, d a d u r c h g e k e n n z e i c h n e t, d a ß in the case of a hollow profile (7) with a circular cross-section, the linear or slightly concave curved area (5c)> 1/5 of the profile diameter.

15. Device according to one of claims 1 to 14, characterized in that ß between the guide element (1) and the bending sleeve (5), a shaped element (le) with an adapted passage opening, which corresponds in sections to the cross section of the profile, is arranged such that it acts as a smoothing wrinkle on the profile (7).

16. The apparatus of claim 15, d a d u r c h g e k e n n z e i c h n e t, that the shaped element (le) is designed as an extension of the guide element (1) in the direction of the bending sleeve (5).

17. The apparatus of claim 15, d a d u r c h g e k e n n z e i c h n e t, that the shaped element (le) is designed as an extension of the bending sleeve (5) in the direction of the guide element (1).

18. The apparatus of claim 15, d a d u r c h g e k e n n z e i c h n e t, that the shaped element (le) is designed as a spiral spring, metal or elastomer rings.