1. Field of the invention
The present invention relates to spin forming process and to apparatus for manufacturing articles by spin forming. The invention has particular, but not necessarily exclusive, application to metal spinning.
2. Related art
Metal spinning refers to a group of forming processes that allow production of hollow, axially symmetric (axisymmetric) sheet metal components. The basic technique of spinning, which is common to this group of processes, consists of clamping a sheet metal blank against a mandrel on a spinning lathe, and gradually forming the blank onto the mandrel surface by a roller, either in a single step or series of steps.
A detailed review of academic literature related to spin forming has been carried out and disclosed by Music et at (2010) [O. Music, J. M. Allwood, K. Kawai “A review of the mechanics of metal spinning” Journal of Materials Processing Technology 210 (2010) 3-23], the entire content of which is hereby incorporated by reference.
It is of interest here to draw a distinction between the terms conventional spinning, shear spinning and tube spinning, all of which are considered to be spin forming processes. A common feature of the three processes is that they typically allow production of hollow, rotationally symmetric parts. The main difference between the three is apparent in the wall thickness of the formed part. In conventional spinning, the wall thickness remains nearly constant throughout the process, so the final wall thickness of the formed part is substantially equal to the thickness of the blank. In contrast, the wall thickness is reduced in shear spinning and tube spinning; in shear spinning, part thickness is dictated by the angle between the wall of the component and the axis of rotation; in tube spinning, the final thickness is defined by the increase in length of the workpiece. Furthermore, while in conventional spinning and tube spinning parts can be formed in a single step or a number of steps, in shear spinning, forming is done in a single step.
A conventional spinning process is illustrated in
A shear spinning process is illustrated in
As α is decreased, the required reduction in wall thickness to achieve the required value for α becomes very significant, leading to failure of the workpiece where the required value for α is too low.
Some workers have recognised that metal spinning is limited to the production of axisymmetric geometries. Therefore some work has been done to try to modify metal spinning processes in order to produce non-axisymmetric geometries.
For example. US 2005/0183484 discloses the use of a control system in order to control the pressing force of a roller tool against a workpiece where the mandrel has a non-axisymmetric geometry. During the process, the workpiece conforms to the outer shape of the mandrel. A similar process is set out in US 2008/0022741.
The inventors have recognised that although US 2005/0183484 and US 2008/0022741 may provide processes for the manufacture of articles with non-axisymmetric geometries, they suffer from the disadvantage that the specific required non-axisymmetric geometry must first be provided in the form of a shaped mandrel, before the metal spinning process is carried out. Although this may be acceptable where the mandrel will be used many times to produce many identically shaped articles, this process is inflexible in that even minor changes to the required geometry necessitates the manufacture of a new mandrel.
The present inventors recognise that a similar problem exists in relation to the manufacture of articles having axisymmetric geometries.
The present invention therefore seeks to address one or more of the above problems, and preferably ameliorates or even overcomes one or more of these problems.
In a general aspect in relation to spin forming, the present invention replaces a conventional mandrel with at least two supports for bearing against a surface of the workpiece, the workpiece being rotatable with respect to the two supports.
In a first preferred aspect, the present invention provides a spin forming process for manufacturing an article of a required shape from a workpiece, the workpiece having, with reference to the required shape of the article, an outer surface and an inner surface, wherein the workpiece is rotated with respect to a forming tool which bears against one of the outer and inner surfaces of the workpiece to deform the workpiece towards the required shape and a first support bears against one of the inner and outer surfaces of the workpiece, and a second support bears against one of the inner and outer surfaces of the workpiece, the workpiece rotating with respect to the supports.
In a second preferred aspect, the present invention provides an apparatus for manufacturing an article of a required shape from a workpiece by spin forming, the workpiece having, with reference to the required shape of the article, an outer surface and an inner surface, the apparatus having:
Preferred and/or optional features of the invention will now be set out. These are applicable singly or in any combination with any aspect of the invention, unless the context demands otherwise.
It is preferred that the workpiece is formed of metal. Any suitable workable metal may be used, e.g. steel, brass, aluminium (and/or its alloys), titanium (and/or its alloys), etc. However, it is possible to carry out spin forming using other workable starting materials, e.g. plastics materials such as PVC.
The workpiece is typically in sheet form. Thus, the inner and outer surfaces of the initial workpiece are designated by the orientation of the workpiece in the apparatus and by the required shape of the article to be formed.
The workpiece may have a uniform initial thickness. However, this is not necessarily essential, since spin forming processes can be carried out using workpieces of non-uniform initial thickness.
It is preferred, for at least some embodiments of the invention, that the spin forming process does not substantially change the thickness of the workpiece. Thus, with reference to the nomenclature introduced above, it is preferred that the spin forming process is a type of conventional spinning, rather than shear spinning.
It is possible to consider the angle between the inner surface of the workpiece and the rotational axis of the workpiece during the spin forming process. More generally (where this angle varies with position in the workpiece), it is possible to define an angle α as the angle between the rotational axis A of the workpiece and the tangent to the inner surface of the workpiece at a particular position, the tangent being drawn in a plane containing the rotational axis A of the workpiece. Where, at that particular position, the initial thickness of the workpiece is t0 and the final thickness of the workpiece is t1, it is preferred that the following inequality (1) is satisfied, for values of α less than 90°:
t
1
>t
0 sin α inequality (1)
Where inequality (1) is satisfied, the thickness of the workpiece after spin forming is greater than would be expected if the spin forming process was a shear spinning process.
At least at some positions on the article formed by spin forming, the angle α may be equal to or less than 45°, more preferably equal to or less than 40°, equal to or less than 35°, equal to or less than 30°, equal to or less than 25°, equal to or less than 20°, equal to or less than 15°, equal to or less than 10°, equal to or less than 5°, equal to or less than 0°, equal to or less than −10°, or equal to or less than −20°. Preferably, any one of these (imitations on the value of a may be satisfied for an area of the internal surface of the article corresponding to at least 5% of the total internal surface area of the article. More preferably, any one of these limitations on the value of a may be satisfied for an area of the internal surface of the article corresponding to at least 10%, at least 20%, at least 30% or at least 40% of the total internal surface area of the article.
The required shape of the article may be an axisymmetric shape. However, in some preferred embodiments, the required shape of the article may be a non-axisymmetric shape.
For example, considering the cross-sectional shape of the article, where the cross section is taken perpendicular to the rotational axis, the cross-sectional shape is typically non-circular. The shape may, for example, be elliptical, oval, regular curved shape, irregular curved shape, triangular, rectangular, regular polygonal, irregular polygonal, or any combination of these shapes (e.g. a generally curved shape including at least one straight wall portion, or a generally polygonal shape including at least one curved wall portion). in some embodiments, the cross-sectional shape (taken perpendicular to the rotational axis) includes a re-entrant portion. The angle α may vary around the perimeter of the cross sectional shape, e.g. by 5% or more.
Considering the cross sectional shape of the article where the cross section is taken along (or parallel) to the rotational axis, the shape can be considered in terms of the variation in the angle α with distance along the rotational axis. This variation may include at least a portion (e.g. at least 5% of the height of the article along the rotational axis) of linear variation of α with distance D along the rotational axis. Additionally or alternatively, this variation may include at least a portion (e.g. at least 5% of the height of the article along the rotational axis) where the first derivative dα/dD is positive or negative.
Additionally or alternatively, this variation may include at least a portion (e.g. at least 5% of the height of the article along the rotational axis) where the second derivative d2α/dD2 is positive or negative.
Preferably, the second support bears against the opposite (inner or outer) side of the workpiece compared with the forming tool. Thus, if the forming tool bears against the outer surface, preferably the second support bears against the inner surface and vice versa.
Similarly, in some embodiments, it is preferred that the first support bears against the opposite (inner or outer) surface of the workpiece compared with the forming tool. However, it is not considered essential in all embodiments that the first and second supports bear against the same surface of the workpiece.
During spin forming, and/or in terms of the finished article, it is possible to define a proximal end and a distal end of the workpiece and/or of the finished article. The proximal end is closer than the distal end to a mounting region of the workpiece at which region the workpiece is rotatably mounted in the apparatus (e.g. by clamping), when considered along the rotation axis of the workpiece. Preferably, the first support is disposed proximally of the second support.
Preferably, there is provided a third support for bearing against the inner or outer surface of the workpiece. As with the first and second supports, the workpiece preferably rotates with respect to the first and second supports. Preferably, the third support is located distally of the first support. The third support is preferably located laterally of the second support.
Preferably, the second and third supports are laterally offset from the first support. More preferably, the second and third supports are laterally offset in opposite directions from the first support. This lateral offset from the first support may be substantially equal for the second and third supports. Preferably, the distance between the second and third supports is less than the distance between the first and second supports. Preferably, the distance between the second and third supports is less than the distance between the first and third supports. Preferably, the distance between the first and second supports is substantially equal to the distance between the first and third supports.
Thus, in some preferred embodiments, the first, second and third supports are disposed in a triangular configuration.
Depending on the required shape for the article, the second and/or third supports may be radially offset from the first support.
The present inventors have found, based on a careful analysis of known spin forming processes, that the mandrel used in known spin forming processes only makes contact with the workpiece at three main locations. These locations vary depending on the relative position of the forming tool on the workpiece, and depending on the rotation of the workpiece. Thus, the role of the mandrel can be taken by the supports used in the present invention. Furthermore, as explained below, it is possible to simulate the use of mandrels of different shapes, by appropriate control of the position of the internal supports. Thus, in general, it is preferred that the first, second and third supports are provided at least at the points of closest contact between the workpiece and a notional mandrel which would be required to form the article to the required shape from the workpiece using the forming toot.
The forming tool is preferably located in order to provide the required shape for the article. The forming tool may be located distally of the second and/or third support (e.g. where the angle α is less than 90°. However, in some embodiments, the angle α may (at least locally) be more than 90°, in which case the forming tool may be located proximally for the second and/or third support. The forming tool is typically radially offset from the second and/or third supports. The forming tool may be located substantially aligned with the first support. The second and/or third supports may be laterally offset from the forming tool.
Preferably, the forming tool includes at least one forming roller. Typically, the forming roller is rotatable with respect to a forming roller arm. The use of a forming roller reduces frictional losses between the forming tool and the rotating workpiece. Preferably, the forming tool is positionable with respect to the rotating workpiece under machine control. Typically, this machine control is computer numerical control (CNC). Using such an approach allows the position of the forming tool to be very precisely controlled at high speeds, so that the forming tool can follow a required path around the workpiece at speeds corresponding to the rotational speed of the workpiece. Preferably, the position of the forming tool is controllable in the proximal-distal direction (parallel to the rotational axis of the workpiece), and/or in the radial direction, and/or in the lateral direction (perpendicular to the radial direction and to the proximal-distal direction).
Preferably, the first support includes at least one first support roller. Typically, the first support roller is rotatable with respect to a first support roller arm. The use of a first support roller reduces frictional losses between the first support and the rotating workpiece. Preferably, the first support is positionable with respect to the rotating workpiece under machine control. Typically, this machine control is computer numerical control (CNC). Using such an approach allows the position of the first support to be very precisely controlled at high speeds, so that the first support can follow a required path around the workpiece at speeds corresponding to the rotational speed of the workpiece. Preferably, the position of the first support is controllable in the proximal-distal direction (parallel to the rotational axis of the workpiece), and/or in the radial direction, and/or in the lateral direction (perpendicular to the radial direction and to the proximal-distal direction).
Preferably, the second support includes at least one second support roller. Typically, the second support roller is rotatable with respect to a second support roller arm. The use of a second support roller reduces frictional losses between the second support and the rotating workpiece. Preferably, the second support is positionable with respect to the rotating workpiece under machine control. Typically, this machine control is computer numerical control (CNC). Using such an approach allows the position of the second support to be very precisely controlled at high speeds, so that the second support can follow a required path around the workpiece at speeds corresponding to the rotational speed of the workpiece. Preferably, the position of the second support is controllable in the proximal-distal direction (parallel to the rotational axis of the workpiece), and/or in the radial direction, and/or in the lateral direction (perpendicular to the radial direction and to the proximal-distal direction).
Preferably, the third support includes at least one third support roller. Typically, the third support roller is rotatable with respect to a third support roller arm. The use of a third support roller reduces frictional losses between the third support and the rotating workpiece. Preferably, the third support is positionable with respect to the rotating workpiece under machine control. Typically, this machine control is computer numerical control (CNC). Using such an approach allows the position of the third support to be very precisely controlled at high speeds, so that the third support can follow a required path around the workpiece at speeds corresponding to the rotational speed of the workpiece.
Preferably, the position of the third support is controllable in the proximal-distal direction (parallel to the rotational axis of the workpiece), and/or in the radial direction, and/or in the lateral direction (perpendicular to the radial direction and to the proximal-distal direction).
Preferably, the first support roller arm extends distally into the workpiece from a proximal structure. Similarly, preferably the second support roller arm extends distally into the workpiece from a proximal structure. Similarly, preferably the third support roller arm extends distally into the workpiece from a proximal structure. The proximal structures of the second and third support roller arm may be connected to each other, but it is preferred that the positions of the second and third supports are independently controllable.
In some embodiments, the process may correspond to a shear spinning process, in which the mandrel known from prior art shear spinning processes is replaced by the supports discussed above. In such a process, the thickness of the workpiece is typically reduced depending on the angle α, as shown in equation (2):
t
1
=t
0 sin α equation (2)
It is possible for the shear spinning process to be carried out using the first, second and (optionally) third supports identified above. However, preferably, the shear spinning process further has a fourth support, the workpiece rotating with respect to the fourth support. Preferably, the fourth support is located substantially in register with the main forming tool. Thus, the fourth support is preferably distally located but axially aligned with the first support . Furthermore, the fourth support is preferably located between the second and third supports.
Suitable control of the fourth support allows the thickness of the workpiece to be varied during the forming process.
The fourth support typically comprises a fourth support roller, in a similar manner as set out with respect to the second and third supports, and is similarly preferably independently controllable.
The apparatus can also be used to carry out a tube forming process, by setting the angle α to be 0°.
In some preferred embodiments, the first and second supports bear against the inner surface of the workpiece. In this respect they can be regarded as first and second internal supports. The forming tool therefore preferably bears against the outer surface of the workpiece. Where the apparatus includes third and/or fourth supports, preferably these also bear against the inner surface of the workpiece. In this way, as discussed above, these preferred embodiments can provide more flexible forming procedures for manufacturing required article shapes.
The present inventors have realised that the present invention is not necessarily limited to the use of internal supports. It is possible instead to apply the forming tool to the inner surface of the workpiece. In that case, it is preferred that the second support bears against the outer surface of the workpiece. In this respect the second support can be regarded as a second external support. The first support may bear against the inner surface of the workpiece, depending on the required configuration. Where the apparatus includes third and/or fourth supports, preferably these also bear against the outer surface of the workpiece. This is of interest in the manufacture of more complex shapes, or in the manufacture of relatively flatter articles from a relatively more concave workpiece, e.g. the manufacture of sheet-like articles from cup-like workpieces.
In order to provide precise control of the shape of the workpiece during the process, some preferred embodiments of the invention utilise at least one sensor adapted to sense the shape of the workpiece during the process. A control system may be provided in order to provide feedback control in order to compare the measured workpiece geometry with the required (or calculated) workpiece geometry. Thus, there is provided a means for comparing a difference between the target workpiece shape and the actual workpiece shape. Where a significant difference is detected, the apparatus is controlled in order to reduce this difference. Suitable control may be control of the position of the forming tool and/or supports, speed of rotation of the workpiece, etc.
The inventors consider that this type of control is not necessarily limited to spin forming processes.
Accordingly, in a further aspect of the invention, there is provided a sheet metal forming process in which a sheet metal workpiece is deformed from an initial configuration towards a final configuration using a sheet metal forming apparatus, wherein the sheet metal forming apparatus includes at least one sensor, the process including sensing the shape of the workpiece using the sensor during the deformation from the initial configuration towards the final configuration, comparing the sensed shape of the workpiece with a required (or calculated) shape of the workpiece, and controlling the apparatus to decrease a difference between the sensed shape of the workpiece with a required (or calculated) shape of the workpiece.
In a further aspect of the invention, there is provided a sheet metal forming apparatus for deforming a sheet metal workpiece from an initial configuration towards a final configuration, the apparatus having:
at least one sensor adapted to sense the shape of the workpiece using the sensor during the deformation from the initial configuration towards the final configuration; and a control system adapted to compare the sensed shape of the workpiece with a required (or calculated) shape of the workpiece, and to control the apparatus to decrease a difference between the sensed shape of the workpiece with a required (or calculated) shape of the workpiece.
Further preferred features of the invention are set out below.
Preferred embodiments of the invention are described below, with reference to the following drawings:
The preferred embodiments of the invention provide a modified spin forming process. In this disclosure, the term “spin forming” is used interchangeably with “metal spinning” although it is acknowledged that the preferred embodiments may work with starting materials other than metal, e.g. ductile plastics materials. However, in the most preferred embodiments of the invention, the starting material is a metallic material, typically sheet metal.
In the preferred embodiments of the present invention, there is provided a flexible spin forming process, in which the role of the mandrel is provided by a suitable arrangement of internal support rollers. This also allows, where desired, for the manufacture of non-axisymmetric components.
With reference to
According to a preferred embodiment of the invention, the mandrel can therefore be replaced using a corresponding arrangement of internal supports, the work piece being allowed to rotate with respect to the internal supports.
An arrangement of internal support rollers bears against the internal surface 42 of the work piece. First internal support roller 44 (also referred to herein as a blending roller) is provided proximal to the tail stock end of the article 33. Second 46 (and third 48—see
The configuration illustrated in
Control of the rotational speed of the work piece, the position of forming roller 36 and the positions of the internal support rollers 44, 46 and 48 is typically provided by computer numerical control (CNC), in a manner which will be understood by the skilled person.
Work piece 94 is rotatably supported by spindle 92. Three identifiable modules interact with work piece 94. These are blending roller module 86, support roller module 88 and forming roller module 90. These are described in more detail with reference to
In
Using appropriate control of the positions of the various rollers in the apparatus of
The present inventors have also realised that embodiments of the present invention can be used to carry out shear spinning and/or tube forming processes.
Thus, in further embodiments of the invention, a shear spinning process is provided, in which a mandrel is replaced by rollers. There are different options for this. In one embodiment, illustrated in
The inventors consider that in the shear spinning embodiments of the present invention, careful control of toolpath is important. The shear spinning toolpath is more ‘aggressive’ than conventional spinning embodiments and consist of mainly straight lines.
It is noted here that an apparatus having four internal support rollers, in the manner indicated in
In a further embodiment, it is possible to use the apparatus with four internal support rollers in order to carry out tube spinning, with wall angle set to α=0°. It is again noted that this configuration exerts high forces on the roller arms, so a relatively stiff machine is typically required.
The present inventors have also realised that the present invention can be used with the forming tool bearing against the inner surface of the workpiece. In an embodiment based on conventional spinning, this is illustrated in
A similar approach can be set out with respect to shear spinning. This is illustrated in
The approach shown in
Thus, forming in both directions can be used to manufacture lightweight components. Carrying out combined spin forming (i.e. based on both conventional and shear spin forming), it is possible to produce components with varying wall thickness in a single component. The thickness can be structurally optimised, allowing the production of structurally optimised, lightweight components.
As an example, it is possible to manufacture a 45 degree cone with varying thickness (along the axis). This is done by first shear-spinning a component with varying wall angle to obtain varying thickness along the wall. Then, ‘reverse’ conventional spinning is carried out (using an internal forming tool and external second and third support rollers) to ‘straighten’ the workpiece back to 45 degrees. Since conventional spinning preserves existing thickness, the combined result of this process would give 45 degree cone with varying thickness.
In order to provide precise control of the shape of the workpiece during the process, preferred embodiments of the invention utilise at least one sensor (not shown) adapted to sense the shape of the workpiece during the process. A control system may be provided in order to provide feedback control in order to compare the measured workpiece geometry with the required (or calculated) workpiece geometry. Thus, there is provided a means for comparing a difference between the target workpiece shape and the actual workpiece shape. Where a significant difference is detected, the apparatus is controlled in order to reduce this difference. Suitable control may be control of the position of the forming tool and/or supports, speed of rotation of the workpiece, etc.
The preferred embodiments of the invention have been described by way of example. On reading this disclosure, modifications to these embodiments, further embodiments and modifications thereof will be apparent to the skilled person and accordingly fall within the scope of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
1016611.4 | Oct 2010 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/GB11/01424 | 9/29/2011 | WO | 00 | 2/27/2013 |