FR2633204A1 - Device for straightening a metal wire - Google Patents

Abstract

The invention relates to a device for straightening a metal wire, comprising a cylinder 1, rotating about its axis 4 in which toroidal rollers 20 rigidly attached to the cylinder 1 are mounted and arranged in such a way that the axis 4 of the cylinder 1 passes through the bore 43 of the rollers 20. The axes of revolution 24 of the rollers 20 are not coplanar with the axis 4 of the cylinder 1 and are stationary in relation to the body 28 of the cylinder 1. The rollers 20 are free to move about their axis of revolution 24. The separation of the axes of revolution 24 of the rollers 20 in relation to the axis 4 of the cylinder 1 can be modified. While the device is rotating, the walls 42 of the rollers 20 define a cylindrical channel 46 in which the wire 10 is straightened.

Description

Wire straightening device
The present invention relates to a device for straightening a metal wire comprising a frame, means for passing the wire through a passageway and means for straightening said wire in said passageway.

 It relates more particularly to the straightening of concrete reinforcing wires delivered in large coils and which must be straightened and cut during implementation.

 There are already known devices for straightening a metal wire constituted by a train of horizontal rollers and a train of vertical rollers which delimit a passageway for the wire. French patent application 74 13 785 mentions such a dressing device installed following a device for unwinding a filiform material. French patent application 71 35 521 describes a straightening triangle consisting of rollers, some of which are pivotable about an axis.

 The disadvantage of known systems is that they are bulky, that they require precise adjustments according to the size of the wire and that they are unsuitable for concrete reinforcing wires which have grooves or grooves on their outer face. .

 In addition, in the case where the wire is unwound in the axial direction of the emitting coil, there are twists during the unwinding of the wire and the known wire straightening devices require an additional system to compensate for these twists.

 The object of the present invention is to propose a wire straightening device which does not require adjustment, which can operate without limiting the running speed of the wire, which is particularly suitable for straightening concrete reinforcing wires on construction sites. whatever the size of these wires, which avoids creating twists in the wire and which eliminates the twists created during the unwinding of the wire from the emitting coil.

 The object is achieved according to the invention by the fact that the device for straightening a proposed metal wire is characterized in that it comprises, on the one hand, a cylinder mounted on said frame and rotating in operation around its axis. by means of a motor, said cylinder having an internal bore and a cylinder body and having at its upstream end a wire inlet mouth and at its downstream end an outlet mouth, said mouths being provided for passage of the wire and being aligned with the axis of rotation of said cylinder, and, on the other hand, a set of rollers of toroidal shape arranged in a substantially aligned along the axis of said cylinder, each roller having an inner wall defining a roller bore, having an axis of revolution and being mounted inside the bore of said cylinder by mounting means in such a way that the axis of said cylinder passes through said roller bore, that said roller can rotate freely around from s on axis of revolution, that the axis of revo'uticn of said roller is fixed relative to the axis of said cylinder and has a fixed position relative to the body of said cylinder of naniere to generate a hyserboloise of revolution to a web having as axis of revolution of the axis of said cylinder at each revolution of said cylinder, the wall of the roller having a roller; a portion of wall close to the axis of said cylinder which envelops a cylindrical trough having as axis the axis of the cylinder å opaque rotation turn of said cylinder, said cylindrical trough constituting the path of passage of the wire, and in that the axes of revolution of the roller rollers are positioned in such a way that the roller wall portions close to the axis of the cylinder all move in the same direction during the rotation or said cylinder, said wall portions constituting the means for thread travel and the means wire straightening.

 Thanks to this structure, each roller is subjected to a movement such that it envelops the cylindrical chute in which the wire will be drawn up, the side of the roller located near the axis of the cylinder undergoes an overall movement in the direction of travel. of the wire, and the side of the roller furthest from the axis of the cylinder undergoes an overall movement in the opposite direction of the travel of the wire.

 The advantage of this structure is that any part of wire which is outside the cylindrical trough enveloped by the wall of a roller will be brought back into the space delimited by this trough during the rotation of the cylinder by a portion of the wall close to the axis of rotation of the cylinder when this portion of the near wall comes into contact with the portion of wire located outside the chute. In addition, the roller being freely movable around its axis of revolution, the wall portion in contact with the wire will follow the movement of the wire, whether this movement is linear or helical, the helical movement being obtained when there are twists. introducing the wire into the device.

The wall portion in contact with the wire is generally close to the axis of rotation of the cylinder, in which case it is subjected by construction to a rectilinear movement which causes the advancement of the wire. The proposed structure thus makes it possible to straighten the wire, to entrain the wire and to eliminate the twists existing when the wire is introduced into the device.

According to a feature of the invention, The positions of the axes of revolution of two consecutive rollers are deduced from one of
The other by a translation along an axis parallel to the axis of the cylinder and a rotation about said axis.

 Preferably, the positions of the axes of revolution of two consecutive rollers are deduced from each other by a translation along an axis parallel to the axis of the cylinder and a rotation of 180 degrees around said axis.

 In this way, the wall portions closest to the axis of the cylinder, of two consecutive rollers, are arranged on either side of the axis of the cylinder, which makes it possible to distribute the dressing forces alternately. along the wire.

 According to a characteristic of the invention, the shape of the wall of the rollers is determined in such a way that the wall portion closest to the axis of the cylinder has the shape of a helix having as axis The axis of the cylinder.

 Thanks to this characteristic, the wire is in contact with the roller over a large area, which reduces the wear of the rollers and facilitates the running of the wire.

Other characteristics and advantages of the invention will appear on reading an embodiment described by way of nonlimiting example and illustrated by the appended drawing, in which
- Figure 1 shows a longitudinal section of an embodiment of the wire straightening device according to
The invention;
- Figure 2 is a cross section of the device of Figure 1 along line II-II, in which the bearing bearing of the roller is not shown;
- Figure 3 is a block diagram showing a cross section of the cylindrical chute serving as a passageway for the wire and enveloped by the internal walls of the rollers
During this rotation of the dressing device;
- Figure 4 is a longitudinal view showing
The contact propeller of a roller with the straightening wire ;;
- Figure 5 shows the path of two points of the roller diametrically opposite and located in a horny plane passing through the axis of rotation of the device;
- Figure 6 is a longitudinal section part-I of the device along the line VI-VI of Figure 1;
- Figure 7 is a perspective view # ve of the wall of a roller in contact with a wire.

 According to the nuce this réa-isation represented by the drawing, the device for straightening a metal wire comprises a cylinder of revolution 1 rotatably mounted using end plates 2 on a frame 3. The cylinder I can rotate around an axis of rotation 4 which coincides with the axis of revolution of the cylinder 1 using a pulley 5 fixed to one end of the cylinder 1 and driven by a not shown die.

 The cylinder 1 comprises a cylinder body 23 and a longitudinal inner bore 27 yes communicates with the outside by an inlet mouth 8 and an outlet mouth 12 coaxial with the axis 4 of the cylinder 1, and formed in the frame 3 .

 The inlet mouth 8 is located at the upstream end 6 of the cylinder 1 and the outlet mouth 12 is located at the downstream end 11 of the cylinder 1.

 The wire 10 is introduced into the cylinder 1 through the inlet mouth 8 and leaves the cylinder 1 through the outlet mouth 12.

 Inside the bore 27 of the cylinder 1 is disposed a set of toric rollers 20 regularly spaced along the axis of rotation 4 of the cylinder 1. These toric rollers 20 are five in number in the drawing. Each roller 20 has the shape of a bracelet having an axis of revolution 24 and is mounted by means of a bearing 21 inside a bore 22 provided in a roller support 23 so that the axis of revolution 24 of the roller 20 and the axis 25 of the bore 22 are coaxial. The roller 20 can rotate freely around its axis of revolution 24 inside the bore 22 of the roller support 23. The roller support 23 has an outer wall 26 which is cylindrical and is arranged transversely inside the bore 27 of the cylinder 1. The roller support 23 is fixed to the body 28 of the cylinder 1 by a bolt 29 or any other fixing means known per se.

 The diameter of the external wall 26 of the roller support 23 is less than the diameter of the internal bore 27 of the cylinder 1. Between the external wall 26 of the roller support 23 and the internal wall 30 of the cylinder 1 is provided an eccentric consisting of 'a washer 31 having an outer diameter equal to the diameter of the inner bore 27 of the cylinder 1 and having an eccentric bore 32 whose diameter is equal to the diameter of the outer wall 26 of the roller support 23. Preferably a radial lumen 33 is provided in the thinnest part of the eccentric washer 31. This light 33 is located in the immediate vicinity of the fixing bolt 29 of the roller support 23.

The body 28 of the cylinder 1 has on the face opposite to the point of attachment 35 of the bolt 29 a transverse lumen 36 in
Which can move an adjustment rod 37 which can be fixed in a bore 38 provided in the eccentric washer 31 and intended to position the eccentric washer 31 relative to the
Roller support 23. When the eccentric washer 31 is appropriately positioned, it is fixed to the body 28 of the cylinder 1 using a locking screw 39 or by any other known means.

 The central point 40 of a roller 20 is off-center with respect to the axis 41 of its roller support 23, and the distance from the central point 40 of the roller 20 to the axis of rotation 4 of the cylinder 1 can be modified by maneuvering the adjustment rod 37 in the light 36, each of the rollers 20 being able to be adjusted independently of the other rollers.

 Each roller 20 having the shape of a bracelet has an inner wall 42 located on the side of the axis of revolution 24 or roller 20 which delimits a bore this scab. 43. The roller support 23 is positioned in the eccentric washer 31 so that the axis of revolution 24 of the roller 20 intersects the clan defined by axis 4 this rotation of the cylinder I and the central point 40 of said roller.

In other words, the axis of revolution 24 of the roller 20 and the axis of revolution 4 of the cylinder 1 are not coplanar.

 The rollers 20 are solid or body 28 of the cylinder 1, when the cylinder 1 rotates around this axis of rotation 4, the axis of revolution 24 that each roller 20 generates a hyperboloid of revolutios to a web having the axis of rotation 4 as axis of revolution.

 The shape of the inner wall 42 of each roller 20 and the cos-tioning of each roller 20 relative to the body 28 of the cylinder 1 are calculated in such a way ore The axis of rotation 4 passes through the bores of rollers 43. The axis of revolution 24 being offset from the axis of rotation 4 Or cylinder, there is a wall portion 44 of the inner wall 42 of the roller 20 which is close to the axis of rotation 4 and a portion of this wall 45 which is distant from the axis of rotation 4. The near wall portion 44 is located on the inner wall 42 on the side that the axis of rotation 4 relative to the axis of revolution 24, and the distant wall portion 45 is if killed on the inner wall 42 or on the same side as the axis of revolution 24 relative to the axis of rotation 4.

 When the cylinder 1 rotates about its axis 4, the wall portion 44 close to the axis of rotation 4 generates a cylindrical chute 46 having the axis of rotation 4 as the axis of revolution. This cylindrical chute 46 delimits the envelope successively covered by the internal walls 42 of the rollers 20 during the rotation of the cylinder 1 about its axis of rotation 4. The cylindrical chute 46 is the compulsory passageway in which the wire 10 introduced by the inlet mouth 8 must be on pain of being straightened by the wall portion 44 close to the axis of rotation 4 of the cylinder of one of the toric rollers 20.

 As can be seen in FIGS. 1 and 2, the central point 40 of the toric roller 20 is the point of the axis of revolution 24 of the toric roller 20 which is located closest to the axis of rotation 4 of the cylinder 1.

 FIG. 3 represents a view along the axis of rotation 4 of the cylinder 1 of three circles C1, C2, C3 Located on the inner wall 42 of the toric roller 20, the circle C1 being the intersection of the wall 42 by a perpendicular plane to the axis of revolution 24 of the toric roller 20 and passing through the central point 40 of the toric roller 20 and the circles C2 and C3 being intersections of the wall 42 by planes parallel to the previous plane and equidistant therefrom.

The representations of the circles C1, C2 and C3 in FIG. 3 are naturally ellipses. Ellipse C1 has a point 441 close to axis 4, ellipse C2 has a point 442 close to axis 4 and ellipse C3 has a point 443 close to axis 4 and which is symmetrical to the point 442 with respect to the plane of circle C1. The form of
the wall 42 is calculated in such a way that the points 441, 442 and 443 of the circles C1, C2, C3 closest to the axis 4 are all at the same distance from the axis of the cylinder 4, in such a way that , during the rotation of the cylinder 1, The wall portion 44 closest to the axis 4 of the cylinder 1 has the shape of a propeller 50 covering the cylindrical chute 46. The shape of the propeller 50 is a function of the shape of the wall 42, and in particular of the angle formed by the plane perpendicular to the axis of revolution 24 of the roller 20 and the axis 4 of the cylinder 1. This angle can have a value close to 60 degrees.

 FIG. 5 shows the curves described by two diametrically opposed points 51 and 52 of the circle C1 and situated in a given plane passing through the axis of rotation 4 of the cylinder 1. In this figure are represented four successive positions 241, 242, 243, 244 of the axis of revolution 24 of the O-ring roller 20, each position being deduced from the previous one by a quarter-turn rotation of the cylinder 1 around the axis of rotation 4 in the direction represented by the arrow F.

When the axis of revolution 24 is in the position shown on the drawing by the line 241, the point 51 is distant from the axis 4 and is in the position 521, the point 52 is in the position 511 in contact with the gou
Lotte cylindrique 46. When cylinder 1 makes a quarter turn in the direction represented by La tecre F, Point 51 moves from position 511 to position 512 and point 52 moves from position 521 to position 522. It is thus easily understood that, when the axis of revolution 24 of the O-ring roller 20 passes successively during a rotation or cylinder 1 through the positions represented in FIG. 5 by lines 241, 242, 243, 244 then 241, the point 51 passes successively through the points represented by the references 511, 512, 513, 514 then again 511 by traversing a curve 61 in the direction represented by the arrow F1. Similarly, the point 52 passes successively through the points 521, 522, 523, 524 before returning to the starting point 521, and also traverses a curve 62 in the direction of the arrow F2. As we can see, the curves 61 and 62 are symmetrical with respect to the axis 4 of the cylinder and are located on either side of the cylindrical chute 46 which is the path for the passage of the wire to be straightened, and they are traversed respectively by points 51 and 52 in opposite senses.

 In the vicinity of the cylindrical trailer 46, the points 51 and 52 move in the same direction and then form part of the wall portions 44 of the inner wall 42 or roller closest to the axis of this rotation 4. These wall portions 44 thus serve to advance the wire 10 which is in the cylindrical chute 46 enveloped by the toric rollers 20.

 Two consecutive toric rollers 20a and 20b are positioned in such a way that the position of the roller 20b comes from the position of the roller 20a by translation along the axis 4 of the cylinder 1 from the distance separating the central points 40a and 40b from the rollers 20a and 20b, followed by a rotation of the roller 20b by an angle of 180 degrees around the axis 4 of the cylinder 1. In other words, the central points 40a and 40b are located on either side of the axis of rotation 4 of the cylinder 1 and the axes of revolution 24a and 24b of the two rollers 20a and 20b are in parallel planes parallel to the axis of rotation 4 located on either side of this axis of rotation 4.The wall portions 44a of the roller 20a closest to the axis of rotation 4 and the wall portions 44b of the roller 20b closest to the axis of rotation 4 are thus on either side of the axis of rotation 4.

 In this way, the portions of the wire 10, which are located outside the cylinder 46, are pushed back by the roller 20a towards the interior of this cylinder 46, and the wire 10 is held on the opposite side by the roller 20b. The wall portions 44 closest to the axis of rotation 4 thus make it possible to draw up a wire 10 which is partially outside the cylindrical chute 46.

FIG. 1 represents a wire straightening device according to the invention having five rollers 20, the rollers of odd rank having their axes of revolution 24 parallel and located in the same plane and the rollers of even rank having their axes of revolution parallel and located in a plane parallel to the previous plane and
Located on the other side of the axis of rotation 4 of the cylinder 1. It goes without saying that the number of rollers 20 can be different from five and that the axes of revolution 24 of the rollers 20 of even or odd rank do not are not necessarily coplanar. What matters is that the axes of revolution 24 are not all parallel to each other and located in the same plane.

 The diameter of the straightening wire 10 must be at most equal to the diameter of the cylindrical chute 46 and, as can be seen in FIG. 3, the diameter of the cylindrical chute 46 can be easily modified by approaching or moving aside the central point 40 of each roller 20 of the axis of rotation 4 of the cylinder 1. This can be done by modifying the position of the eccentric washer 31 relative to the roller support 23 by the adjustment rod 37 after having loosened the locking screw 39 as this was explained above.

 The rollers 20 are freely movable around their axis of revolution 24 and, during operation, the device does not create a twist in the straightened wire. In addition, if the wire is unwound from a large spool along the axis of the latter, the straightening device proposed does not prevent the wire from turning on itself around this axis of rotation 4 of the cylinder 1 to eliminate the twists caused during the unwinding of the spool thread.

It is easy to understand that if the wire 10 introduced into the inlet channel 8 is already erected and if this wire has a diameter less than the diameter of the cylindrical chute 46, the wire 10 does not touch the rollers 20 and is therefore not not driven by the walls 42, this is why it is wise to provide rollers between; - wind, not shown In the drawing, which pull the wire 10 which
Exits through the outlet mouth 12.

In operation, the cylinder 1 rotates around its axis 4, the straightening wire 10 is introduced into the inlet mouth 8 and will be driven by the wall portion 44 of the first roller 20, which is close to the axis 4 Or cylinder 1. This portion of wall moves in the direction of travel of the wire which is defined by the axis 4 in the direction of the inlet mouth 8 towards the outlet mouth 12. The portion this wall 44 of the first roller 20 pushes the portion of wire (10) outside the cylindrical chute 46 toward
The axis 4 d cylinder 1 while driving the wire 10 towards the bore 43 of the roller Next 20. Like the wall portions 44 Closest to the cylinder axis All reposition in the same direction, these wall portions 44 execute two functions, the function of straightening the wire 10 and the forcing the wire 10 into the cylindrical chute 46.

 Various modifications can be made by man or person skilled in the art to the structures described above without departing from or within the scope of the present invention.

Claims (9)

1. Device for straightening a metal wire comprising a frame (3), means for passing the wire (10) through a passageway and means for straightening said wire (10) in said passageway,  characterized in that it comprises, on the one hand,  a cylinder (1) mounted on said frame (3) and rotating in operation about its axis (4), using a motor, said cylinder (1) having an internal bore (27) and a body of cylinder (28) and having at its upstream end (6) a wire inlet mouth (8) and at its downstream end (11) an outlet mouth (12), said mouths being provided for the passage of the wire (10 ) and being aligned with the axis of rotation (4) of said cylinder,  and, on the other hand, a set of rollers (20) of toroidal shape arranged in a substantially aligned manner along the axis (4) of said cylinder (1), each roller (20) having an inner wall (42) delimiting a roller bore (43), having an axis of revolution (24) and being mounted inside the bore (27) of said cylinder (1) by mounting means such that the axis (4) said cylinder (1) passes through said roller bore (43), that said roller (20) can rotate freely around its axis of revolution (24), that the axis of revolution (24) of said roller (20) is offset relative to the axis (4) of said cylinder and has a fixed position relative to the body (28) of said cylinder (1) so as to generate a hyperboloid of revolution in a web having as axis of revolution the axis (4) of said cylinder (1) at each turn of said cylinder (1), said wall (42) of said roller (20) thus having a wall portion (44) close to the axis (1 'of said cylinder which envelops a gouLotte cylindrical (46) having as axis the axis (4) of the cylinder at each rotation of said cylinder (1), said cylindrical chute (46) constituting the passageway for the wire (10),  and in that the axes of revolution (24) of said rollers (20) are positioned in such a way that the wall portions (44) of rollers close to the axis (4) of the cylinder all move in the same direction when the rotation of said cylinder (1), said wall portions (44) constituting the wire running means (10) and the wire straightening means (10). 2. A wire straightening device according to claim 1, characterized in that the positions of the axes of revolution (24a, 24b) of two consecutive rollers (20a, 20b) are deduced from each other by a translation along a parallel axis lele to the axis (4) of the cylinder (1) and a rotation about said axis (4). 3. A braiding device for a metal wire according to claim 2, characterized in that the positions of the axes of evolution (24a, 24p) of those rollers (20a, 20b) consecutive anneal from each other by a translation along a parallel axis such as the axis (4) or cylinder (1) and a rotation of 180 degrees around said axis (4). 4. Device for straightening a metal wire according to one of these revenocations 1 to 3, characterized in that the shape of the wall (42) of the gaLets is determined in such a way that the portion (44) of the nearest wall is read of the axis of the cylinder has the shape of a helix having as axis The axis (4) of the cylinder 1. 5. Device for straightening a metal wire according to one of claims 1 to 4, characterized in that said roller mounting means are constituted by a roller support (23) disposed transversely in the bore (27) of the cylinder (1) and comprising a bore (22) having an axis (25) offset relative to the axis (4) of the cylinder (1), said bore (22) of said gaLet support (23) being provided for mounting said roller (20) in such a way that the axis of revolution '(24) of said a Le (20) is coaxial with the axis (25) of the bore (22) of said roller support (23). 6. Device for straightening # a metal wire according to claim 5, characterized in that said roller support (23) is disposed inside an eccentric bore (32) of a washer (31) arranged transversely in the bore (27) of the cylinder (1).  7. A wire straightening device according to claim 6, characterized in that the central point (40) of said roller (20) is eccentric relative to the longitudinal axis (41) of its roller support (23) . 8. A wire straightening device according to claim 7, characterized in that the position of said roller support (23) can be modified relative to said eccentric washer (31) so as to adjust the distance from the central point ( 40) of said roller (20) of the axis of rotation (4) of the cylinder (1). 9. A wire straightening device according to one of claims 1 to 8, characterized in that the plane perpendicular to the axis of revolution (24) of each of said rollers (20) makes an angle close to 60 degrees with the axis of rotation (4) of the cylinder (1).