The present invention relates to a method and apparatus for roll forming for producing a shaped steel which varies in cross-sectional shape in the longitudinal direction.
As a method of producing a hat-shaped steel, which is one type of shaped steel, press forming using a punch and die is widely known. In bending into a hat shape by press forming, the problem of springback, that is, the sheet material trying to return to its original state due to the reaction force when the press pressure is removed, easily arises, and therefore in the past, countermeasures for suppressing springback have been studied.
In this regard, in recent years, use of high tensile steel has been expanding. As one example, in the automobile industry, it is believed that reduction of the weight of the vehicle body will lead to reduction of the amount of emission of CO2 and therefore high tensile steel is being proactively used for the vehicle body material. For this reason, on the production floor of shaped steels, the problem of the springback due to the high strength characteristics of steel materials has been surfacing. Furthermore, in recent years, high tensile steel which has an over 980 MPa tensile strength has also been being produced. With general press forming, it is difficult to produce a hat-shaped steel as designed from such high tensile steel.
As another method of producing a shaped steel, the roll forming method is known. Roll forming is, for example, a continuous bending process which runs a strip, which is taken out from a coil, through roll units provided at a plurality of successively arranged stations. Roll forming is, in particular, suitable for forming H-beams, L-beams, and other steel products and pipes and other long products with constant cross-sectional shapes in the longitudinal direction. On the other hand, roll forming, unlike press forming (drawing), is not suited for forming a shaped steel which varies in cross-sectional shape in the longitudinal direction.
PLTs 1 to 3 disclose the art of roll forming to produce a shaped steel which varies in cross-sectional shape in the longitudinal direction by variable control of the roll widths of split rolls. However, the roll forming process and apparatus disclosed in PLTs 1 to 3 have the problem of a complicated structure and method of control of the apparatus. For this reason, it is difficult to convert existing facilities for use for working the inventions of PLTs 1 to 3. Introduction of new facilities is necessary, and therefore the cost becomes high.
Further, if, as in the inventions of PLTs 1 and 3, broadening the roll widths of the split rolls during roll forming, there are the problems that only the corner parts at the front sides of the rolls will linearly contact the steel sheet material and, in high tensile steel or other materials, stiffness of a mill is insufficient, and therefore it is not appropriate for mass production.
PLT 1: Japanese Patent Publication No. H10-314848 A
PLT 2: Japanese Patent Publication No. H7-88560 A
PLT 3: Japanese Patent Publication No. 2009-500180A
The present invention was made to solve the above problem and has as its object to provide art which enables production of a shaped steel which varies in cross-sectional shape in the longitudinal direction by simple roll forming without the need for complicated control and apparatuses such as in the prior art.
Further, another object of the present invention is to provide art which enables suppression of insufficiency in stiffness of a mill when using, for example, high tensile steel, in the case of producing a shaped steel, which varies in cross-sectional shape in the longitudinal direction, by roll forming.
To solve the above-mentioned problem, according to the present invention, there is provided a method of producing a shaped steel which varies in cross-sectional shape in the longitudinal direction from a sheet by roll forming, comprising: a step of preparing a first rolling die which has a rotation shaft and an annular ridge part which varies in cross-sectional shape in a circumferential direction which is centered about the rotation shaft; a step of arranging the first rolling die so that the rotation shaft of the first rolling die becomes perpendicular to a sheet feed direction; a step of preparing a second rolling die which has a rotation shaft and an annular groove part which varies in cross-sectional shape in a circumferential direction which is centered about the rotation shaft; a step of arranging the second rolling die so that a gap which is equal to a thickness of the sheet is formed between the first rolling die and second rolling die and the annular ridge part of the first rolling die and the annular groove part of the second rolling die engage; a step of making the first rolling die and the second rolling die rotate synchronized; and a step of feeding a sheet between the first rolling die and second rolling die, wherein the side surfaces of the annular ridge part of the first rolling die are provided with relief so that the gap with respect to side surfaces of the annular groove part of the second rolling die broadens inward in the radial direction over an entire of the circumference.
Furthermore, the present invention has as its gist a roll forming apparatus for roll forming use for producing a shaped steel which varies in cross-sectional shape in the longitudinal direction from a sheet, comprising: a first rolling die which has a rotation shaft and an annular ridge part which varies in cross-sectional shape in a circumferential direction which is centered about the rotation shaft, the first rolling die arranged so that the shaft of the first rolling die becomes perpendicular to a sheet feed direction; a second rolling die which has a rotation shaft and an annular groove part which varies in cross-sectional shape in a circumferential direction which is centered about the rotation shaft, the second rolling die arranged so that the rotation shaft of the second rolling die becomes parallel to the rotation shaft of the first rolling die; and a drive device which synchronizes and rotationally drives the first rolling die and the second rolling die, the first rolling die and second rolling die being arranged relatively so that a gap which is equal to a thickness of the sheet is formed between the two and the annular ridge part of the first rolling die and the annular groove part of the second rolling die engage, wherein the side surfaces of the annular ridge part of the first rolling die are provided with relief so that the gap with respect to side surfaces of the annular groove part of the second rolling die broadens inward in the radial direction over an entire of the circumference.
According to the present invention, by using a first rolling die having an annular ridge part which varies in cross-sectional shape in the circumferential direction and a second rolling die having an annular groove part which receives the annular ridge part of the first rolling die while maintaining a gap with the annular ridge part of the amount of thickness of the shaped steel, by simple control for making at least the first and second rolling dies rotate synchronized, a shaped steel with a cross-sectional shape which varies in the longitudinal direction can be produced. Accordingly, complicated control such as variable control of the roll widths of split rolls for broadening the width of the cross-section becomes unnecessary. Further, it is possible to realize the rolling forming apparatus of the present invention by changing the rolls of existing roll forming apparatuses to the first and second rolling dies.
In addition, according to the present invention, by using the first and second rolling dies which have the above-mentioned roll barrel parts, even if the cross-sectional shape varies in the longitudinal direction, shaping is possible in the state where the roll barrel parts and material contact sufficiently on surface to each other, and therefore it is possible to suppress insufficiency in stiffness of a mill when using, for example, high tensile steel.
Below, a method of production of a shaped steel which varies in cross-sectional shape in the longitudinal direction and a roll forming apparatus for the same according to preferable embodiments of the present invention will be explained in detail, while referring to the attached drawings. However, the embodiments explained below shall not cause the present invention to be interpreted limited in technical scope in any way.
First, the shaped steel produced in the present embodiment will be explained. The shaped steel which is shown in
The hat-shaped steel 1 further has ^portions 10a, 10b having top wall width of L1, a portion 11 having top wall width of L2 (>L1), and tapered transition portions 12a and 12b having expanding (or contracting) top wall width of L1 to L2. The hat-shaped steel 1 has hat-shape horizontal cross-sections with side walls which flare outward at the portions 10a to 12b. The side walls may have gradient angles which differ at the portions 10a to 10b or which are the same at the portions 10a to 10b. Further, the thickness of the steel shape can, for example, be set to various thicknesses according to the specifications, applications, etc. However, in the present embodiment, the different portions 10a to 12b are not individually shaped and joined by welding etc., but are integrally shaped from a single sheet or strip by roll forming. Therefore, the boundary lines between portions of
Furthermore, the flanges 13 formed at the opening part of the bottom surface side along the longitudinal direction are also obtained by bending the sheet or strip by roll forming. Further, the corner parts which formed by bending can, for example, have chamfered shapes or rounded shapes such as shown in
The type and strength of the material are not particularly limited. All metal materials which can be bent can be covered. As examples of the metal material, there are carbon steel, alloy steel, nickel-chromium steel, nickel-chromium-molybdenum steel, chromium steel, chromium-molybdenum steel, manganese steel, and other steel materials. If based on strength, steel with tensile strengths of 340 MPa or less can be roughly classified as general steel and steel with higher strengths can be roughly classified as high tensile steel, but in the present embodiment, either can be applied. Furthermore, high tensile steel includes steel of for example the 590 MPa grade or 780 MPa grade. Currently, steel of the 980 MPa grade called “ultra high tensile steel” are being produced. Regarding ultra high tensile steel, sometimes bending into hat shapes becomes difficult with conventional press forming (drawing), but with the roll forming of the present embodiment, 980 MPa or more ultra high tensile steel can also be applied. Furthermore, as examples of materials other than steel materials, there are the poorly malleable materials including titanium, aluminum, or magnesium or their alloys.
Next, the roll forming apparatus for producing a steel shape which varies in cross-sectional shape in the longitudinal direction will be explained.
The rolling dies of the roll unit 20a of the downstream-most station (final station) (below, sometimes referred to as the “finishing rolls”) are shaped corresponding to the target product shape. The rolling dies of the stations at the upstream side from the finishing rolls are designed so that intermediates which approach the final product shape in stages the further toward the downstream side are formed at the different stages.
On the other hand, at each of the fourth station to the 10th station which perform the second half bending process, the roll units 20e to 20a have the dies which have the annular ridge parts at the bottom side and the dies which have the annular groove parts at the top side. Further, the entry station (roll unit 20k: 0th station) to fifth station (roll unit 20f) are the first half process for forming the flanges 13 (flange bending) and the sixth station (roll unit 20e) to the final station or the 10th station (roll unit 20a) are the second half process for forming the top wall of the hat-shaped steel 1 (top wall bending).
The roll unit 20k of the entry station has rolling dies having plain cylindrical shape arranged at both the top and bottom. Further, the roll units 20j to 20f from the first station to the fifth station become gradually smaller in diameters in the directions toward the ends at both two end portions of the top rolls, while the two end portions of the roll barrel parts of the bottom rolls become gradually larger in diameter in the directions toward the ends. Further, the gradient angles of the two end portions of the dies become sharper in order from the first station to the fifth station. At the roll unit 20f of the fifth station, the two ends of the sheet or strip M are bent about 900, whereupon the flanges 13 are formed. The dies have, in the circumferential direction, parts of narrow widths and wide widths and parts of tapers of increasing/decreasing width, at the centers of the roll barrel parts, so that flanges 13 of the portions 10a to 12 of the shaped steel are formed.
On the other hand, the roll units 20e to 20a from the sixth station to the final station have bottom rolls with annular ridge parts in which the center of the roll barrel parts are raised in projecting shapes and have top rolls with annular groove parts in which the center of the roll barrel parts are sunk in recessed shapes. Further, more specifically, the annular ridge parts of the bottom rolls and the annular groove parts of the top rolls comprises narrow width parts, wide width parts, and tapered parts with increasing width/decreasing width, arranged in the circumferential direction, so that the top walls of the portions 10a to 12 of the hat-shaped steel 1 are formed.
The gradient angles of the side surfaces of the annular ridge parts and annular groove parts of the rolls become sharper in the order from the sixth station to the final station. At the roll unit 20a of the final station, the side walls of the sheet or strip M are bent about 900 whereby the top wall of the hat is formed. However, the configuration of the rolling dies which is shown in
Note that, in the present embodiment, the cross-sectional shape is not just increased in width. After the portion 11 where the width becomes maximum, portions 12b and 10b which are decreased in widths are formed by the rolls, and therefore the intervals between the roll units 20a to 20k are set to at least the lengths of the products.
Next, the configuration of the roll units 20a to 20k will be explained.
The shafts 31 and 41 of the rolls 3 and 4 are, for example, rotatably supported by ball bearings or other bearing mechanisms 5 at stands or other support members 51. The rolls 3 and 4 are supported to be able to be raised and lowered and can be adjustable in distance of separation of the rolls. Furthermore, it is also possible to use a hydraulic pressure cylinder or other pressing device to enable adjustment of the pressing forces of the top and bottom rolls 4 and 3.
The top and bottom rolls 4 and 3 are driven to rotate synchronized by a gear set 52. The gear set 52 comprises gears 52a and 52b which are coupled with the shafts 31 and 41 respectively and are engaged with each other.
The gear set 52 only need make the top and bottom rolls 4 and 3 rotate synchronously by the same peripheral speed. The gears need not be spur gears such as shown in
The top and bottom rolls 4 and 3 which are arranged at the final station are shaped corresponding to the target product shape. Specifically, as shown in
That is, the annular ridge part 33 has a region 33a which is set in width of the outer circumferential surface to the first roll width, a region 33b which is set in width of the outer circumferential surface to the second roll width, and tapered regions (in the following explanation, sometimes called the “transition parts”) 33c and 33d which are arranged between the regions 33a and 33b and vary in widths of the outer circumferential surfaces from the first roll width to the second roll width. The left and right side surfaces of the annular ridge part 33 form slanted surfaces which expand to the outward sides the further toward the shaft 31 side. Further, the width and height of the annular ridge part 33 and the gradient angle of the side surfaces are dimensions which correspond to the width and height and the gradient angle of the target hat shape. Furthermore, the corner parts at the outsides of the annular ridge part 33 and the corner parts at the insides of the flank parts 43 are rounded or are chamfered. Note that,
The region 33b of the annular ridge part 33 forms the portion 11 of the width L2 of the hat-shaped steel 1, while the regions 33c and 33d form the tapered portions 12a and 12b of the hat-shaped steel 1. Therefore, the arc length of the region 33b is set to the length of the portion 11, while the arc lengths of the regions 33c and 33d are set to lengths of the portions 12a and 12b. On the other hand, the region 33a of the annular ridge part 33 forms both the portions 10a and 10b of the hat-shaped steel 1. Therefore, the arc length of the region 33a is set to a length corresponding to the sum of the lengths of the portions 10a and 10b. In this case, the intermediate point which equally divides the region 33a becomes the start point of the roll. However, when a continuous sheet or strip M for continuous forming is used and the finally shaped product is successively cut downstream of the apparatus, regions giving cutting margins may also be added to the regions 33a. In this case, a mark for indicating the cutting position (for example, small hole, projection, etc.) may also be formed at the surface of the sheet or strip M.
On the other hand, the top roll 4 is formed to face the roll barrel part of the bottom roll 3 across a gap of the amount of thickness of the hat-shaped steel 1. Therefore, the top roll 4 has an annular groove part 42 which rolls the outside bottom surface of the hat shape and flank parts 43 which are formed at the two sides of the annular groove part 42 and roll the outside surfaces of the hat shape and the bottom surfaces of the flanges 13. The inside surfaces of the annular groove part 42 are also formed to face the side surfaces of the annular barrel part 33 of the bottom roll 3 through a gap of the amount of thickness of the hat-shaped steel 1. Due to this, the annular groove part 42 of the top roll 4 varies in cross-sectional shape in the circumferential direction.
The side surfaces of the annular groove part 42 of the top roll 4, like the annular ridge part 33 of the bottom roll 3, are formed with the region 43b which forms the portion 11 of the hat-shaped steel 1, the regions 43c and 43d which form the tapered portions 12a and 12b respectively, and the region 43a which forms the portions 10a and 10b, in the circumferential direction. Furthermore, in the same way as the annular ridge part 33, the intermediate point which equally divides the region 43a forms the start point of the rolls, and therefore when assembling the top and bottom rolls 4 and 3 in the apparatus, the top and bottom rolls 4 and 3 are positioned in the rotation direction at the positions where their start points face each other (same phase).
If viewed in the shaft direction, the annular ridge part 33 of the bottom roll 3 and the flank part 43 of the top roll 4 have cylindrical surfaces with outer circumferential surfaces of the same diameters. Due to this, if making the top and bottom rolls 4 and 3 rotate by the same peripheral speeds, the relative phase of the top and bottom rolls 4 and 3 will not change. In the case of a pair of top and bottom rolls, so-called “slip” is liable to cause the relative phase of the turning top and bottom rolls 4 and 3 to change. If the rolls have cross-sectional shapes which are constant in the circumferential direction, “slip” does not become that much of a problem, but the top and bottom rolls 4 and 3 of the present embodiment have regions which vary in cross-sectional shape in the circumferential direction, and therefore if “slip” causes the top and bottom rolls 4 and 3 to become offset in phase, the finished product is liable to become off in thickness from the design value and the top and bottom rolls are liable to collide. Therefore, in the present embodiment, it is important to make the top and bottom rolls 4 and 3 turn without changing their relative phases. The gear 52 which forms the above-mentioned synchronized rotation mechanism also has the role of preventing the relative phase of the turning top and bottom rolls 4 and 3 from changing.
Note that, the top and bottom rolls 4 and 3 only have to be made from a material which is higher in rigidity than the sheet or strip M at the roll barrel parts. The material is not limited. Further, it is also possible to arrange the rolling die which has the annular ridge part at the top side and the rolling die which has the annular groove part at the bottom side.
The present invention is not limited to the following dimensions, but to further deepen understanding, an example of the dimensions of the different regions of the bottom roll 3 will be shown. First, the radius of the bottom roll 3 to the outer circumferential surface is 500 mm at the annular ridge part 33 and 450 mm at the flank parts 32. The difference of the two corresponds to the height of the hat shape. The width of the outer circumferential surface of the region 33a is 50 mm, while the arc length is 400 mm. Further, the width of the outer circumferential surface of the region 33b is 80 mm, while the arc length is 400 mm. Further, the portions 33c and 33d have arc lengths of 300 mm and expand in width or contract in width by a 15° gradient angle. The top roll 4 faces the bottom roll 3 through a gap of 2 mm.
Next, the method of using the multistage roll forming apparatus 2 to produce the hat-shaped steel 1 will be explained. First, the top and bottom rolls 4 and 3 of the roll units 20a to 20k are made to rotate at a predetermined speed and the sheet or strip M is fed to the roll unit 20k of the entry station. For example, as the steel sheet or strip M, it is possible to use steel sheet which is sent from an upstream rolling process or use a strip which is wound in a coil shape. At this time, the sheet or strip M is fed so that the length direction becomes perpendicular to the axial direction of the top and bottom rolls 4 and 3 and is roll formed in the length direction of the sheet or strip M. The sheet or strip M (intermediate) which is fed out from the roll unit 20k is conveyed by the rotational operation of the top and bottom rolls 4 and 3 to the roll unit 20j of the next station. Further, it is roll formed by this second stage roll unit 20j along the length direction and is further conveyed to the roll unit 20i of the next station.
Note that, when continuously roll forming the sheet or strip M, the roll units 20a to 20k of the different stations may be used to form it while applying back tension and/or forward tension. Further, they may form it by cold, warm, or hot roll forming.
The state where the finishing rolls perform the final forming operation is shown in
The finished product which is fed out from the finishing roll after final shaping is completed is cut at the position forming the terminating end (that is, the end part of the portion 10b) and, is conveyed to other next step, for example, to the product inspection step. The cutting position can be automatically discerned by for example detecting a mark (for example, small hole, projection, etc.) which is formed at intervals in the length direction of the sheet or strip M, by a sensor. The mark may be provided at intervals corresponding to the lengths of the finished products at the sheet or strip M in advance or may be provided during roll forming. As the method of providing a mark during roll forming, using top and bottom rolls 4 and 3 which are formed with projections forming the mark at a position corresponding to the starting point of the rolls so as to transfer a mark along with bending to the hat shape may be mentioned as one example. In addition to a mark, a predetermined relief shape may be formed on the surface of the roll barrel part so as to form a bead, embossing, or other shape.
According to the present embodiment, when using a bottom roll 3 which has an annular ridge part 33 and a top roll 4 which has an annular groove part which faces the annular ridge part 33 to produce a hat-shaped steel 1, by the shapes of the annular ridge part 33 and the annular groove part 42 being made shapes which vary in cross-sectional shape in the circumferential direction, a hat-shaped steel 1 which varies in cross-sectional shape (that is, the hat shape) in the longitudinal direction can be produced by simple control for making the top and bottom rolls 4 and 3 rotate synchronized.
In this way, the roll forming according to the present embodiment does not require the complicated control method for changing the roll widths of split rolls like in the past, and therefore does not require the introduction of new control modules for this purpose. Accordingly, for example, it is possible to realize the roll forming apparatus of the present embodiment by changing the rolls of an existing roll forming apparatus to the top and bottom rolls 4 and 3 of the present embodiment.
Note that, in the multistage roll forming apparatus 2 of
Furthermore, according to the present embodiment, by the roll barrel part which varies in cross-sectional shape in the circumferential direction, the roll barrel part and material can sufficiently contact each other in the forming operation, and therefore for example even if the material is high tensile steel, insufficient mill rigidity can be suppressed. Accordingly, the roll forming method and apparatus of the present embodiment can also be applied to tensile strength 980 MPa or more ultra high tensile steel.
Next, a modification of the rolling dies which are shown in the above-mentioned first embodiment will be explained. In the rolling dies of the present embodiment, as shown in
The relief which is provided at the side surfaces of the ridge part 33 of the bottom roll 3 will be explained in detail.
On the other hand, it is learned that when providing relief, the gap is varied in the transition parts 33c, 33d, 43c and 43d, but the amount of variation thereof is extremely small and the gap is maintained substantially constant over 0° to 180° as a whole. While depending on the thickness or shape of the shaped steel, the preferable minimum gap when considering the product specifications etc. becomes the thickness of the sheet or more. According to the present embodiment, by providing relief at the side surfaces of the annular ridge part 33 of the bottom roll 3, it becomes possible to secure a minimum gap of the sheet thickness or more. Further, in order to compare,
The variation in the gap between the top and bottom rolls 4 and 3 in the circumferential direction may result in a variation in thickness of products. Therefore, it is significantly advantageous that the gap between the top and bottom rolls 4 and 3 in the circumferential direction can be substantially constant by providing a relief on the side surfaces of the annular ridge part 33 of the bottom roll 3 so as to offset in the axial inner direction of the roll. In addition, in the case where the relief if provided on the annular ridge part 33, in addition to enabling the gap to be maintained substantially constant, the effect that a generation of slip of the sheet on the side surface of the bottom roll 3 is suppressed to prevent generation of wrinkling, can be obtained, and it is possible to prevent a reduction in sheet thickness at the base region of the annular ridge part 33, which prevents the sheet thickness from falling below a fracture criteria. From the above, in the second embodiment as well, it is possible to obtain effects similar to the first embodiment and, furthermore, it is possible to form a shaped steel which is kept down in variation in sheet thickness.
Note that, it is preferable to provide relief at the side surfaces of the annular ridge part 33 of the bottom roll 3 not only at the roll unit 20a of the final station, but also part or all of the other roll units 20b to 20k which are arranged upstream of it. The multistage roll forming apparatus 2 which is shown in
However, the top and bottom rolls 4 and 3 of the stations differ in roll shape (in particular, the inclination of the annular ridge part 33), and therefore each of them has a preferable relief amount. Therefore, the inventors etc. engaged in actual designs and conducted intensive studies and as a result discovered that the preferable relief amount x has a relationship x=α×H×tan θ with respect to the angle θ of the side walls of the shaped steel and the height H of annular ridge part 33. In this regard, the relief amount x, the side wall angle θ of the shaped steel, and the height H of the annular ridge part 33 are as shown in
Further, as a result of studying the relationship among the relief amount x, the side wall angle θ and the height H of the annular ridge part 33, it is confirmed that the minimum gap of 1 mm is secured by providing a relief of not less than an amount calculated by the correlation equation: x=0.0046×H×tan θ (note that θ<85°) shown in
The multistage roll forming apparatus 2 of
Therefore, as another example, the multistage roll forming apparatus 2 which is shown in
In this way, even when the roll shape varies at each station, by setting a relief amount x according to the above equation: x=0.0046×H×tan θ (note that θ<85°) as shown in
Note that the constant α in the above equation can be determined by obtaining several kinds of data shown in
Further, if the constant α is determined according to the roll shapes of the final station, the equation: x=α×H×tan θ is used to calculate the optimum relief amount of the rolls of the step before the final station. In the example of
Furthermore, preferably, as shown in
Note that, the shapes of the top and bottom rolls 4 and 3 according to the above-mentioned embodiments are examples for producing the hat-shaped steel 1 which is shown in
Furthermore, the shaped steel which is produced is also not limited to a hat-shaped steel. For example, it is possible to make the cross-sectional shape of the annular ridge part 33 a square shape and produce a shaped steel with a cross-sectional shape of a staple shape or to make the top part of the annular ridge part 33 curved to make the cross-sectional shape a U-shape. Further, it is possible to make the cross-sectional shape of the annular ridge part 33 a triangular shape and produce a shaped steel with a cross-sectional shape of a V-shape. In each case, by using a roll with a cross-sectional shape of the annular ridge part 33 which is varied in the circumferential direction, a staple shaped steel, U-shaped steel, or V-shaped steel which varies in cross-sectional shape in the longitudinal direction is formed. Furthermore, it is possible to vary to a different shape, for example, from a hat-shape to a U-shape, in the longitudinal direction. The invention is not limited to these, but modifications of the shaped steels which are produced and examples of the finishing rolls for forming the shaped steels will be explained while referring to
According to the present embodiment, by simple control for making the top and bottom rolls rotate synchronized, a hat-shaped steel with a cross-sectional shape in the longitudinal direction which curves in the width direction can be produced. Furthermore, if arranging the roll units 20a to 20k in tandem curved in the up-down direction, a hat-shaped steel which is curved in the longitudinal direction can also be produced.
In the present embodiment, a steel shape which forms a cross-sectional U-shape is produced.
The U-shaped steel 6 of
The present embodiment also produces shaped steel having a U-shape cross-section. However, while the above-mentioned fifth embodiment has a constant height, in the present embodiment, as shown in
Except for the point of the U-shaped steel 6 of
The present embodiment produces a shaped steel which forms a cross-sectional V-shape.
Above, the present invention was explained in detail with reference to specific embodiments, but various substitutions, alterations, changes, etc. relating to the format or details are possible without departing from the spirit and scope of the invention such as defined by the language in the claims will be clear to a person having ordinary skill in the technical field. Therefore, the scope of the present invention is not limited to the above-mentioned embodiment and attached figures and should be determined based on the description of the claims and equivalents to the same.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2012/074443 | 9/24/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/045449 | 3/27/2014 | WO | A |
Number | Name | Date | Kind |
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4317350 | Sivachenko et al. | Mar 1982 | A |
20090113974 | Ingvarsson | May 2009 | A1 |
Number | Date | Country |
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57-206522 | Dec 1982 | JP |
59-27722 | Feb 1984 | JP |
59-179228 | Oct 1984 | JP |
63-295019 | Dec 1988 | JP |
5-329555 | Dec 1993 | JP |
6-226356 | Aug 1994 | JP |
7-88560 | Apr 1995 | JP |
7-89353 | Apr 1995 | JP |
10-34244 | Feb 1998 | JP |
10-314848 | Dec 1998 | JP |
2008-221289 | Sep 2008 | JP |
2009-500180 | Jan 2009 | JP |
Entry |
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English translation of JP-59-179228-A, published Oct. 11, 1984. |
Taiwanese Office Action and Search Report, issued Feb. 4, 2015, for Taiwanese Application No. 101135599. |
International Search Report, mailed Dec. 11, 2012, issued in PCT/JP2012/074443. |
Number | Date | Country | |
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20150251234 A1 | Sep 2015 | US |