CA2007981A1 - Orthogonal adjustment unit and method for orthogonal adjustment of straightened bars - Google Patents
Orthogonal adjustment unit and method for orthogonal adjustment of straightened barsInfo
- Publication number
- CA2007981A1 CA2007981A1 CA002007981A CA2007981A CA2007981A1 CA 2007981 A1 CA2007981 A1 CA 2007981A1 CA 002007981 A CA002007981 A CA 002007981A CA 2007981 A CA2007981 A CA 2007981A CA 2007981 A1 CA2007981 A1 CA 2007981A1
- Authority
- CA
- Canada
- Prior art keywords
- straightening
- adjustment
- bar
- roll
- unit
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
Links
- 238000000034 method Methods 0.000 title claims abstract description 12
- 239000007787 solid Substances 0.000 claims abstract description 6
- 238000005259 measurement Methods 0.000 description 9
- 238000006073 displacement reaction Methods 0.000 description 4
- 230000000712 assembly Effects 0.000 description 3
- 238000000429 assembly Methods 0.000 description 3
- 238000010276 construction Methods 0.000 description 2
- 238000010586 diagram Methods 0.000 description 2
- 238000012423 maintenance Methods 0.000 description 2
- 230000002787 reinforcement Effects 0.000 description 2
- 238000011144 upstream manufacturing Methods 0.000 description 2
- 239000003637 basic solution Substances 0.000 description 1
- 238000005452 bending Methods 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 230000001419 dependent effect Effects 0.000 description 1
- 230000001788 irregular Effects 0.000 description 1
- 239000000463 material Substances 0.000 description 1
- 239000000243 solution Substances 0.000 description 1
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D3/00—Straightening or restoring form of metal rods, metal tubes, metal profiles, or specific articles made therefrom, whether or not in combination with sheet metal parts
- B21D3/02—Straightening or restoring form of metal rods, metal tubes, metal profiles, or specific articles made therefrom, whether or not in combination with sheet metal parts by rollers
- B21D3/05—Straightening or restoring form of metal rods, metal tubes, metal profiles, or specific articles made therefrom, whether or not in combination with sheet metal parts by rollers arranged on axes rectangular to the path of the work
Abstract
ABSTRACT
Method for orthogonal adjustment of straightened bars, whereby the bars may be of a rolled, drawn or extruded type or be obtained with a forming machine and may have any round, oval, square, rectangular or polygonal, etc.
section and be solid or hollow, whereby a desired variable deformation opposed to the curved development determined by the last three staggered rolls (30-31-131) of a straightening assembly (11) is imparted to the bar (14-114) after the straightening and immediately downstream of the straightening assembly (11), the deformation imparted to the bar (14-114) acting thereon radially in a desired position, within an angle of 360°, lying on a plane normal to the nominal axis of the straightening machine working and having as its axis that nominal axis.
Orthogonal adjustment unit located downstream of a bar straightening machine, wherein the bar may be of a rolled, drawn or extruded type or be obtained with a forming machine and may have any round, oval, square, rectangular or polygonal, etc. section and be solid or hollow, the orthogonal adjustment unit (10) being located immediately downstream of a straightening assembly (11) and between the straightening assembly (11) and the contrast unit (12),the orthogonal adjustment unit comprising at least one adjustment roll (13) capable of idling and of being positioned as required within an angle of 360° on a plane normal to the nominal axis of the straightening machine and having that nominal axis as its axis, the adjustment roll (13) being in contrast with the last outlet roll (131) of the straightening assembly (11), the contrast unit (12) and straightening assembly (11) lying substantially on the same plane parallel to or coinciding with the plane on which the adjustment roll (13) lies.
Method for orthogonal adjustment of straightened bars, whereby the bars may be of a rolled, drawn or extruded type or be obtained with a forming machine and may have any round, oval, square, rectangular or polygonal, etc.
section and be solid or hollow, whereby a desired variable deformation opposed to the curved development determined by the last three staggered rolls (30-31-131) of a straightening assembly (11) is imparted to the bar (14-114) after the straightening and immediately downstream of the straightening assembly (11), the deformation imparted to the bar (14-114) acting thereon radially in a desired position, within an angle of 360°, lying on a plane normal to the nominal axis of the straightening machine working and having as its axis that nominal axis.
Orthogonal adjustment unit located downstream of a bar straightening machine, wherein the bar may be of a rolled, drawn or extruded type or be obtained with a forming machine and may have any round, oval, square, rectangular or polygonal, etc. section and be solid or hollow, the orthogonal adjustment unit (10) being located immediately downstream of a straightening assembly (11) and between the straightening assembly (11) and the contrast unit (12),the orthogonal adjustment unit comprising at least one adjustment roll (13) capable of idling and of being positioned as required within an angle of 360° on a plane normal to the nominal axis of the straightening machine and having that nominal axis as its axis, the adjustment roll (13) being in contrast with the last outlet roll (131) of the straightening assembly (11), the contrast unit (12) and straightening assembly (11) lying substantially on the same plane parallel to or coinciding with the plane on which the adjustment roll (13) lies.
Description
~0~
]
1"ORT}IOGONAL ADJUSTMENT UNI~ AND METHOD FOR
2ORTHOGONAL ADJUSTMENT OF STRAIGHTENED BARS"
3* * * * * * *
4This invention concerns an orthogonal adjustment unit that cooperates with a bar straightening machine. To be 6 more exact, the invention concerns an orthogonal 7 adjustment unit which, by working between the 8 straightening machine and a contrast unit and being 9 located immediately downstream of the straightening machine, enables a bar leaving the straightening machine 11 to be correctly straightened.
12 According to the invention the contrast unit may 13 consist also of, or act as, a means to measure length.
14 We shall deal hereinafter with the case where the contrast unit acts as a means to measure length but will 16 also cover other possible cases.
17 The invention concerns also a method for the orthogonal 18 straightening of a straightened bar, namely by working on 19 an angle of 360.
It is known that the straightening of bars takes place 21 by making them pass through a straightening machine.
22 By bars is meant here any linear element having a 23 cylindrical, oval, square, rectangular, etc. solid or 24 hollow section with an outer surface which is smooth or bears projections or other shapes comprised in 26 reinforcement bars, for instance.
27 The bars according to this invention may be rolled, 28 drawn, extruded, formed, etc.
29 Various systems have been devised to obtain straightened bars since the last three rolls (30-31-131) 31 in a straightening assembly (Fig.1) perform a known 32 extending function. The lay-out of these three rolls 33(30-31-131) is indifferent as also is the choice whether 20~7~38i.
~ the lower or upp~r or both sets of rolls of the assembly 2 should consist of powered rolls to carry out the drawing 3 action ~oo.
]
1"ORT}IOGONAL ADJUSTMENT UNI~ AND METHOD FOR
2ORTHOGONAL ADJUSTMENT OF STRAIGHTENED BARS"
3* * * * * * *
4This invention concerns an orthogonal adjustment unit that cooperates with a bar straightening machine. To be 6 more exact, the invention concerns an orthogonal 7 adjustment unit which, by working between the 8 straightening machine and a contrast unit and being 9 located immediately downstream of the straightening machine, enables a bar leaving the straightening machine 11 to be correctly straightened.
12 According to the invention the contrast unit may 13 consist also of, or act as, a means to measure length.
14 We shall deal hereinafter with the case where the contrast unit acts as a means to measure length but will 16 also cover other possible cases.
17 The invention concerns also a method for the orthogonal 18 straightening of a straightened bar, namely by working on 19 an angle of 360.
It is known that the straightening of bars takes place 21 by making them pass through a straightening machine.
22 By bars is meant here any linear element having a 23 cylindrical, oval, square, rectangular, etc. solid or 24 hollow section with an outer surface which is smooth or bears projections or other shapes comprised in 26 reinforcement bars, for instance.
27 The bars according to this invention may be rolled, 28 drawn, extruded, formed, etc.
29 Various systems have been devised to obtain straightened bars since the last three rolls (30-31-131) 31 in a straightening assembly (Fig.1) perform a known 32 extending function. The lay-out of these three rolls 33(30-31-131) is indifferent as also is the choice whether 20~7~38i.
~ the lower or upp~r or both sets of rolls of the assembly 2 should consist of powered rolls to carry out the drawing 3 action ~oo.
4 The cited extending function leads to the imparting of a curved development to the bar leaving the 6 straightening assembly. This curved development may have 7 a more or less marked appearance but it always exists.
8 Moreover, in the case of non-homogeneous or 9 discontinuous sections (such as round bars shaped at their upper end for reinforcement purposes in building 11 work) or of given materials, this curved development 12 cannot lie on the plane containing the rolls or cannot 13 always lie on the same plane as the rolls.
14 If a contrast unit (12) (Fig.lb) is included downstream of the straightening assembly, this curved development is 16 partly compensated by the straightening assembly, as 17 taught in DE-C-380128.
18 Contrary to what DE-C-380128 states, the bar leaving 19 the straightening assembly is never perfectly straightened if a system of that kind is employed.
21 This is even more true when the bar has a non-22 homogeneous section or has an irregular section.
23 Also, when the bar arrives from a reel, the final 24 straightening is not perfect since auxiliary twists will have been imparted to that bar while it is being unwound 26 from the reel.
27 DE-C-180901 tends to obviate this drawback with an 28 automatic self-straightening system, which could be 29 effective if the curved deformation remaining in the bar at the outlet of the straightening machine were to lie 31 only on one plane (in this case a lengthwise vertical 32 plane according to DE-C-180901).
33 But unfortunately, where the bars are non-homogeneous _ 3 _ ~ ~ 0 7 1 or ha~e cln irregu:Lar section or have been unwound from a 2 reel, the remaining deformation often contains also 3 developlnents oriented on other planes and not only on a 4 vertical lengthwise plane.
DE-A-2518798 arranges to bend a tube according to a 6 determined spiral by means of an orientation movement of 7 the last rolls, but this document does not teach the 8 straightening of a bar leaving a straightening machine 9 with a residual deformation which may be oriented within an angle of 360.
11 GB-A-1132609 too arranges to obtain desired 12 deformations, that is, to obtain circles but not to 13 straighten bars.
14 Various other systems have been designed by the present 15 applicant to prevent the limitations of the known art. A
16 first system disclosed in EP-A-86102121.0 consists in 17 placing at least two straightening assemblies 18 substantially at a right angle to each other so as to 19 process on two cartesian axes of the bar; in this case too the final outcoming bar retains this curved 21 development, albeit to a small extent, in the cases cited 22 above.
23 Another system disclosed in EP-A-0269157 provides for 29 the creation of at least one half-loop in the bar passing through the straightening assembly, thereby fixing also 26 the lengthwise twists due, for instance, to the unwinding 27 of the bar from a reel.
28 These systems give good results but are costly as they 29 require either the doubling of the straightening assembly or the construction of straightening assemblies having a 31 curved development which entail considerable problems of 32 setting-up, adjustment, construction, maintenance, etc.
33 As these assemblies cause very burdensome work, the 73~1 simpler they are, the more the end-user ls assisted, 2 since the problems of maintenance, setting-up and 3 adjustment are eliminated and the life of the device is 4 improved.
To obviate these drawbacks and to achieve other 6 advantages which will become clear in the following 7 description, the present applicant has studied, tested 8 and embodied this invention.
9 The invention is set forth in the main claims, while the dependent claims describe variants of the idea of the 11 main solution.
12 According to the invention an orthogonal adjustment 13 unit is positioned downstream of the straightening 14 assembly and upstream of a contrast unit and can act on the bar in any position within 360. The invention 16 arranges that the straightening assembly and the contrast 17 unit can lie substantially on the same plane, which can 18 be substantially vertical or horizontal or in any other 19 position between the vertical and horizontal, even at an angle inverted in relation to the axis of feed of the 21 bar.
22 The invention provides for the orthogonal adjustment 23 unit located upstream of the contrast unit, which will 24 advantageously but not only act as a measurement unit, to be able to act on the bar at the same time along both the 26 cartesian axes generating orthogonal planes, the original 27 intersection of which coincides with the axis of the 28 straightening machine.
29 According to the position taken up by the orthogonal adjustment unit, the bar on leaving the measurement unit 31 takes up any three-dimensional positions within an angle 32 of 360 created by a conoid the vertex of which lies 33 between the rolls of the measurement unit, the axis of 2~73~
1 which coincides wi~h the axis of the straightening 2 machine and extends downstream thereof.
3 Let us see some particular embodiments of the invention 4 with the help of the attached figures, which are given as a non-restrictive example and in which:
6 Figs.la and lb show the state of the art;
7 Fig.2 show a diagram of a general embodiment of the 8 invention;
9 Fig.3 gives a three-dimensional, partly cutaway view of a possible orthogonal adjustment unit;
11 Fig.4 gives a diagram of a variant with two independent 12 orthogonal adjustment units suitable to process 13 two bars at the same time;
14 Fig.5 show a variant of the embodiment of Fig.4.
In the figures a bar 14 with a direction of feed 16 according to the arrow 15 is passed through a 17 straightening assembly 11 at the downstream end of which 18 are comprised rolls 30 (here an upper roll) and 31 and 19 131 (here lower rolls). The row of powered rolls may be the row including the upper roll 30 or the lower rolls 21 31-131 or both rows of rolls.
22 A contrast unit 12 is located downstream of the 23 straightening assembly 11 and in this example has the 24 functions of a measurement unit and comprises an upper roll 27 and lower roll 26. These rolls 26-27 are thrust 26 resiliently against each other advantageously.
27 The rolls of the straightening assembly 11 and the 28 rolls of the contrast meaqurement unit 12 in this case 29 advantageously lie substantially on the same plane.
The orthogonal adjustment unit 10 is included between 31 the last downstream roll 131 of the straightening 32 assembly 11 and the contrast measurement unit 12. The 33 orthogonal adjustment unit 10 comprises an adjustment ~007~81 1 roll 13 abl~ to move in Eour directions along two 2 cartesian axes that generate planes cooperating with the 3 axis of the bar 14.
4 These cartesian axes ~A-C and B-D) lie substantially on a plane perpendicular to the nominal axis of the machine 6 and therefore of the bar 19.
7 According to the embodiment shown in Figs.2, 3 and 4 8 the adjustment roll 13 of the orthogonal adjustment unit 9 10 can move axially or in a direction normal to its own axis and therefore along axes perpendicular to the axis 11 of the bar 14.
12 The movement which the adjustment roll 13 can carry 13 out induces in the bar 14 leaving the contrast 14 measurement unit 12 any three-dimensional position contained in a conoid 29 having at its vertex a position 16 between the two rolls 26-27 of the contrast measurement 17 unit 12. This means that if the adjustment roll 13 is 18 thrust, for instance, along the axis C, the position 19 taken up by the bar 14 in the conoid 29 will be that corresponding to a direction contrary to the direction C, 21 namely the direction marked with A' in Fig.2.
22 Analogously an axial movement of the adjustment roll 13 23 along the axis D will induce a displacement of the bar 14 24 in the direction B' in the conoid 29.
It is possible to identify by analogy the directions of 26 the bar 14 induced instead by other displacements of the 27 adjustment roll 13.
28 The degree of displacement of the adjustment roll 13 29 will obviously induce an analogous degree of displacement within the conoid 29 when the curved loop induced on 31 departure from the straightening assembly 11 has been 32 taken up.
33 The scope of the invention provides for the embodiment 20~73~1 l of Fi~.~ to be ~rr~nged as a symmetr~cal counterpart of 2 the embodim~nt as shown in Fig.2.
3 Let us now see some examples of the embodiment in more 4 detail.
S A possible orthogonal ad~ustment unlt 10 i9 shown in 6 Fig.3, wherein the adjustment roll 13 comprises a 7 circumferential crown 16, within which the bar 14 is 8 partly engaged, and is supported so as to be able to idle 9 by a flange 17 which is solidly fixed to a rotation-prevention shaft 18.
11 The rotation-prevention shaft 18 is free to slide 12 axially in a slider element 21 and is positioned axially 13 by a first threaded shaft 19 driven in turn by a first 14 motor 20.
The slider element 21 is able to slide in appropriate 16 guides in a frame 24 and is moved vertically by a second 17 threaded shaft 22 driven by a second motor 23.
18 Thus, owing to the drives of the first and second 19 motors 20-23 the adjustment roll 13 can be displaced along the axis B-D or along the axis A-C as required.
21 When two bars 14 are straightened at the same time, the 22 problem arises as to how to handle the two bars 14 23 independently since both of them may have specific 24 straightening requirements; in this case it is possible to employ the embodiment of Fig.4, which provides for the 26 doubling of the embodiment of Fig.3 and in which two 27 adjustment rolls 13 and 113 cooperate with the respective 28 bars 14 and 114.
29 In practice the first motor 20 (or 120) which drives the adjustment roll 13 (or 113) more exposed to the 31 bending loop may be placed elsewhere and the relative 32 command may be transferred by known transmission means.
33 In Fig.4 both the rolls 13-113 with their respective 20~
1 rotation-pr~venLIon sha~t3 L8-~la are lndependen~ and can 2 be moved along the axis A-C or B-D by the respective 3 first and second motors 20-30 and 120-123 by means of the 4 slider elements 21-121 with the relative second threaded shafts 22-1~2 and by means of the first threaded shafts 6 19-119.
7 A support 25 enables the duplicate orthogonal 8 adjustment unit 110 to be properly supported in 9 cooperation with the original orthogonal adjustment unit 10 10.
11 Fig.5 shows the embodiment of a variant in which it is 12 possible to obtain the function performed by the twin 13 unit of Fig.4. In Fig.5 the orthogonal adjustment unit 14 10 comprises two independent adjustment rolls 13-113 which can move independently in relation to their own 16 axis of rotation.
17 If so required, both the adjustment rolls 13-113 can be 18 supported on one single support, which makes it possible 19 to move them also according to their vertical axis by means of the second motor 23.
21 But in the case of Fig.5 it is necessary for the 22 contrast measurement units 12-112 to be movable 23 independently, for instance by means of third motors 28-24 128 on a vertical plane.
In the case of Fig.5, therefore, the adjustment rolls 26 13-113 are undoubtedly able to move independently along 27 the axis B-D, while the contrast measurement units 12-112 28 can move independently along the axis A-C.
29 By means of this variant, which can also be applied in the event of a single bar, it is possible to obtain a 31 variant of the idea of the basic solution while keeping 32 unchanged the method of the orthogonal adjustment in the 33 straightened bar 14.
~0~381 9 _ 1 ~ccordinc3 to the invention the method therefore 2 arranges that after the straightening and immediately 3 downstream of the straightening assembly a desired and 4 variable deformation which is opposed to the curved S development produced by the three downstream rolls of the 6 straightening assembly is imparted to the bar.
7 According to the invention too the deformation imparted 8 to the bar acts radially on the bar in a desired 9 position, within a full circle of 360, lying on a plane normal to the nominal axis of the bar.
8 Moreover, in the case of non-homogeneous or 9 discontinuous sections (such as round bars shaped at their upper end for reinforcement purposes in building 11 work) or of given materials, this curved development 12 cannot lie on the plane containing the rolls or cannot 13 always lie on the same plane as the rolls.
14 If a contrast unit (12) (Fig.lb) is included downstream of the straightening assembly, this curved development is 16 partly compensated by the straightening assembly, as 17 taught in DE-C-380128.
18 Contrary to what DE-C-380128 states, the bar leaving 19 the straightening assembly is never perfectly straightened if a system of that kind is employed.
21 This is even more true when the bar has a non-22 homogeneous section or has an irregular section.
23 Also, when the bar arrives from a reel, the final 24 straightening is not perfect since auxiliary twists will have been imparted to that bar while it is being unwound 26 from the reel.
27 DE-C-180901 tends to obviate this drawback with an 28 automatic self-straightening system, which could be 29 effective if the curved deformation remaining in the bar at the outlet of the straightening machine were to lie 31 only on one plane (in this case a lengthwise vertical 32 plane according to DE-C-180901).
33 But unfortunately, where the bars are non-homogeneous _ 3 _ ~ ~ 0 7 1 or ha~e cln irregu:Lar section or have been unwound from a 2 reel, the remaining deformation often contains also 3 developlnents oriented on other planes and not only on a 4 vertical lengthwise plane.
DE-A-2518798 arranges to bend a tube according to a 6 determined spiral by means of an orientation movement of 7 the last rolls, but this document does not teach the 8 straightening of a bar leaving a straightening machine 9 with a residual deformation which may be oriented within an angle of 360.
11 GB-A-1132609 too arranges to obtain desired 12 deformations, that is, to obtain circles but not to 13 straighten bars.
14 Various other systems have been designed by the present 15 applicant to prevent the limitations of the known art. A
16 first system disclosed in EP-A-86102121.0 consists in 17 placing at least two straightening assemblies 18 substantially at a right angle to each other so as to 19 process on two cartesian axes of the bar; in this case too the final outcoming bar retains this curved 21 development, albeit to a small extent, in the cases cited 22 above.
23 Another system disclosed in EP-A-0269157 provides for 29 the creation of at least one half-loop in the bar passing through the straightening assembly, thereby fixing also 26 the lengthwise twists due, for instance, to the unwinding 27 of the bar from a reel.
28 These systems give good results but are costly as they 29 require either the doubling of the straightening assembly or the construction of straightening assemblies having a 31 curved development which entail considerable problems of 32 setting-up, adjustment, construction, maintenance, etc.
33 As these assemblies cause very burdensome work, the 73~1 simpler they are, the more the end-user ls assisted, 2 since the problems of maintenance, setting-up and 3 adjustment are eliminated and the life of the device is 4 improved.
To obviate these drawbacks and to achieve other 6 advantages which will become clear in the following 7 description, the present applicant has studied, tested 8 and embodied this invention.
9 The invention is set forth in the main claims, while the dependent claims describe variants of the idea of the 11 main solution.
12 According to the invention an orthogonal adjustment 13 unit is positioned downstream of the straightening 14 assembly and upstream of a contrast unit and can act on the bar in any position within 360. The invention 16 arranges that the straightening assembly and the contrast 17 unit can lie substantially on the same plane, which can 18 be substantially vertical or horizontal or in any other 19 position between the vertical and horizontal, even at an angle inverted in relation to the axis of feed of the 21 bar.
22 The invention provides for the orthogonal adjustment 23 unit located upstream of the contrast unit, which will 24 advantageously but not only act as a measurement unit, to be able to act on the bar at the same time along both the 26 cartesian axes generating orthogonal planes, the original 27 intersection of which coincides with the axis of the 28 straightening machine.
29 According to the position taken up by the orthogonal adjustment unit, the bar on leaving the measurement unit 31 takes up any three-dimensional positions within an angle 32 of 360 created by a conoid the vertex of which lies 33 between the rolls of the measurement unit, the axis of 2~73~
1 which coincides wi~h the axis of the straightening 2 machine and extends downstream thereof.
3 Let us see some particular embodiments of the invention 4 with the help of the attached figures, which are given as a non-restrictive example and in which:
6 Figs.la and lb show the state of the art;
7 Fig.2 show a diagram of a general embodiment of the 8 invention;
9 Fig.3 gives a three-dimensional, partly cutaway view of a possible orthogonal adjustment unit;
11 Fig.4 gives a diagram of a variant with two independent 12 orthogonal adjustment units suitable to process 13 two bars at the same time;
14 Fig.5 show a variant of the embodiment of Fig.4.
In the figures a bar 14 with a direction of feed 16 according to the arrow 15 is passed through a 17 straightening assembly 11 at the downstream end of which 18 are comprised rolls 30 (here an upper roll) and 31 and 19 131 (here lower rolls). The row of powered rolls may be the row including the upper roll 30 or the lower rolls 21 31-131 or both rows of rolls.
22 A contrast unit 12 is located downstream of the 23 straightening assembly 11 and in this example has the 24 functions of a measurement unit and comprises an upper roll 27 and lower roll 26. These rolls 26-27 are thrust 26 resiliently against each other advantageously.
27 The rolls of the straightening assembly 11 and the 28 rolls of the contrast meaqurement unit 12 in this case 29 advantageously lie substantially on the same plane.
The orthogonal adjustment unit 10 is included between 31 the last downstream roll 131 of the straightening 32 assembly 11 and the contrast measurement unit 12. The 33 orthogonal adjustment unit 10 comprises an adjustment ~007~81 1 roll 13 abl~ to move in Eour directions along two 2 cartesian axes that generate planes cooperating with the 3 axis of the bar 14.
4 These cartesian axes ~A-C and B-D) lie substantially on a plane perpendicular to the nominal axis of the machine 6 and therefore of the bar 19.
7 According to the embodiment shown in Figs.2, 3 and 4 8 the adjustment roll 13 of the orthogonal adjustment unit 9 10 can move axially or in a direction normal to its own axis and therefore along axes perpendicular to the axis 11 of the bar 14.
12 The movement which the adjustment roll 13 can carry 13 out induces in the bar 14 leaving the contrast 14 measurement unit 12 any three-dimensional position contained in a conoid 29 having at its vertex a position 16 between the two rolls 26-27 of the contrast measurement 17 unit 12. This means that if the adjustment roll 13 is 18 thrust, for instance, along the axis C, the position 19 taken up by the bar 14 in the conoid 29 will be that corresponding to a direction contrary to the direction C, 21 namely the direction marked with A' in Fig.2.
22 Analogously an axial movement of the adjustment roll 13 23 along the axis D will induce a displacement of the bar 14 24 in the direction B' in the conoid 29.
It is possible to identify by analogy the directions of 26 the bar 14 induced instead by other displacements of the 27 adjustment roll 13.
28 The degree of displacement of the adjustment roll 13 29 will obviously induce an analogous degree of displacement within the conoid 29 when the curved loop induced on 31 departure from the straightening assembly 11 has been 32 taken up.
33 The scope of the invention provides for the embodiment 20~73~1 l of Fi~.~ to be ~rr~nged as a symmetr~cal counterpart of 2 the embodim~nt as shown in Fig.2.
3 Let us now see some examples of the embodiment in more 4 detail.
S A possible orthogonal ad~ustment unlt 10 i9 shown in 6 Fig.3, wherein the adjustment roll 13 comprises a 7 circumferential crown 16, within which the bar 14 is 8 partly engaged, and is supported so as to be able to idle 9 by a flange 17 which is solidly fixed to a rotation-prevention shaft 18.
11 The rotation-prevention shaft 18 is free to slide 12 axially in a slider element 21 and is positioned axially 13 by a first threaded shaft 19 driven in turn by a first 14 motor 20.
The slider element 21 is able to slide in appropriate 16 guides in a frame 24 and is moved vertically by a second 17 threaded shaft 22 driven by a second motor 23.
18 Thus, owing to the drives of the first and second 19 motors 20-23 the adjustment roll 13 can be displaced along the axis B-D or along the axis A-C as required.
21 When two bars 14 are straightened at the same time, the 22 problem arises as to how to handle the two bars 14 23 independently since both of them may have specific 24 straightening requirements; in this case it is possible to employ the embodiment of Fig.4, which provides for the 26 doubling of the embodiment of Fig.3 and in which two 27 adjustment rolls 13 and 113 cooperate with the respective 28 bars 14 and 114.
29 In practice the first motor 20 (or 120) which drives the adjustment roll 13 (or 113) more exposed to the 31 bending loop may be placed elsewhere and the relative 32 command may be transferred by known transmission means.
33 In Fig.4 both the rolls 13-113 with their respective 20~
1 rotation-pr~venLIon sha~t3 L8-~la are lndependen~ and can 2 be moved along the axis A-C or B-D by the respective 3 first and second motors 20-30 and 120-123 by means of the 4 slider elements 21-121 with the relative second threaded shafts 22-1~2 and by means of the first threaded shafts 6 19-119.
7 A support 25 enables the duplicate orthogonal 8 adjustment unit 110 to be properly supported in 9 cooperation with the original orthogonal adjustment unit 10 10.
11 Fig.5 shows the embodiment of a variant in which it is 12 possible to obtain the function performed by the twin 13 unit of Fig.4. In Fig.5 the orthogonal adjustment unit 14 10 comprises two independent adjustment rolls 13-113 which can move independently in relation to their own 16 axis of rotation.
17 If so required, both the adjustment rolls 13-113 can be 18 supported on one single support, which makes it possible 19 to move them also according to their vertical axis by means of the second motor 23.
21 But in the case of Fig.5 it is necessary for the 22 contrast measurement units 12-112 to be movable 23 independently, for instance by means of third motors 28-24 128 on a vertical plane.
In the case of Fig.5, therefore, the adjustment rolls 26 13-113 are undoubtedly able to move independently along 27 the axis B-D, while the contrast measurement units 12-112 28 can move independently along the axis A-C.
29 By means of this variant, which can also be applied in the event of a single bar, it is possible to obtain a 31 variant of the idea of the basic solution while keeping 32 unchanged the method of the orthogonal adjustment in the 33 straightened bar 14.
~0~381 9 _ 1 ~ccordinc3 to the invention the method therefore 2 arranges that after the straightening and immediately 3 downstream of the straightening assembly a desired and 4 variable deformation which is opposed to the curved S development produced by the three downstream rolls of the 6 straightening assembly is imparted to the bar.
7 According to the invention too the deformation imparted 8 to the bar acts radially on the bar in a desired 9 position, within a full circle of 360, lying on a plane normal to the nominal axis of the bar.
Claims (6)
1 - Method for orthogonal adjustment of straightened bars, whereby the bars may be of a rolled, drawn or extruded type or be obtained with a forming machine and may have any round, oval, square, rectangular or polygonal, etc. section and be solid or hollow, whereby a desired variable deformation opposed to the curved development determined by the last three staggered rolls (30-31-131) of a straightening assembly (11) is imparted to the bar (14-114) after the straightening and immediately downstream of the straightening assembly (11), the method being charcaterized in that the deformation imparted to the bar (14-114) acts thereon radially in a desired position, within an angle of 360°, lying on a plane normal to the nominal axis of the straightening machine working and having as its axis that nominal axis.
2 - Method as claimed in Claim 1, in which the deformation is imparted between the last roll (131) of the straightening assembly (11) and a vertically immovable contrast unit (12-112) located immediately downstream of the straightening assembly (11).
3 - Method as claimed in Claim 1 or 2, in which the deformation is imparted immediately downstream of the last roll (131) of the straightening assembly (11) by direct cooperation between an adjustment roll (13-113) and the contrast unit (12-112) located downstream of the straightening assembly (11), the adjustment roll (13-113) lying on a plane parallel to the plane of positioning of the straightening rolls and able to move on the two cartesian axes.
4 - Orthogonal adjustment unit located downstream of a bar straightening machine, wherein the bar may be of a rolled, drawn or extruded type or be obtained with a forming machine and may have any round, oval, square, rectangular or polygonal, etc. section and be solid or hollow, the orthogonal adjustment unit (10) being located immediately downstream of a straightening assembly (11) and between the latter (11) and a contrast unit (12) and being characterized in that it comprises at least one adjustment roll (13) capable of idling and of being positioned as required within an angle of 360° on a plane normal to the nominal axis of the straightening machine and having that nominal axis as its axis, the adjustment roll (13) being in contrast with the last outlet roll (131) of the straightening assembly (11), the contrast unit (12) and straightening assembly (11) lying substantially on the same plane parallel to or coinciding with the plane on which the adjustment roll (13) lies.
5 - Orthogonal adjustment unit (10) as claimed in Claim 4, in which the idler adjustment roll (13) is fitted to two orthogonal elements (18-21) which can be positioned reciprocally as required.
6 - Orthogonal adjustment unit (10) positioned downstream of a bar straightening machine, in which the bar may be of a rolled, drawn or extruded type or be obtained with a forming machine and may have any round, oval, square, rectangular or polygonal, etc. section and be solid or hollow, the orthogonal adjustment unit 10 comprising at least one idler adjustment roll (13) and at least one pair of rolls (26-27) of a contrast unit (12), the adjustment roll (13) and the contrast unit (12) being positioned in sequence immediately downstream of the straightening assembly (11) and lying substantially on the same plane as the straightening assembly (11), the adjustment roll (13) being capable of at least one controlled axial movement, the contrast unit (12) being capable of at least one controlled movement substantially normal lo the movement of the adjustment roll (13).
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| IT8915901A IT1235174B (en) | 1989-01-18 | 1989-01-18 | ORTHOGONAL ADJUSTMENT GROUP AND PROCEDURE FOR THE ORTHOGONAL ADJUSTMENT OF STRAIGHTENED PROFILES |
| IT15901A/89 | 1989-01-18 |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA2007981A1 true CA2007981A1 (en) | 1990-07-18 |
Family
ID=11148298
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA002007981A Abandoned CA2007981A1 (en) | 1989-01-18 | 1990-01-17 | Orthogonal adjustment unit and method for orthogonal adjustment of straightened bars |
Country Status (5)
| Country | Link |
|---|---|
| US (1) | US5111677A (en) |
| EP (1) | EP0379028A1 (en) |
| JP (1) | JPH02229620A (en) |
| CA (1) | CA2007981A1 (en) |
| IT (1) | IT1235174B (en) |
Families Citing this family (9)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| DE4325492A1 (en) * | 1993-07-29 | 1995-02-02 | Meyer Roth Pastor Maschf | Straightening machine for strand or band-shaped straightening goods |
| EP0832688B1 (en) | 1996-04-11 | 2007-08-29 | ICT Co., Ltd. | Exhaust gas purifying catalyst and exhaust gas purifying method |
| IT1299943B1 (en) * | 1998-03-30 | 2000-04-04 | Schnell Spa | METHOD AND EQUIPMENT FOR STRAIGHTENING METAL PROFILES AND SIMILAR. |
| US6260502B1 (en) | 1998-03-31 | 2001-07-17 | Owen Kratz | Semi-submersible vessel |
| ATE320868T1 (en) * | 2000-02-03 | 2006-04-15 | Stema Engineering As | METHOD AND DEVICE FOR REDUCING INTERNAL STRESSES IN REINFORCING IRONS OR THE SIMILAR |
| DE10120050C1 (en) * | 2001-04-24 | 2002-10-10 | Valeo Auto Electric Gmbh | Method, for producing curved spring strip sections, involves adjusting one support position adjacent to a further support position perpendicular to the spring strip in the direction of the strip thickness |
| ITBO20020604A1 (en) * | 2002-09-25 | 2004-03-26 | Schnell Spa | FINAL CORRECTION GROUP IN EQUIPMENT FOR |
| IT1391890B1 (en) * | 2008-10-14 | 2012-01-27 | Piegatrici Macch Elettr | TOWING AND / OR STRAIGHTENING GROUP FOR OBLUNG METAL PRODUCTS, SUCH AS BARS, ROUNDS OR METAL WIRES |
| DE102012018169B4 (en) * | 2011-12-29 | 2015-11-05 | Waldaschaff Automotive GmbH | Device for advancing and bending metal profiles |
Family Cites Families (14)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| GB595071A (en) * | 1944-09-28 | 1947-11-26 | John Wilson Warburton | Improvements in or relating to the straightening of wire strip |
| DE180901C (en) * | ||||
| US1054022A (en) * | 1909-10-21 | 1913-02-25 | Louden Machinery Co | Wire-straightener. |
| US1239175A (en) * | 1916-09-18 | 1917-09-04 | Albert P Gilbert | Wire-straightening machine. |
| DE380128C (en) * | 1922-01-29 | 1923-09-03 | Sack Gmbh Maschf | Roller straightening machine for rod-shaped bodies or plates of constant cross-section with outlet roller and segment, lever or star-shaped body for bending the front end of the rod |
| US2095474A (en) * | 1935-09-13 | 1937-10-12 | Macwhyte Company | Apparatus for and method of shaping wire |
| US2136714A (en) * | 1936-05-16 | 1938-11-15 | Washburn Wire Company Inc | Mechanism for straightening wire |
| US2219811A (en) * | 1938-07-19 | 1940-10-29 | Nat Machinery Co | Rod straightening and handling mechanism for headers |
| DE1250237B (en) * | 1962-09-13 | |||
| FR1427150A (en) * | 1964-12-21 | 1966-02-04 | Quillery | Process for forming metal circles and machine for implementing this process |
| DE2518798C3 (en) * | 1975-04-28 | 1979-02-01 | Vladimir Nikolaevitsch Shubin | Bending head for tube bending machines |
| AT368725B (en) * | 1981-01-30 | 1982-11-10 | Evg Entwicklung Verwert Ges | COMBINED LEVELING AND BENDING MACHINE |
| EP0231092B1 (en) * | 1986-01-29 | 1991-08-21 | Ronald Edward Benton | Bending machine |
| EP0269157B1 (en) * | 1986-11-26 | 1992-01-29 | M.E.P. Macchine Elettroniche Piegatrici S.p.A. | Antirotation method to straighten sections and antirotation straightening machine which employs such method |
-
1989
- 1989-01-18 IT IT8915901A patent/IT1235174B/en active
-
1990
- 1990-01-09 EP EP90100333A patent/EP0379028A1/en not_active Withdrawn
- 1990-01-17 JP JP2006494A patent/JPH02229620A/en active Pending
- 1990-01-17 CA CA002007981A patent/CA2007981A1/en not_active Abandoned
-
1991
- 1991-01-23 US US07/643,682 patent/US5111677A/en not_active Expired - Fee Related
Also Published As
| Publication number | Publication date |
|---|---|
| JPH02229620A (en) | 1990-09-12 |
| US5111677A (en) | 1992-05-12 |
| IT1235174B (en) | 1992-06-23 |
| IT8915901A0 (en) | 1989-01-18 |
| EP0379028A1 (en) | 1990-07-25 |
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Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| FZDE | Discontinued |