EP0106030A1 - Bending machine with mandrel - Google Patents

Abstract

In a pipe bending machine with a mandrel arranged in the pipe to be bent in the vicinity of the bending template, which is attached to the head end of a mandrel rod, the rear end of which is connected to a mandrel retraction, the mandrel rod is provided or connected to a measuring device which is used in an axial direction and radial overloading of the mandrel rod actuates a switching element that switches off or eliminates the overloading of the mandrel or the mandrel rod.

Description

The invention relates to a pipe bending machine with a feed carriage having a clamping sleeve, a bending template with a clamping jaw and an adjacent slide rail and a bending mandrel arranged in the pipe to be bent in the vicinity of the bending template and fastened to the head end of a mandrel bar.

When bending pipes, a mandrel is often used so that the round inner cross-section is preserved or largely preserved during bending. Also for bending two nested tubes, such as e.g. described in DE-OS 27 32 046 by the applicant, mandrels are used.

Bending mandrels, which come into effect in the area of the bending template and the slide rail, are fastened to a mandrel rod which has a smaller cross section than the bending mandrel. The mandrel rod is attached to the piston of a piston cylinder assembly that advances the mandrel rod with the mandrel for bending and retracts after bending.

The pipes to be bent on a pipe bending machine, which are pushed over the mandrel and the mandrel rod to load the pipe bending machine, do not always have the guarantee that they are straight. For example, individual pipes can be slightly curved, often as a result of damage during transport.

Many pipes are manufactured in such a way that they are bent from a sheet metal strip into a pipe and then welded lengthways. In most cases, the weld seam is dimensioned such that no subsequent processing needs to take place in order to remove protrusions of the weld seam that protrude inwards or outwards. Nevertheless, it cannot be ruled out that parts of the weld seam protrude inwards and thus lead to a tapering of the inner pipe cross section.

Pipes that are not straight or pipes with a part of the weld projecting inwards make it difficult to push the pipe over the mandrel. Since this sliding is done mechanically, it often happens that ver by bending or by a weld wrinkled inner tube cross-section when pushed over by striking the mandrel against the inwardly projecting tube wall as a result of the reduction in the tube cross-section, the mandrel rod is not only compressed, but in many cases is bent by the sprain so that it becomes unusable and must be replaced with another mandrel rod . Since in many cases the tube should not be displaceable over the mandrel rod due to the bending of the mandrel rod, but nevertheless takes place through the tube feed, it cannot be ruled out that further damage will occur in addition to the bending of the mandrel rod.

In this context, it is also possible that a tube provided with a reduced tube cross-section is displaced over the mandrel of the mandrel rod, but leads to such damage to the mandrel rod by bending that this only becomes noticeable when the tube is bent on the bending template, for example in the way that after the bending the retraction or before the bending the advancement of the mandrel over the mandrel bar is difficult or not feasible.

If a pipe is bent over the bending template in one plane, then the subsequent pipe bend is bent in another bending plane in many cases. To do this, the tube is rotated before the bend. During this turning, the mandrel remains in the tube. If, for the reasons mentioned above, the pipe cross section at local Place is tapered, then this tapered tube cross-section can also lead to a clamping of the mandrel on the inner tube wall, with the result that when the mandrel rotates, caused by the clamping sleeve on the feed carriage, the mandrel rod is subjected to torsion, which over the plastic area of the Mandrel rod can lead to permanent deformation of the mandrel rod as well as to a torsional break. Damage to the mandrel or the mandrel rod or consequential damage to other parts of the pipe bending machine, for example the mandrel retraction or the like, is particularly serious in pipe bending machines that work automatically, for example in such a way that the loading for bending and the removal of the bent pipe from the pipe bending machine can be done fully automatically, as described for example in the application according to DE-OS 28 32 980 of the applicant. In such bending machines with automatic loading and automatic removal, even small deformations of the bending mandrel or its mandrel rod that go beyond a certain tolerance act to severely obstruct the program sequence.

The present invention is based on the object of ensuring in a pipe bending machine that the mandrel or the mandrel bar carrying it does not suffer any deformation beyond an adjustable tolerance limit.

To solve this problem with a pipe bending machine a feed carriage having a clamping sleeve, a bending template with clamping jaw and an adjacent slide rail and a bending mandrel arranged in the pipe to be bent in the vicinity of the bending template, which is fastened to the head end of a mandrel rod, the rear end of the mandrel rod having a mandrel retraction in the shape of a Piston-cylinder arrangement is provided, proposed according to the invention, that the mandrel rod is connected or provided with a measuring device which, when the mandrel rod is overstressed, actuates a switching element which switches off or eliminates the overstressing of the mandrel.

The proposal according to the invention ensures that when the mandrel rod is stressed beyond an adjustable amount, those measures are taken which eliminate further stress on the mandrel rod.

The measures to be carried out can be of many types, depending on the stress through which the mandrel or the mandrel rod carrying it has been overstressed. If, for example, the upper stress on the mandrel or the mandrel rod is carried out by pushing the tube to be bent over the mandrel, then the pushing is stopped with the effect that the excessive stress stops immediately. Then the pipe which is not suitable for bending is automatically removed from the bending machine by the device which it is in the bending machine has been introduced, removed or prepared by machine so that it can be removed from the bending machine by hand.

If the upper stress on the mandrel or the mandrel rod was caused by the rotation of the tube, this rotary movement is stopped immediately. The measures are then carried out which are necessary to remove the pipe which is unsuitable for bending from the pipe bending machine or, if necessary, to continue bending after the fault has been eliminated.

The proposal according to the invention to provide the mandrel bar with a measuring device can be implemented particularly advantageously with the proviso that the mandrel bar is connected or provided with a measuring device at its rear end. This measuring device can detect the axial stress on the mandrel rod and switch it off or eliminate it via a switching element. This measuring device can also separately or additionally detect the torsional or torsional stress on the mandrel rod and switch it off or eliminate it via a switching element.

The signals resulting from an overstressing of the mandrel bar can be entered into the computer control of the pipe bending machine, so that in the program control in the event of an overstressing of the mandrel bar provided or necessary Measures are carried out, depending on the respective cause, so that in addition to avoiding damage to the mandrel rod, other consequential damages are also avoided.

The further solution according to the invention is particularly advantageous in that the rear end of the mandrel rod is mounted on a housing which is provided with at least one piston-cylinder arrangement for measuring the force exerted on the mandrel rod. This solution thus includes the two measures that the housing of the measuring device carries the mandrel rod at the same time and the excessive stress emanating from the mandrel rod is transferred to a piston-cylinder arrangement, so that the measured value is recorded or determined hydraulically. This solution, to transfer the overstressing of the mandrel rod to the piston of a piston-cylinder arrangement, first has the advantage that the hydraulic fluid arranged in the cylinder, in conjunction with corresponding valves, allows a first damping to take place, so that the piston in the piston -Cylinder arrangement via an upper load on the mandrel rod also acts and can act as a shock absorber, so that if too much axial pressure is exerted on the mandrel rod when pushed over it, this is elastic due to the yielding of the mandrel rod or the piston in the cylinder space can be caught. At the same time, the pressure that can be set for the mandrel can also be measured by the pressure that can be set in the cylinder chamber rod corresponds to damage-free deformation in its elastic or plastic range.

The setting of the pressure can be regulated by pressure valves known in the art. Depending on the cross-section and / or the material properties and the length of the mandrel bar, the force is set, beyond which the measures for protecting the mandrel bar and other machine elements take place.

In a further embodiment according to the invention, it is proposed that the piston consists of a front section which projects from the measuring housing and is connected to the mandrel rod and a rear section which projects into the cylinder space connected to the pressure source and a sensor is arranged on the piston, which cooperates with a switch arranged on the measuring housing. The sensor on the piston protrudes particularly advantageously in the radial direction and interacts with a preferably contactless limit switch.

The above-described piston, which carries the mandrel rod at the front and engages at its rear end in a cylinder chamber which determines the load, permits the further solution that an essentially radially projecting add-on element is present in the central region of the piston, which in two opposite sides Radial plane extending pistons are associated with cylinders. This solution has the effect that the measuring housing, which measures and evaluates the axial thrust on the piston rod, at the same time also measures the measuring device for the torsional or torsional stress on the mandrel rod, and thus several stresses can be measured or recorded in one measuring housing.

The pistons are particularly advantageously designed with an enlarged diameter at their ends facing the assigned cylinder spaces, each cylinder space having two different diameters correspondingly stepped.

Another proposal according to the invention is that there is a single measuring pin on the piston for the axial movement and the rotary movement of the mandrel rod, which cooperates with only one contactless limit switch. The contactless limit switch particularly advantageously has a surface lying in the radial plane of the piston and adjoining surfaces that extend obliquely thereto in the manner of a broken edge.

Another proposal according to the invention is that the measuring housing is provided on its side facing away from the mandrel rod with a holder for the piston rod of the mandrel retraction in the form of a cylinder connected to the piston rod.

The invention is exemplified in the drawing.

• Figur 1 im wesentlichen schematisch eine Rohrbiegemaschine mit Dorn,
• Figur 2 in Oberansicht und im Schnitt sowie im wesentlichen schematisch die zum Biegen mit Biegedorn notwendigen Bauelemente,
• Figur 3 die Meßeinrichtung im vertikalen Schnitt,
• Figur 4 die Meßeinrichtung nach Figur 3 in der Ansicht von oben,
• Figur 5 die Meßeinrichtung nach den Figuren 3 und 4 im Querschnitt, teilweise im Schnitt dargestellt entsprechend der Linie IV-IV nach Figur 4.

Show it:

• FIG. 1 essentially schematically a pipe bending machine with a mandrel,
• FIG. 2 in top view and in section, and essentially schematically, the components required for bending with a mandrel,
• FIG. 3 the measuring device in vertical section,
• FIG. 4 the measuring device according to FIG. 3 in a view from above,
• 5 shows the measuring device according to FIGS. 3 and 4 in cross section, partly shown in section along the line IV-IV according to FIG. 4.

FIG. 1 shows a pipe bending machine with the feed carriage 10, which can be pushed back and forth on one or more guide rails 11 on the upper side of the machine housing 12. The feed carriage 10 has a tubular cylinder 13, in the interior of which there is a clamping sleeve 14, in which the tube 15 to be bent is clamped. The tube 15 is guided around a pivotally mounted bending template 16, which has a recess 17 corresponding to the tube radius.

The tube 15 is pressed against the bending template via a clamping jaw 18, the clamping jaw being actuated on a clamping device 19 via a hydraulic cylinder 20. Both are arranged on the swivel table 21, which is rotated in the indicated direction 22 of the arrow. 23 is a slide rail.

The mandrel 24, which is fastened to the front end of the mandrel rod 25, is present within the tube 15 in the region of the bending template and the slide rail. The mandrel rod itself is mounted on a measuring housing 26, which is provided with a foot 27 on the rail 11 in the axial direction of the pipe to be bent back and forth. The measuring housing 26 is attached to the piston rod 28 of the hydraulic cylinder 29. Components 28 and 29 are also referred to as mandrel retraction. These are carried by the stand 30. It should be noted that the tube bending machine described above also has guides in order to be able to move the slide 10 and the measuring housing 26 or the stand 30 transversely to the longitudinal extent of the tube to be bent, so that an adaptation to the bending radius is possible the template 16 is present.

It should be noted that with the solution according to the invention, to be described in detail below, not only can a mandrel bar be carried and secured against overstressing, as happens when bending a single tube, but also according to the teaching according to DE-OS 27 32 046 two nested tubes can be bent, with the proviso that the measuring housing accommodates two mandrel rods, each individual mandrel rod can be provided with an associated measuring device in order to avoid overstressing by compression or torsion.

Figures 3 to 5 show a particularly advantageous device for determining and evaluating an upper load on the mandrel or the mandrel bar. The mandrel rod 25 is connected at its rear end to a mandrel sleeve 31. The mandrel sleeve is thus a coupling element. It has a radial bore 32. The sleeve overlaps a piston 33, which is also provided with a radial bore, so that the non-positive connection between the sleeve and piston 33 is provided by a bolt inserted into the two bores. The piston 33 is initially supported in its central region 33b in the measuring housing section 26a. With its rear region 33c it engages in a cylinder space 34 which is arranged in the housing part 26b. The cylinder chamber 34 is provided with a channel 35 so that an oil pressure adjustable pressure is available via a connection 36. This adjustable oil pressure is carried out using means known per se, for example corresponding pressure valves. The housing ring 26c, to which the piston rod 28 is fastened, is flanged to the housing 26b via screws 37, 37a. In order to ensure the displacement of the measuring housing, this is provided with a slide 38 which rests on the rail 11 (see also FIG. 1) and is provided with numerous lubrication channels 39 and 40 for simplified sliding movement.

In the central region 33b of the piston, the diameter of which is larger than that of the front region 33a or the rear region 33c, there is a radially projecting attachment 41, which is part of a switching element. First there is a radially projecting bolt 42, which is extended at its upper end by a screw bolt of smaller diameter 43. This screw bolt as pin 43 is assigned a contactless limit switch 44, preferably from a Turck company. This limit switch is also shown in Figure 4. It has a flat surface 45 running in the radial plane of the piston. It should be noted that the shaft of the screw 43 does not rest against this surface 45, even in the starting position, as can be seen from FIG. 3. Figure 4 shows an avoidable system, which is not present, however, because the head 43a of the screw is present above the aforementioned surface 45.

In the zero position, in which no compressive force or no significant compressive force is exerted on the mandrel rod or all forces act in the plastic or elastic range, the pin 43 is assigned to the surface 45 at such a distance that a neutral position is present, ie the movement sequences for Pipe bending can be done. However, if an appreciable compressive force is exerted on the mandrel rod and from it via the mandrel sleeve 31 to the piston 33, which entails the risk of damage with consequential damage, then the piston 33c overcomes the counterforce built up by the oil pressure in the cylinder space 34 the result that the piston 33 is pushed into the cylinder space 34 by an amount, that is to say axially displaced, that the pin 43 is removed from the surface 45 of the limit switch by such an amount that the neutral behavior is canceled and a signal is given . This signal, for example entering into the control, triggers then take those measures that eliminate the axial load on the mandrel bar.

The aforementioned bolt 42 is provided with a spacer ring 46 and carries a support roller 47, which is shown in particular in FIG. 5. This support roller has two opposing surfaces 48 and 49, to which pistons 50 and 51 are assigned, the head surfaces 50a and 51a of which have an enlarged diameter. Correspondingly, the associated cylinder spaces 52 and 53 are stepped. This expansion of the diameter of the piston heads and the cylinder space causes the pistons to not be displaceable by a predetermined amount in the direction of the support roller 47, so that a gap to be maintained exactly between the head ends 48 and 49 of the support roller with the associated opposite head ends of the pistons 50 and 51 is preserved.

The cylinder spaces 52 and 53 are closed off from the outside by screwed-on covers 54 and 55. They have threaded ports 55 and 56 to allow connection to an oil pressure source. The cylinder chambers are also provided with a set oil pressure. If a torsional force of such a strength is exerted on the bending mandrel or via this on the mandrel rod, for example when rotating the tube by clamping the mandrel on the inner wall of the tube, that a predetermined dimension is exceeded, then either depends on the direction of rotation Head surface 48 on the piston 50 or the head surface 49 on the piston 51. If the out exerted force overcomes the set back pressure, then the pin 43 is moved in the circumferential direction. A movement by a small amount does not give any change, as can be seen from FIG. 4. From this it can be seen that the surface 45 has a certain length in the radial plane, which can also be changed by exchanging it for a differently dimensioned limit switch. The contactless limit switch has tapered edge surfaces 57 and 58. As soon as the pin 33 leaves the region of the surface 45 due to the rotation of the piston 33 about its longitudinal axis, this likewise results in the triggering of a signal. In conjunction with measures stored in the control, this signal then leads to avoid further overloading of the mandrel bar.

Claims (16)

1. Pipe bending machine with a feed sleeve having a clamping sleeve, a bending template with clamping jaw and an adjacent slide rail and a bending mandrel arranged in the tube to be bent in the vicinity of the bending template, which is attached to the head end of a mandrel rod, the rear end of the mandrel rod with a Mandrel retraction is provided in the form of a piston-cylinder arrangement, characterized in that the mandrel rod (25) is provided or connected to a measuring device (33, 34) which, when the mandrel rod (25) is overstressed, has a switching element (43, 44) actuated, which switches off or eliminates the upper stress on the mandrel or the mandrel rod (25). 2. Device according to claim 1, characterized in that the mandrel rod (25) is connected or provided at its rear end with a measuring device (33, 34). 3. Apparatus according to claim 1 and optionally according to claim 2, characterized in that the measuring device (33,34) detects the axial stress on the mandrel rod and switches it off or eliminates it via a switching element (43,44). 4. The device according to claim 3, characterized in that the measuring device (33, 34) additionally detects the torsional or torsional stress of the mandrel rod (25) and switches it off or eliminates it via a switching element (43, 44). 5. The device according to claim 1, character- ized in that the rear end of the mandrel rod (25) is mounted on a housing (26) having at least one piston-cylinder arrangement (33,34) for measuring the on the mandrel rod (25) exerted force is provided. 6. The device according to claim 5, character- ized in that the rear end of the mandrel rod via a connecting element (31, 32), in particular in the form of a sleeve, is provided with a piston 33 extending in the axial extension of the mandrel rod, the cylinder space ( 34) is connected to a pressure source. 7. The device according to claim 6, characterized in that the pressure with the cylinder space (34) is variably adjustable. 8. Device according to claims 1 to 7, characterized in that the piston (33) from one front section (33a), which protrudes from the measuring housing (26) and is connected to the mandrel bar (25) and a rear section (33c), which projects into the cylinder space (34) connected to the pressure source and on the piston (33 ) a sensor (43) is arranged which interacts with a switch (44) arranged on the measuring housing (26). 9. The device according to claim 8, characterized in that the sensor (43) on the piston (33) protrudes in the radial direction and interacts with a limit switch (44), in particular a contactless limit switch. 10. The device according to claim 1 and one or more of claims 2 to 9, characterized in that a substantially radially projecting attachment element (42, 46, 47) is present in the central region (33b) of the piston (33), to which Two opposing pistons (50, 51) with cylinders (52, 53) extending in the radial plane are assigned. 11. The device according to claim 10, characterized in that the cylinder space (34 or 52, 53) is provided with an oil supply line for an adjustable pressure. 12. The apparatus according to claim 11, character- ized in that the pistons (51, 52) formed at their ends facing the cylinder space (52, 53) with an enlarged diameter and the cylinder space correspondingly stepped, two different diameters. 13. The apparatus according to claim 1 and one or more of claims 2 to 12, characterized in that the piston (33) for the axial movement and the rotary movement is assigned a single pin (43) which cooperates with a contactless limit switch (44). 14. The apparatus according to claim 13, character- ized in that the contactless limit switch (44) has a surface (45) extending in the radial plane of the piston (33) and surfaces (57 and 58) extending obliquely thereto in the manner of a broken edge . 15. The apparatus according to claim 1 and one or more of claims 2 to 14, characterized in that the measuring housing (26) on its side facing away from the mandrel edge (25) with a holder (26c) for the piston rod (28) of the mandrel retraction (28th , 29) is provided. 16. The apparatus according to claim 1 and one or more of claims 2 to 15, characterized in that the measuring housing (26) consists of three housing parts (26a, 26b, 26c) divided in the radial plane and connected by screws (27), the first housing part receiving the piston (33) with the measuring pin (43), the second housing part the cylinder space (34) and the third housing part receives the piston rod (28) of the mandrel retractor (28, 29).

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