This application is a 35 U.S.C. § 371 national phase application of PCT/EP2019/073107 (WO-2020/043832-A1), filed on Aug. 29, 2019, entitled “WORKING OF SHEET METAL”, which application claims the benefit of GB Patent Application No. 1814069.9, filed Aug. 29, 2018, each of which are incorporated herein by reference in entirety.
The present invention relates to methods for working of sheet metal and to workpieces that are obtainable by such methods of working of sheet metal. The present invention also relates to sheet metal working apparatus.
Up to half of all the sheet metal made globally each year is not used in a final product but is cut off during manufacture. Two main causes of this loss are blanking (cutting a flat shape out of the coiled up long flat sheets made in rolling mills) and trimming after deep drawing, with the latter dominating. These losses are an unavoidable by-product of these processes. Further discussion and quantification of these losses is set out in Horton and Allwood (2017).
The cost in both money and carbon emissions associated with these losses is high, although at present the process of blanking followed by deep drawing is considered to be the most efficient way to make shaped sheet metal components such as e.g. car body components. In blanking and deep drawing, a key consideration is the avoidance of wrinkling and tearing during forming.
It would be advantageous to be able to form components of similar shape as made at present by deep drawing but with less wastage of the starting material.
The present invention has been devised in order to address at least one of the above problems. Preferably, the present invention reduces, ameliorates, avoids or overcomes at least one of the above problems.
The present inventors have realised that it is possible to form suitable component shapes from sheet metal by a different process. It is recognised by the inventors that the geometrical features of any sheet-metal part can be described as a combination of the three-types of ‘flange’ illustrated in
Accordingly, in a first preferred aspect, the present invention provides a method of manufacturing a formed sheet metal structure, comprising the steps of:
The at least one edge of the sheet metal workpiece may comprise first and second edge regions, and the method may further comprise bending the workpiece to form said first sidewall portion and a second sidewall portion respectively defined between the first and second edge regions and the basal region, and to define the curved fold region intermediate the first and second sidewall portions.
The forming tool and/or the anvil tool may be progressively slid along the curved fold region in a direction away from the basal region. Additionally or alternatively, the forming tool and/or the anvil tool may be progressively slid along the curved fold region laterally to the basal region. The precise direction in which the forming tool and/or anvil tool are slid along the curved fold region will depend on a number of considerations, and may be selected as appropriate given the initial shape of the sheet metal workpiece, and the desired final shape of the formed sheet metal structure.
The above method (otherwise termed herein a “Folding-Shearing” method) may allow for production of a formed sheet metal structure which requires minimal or no trimming after forming, in comparison to e.g. production of the same part via a deep drawing process. Additionally, the above method may allow for reduced metal waste whilst also maintaining satisfactory sheet qualities (e.g. reducing or avoiding unwanted material deformation such as wrinkling or tearing).
The term “basal region” is here used to define a region of the sheet metal workpiece which is a planar, base-like region. The basal region may undergo little or no bending and/or deformation during the forming process. In other words, the basal region may be a region of the workpiece which, during the forming operation, remains unchanged from its original size and shape. In some alternative forming processes, the basal region may undergo some shear deformation. The size and shape of the basal region is not particularly limited and may be selected as appropriate given the intended form of the formed sheet metal structure.
The term “curved” used here to define the curved fold region is considered to be synonymous to “rounded”, and is used to generally refer to a region having some degree of curvature. The curvature may vary across the region. Accordingly, the terms curved or rounded are not used herein to solely refer to regions of constant curvature (i.e. they are not intended to be limited only to cylindrical or spherical regions).
The precise shape of the curved fold region is not particularly limited, and may take a number of different forms depending on the specific forming process and the desired final shape of the product. In some embodiments, the curved fold region may initially be approximately cone-shaped, or near-cone-shaped with an apex at an intersection of the sidewall portion(s) and the basal region. During deformation of the curved fold region, it may undergo a cone-to-cylinder deformation. In some embodiments, the curved fold region may initially be approximately cylindrical, and undergo cylinder to cylinder deformation.
The precise nature of the further deformation of the curved fold region during the step of progressively sliding the forming tool and/or the anvil tool along the curved fold region is not particularly limited, and will depend on the specific forming process and the desired final shape of the product. In some embodiments, the curved fold region may be deformed in such a way as to cause portions of the curved fold region to be flattened. Such flattened portions of the original curved fold region may lie in the same plane as the sidewall(s) of the sheet metal workpiece. Alternatively, such flattened portions of the original curved fold region may lie in the same plane as a basal region of the sheet metal workpiece. In some embodiments, the forming tool and/or the anvil tool may be progressively slid along only a portion of the curved fold region such that deformation of the curved fold region only takes place at or adjacent said portion.
The shear material transfer in the curved fold region may occur via material transfer from the curved fold region to at least one sidewall portion and/or material transfer to the curved fold region from at least one sidewall portion. However in some embodiments, the shear material transfer in the curved fold region may additionally or alternatively occur via shear material transfer to or from a basal region of the sheet.
Material transfer from the curved fold region to at least one sidewall portion may provide for improved shrink flange formation. Material transfer to the curved fold region from at least one sidewall portion may provide for improved stretch flange formation. By allowing for such material transfer, it may be possible to create flanges of a variety of shapes with little or no material thinning or thickening at the flange region, thus helping the reduce the occurrence of wrinkling and/or tearing during the forming process.
The term “sidewall portion” is used herein to generally define a portion of the workpiece which forms a sidewall with respect to a basal region of the sheet. In other words, it is a portion of the sheet which is inclined relative to a basal region of the sheet in such a way as to form a sidewall. The bending/folding performed to form such sidewall portions may be partially elastic or may be fully plastic. In some cases, folding may occur along a fold line adjacent the basal region of the sheet. Such fold line may define an edge of the basal region. The number of sidewall portions may be selected as appropriate given the desired final shape of the formed sheet metal structure. As discussed above, there may be at least first and second sidewall portions. Preferably the sidewall portion(s) respectively extend from the basal region (e.g. from a fold line defining an edge of the basal region) to the edge(s) of the sheet metal workpiece. In this way, the sidewall portion(s) can be considered to be flange portions connected to and extending from the basal region.
Bending of the workpiece to form the sidewall portion(s) may be performed by partially folding the sheet metal workpiece. This may be achieved by e.g. applying a bending moment to the first and/or second surface of the sheet metal at one or more locations between the basal region and the edge of the workpiece. Bending of the workpiece may be performed by engagement of the sheet metal workpiece between the anvil tool and the forming tool alone, during the step of contacting the sheet metal workpiece with the anvil tool and the forming tool. Alternatively, the bending moment may be applied using one or more bending tools. Accordingly the method may further comprise a step of providing one or more bending tools to perform the step of bending the workpiece to form the sidewall portion(s). Where one or more bending tools are used, the precise form of the bending tool(s) is not particularly limited and may comprise e.g. one or more rods or rollers, gripping members, or any other member(s) suitable for application of a bending moment to the sheet workpiece. Preferably, the bending tool(s) have an elongate form. This may allow for an even application of bending moment across the width of the sidewall portion(s). The bending moment may be applied using a plurality of bending tools. Where there are multiple bending tools, there may be one or more bending tools disposed either side of the sheet metal workpiece. For example, there may be two rods/rollers, with a single rod/roller respectively disposed on either side of the workpiece. Alternatively there may be 3 rods/rollers, two opposing one, or 4 or more rods/rollers. In this way, the position or force may be controlled between them to create curvature of the workpiece as the tool is moved along the surface.
Where one or more bending tool(s) are used to form the sidewall portion(s), they may be positioned to constrain the first and/or second surfaces of the sidewall portion(s) as the forming tool progressively slides over the curved fold region. Preferably, the sidewall portion(s) are respectively constrained at one or both of their first and second surfaces immediately adjacent the forming tool. Where the forming tool has a rounded tool surface, the sidewall portion(s) may be constrained immediately adjacent the rounded tool surface of the forming tool. Providing such additional surface constraint of the sidewall portion(s) can help to achieve the desired deformation of the curved fold region.
In a cross section through the thickness of the workpiece, during deformation the curved fold region may be S-shaped. That is, in a cross section through the thickness of the workpiece, a first portion of the curved fold region (for example, a portion adjacent the basal region) may have a first curvature, and a second portion of the curved fold region (for example, a portion adjacent the first/second edge region) may have a second curvature, wherein the second curvature is opposite to the first curvature. There may be a region of zero curvature connecting the first and second curvature portions. The first and second curvatures may not be equal in magnitude. Preferably the magnitude of the first curvature will be greater than the magnitude of the second curvature. Providing this reverse curvature can lower the effective apex of the curved fold region to below the plane of the basal region, thus reducing or preventing the material from attempting to lift or further deform in already worked areas. Where the curved fold region is S-shaped, the sidewall portion(s) may also be S-shaped.
After working, the sidewall portion(s) and the curved fold region may together define a continuous wall or flange, upstanding from the basal region (or downwardly-depending, based on the orientation of the workpiece). The continuous wall or flange may comprise a shrink flange, a stretch flange, or a composite shrink-stretch flange (sometimes referred to as an ‘S’ flange).
It may be advantageous to provide an additional tool set to hold the edge of the workpiece at the curved fold region during deformation of the curved fold region. For example, a clamping arrangement could be provided to hold the edge of the workpiece to provide an additional load on the curved fold region. This may result in an altered stress state of the material with the potential to further improving formability of the sheet metal.
The method may further comprise iteratively repeating steps of:
By iteratively repeating the above steps, it may be possible to provide for formed sheet metal structure having greater deformation from its original form with reduced material wastage in comparison to e.g. deep drawing processes, and at the same time as reducing and/or preventing occurrence of unwanted sheet deformation (e.g. wrinkling or tearing). For example, in a single iteration of the above process it may be possible to provide a formed sheet metal structure having a flange bent at an angle of e.g. up to 30° or up to 40° from the plane of the basal region. By performing 2 further iterations of the above process steps (each iteration providing a further incremental deformation of up to e.g. 30°), it may therefore be possible to provide a formed sheet metal structure having a flange bent at an angle of up to e.g. 90° from the basal region plane. Where multiple iterations are used, the incremental deformation on each iteration may not be identical. For example, it is theorised that e.g. a first iteration could provide a greater angle deformation, with subsequent iterations providing smaller angle deformations.
The above process steps may be repeated 1, 2, 3, or 4 or more times. The further anvil tool and further forming tool(s) may be selected to be different in each iteration of the process, to accommodate for the increasing extent of deformation. They may be selected as appropriate to achieve the desired shape change in the sheet metal workpieces at each iteration—in this way, the same considerations apply to the further anvil tools and further forming tool(s) as apply to the first anvil tool and first forming tool discussed above. Alternatively, it is envisaged that in some embodiments, it may be possible to use anvil tools and forming tools which are the same for the first iteration as for further iterations. The precise number of iterations is not particularly limited, although may depend in part on e.g. the magnitude of deformation in each prior iteration, and the material selection. One or more intermediate material heat treatments may be applied between iterations, which may improve mechanical properties of the workpiece. For example, an annealing step may be performed between subsequent iterations of the formed process. This may be advantageous to reduce and/or eliminate work-hardening of the material, and thus increase the sheet's formability.
In a second preferred aspect, the present invention provides a workpiece obtained or obtainable using the method according to the first aspect. Workpieces obtainable using the method according to the first aspect may generally have reduced variation in material thickness across the workpiece compared to those produced by e.g. deep drawing methods—i.e. greater sheet uniformity. This is achieved by deforming the material primarily in a shear deformation mode, as opposed to in tension which can cause thinning and/or material failure for the same degree of deformation.
In a third preferred aspect, the present invention provides sheet metal working apparatus suitable for performing a method for manufacturing a formed sheet metal structure according to the first aspect, the sheet metal working apparatus comprising a first anvil tool and a first forming tool, and wherein the first anvil tool and first forming tool are configured to be moveable so as to maintain (i) a fixed distance between the forming tool and the anvil tool, or (ii) a fixed force on a sheet metal workpiece disposed between the forming tool and the anvil tool.
The anvil tool and/or the forming tool may comprise a rounded tool surface. The rounded tool surface of the anvil tool may be complementary to that of the forming tool. For example, the curvature of the rounded tool surface of the anvil tool may be opposite to the curvature of the rounded tool surface of the forming tool. Preferably the rounded tool surface has a curvature equal to the desired curvature of a portion of the curved fold region of the sheet metal workpiece after deformation.
The forming tool may comprise a frame, and the rounded tool surface of the forming tool may be located on a cross-bar portion of the frame. The rounded tool surface may have a radius of curvature equal to the desired radius of curvature of the second surface of the sheet metal workpiece at the curved fold region after deformation. The forming tool may comprise one or more constraining arms (e.g. a pair of arms) which, during use, engage with the second surface of the sheet metal workpiece to help prevent undesirable horizontal deformation of the curved fold region. Where the forming tool comprises one or more such arms, preferably, the rounded tool surface is located adjacent to a constraining arm, or intermediate two such arms (for example, on a cross-bar portion connecting said arms), such that constraint is provided adjacent to the rounded tool surface. The forming tool may therefore comprise an approximately ‘V’- or ‘U’-shaped frame portion. Where the forming tool comprises a pair of constraining arms, the arms may disposed at an angle to one another. For example, the arms may be disposed at an angle of from 60° to 150° to one another, more preferably from 70° to 140°, more preferably from 80° to 130°, and most preferably at an angle of from 90° to 120°.
Selecting such an angle may help to avoid wrinkling and/or tearing of the sheet metal workpiece during deformation.
However, the precise shape of the forming tool is not particularly limited, and indeed, any shape suitable for surrounding at least a part of the curved fold region may be suitable. In some embodiments, the forming tool may be a multi-part tool. It may comprise two or more parts. For example, the forming tool may comprise two ‘L’-shaped portions which form a ‘V’- or ‘U’-shaped frame portion when brought together. In such embodiments, the respective parts of the forming tool may be used separately during selected stages of deformation of the workpiece, and may be brought together during other selected stages of deformation of the workpiece. Such embodiments may be particularly useful for formation of large-radius flanges, as discussed below in relation to
Preferably the anvil tool and/or the forming tool has one or more angled ‘lead-in’ faces for guiding the workpiece between the forming tool and anvil tool. Providing an angled ‘lead-in’ face on the forming tool may help to prevent tearing of the sheet metal workpiece. Providing an angled ‘lead-in’ face on the anvil tool may help to prevent buckling of the sheet metal workpiece. The angled ‘lead-in’ face may be formed immediately adjacent a metal-contacting surface of the anvil tool or the forming tool which contacts and constrains a surface of the sheet metal workpiece. Such metal-contacting surface may be a rounded tool surface, where present. The angled ‘lead-in’ face may be formed at an angle of 10° to about 80°, more preferably 20° to 70° more preferably 30° to 60° more preferably 40° to 50°, and most preferably about 45° with respect to the plane in which the metal-contacting surface of the anvil tool or the forming tool lies. However, the angle of the lead-in face may be selected as appropriate for the particular forming process in which the anvil and/or forming tools are to be used. In many forming processes, the sheet metal workpiece may approach the metal contacting surface of the anvil tool and/or the forming tool at an angle; in such cases, the angled ‘lead-in’ face of the anvil tool and/or forming tool may be formed to be approximately 5° either side of the approach angle of the sheet metal workpiece. For example where the metal contacting surface of the anvil tool and forming tool lie in a horizontal plane, and the approach angle of the sheet metal workpiece is 18° above the horizontal plane, the lead-in face of the forming tool (upper die) may be formed to be 23° above the horizontal plane, and the lead-in face of the anvil tool (lower die) may be formed to be 13° above the horizontal plane. Providing such a lead-in face may help to prevent buckling or tearing of the workpiece during a step of progressively sliding the forming tool and/or the anvil tool against the curved fold region to deform the curved fold region. The forming tool and/or the anvil tool may additionally have one or more chamfered edges to reduce risk of tearing of the workpiece during deformation.
The anvil tool may comprise a solid lower die. Alternatively, the anvil tool may comprise a frame. The precise shape of the anvil tool is not particularly limited, and will be selected as appropriate given the desired shape of the formed sheet metal workpiece. However preferably, the anvil tool has a similar shape to the forming tool. Accordingly, the anvil tool may comprise a frame, and the rounded tool surface of the anvil tool may be located on a cross-bar portion of the frame. The anvil tool may comprise one or more constraining arms (e.g. a pair of arms) which, during use, engage with the first surface of the sheet metal workpiece to help prevent undesirable horizontal deformation of the curved fold region. Where the anvil tool comprises one or more such arms, preferably, the rounded tool surface is located adjacent to a constraining arm, or intermediate two such arms (for example, on a cross-bar portion connecting said arms), such that constraint is provided adjacent to the rounded tool surface. The anvil tool may therefore comprise an approximately ‘V’- or ‘U’-shaped frame portion. Where the anvil tool comprises a pair of constraining arms, the arms may disposed at an angle to one another. For example, the arms may be disposed at an angle of from 60° to 150° to one another, more preferably from 70° to 140°, more preferably from 80° to 130°, and most preferably at an angle of from 90° to 120°.
As discussed above in relation to the forming tool, the anvil tool may be a multi-part tool. It may comprise two or more parts. For example, the anvil tool may comprise two ‘L’-shaped portions which form a ‘V’- or ‘U’-shaped frame portion when brought together. In such embodiments, the respective parts of the anvil tool may be used separately during selected stages of deformation of the workpiece, and may be brought together during other selected stages of deformation of the workpiece. Where the anvil tool comprises a solid lower die, a workpiece-engaging surface of the die may be selected to have a shape which matches the desired shape of the workpiece after forming.
The anvil tool may remain stationary during deformation of the curved fold region. Alternatively, and more preferably, the anvil tool may be progressively slid beneath the curved fold region at the same time as the forming tool is progressively slid above the curved fold region to assist in formation of the final desired shape of the workpiece. For example, the anvil tool may move in a fixed position relative to the forming tool. Alternatively, the anvil tool may be moved in such a way as to provide a controlled force on the workpiece in the direction of travel and/or perpendicular to the direction of travel of the anvil tool.
The sheet metal working apparatus may be configured to allow for each region of folding and shearing to be separately actuated. This can provide for greater flexibility in assessment of effectiveness of different tool features for manufacture of a specific component part.
Preferably, the sheet metal working apparatus is retrofittable to existing press-lines. For example, the bending stage could be performed by existing tools presently used in part of deep-drawing processes.
Preferably, the first anvil tool and the first forming tool are interchangeable for further anvil tools and further forming tools respectively.
In a fourth preferred aspect, the present invention provides a kit comprising the sheet metal working apparatus of the third aspect and one or more further anvil tools and one or more further forming tools.
Features indicated above as preferred and/or optional are combinable singly or in any combination with any aspect of the invention, unless the context demands otherwise.
Embodiments of the invention will now be described by way of example with reference to the accompanying drawings in which:
a-f) show consecutive process steps in a first stage of a method of manufacturing a formed sheet metal structure having a shrink flange;
a-f) show consecutive process steps in a second stage of a method of manufacturing a formed sheet metal structure having a shrink flange;
a-f) show consecutive process steps in a third stage of a method of manufacturing a formed sheet metal structure having a shrink flange;
a-e) show consecutive process steps in a method of manufacturing a formed sheet metal structure having a large radius shrink flange.
a-e) show consecutive process steps in a method of manufacturing a formed sheet metal structure having a composite shrink-stretch flange.
a-c) show a plan view of one step of the process shown in
a-d) show consecutive process steps in a first stage of a method of manufacturing a formed sheet metal structure having a stretch flange;
a-d) show consecutive process steps in a second stage of a method of manufacturing a formed sheet metal structure having a stretch flange;
a-d) show consecutive process steps in a third stage of a method of manufacturing a formed sheet metal structure having a stretch flange;
The process described herein can be understood as “Folding-Shearing”. The process may be used for the deformation of sheet metal blanks into the shell shapes currently made by deep-drawing (such as cans, boxes or car body parts) with a reduced need for trimming after shaping. As will be described in more detail below, with reference to
The process will now be described with reference to
In a first stage of the forming process, shown in
The flat sheet metal workpiece 1 is located in a sheet metal working apparatus (only part shown). The sheet metal working apparatus comprises a first anvil tool 15 having a rounded tool surface (not shown), and a first forming tool 17 having a rounded tool surface 19. The sheet metal working apparatus further comprises a plurality of bending tools: here, two sets of rollers 21a, b. Each set of rollers includes at least two rollers, with at least one roller 23 disposed on either side of the sheet metal workpiece. The rollers 23 are configured to be moveable relative to the workpiece to allow for application of a bending moment to the workpiece.
As the first and second sidewall portions are created, an intermediate curved fold region 31 forms between the first and second sidewall portions. Here, the curved fold region has a generally convex curvature, as a shrink flange is being formed. The curved fold region is initially approximately cone-shaped with an apex at an intersection 30 of the first and second sidewall portions and the basal region.
During or soon after the initial bending step, the forming tool 17 is brought into contact with the second (upper) surface of the sheet metal workpiece at the curved fold region 31, and the anvil tool 15 is brought into contact with the first (lower) surface of the sheet metal workpiece at the curved fold region 31. Specifically, the rounded tool surface 19 of the forming tool contacts the curved fold region. The first anvil tool also has a rounded tool surface (not shown) which contacts the curved fold region. The forming tool is here conveniently formed as an approximately ‘V’-shaped member or frame, the rounded tool surface 19 being located in a cross-bar of the tool, intermediate first and second constraining arms 33a, b which, during use, engage with the second surface 5 of the sheet metal workpiece 1 to help prevent undesirable deformation of the curved fold region and/or the sidewall portions. The first anvil tool 15 also has a rounded tool surface, although this is not visible.
Here, the anvil tool 15, like the forming tool 17, is also moveable relative to the sheet metal workpiece 1 and is also progressively slid beneath the curved fold region 113 at the same time as the forming tool is slid over the curved fold region 113. The forming tool and anvil tool are moved simultaneously so as to maintain a fixed distance between the tools. This can assist in formation of the final desired shape of the workpiece.
Additionally, the rollers 23 are also progressively moved to constrain the first and second surfaces 3, 5 of the first and second sidewall portions 25, 27 adjacent the rounded tool surface 19 of the forming tool 17, as the forming tool progressively slides over the curved fold region 31. Providing this additional surface constraint of the sidewall portions can help to achieve the desired deformation of the curved fold region by preventing unwanted deformation of the curved fold region and/or sidewall portions.
During the progressive sliding of the forming tool over the curved fold region, the first and second sidewall portions 25, 27 are approximately ‘S’-shaped in a cross section taken through the thickness of the workpiece, from the basal region 29 to the respective edge region 9, 11 of the sidewall portion 25, 27. That is, a first portion of the sidewall portion adjacent the basal region has a first curvature, and a second portion of the sidewall portion adjacent the edge region has a second curvature, wherein the second curvature is opposite to the first curvature. Providing this “reverse curvature” of the sidewall portions can assist formation of the final desired shape of the workpiece.
During the further deformation of the curved fold region which occurs during sliding of the anvil tool and forming tool across the curved fold region, portions of the original curved fold region adjacent the sidewall portions of the sheet metal workpiece are flattened such that they lie in the same plane as the sidewall portions (see
The formed sheet metal structure 100 at the end of this first stage of working (as shown in
The above process as described in relation to
In the second stage of the forming process, shown in
The first anvil tool and first forming tool used in the first stage of the forming process (
As described above, the sheet metal working apparatus comprises a plurality of bending tools: here, two sets of rollers 21a, b are shown, each set of rollers including a roller 23 disposed on either side of the sheet metal workpiece 100.
During or soon after the bending step, the forming tool 117 is brought into contact with the second (upper) surface 5 of the sheet metal workpiece 100 at the curved fold region 131, and the anvil tool 115 is brought into contact with the first (lower) surface of the sheet metal workpiece at the curved fold region 131. Specifically, the rounded tool surface 119 of the forming tool contacts the curved fold region.
As described above in relation to the first stage, the further anvil tool 115, like the forming tool 117, is also moveable relative to the sheet metal workpiece 100 and is also progressively slid beneath the curved fold region 131 at the same time as the forming tool is slid over the curved fold region. Furthermore, as also described above in relation to the first stage, the rollers 23 are also progressively moved to constrain the first and second surfaces 3, 5 of the first and second sidewall portions 125, 127 adjacent the rounded tool surface 119 of the forming tool 117, as the forming tool progressively slides over the curved fold region 131.
The formed sheet metal structure at the end of the second stage of working (as shown in
In the third stage of the forming process, shown in
The further anvil tool and further forming tool used in the second stage of the forming process (
During or soon after the bending step, the forming tool 217 is brought into contact with the second (upper) surface 5 of the sheet metal workpiece 200 at the curved fold region 231 and the anvil tool 215 is brought into contact with the first (lower) surface of the sheet metal workpiece at the curved fold region 231. Specifically, the rounded tool surface 219 of the forming tool contacts the curved fold region.
As described above in relation to the first and second stages, the further anvil tool 215, like the forming tool 217, is also moveable relative to the sheet metal workpiece 200 and is also progressively slid beneath the curved fold region 231 at the same time as the forming tool is slid over the curved fold region. Furthermore, as also described above in relation to the first stage, the rollers 23 are also progressively moved to constrain the first and second surfaces 3, 5 of the first and second sidewall portions 225, 227 adjacent the rounded tool surface 219 of the forming tool 217, as the forming tool progressively slides over the curved fold region 231.
The formed sheet metal structure at the end of the third and final stage of working (as shown in
a-e) show consecutive process steps in a method of manufacturing a formed sheet metal structure having a large radius shrink flange. The initial bending step performed on a flat sheet metal workpiece is not shown. The metal workpiece has first and second surfaces opposed to each other—here, the first and second surfaces are lower (not visible) and upper faces of the sheet respectively. The sheet has a peripheral edge 307, the edge here comprising two straight edge regions 309, 311, and a rounded edge region 313 between the two straight edge regions (although we note that that the precise shape of these edge regions is non-essential, and may be selected as appropriate for the particular component part. First and second sidewall portions 325, 327 extend between the first and second edge regions 309, 311 and a planar basal region 329 of the workpiece, and an intermediate curved fold region 331 is defined between them. The curved fold region here has a generally convex curvature, as a (large radius) shrink flange is being formed. The curved fold region is initially approximately cone-shaped with an apex at an intersection of the first and second sidewall portions and the basal region.
In this process, a two-part forming tool 317a, b and a two-part anvil tool 315a, b are used instead of one-piece tools such as those shown and described above in relation to
The anvil tool 315 and forming tool 317 are moved towards one other until they contact the first and second sides of the sheet metal workpieces respectively in a position as shown in
The formed sheet metal structure at the end of this stage of working (not shown) comprises a continuous wall or shrink flange defined by the first and second sidewall portions 325, 327 and the curved fold region 331, and upstanding from the basal region 329. Here, the flange lies in a plane offset by about 30° from the plane of the basal region.
a-e) show consecutive process steps in a method of manufacturing a formed sheet metal structure having a composite shrink-stretch flange. The initial bending step performed on a flat sheet metal workpiece is not shown. The metal workpiece has first and second surfaces opposed to each other—here, the first and second surfaces are lower (not visible) and upper faces of the sheet respectively. The sheet has a peripheral edge 407, the edge here comprising at least one straight edge region 409. A first sidewall portion 425 extends between the edge region 409 and a planar basal region 429 of the workpiece. A curved fold region 431 is defined adjacent to the sidewall portion 425. The curved fold region initially has a generally convex curvature.
The anvil tool 415 and forming tool 417 are moved towards one other until they contact the first and second sides of the sheet metal workpieces respectively in a position as shown in
The formed sheet metal structure at the end of this stage of working comprises a continuous wall or shrink flange defined by the first sidewall portions 425 and the curved fold region 431, and upstanding from the basal region 429. Here, the flange lies in a plane offset by about 30° from the plane of the basal region.
a-c) show a plan view of one step of the process of forming a sheet metal workpiece shown in
As best seen in
Stretch flanges also exist in isolation, as internal corners (such as the wheel-arch shape of a car-body front wing). This could be created by a similar gathering of material being moved inwards towards the stretch flange as described above in relation to the method for forming a composite shrink-stretch flange.
In a first stage of the forming process, shown in
The flat sheet metal workpiece 501 is located in a sheet metal working apparatus (only part shown). The sheet metal working apparatus comprises a plurality of bending tools: here, two sets of gripping members 521a, b, each arranged for gripping a portion of the sheet metal workpiece. The gripping members 521a, b are configured to be moveable relative to the workpiece to allow for application of a bending moment to the workpiece.
The sheet metal working apparatus comprises a first anvil tool 515 and a first forming tool 517. Each of the first anvil tool and first forming tools comprises a metal contacting tool surface which lies in an approximately horizontal plane for contact with and constraint of the sheet metal workpiece at the first and second surfaces respectively. Each of the first anvil tool and first forming tool further comprises an angled lead-in face for guiding of the sheet metal workpiece between the anvil tool and the forming tool. Here, the forming tool and anvil tool are conveniently formed as an approximately ‘V’-shaped members having first and second constraining arms 533a, b; 534a, b which, during use, engage with respective surfaces of the sheet metal workpiece to help prevent undesirable deformation of the curved fold region and/or the sidewall portions. The angle between the constraining arms of each of the forming tool and the anvil tool is about 119°.
During or soon after the initial bending step, the forming tool 517 is brought into contact with the second (upper) surface of the sheet metal workpiece at the curved fold region 531, and the anvil tool 515 is brought into contact with the first (lower) surface of the sheet metal workpiece at the curved fold region 531.
The anvil tool 515 and forming tool 517 are then progressively slid along a portion of the curved fold region 531 in a direction away from the basal region such that the curved fold region and adjacent sidewall portions 525, 527 are partially flattened so as to lie in the same plane as the basal region of the sheet metal workpiece (see
The formed sheet metal structure 600 at the end of this first stage of working (as shown in
The above process as described in relation to
In the second stage of the forming process, shown in
The anvil tool 615 and forming tool 617 are then progressively slid along a portion of the curved fold region 631 in a direction away from the basal region such that the curved fold region and adjacent sidewall portions 625, 627 are partially flattened so as to lie in the same plane as the basal region of the sheet metal workpiece (see
The formed sheet metal structure 700 at the end of this second stage of working (as shown in
In the third stage of the forming process, shown in
The second further anvil tool 715 and second further forming tool 717 are then progressively slid along a portion of the curved fold region 731 in a direction away from the basal region such that the curved fold region and adjacent sidewall portions 725, 727 are partially flattened so as to lie in the same plane as the basal region of the sheet metal workpiece (see
The formed sheet metal structure 800 at the end of this third stage of working comprises a continuous wall or stretch flange defined by the non-flattened portions of the first and second sidewall portions 725, 727 and the curved fold region 731, upstanding from basal region 729. Here, the flange lies in a plane offset by about 87° from the plane of the basal region, as measured between the basal region and the curved fold region of the flange.
The process described above is capable of producing flanges which lie in a plane offset by 90° from the basal region, i.e. flange formed at approximately at right angles to the basal region.
The features disclosed in the foregoing description, or in the following claims, or in the accompanying drawings, expressed in their specific forms or in terms of a means for performing the disclosed function, or a method or process for obtaining the disclosed results, as appropriate, may, separately, or in any combination of such features, be utilised for realising the invention in diverse forms thereof.
While the invention has been described in conjunction with the exemplary embodiments described above, many equivalent modifications and variations will be apparent to those skilled in the art when given this disclosure. Accordingly, the exemplary embodiments of the invention set forth above are considered to be illustrative and not limiting. Various changes to the described embodiments may be made without departing from the spirit and scope of the invention.
For the avoidance of any doubt, any theoretical explanations provided herein are provided for the purposes of improving the understanding of a reader. The inventors do not wish to be bound by any of these theoretical explanations.
Any section headings used herein are for organizational purposes only and are not to be construed as limiting the subject matter described.
Throughout this specification, including the claims which follow, unless the context requires otherwise, the word “comprise” and “include”, and variations such as “comprises”, “comprising”, and “including” will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps.
It must be noted that, as used in the specification and the appended claims, the singular forms “a,” “an,” and “the” include plural referents unless the context clearly dictates otherwise. Ranges may be expressed herein as from “about” one particular value, and/or to “about” another particular value. When such a range is expressed, another embodiment includes from the one particular value and/or to the other particular value. Similarly, when values are expressed as approximations, by the use of the antecedent “about,” it will be understood that the particular value forms another embodiment. The term “about” in relation to a numerical value is optional and means for example +/−10%.
One or more publications are cited above in order to more fully describe and disclose the invention and the state of the art to which the invention pertains. Full citations for these references are provided below. The entirety of each of these references is incorporated herein.
Number | Date | Country | Kind |
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1814069 | Aug 2018 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/073107 | 8/29/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/043832 | 3/5/2020 | WO | A |
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6715329 | Hametner | Apr 2004 | B1 |
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20160158821 | Fujii | Jun 2016 | A1 |
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105392575 | Mar 2016 | CN |
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Horton, P.M. and Allwood, J.M. (2017): “Yield improvement opportunities for manufacturing automotive sheet metal components”, Journal of Materials Processing Technology, 249 78-88. |
International Search Report and Written Opinion, International Application No. PCT/EP2019/073107, dated Oct. 29, 2019, 15 pages. |
UKIPO Search Report, GB Application No. 1814069.9, dated Jan. 31, 2019, 4 pages. |
Chinese Office Action, Chinese Application No. 201980071436.0, CNIPA, dated Sep. 30, 2022, 25 pages. (with English Translation). |
Second Chinese Office Action, Chinese Application No. 201980071436.0, CNIPA, dated Feb. 11, 2023, 9 pages. (with English Translation). |
Number | Date | Country | |
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20210323041 A1 | Oct 2021 | US |