EP0473036A2 - Wire bending machine for insulated wire - Google Patents

Abstract

A wire bending machine, for insulated wire consisting of solid material, comprises a wire feeding station, a bending station by means of which the wire is bent, at least one stripping station and a cutting station. The bending station has a support (94), which can be rotated about the longitudinal axis of the wire supplied, for a bending journal support (111, 124) with a bending journal (112, 125) fitted thereto. The bending journal support (111, 124) is supported on the support (94, 114) such that it can rotate about an axis running at right angles to the longitudinal axis of the wire feed, and the bending journal (112, 125) is mounted eccentrically on the bending journal support (111, 124), its longitudinal axis running parallel to its rotation axis and its length measured from the bending journal support being greater than the distance of the bending journal support from the longitudinal axis of the wire, in such a way that the bending journal (112, 125) carries out a movement having a cylindrical shape, the centre axis of the wire cutting through the cylindrical shape. <IMAGE>

Description

The invention relates to a wire bending machine according to the preamble of claim 1.

Wiring in electrical engineering devices often requires insulated wires made of solid material, which are cut to a certain length and bent into a certain shape, the ends of the bent wires having to be stripped so that the pieces of wire can be reworked at the appropriate places in the device without rework can be inserted and connected in an electrically conductive manner.

For this purpose, pieces of wire of a certain length were cut from an endless wire, stripped of insulation and bent into the appropriate shape using a bending machine. The bending machine contained two jaws that could be moved towards each other, between which the wire to be bent was manually inserted has been; the jaws were in the shape that the wire should be bent, such as an L-shape and the like. The bending process was triggered manually each time.

A wire bending machine in which the bending process for wire pieces is essentially automatic is known. This wire bending machine has a wire feed station which has two pairs of opposing rollers between which the wire is conveyed; it has a bending station by means of which the wire is bent, a stripping station and a cutting station. The bending station has suitably associated jaws of a desired shape, similar to the jaw shape of the device described above. However, this means that only one bending shape can be produced at a time; if the wire is to be bent into another bending shape, the jaws of the bending station must be replaced.

The object of the invention is to provide a wire bending machine of the type mentioned, in which wire with different thicknesses can be bent in any shape with any wire length without exchanging elements and components.

This object is achieved according to the invention by the characterizing features of claim 1.

According to the invention, the bending station has a support which can be rotated about the longitudinal axis of the wire and on which is mounted a bending pin which can be rotated eccentrically about an axis running perpendicular thereto. If the eccentrically arranged bending pin is rotated about its axis of rotation, then the wire protruding from the carrier can pass through the Pins are bent, the direction of bending being dependent on the angular position of the support and thus the axis of rotation of the bending pin. This allows the bends to be bent in different directions so that any bending shape can be achieved.

The carrier and the bending pin carrier to which the bending pin is attached can expediently be set in rotation about their own axis independently of one another.

There are two options: on the one hand, a motor for rotating the bending pin carrier can be fastened to the carrier, and on the other hand the carrier can have a cylinder section and a bearing block attached to it, with a cylindrical bore in which the axis of rotation of the bending pin carrier is rotatably mounted.

In a particularly advantageous embodiment according to the second possibility of the invention, the cylinder section of the carrier comprises a drive shaft (also called a drive pin) with a central through hole for receiving the wire, with rotary bearings being provided between the cylinder section and the drive pin or the drive shaft. The drive shaft preferably has a bevel gear, which meshes with the bending pin carrier, which is also designed as a bevel gear. If you now control the carrier on the one hand and the drive pin on the other hand in a suitable manner by different motors, then the carrier can be controlled together with the drive pin and the bending pin carrier in such a way that the plane of rotation or rather the rotary cylinder described by the bending pin with its or its central axis each Take any angular position in relation to the central axis of the wire fed can. Accordingly, the wire can be bent in any direction. This is also possible if a motor is attached to the support for driving the bending pin support; here, however, since when the carrier is rotated, the motor also rotates, so that a high output is required for driving the carrier because of the weight of the motor for the turntable. With the version in which the bending pin carrier is rotatably mounted on the carrier and is rotatably coupled to the drive pin by means of the bevel gear arrangement, the drive motor for the carrier is considerably lighter and simpler to design than the version with its own motor for the bending pin carrier.

In the latter case, two drive motors are provided which preferably drive the drive pin and the carrier by means of a toothed belt drive.

To drive the wire, that is to say to advance it, two pairs of rollers are provided, each having a driven and a loosely rotating wheel, which promote the connection of the wire between them by friction. At least one stripping station is then provided in the intermediate area, ie in the area between the two pairs of rollers.

In order for there to be an optimal tension when the wire is being conveyed in the wire, the pressure of the pair of rollers located at the front in the conveying direction on the wire located between them is greater than that of the rear pair of rollers, so that the wire area is tensioned between the pairs of rollers. This can be achieved in that the diameter of at least one of the wheels of the pair of rollers at the front in the wire conveying direction is larger than that of the rollers of the other pair of rollers, which increases the surface pressure between the rollers of the front pair of rollers and also the peripheral speed of the rollers is greater, whereby the wire is pulled and the wire is tensioned.

In a further embodiment of the invention, the idler, idler rollers of each pair of rollers can be lifted off the other roller. This prevents the wire from being threaded between the pairs of rollers in the direction of its longitudinal axis. The wire can then simply be inserted laterally.

In the area between the pairs of rollers there are preferably a plurality of stripping stations which can stripping wires of different diameters. Each of the stripping stations is responsible for one wire diameter.

The structure of each stripping station can advantageously be chosen so that the stripping station has an anvil on which the wire rests, the support surface (anvil surface) in the direction transverse to the conveying direction of the wire corresponds approximately to the diameter of the core of the wire, that a relative to that Anvil U-shaped cutting element displaceable perpendicular to the conveying direction is provided, the leg ends of which are provided with cutting edges, and that the spacing of the legs corresponds to the width of the anvil surface and thus approximately the thickness of the core of the wire, so that insulating sections are moved by moving the cutting element over the anvil cut off on the insulation of the wire.

Seen in the wire conveying direction, the front and rear of the anvil or the cutting element are provided with vertically extending cutting knives connected in such a way that the insulation of the wire in front of and behind the anvil or the cutting element is cut off from above and from below.

Further refinements of the invention can be found in the further subclaims.

The entire bending device for wire is of course only suitable for wire made of solid material. The entire bending device is controlled electronically by means of a program control. The program contains the device data, the number and the distance of the stripping device, the distance of the bending head and the distance of the cutting device (scissors) from a reference point. This reference point is preferably the bending point. To carry out the bending process, the following data are entered into the program control: diameter of the wire, length of the wire between the bending point and the cutting length, bending direction, number of bent wire pieces, stripping length. From this, the computer calculates the stripping point, the required feed and the angle of rotation of the stepper motors, whereby the bending radius is taken into account when dimensioning the cutting length, depending on the wire thickness. Furthermore, the stripping station corresponding to the wire diameter is always activated.

The invention, further advantageous refinements and improvements and further advantages are to be explained and described in more detail with reference to the drawing, in which two exemplary embodiments of the invention are shown.

Figur 1

eine perspektivische Ansicht einer erfindungsgemäßen Biegevorrichtung,

Figur 2

eine Schnittansicht durch eine erste Ausführungsform des Biegekopfes für die Maschine gemäß Figur 1,

Figur 3

eine weitere Ausführungsform des Biegekopfes für eine Biegevorrichtung nach Figur 1,

Figur 4

eine perspektivische Ansicht einer Abisolierstation, in schematischer Darstellung,

Figur 5

eine Schnittansicht durch die Abisolierstation gemäß Figur 4, nach dem Abisoliervorgang und

Figur 6

eine Aufsicht auf ein Rollenpaar, mit geschnittenem Draht.

Show it:

Figure 1

a perspective view of a bending device according to the invention,

Figure 2

2 shows a sectional view through a first embodiment of the bending head for the machine according to FIG. 1,

Figure 3

1 shows another embodiment of the bending head for a bending device according to FIG. 1,

Figure 4

1 shows a perspective view of a stripping station, in a schematic illustration,

Figure 5

a sectional view through the stripping station according to Figure 4, after the stripping process and

Figure 6

a top view of a pair of rollers, with cut wire.

The bending device according to FIG. 1 has a base frame 10, which consists of two spaced apart feet 11 and 12 made of U-shaped profile material, one cross bar 13 and 14 arranged at the upper end of each foot 11 and 12, and two on the cross bars 13 and 14 attached horizontal support tubes 15 and 16 is formed. A plurality of clamping devices 17, 18, 19, 20, 21 and 22 are fastened between the support pipes 15 and 16 (and a clamping device 17 to 22 is fastened on each support pipe 15 and 16, which clamping devices 17 to 22 for fixing and holding) the individual components of the bending device on the support tubes 15 and 16). The clamping devices 17 to 22 are slidably fastened on the support tubes 15 and 16 in the direction of the support tubes 15 and 16.

On the clamping devices 17 and 21, a support plate 23 and 24 are attached, on each of which two bearing blocks 25 and 26, 25₁ / 26₁ and 25₂ / 26₂ are screwed. The two bearing blocks 25 and 26 each have a distance between them and are penetrated by a drive shaft 27 and 28, respectively. Both drive shafts extend transversely to the longitudinal extent of the carrier tubes 15 and 16, respectively. On both drive shafts 27 and 28 between the two bearing blocks 25 and 26 there is a roller wheel 29 and 30, the roller wheel 29 on the left in the drawing FIG. 1 by means of a drive motor 31 is driven. At the free end of the drive shafts 27 and 28 there are gears 32 and 33 which are wound around each other by a toothed belt, so that this results in a toothed belt drive through which the gear 33 is driven with the roller 30.

A loosely running roller 35 and 36 interacts with the rollers 29 and 30, which two rollers 35 and 36 are each pressed against the lower rollers 29 and 30 by means of a spring arrangement 37 and 38. The two spring arrangements 37 and 38 are the same, so that only the spring arrangement facing the viewer is to be described. A support frame 39 is fastened on the support plate 23 and is formed from a base plate 40, two transverse side plates 41 and 42 and a transverse support wall 44 provided with a recess 43. The base plate 40 lies on the support plate 23 and is fastened to it. The two side walls 41 and 42 run perpendicular to the base plate 40 and transversely to the longitudinal extension of the two support tubes and the support wall 44 extends perpendicular to the base plate 40, perpendicular to the side walls 41 and 42 and parallel to the longitudinal extension of the support tubes. On the outside of the support wall 44, the drive motor 31 is fastened, and the end of the drive shaft 27 on the drive motor side passes through the support wall 44 at the bore 43. A bore 45 is provided on the upper end of the side walls 41 and 42 opposite the base plate 40, only the bore of the side wall 41 is visible. The bore 45 is penetrated by an axis of rotation 46 and serves to support a triangular holder 47, on the tip of which the roller 35 is mounted. On the surface of the bearing block 25₁, a bolt 48 is attached, at the free end of a cross plate 49 is attached. Between a bridge element 50 attached to the triangular support 47 and the cross plate 49 there is a compression spring 51 which presses the bridge element 50 and thus the triangular support 47 downwards, that is to say against the bearing block 25 1 and thus the roller 35 against the roller 29. At the tip end of the triangular support, a pivot lever 52 is rotatably supported, which rests with its tip on the upper surface of the bearing block 25 1. By pivoting the pivot lever 52 about its axis of rotation - since the tip performs a circular arc movement about the axis of rotation of the pivot lever and thus about the axis of rotation of the roller 35 - the triangular support can be raised so that the roller 35 is raised and a wire to be fed (not shown) are inserted laterally across the roller plane between the rollers.

The same design is also found in the area of the roller 36, so that the roller 36 can also be lifted off the roller 30 by means of a pivoting lever 52₂.

The diameter of the roller 30 is slightly larger than the diameter of the roller 29, so that the pressure between the rollers 30, 36 on the wire is greater than the pressure between the rollers 35 and 29. The peripheral speed of the roller 30 is greater than that Roll 29, which is why the wire between the two pairs of rollers 35/29 and 36/30 is stretched.

Between the two pairs of rollers 35/29 and 36/30 there are three stripping stations 53, 54 and 55 which are fastened on the clamping devices 18, 19 and 20.

As can be seen from FIG. 4, each of the stripping devices 53, 54 and 55 has a fixed anvil 56, on the front and rear sides of which a cutting knife 57 and 58 is arranged in the conveying direction of the wire, which cutting knives 57, 58 have the upper anvil surface 59 protrude according to the thickness of the insulation of the wire to be stripped. A semi-circular recess 60 or 61 corresponding to the thickness of the wire insulation is provided on the cutting knife 57 or 58 at its upper edge. The fixed anvil 56 interacts with a cutting element 62 which can be displaced in the vertical direction. The cutting element 62 is U-shaped and accordingly has two legs 63 and 64, the clearance between which corresponds to the thickness of the fixed anvil transverse to the conveying direction. The ends of the legs 63 and 64 are sharpened by a bevel 65 and 66 and thus have cutting edges 67 and 68. Connected to the cutting element 62 are upper cutting knives 69 and 70, which correspond to the lower cutting knives, correspondingly project beyond the cutting edges 67 and 68 and also have a recess 71, only the front recess 71 being visible in FIG. 4.

Figure 5 shows the effect of the stripping station. On the upper anvil surface 59 of the anvil 56 there is a wire 72 with a wire core 73 and an insulation 74 enveloping it. When the cutting element 62 moves downward in the direction of arrow P from the position shown in FIG. 4, the cutting edges 67 and 68 cut off the insulation regions which protrude beyond the side surfaces of the anvil 56; the cut-off partial areas 75, 76 of the insulation 64 are segment-like and are shown in FIG. 5 on the left and on the right, sloping downward. The insulation 74 is cut in the vertical direction by the front and rear cutting knives 57, 58, 69, 70 and when the wire 72 is conveyed further, the upper and lower insulating masses 77 and 78, which are still located between the legs 63 and 64, fall in FIG out. The wire is stripped. Under certain circumstances, the front and rear cutting blades 57, 58; Arrange 69, 70 movably in the vertical direction. Then you cut off the insulation up to a stop and then the side sections 75 and 76 are removed.

From Figure 1 it can be seen that the actuation of the cutting element 62 is actuated by means of piston-cylinder arrangements 79, 80, 81. The piston-cylinder arrangements 79, 80 and 81 are fastened at the bottom to the clamping devices 18, 19 and 20 and the transmission of the piston-cylinder movement takes place via connecting bolts 82, 83 and 84, which are connected to an upper crossbar 85, 86 and 87, to which the cutting elements 62 with the cutting knives 69 and 70 are attached. The cutting elements 62 can be seen from the outside, below which the cutting anvil 56 is located.

On the clamping device 22, which lies at the front in the conveying direction, a bearing block 90 is fastened, on which a bending head 91 is supported. Reference is made here to FIG. 2. The bearing block 91a can be seen schematically, which has a cylindrical longitudinal bore 92, in which the cylindrical section 93 of a carrier 94 is rotatably mounted by means of bearing elements 95, preferably ball bearings. The cylindrical section 93 is likewise provided with a cylindrical bore 96, in the interior of which a drive shaft or a drive pin 99, which is mounted with a through bore 98, is received by means of bearing elements 97. At the front end, the drive pin has a bevel gear 100. At the rear end, the drive pin 99 has a gear 101, which is coupled via a toothed belt drive 102 to the pinion 103 of a fixedly mounted drive motor 104. The drive motor 104 can be seen in FIG. 1 on the right-hand side in the conveying direction of the wire. The cylindrical section 93 is also connected at its rear end, as seen in the conveying direction, by means of a toothed belt drive 105 to a drive motor 106, which drive motor 106 is located on the left side of the device (see FIG. 1). The carrier 94 has an eccentric projection 107, in which a receiving bore 108 running transversely to the conveying direction of the wire is made, in which a pin 110 is supported by means of bearing elements 109, on the axis of the conveying axis of the wire, which is denoted by MM in FIG. 2 , facing end, a turntable 111 serving as a bending pin carrier is attached, on which a bending pin 112 is attached eccentrically to the central axis of the pin 110. This bending pin 112 rotates about the central axis of the pin 110 and in this way describes a hollow cylinder which is penetrated by the central axis of the conveying direction of the wire is, so that when the wire protrudes from the through hole 98, the bending pin 112 can bend the wire when it is driven by the turntable 111 on its cylindrical arc. The turntable 111 is also designed as a bevel gear and meshes with the bevel gear 100.

In order to offset the bending pin 112, the drive pin 99 is driven by means of the motor 104, as a result of which the bevel gear 100 and thus also the bevel gear 111 rotate. If the bending direction is to change, both motors 104 and 106 are driven. And because the peripheral speeds of the bevel gears 100 and 111 are the same, the pin 112 remains in its angular position with respect to the pin 110. The motor 106 probably causes the projection 107 to rotate, but the bending pin 112 does not rotate about its axis. If necessary, the rotary movement of the pin 112 about the central axis of the pin 110 can also be measured by a rotary transducer on the motor 104, so that no right angles are bent, but angles between 0 and 90 °. Of course, such a rotary transducer can also be arranged on the motor 106 in order to be able to adjust the angular position of the carrier.

2 is implemented in the machine according to FIG. 1. One recognizes there the two gear wheels 101 and the gear wheel 113 of the toothed belt drive 105, which are driven by the motors 104 and 106.

FIG. 3 shows a further embodiment of the invention. A carrier 114 in the form of a hollow cylindrical shaft is mounted in the bearing block 91a. The rear end, seen in the conveying direction, on the left in FIG. 3, is provided with a toothed wheel 115 which is coupled via a toothed belt 116 to a pinion 117 of a drive motor 118. At the front end there is an L-shaped holder 119, one leg 120 of which is arranged on the end face of the shaft 114 and the other leg is arranged eccentrically to the central longitudinal axis of the wire. On the outer surface of the leg 121, a drive motor 122 is attached, the longitudinal axis of which is oriented transversely to the line M-M. The motor pin 123 passing through the leg 121 carries a turntable 124, to which a bending pin 125 is fastened. The mode of operation is the same as that of the device according to FIG. 2, only the motor 104 as the motor 122 being fastened directly to the carrier head via the L-shaped holder 119. Due to the weight ratios of the motor 122, the arrangement according to FIG. 3 is not quite as optimal as that according to FIG. 2.

FIG. 6 shows a roller arrangement or a pair of rollers with a driven roller 29 and a loose idler roller 35. The idler idler roller 35 has a V-shaped cutout 126 on the circumference, so that the wire 72 is pressed at three points, as by arrows P1, P2 and P3 are shown.

The drive motors 104, 106; 118 and 120 are stepper motors that can be rotated into certain angular positions of their drive pins.

It has been shown above that the cutting element 62 is pulled down by means of a piston-cylinder arrangement 79, 80, 81. Of course, the cutting element 62 can also be arranged in a stationary manner and the anvil 56 can be moved upwards. Under certain control circumstances, both can also be moved against one another by means of suitable mechanics.

The central bore 98 through the drive pin 99 must of course be shaped accordingly in the area in which the bending pin 112 is located. Accordingly, it has a constriction, not shown in FIG. 2, at the front end located in the conveying direction, the inside diameter of which corresponds to the largest wire diameter, and at the transition from the inner wall of this constriction to the outer end face of the drive pin, which in FIG Bevel gear 100, a circular transition is provided, through which a bending radius is formed. In other words: there is a kind of funnel, the funnel opening of which corresponds to the required bending radius.

The bending device or bending machine is controlled electronically by means of a program control, the program control controlling the electric motors for bending and advancing the wire, as well as electromagnetic valves for actuating the piston-cylinder arrangement 79, 80 and 81. The distances between the individual stripping devices, the bending head, d. H. the bending pin in the position in which it moves in the immediate vicinity of the bending radius, and the distance of a separating device, which is not shown in FIG. 1, from this bending point; Entered as variable sizes are the diameter of the wire, the length of the wire between the bending point and the cutting length, taking into account the bending radius, the bending direction, the number of bent wires and the stripping length.

Claims (18)

Wire bending machine for wire made of solid material provided with insulation, with a wire feed station, with a bending station by means of which the wire is bent, with at least one stripping station and a cutting station, characterized in that the bending station has a support (94 ) for a bending pin carrier (111, 124) with a bending pin (112, 125) attached to it, that the bending pin carrier (111, 124) is rotatably mounted on the carrier (94, 114) about an axis running perpendicular to the longitudinal axis of the wire feed and that the bending pin (112, 125) is attached eccentrically to the bending pin carrier (111, 124), its longitudinal axis running parallel to its axis of rotation and its length measured from the bending pin carrier being greater than the distance of the bending pin carrier from the longitudinal axis of the wire, in such a way that the bending pin ( 112, 125) performs a movement which has a cylindrical shape etzes and the central axis of the wire cuts through the cylindrical shape. Bending machine according to claim 1, characterized in that the carrier (94, 114) and the bending pin carrier (111, 124) can be set in rotation about their axis independently of one another. Bending machine according to claim 2, characterized in that a motor (122) for rotating the bending pin carrier (124) is attached to the carrier (114). Bending machine according to one of claims 1 to 3, characterized in that the carrier (114) is designed as a sleeve which comprises the wire to be fed in order to guide it. Device according to one of claims 1, 2 and 4, characterized in that the carrier (94) has a cylinder section (93) and an attached bearing block (projection 107) with a cylindrical bore (108) which extends from the axis of rotation of the bending pin carrier (111 , 124) is reached. Bending machine according to claim 5, characterized in that the cylinder section (93) surrounds a drive shaft (99) with a central through-bore (98) for receiving the wire, that rotary bearings (97) are provided between the cylinder section (93) and drive shaft (99) and in that the drive shaft (99) carries a bevel gear (100) which meshes with the bending pin carrier (111) designed as a bevel gear. Bending machine according to one of the preceding claims, characterized in that two drive motors (104, 106) are provided which drive the drive shaft (99) and the carrier (94), preferably each by means of a toothed belt drive (102, 105). Bending machine according to one of claims 1 to 6, characterized in that two drive motors (118, 122) are provided, one of which drives the carrier (114) and the other the bending pin carrier (124) and is fastened to the carrier (114). Bending machine according to one of the preceding claims, characterized in that two pairs of driven rollers (29, 30) and a loose idler roller (35, 36) are provided for driving the wire, which take the wire between them and convey them by means of frictional engagement. Bending machine according to claim 9, characterized in that a roller (29) of the pair of rollers located at the rear in the wire conveying direction is driven by a motor (31) and that a roller (30) of the pair of rollers located at the front is driven by chain or toothed belt drive (34). Bending machine according to claim 9 or 10, characterized in that the pressure of the pair of rollers (35, 36) located at the front in the conveying direction on the wire located therebetween is greater than that of the rear pair of rollers (29, 35), so that the wire area is tensioned between the pairs of rollers is. Bending machine according to claim 11, characterized in that the diameter of at least the driven roller (30) of the pair of rollers at the front in the wire conveying direction is larger than that of the rollers (29, 35) of the other pair of rollers. Bending machine according to claim 12, characterized in that the loose, non-driven rollers (35, 36) of each pair of rollers are arranged above the driven rollers (29, 30) and by the associated driven roller (29, 30) against the force of a spring ( 48) can be lifted off. Bending machine according to one of the preceding claims, characterized in that at least one stripping station (56, 59; 62, 67, 68) is arranged between the pairs of rollers. Bending machine according to one of the preceding claims, characterized in that the stripping station has an anvil (56) on which the wire rests, the support surface (anvil surface 59) in the direction transverse to the conveying direction of the wire corresponds approximately to the diameter of the core of the wire in that a U-shaped cutting element (62) which is displaceable relative to the anvil (56) and perpendicular to the conveying direction is provided, the leg ends of which are provided with cutting edges (67, 68), and that the distance between the legs is the width of the anvil surface and thus approximately the thickness of the Corresponds to the core of the wire, so that by moving the cutting element over the anvil (56), in which the legs take the anvil between them, insulating sections on the insulation of the wire are cut off. Bending machine according to claim 14, characterized in that, viewed in the wire conveying direction, the vertically running cutting knives (57, 58; 69, 70) connected to the anvil (56) or the cutting element (62) are provided on the front and behind the anvil (56) and provide the insulation Cut the wire in front of and behind the anvil or the cutting element from above and below. Bending machine according to claim 15 or 16, characterized in that either the anvil with the cutting knives assigned to it and / or the cutting element with the cutting knives assigned in it can be displaced relative to one another by means of a piston-cylinder arrangement. Bending machine according to one of the preceding claims, characterized in that it has a frame which consists of two cross braces (11, 12) oriented vertically at a distance from one another, one cross beam assigned to each of the foot supports (11, 12) and a horizontal spacing on the cross beams Carrier tubes (15, 16) is formed, wherein clamping devices (17, 18, 19, 20, 21, 22) are provided, which are adjustably attachable or clampable to the carrier tubes (15, 16) and the individual components of the bending machine, such as Wear pairs of conveyor rollers, stripping stations, bending heads and the like.

Images