The operator of the machine passes the sheet metal between the anvil wheel and the rolling wheel. This process stretches the material and causes it to become thinner. As the material stretches, it forms a convex surface over the anvil wheel. This surface is known as "crown". A high crown surface is very curved, a low crown surface is slightly curved. The rigidity and strength in the surface of a workpiece is provided by the high crown areas. The radius of the surface after working depends on the degree that the metal in the middle of the work piece stretches relative to the edge of the piece. If the middle stretches too much the operator can recover the shape by wheeling the edge of the piece. Wheeling the edge has the same effect in correcting mis-shape due to over-stretching in the middle as does shrinking directly on the overstretched area by the use of heat shrinking or
Eckold-type shrinking. This is because the edge holds the shape in place. Shrinking the edge prior to wheeling aids the formation of shape during wheeling, and reduces the amount of stretching and thinning needed to reach the final shape. Shrinking processes reduce the surface area by thickening the sheet metal. Shrinking by hand is harder to do and slower than stretching using panel beating tools or wheeling; because of this it should only be used when absolutely necessary. Aluminium sheet should be
annealed before wheeling because rolling at the mill during its production
work hardens it. Strength and rigidity is also provided by the edge treatment such as
flanging or wiring, after the fabrication of the correct surface contour has been achieved. The flange is so important to the shape of the finished surface that it is possible to fabricate some panels by shrinking and stretching of the flange alone, without the use of surface stretching.
Adjustment The pressure of the contact area and the number of wheeling passes determine the degree to which the material stretches. Contact area pressure varies with the radius of the dome on the anvil wheel and the pressure of the adjusting screw. Some operators prefer a foot adjuster so they can maintain constant pressure over varying sheet metal thickness for smoothing, with both hands free to manipulate the work piece. This style of adjuster is also helpful for blending the edge of high crown areas that are thinner, with low crown areas that are relatively unstretched. A drawback of the foot adjuster is that it can get in the way of very longitudinally curved panels, such as the cycle type mudguards (wings/
fenders) used on motorcycles, pre-WW2 sports cars, and current open-wheeled cars like the Lotus /
Caterham 7. To address this problem some wheeling machines have a hand adjuster close beneath the anvil yoke (also known as the wheel holder) so such panels can curve underneath unobstructed. This type of machine typically has a diagonal lower C-shaped frame that curves lower to the floor, with a hand-operated adjuster close to the anvil wheel holder, instead of the horizontal and long vertical hand adjuster shown in the above picture. A third type of adjuster moves the top wheel up and down with the bottom anvil wheel left static.
Shaping At every fabrication stage the operator must constantly reference the shape that they want to reproduce. This may involve the use of
template paper, section templates (made using paper or thin sheet metal), station bucks, formers, profile gauges, profile templates and of course an original panel. Quick-release levers, which enable the operator to drop the anvil wheel away from the upper wheel so the work piece can be removed and inserted quickly without losing the pressure setting, are great time savers during this part of the process. The operator must have painstaking patience to make many passes over an area on the sheet to form the area correctly. They may make additional passes with different wheels and in different directions (at 90 degrees for a simple double curvature shape, for example) to achieve the desired shape. Using the correct pressure and appropriate anvil wheel shape, and accurate close patterns of overlapping wheeling passes (or actually overlapping with low crown anvils) makes using the machine something of an art. Too much pressure produces a part that is undulating, marred, and stressed—while too little pressure makes the job take a long time. Localised wheeling on one part of the panel is likely to cause mis-shaping in adjacent areas. Raising or stretching an area causes adjacent areas to sink, and correcting that may affect areas further away from the original panel working. This is because the tensions in the panel caused by stretching affect the panel shape further away than might be imagined. This means the operator must work over a large area of the panel, fixing these side effects while causing more side effects that must also be fixed. Key to producing the right shape is to have the right amount of stretched metal surface over this wider area. If this is achieved, it is possible to "move" the metal with minimal extra stretching, filling the low spots with metal from the high spots. This smoothing is almost like
planishing using a moderate pressure setting, but is still heavier than that used for planishing. It is a time consuming and fiddly
iterative process, that is one of the most difficult and skillful parts of wheeling. As the size of the panel/section increases, the work involved and the level of difficulty increases disproportionately. This is also a reason that very large panels can be very difficult to do and are made in sections. High crown panels/sections may need to be
annealed due to work-hardening of the metal, which makes it brittle unworkable and liable to fracture. After achieving the correct basic shape with the correct amount of metal in the right places, the worker must blend the edges of high crown areas with low crown areas, so that the surface contour transitions from one to the other smoothly. After this, the final wheeling stage involves very light pressure wheeling to
planish the surface to make it a smooth, cohesive shape. This stage does not stretch the metal but moves the already stretched metal around, so using the minimum anvil pressure and as wide an anvil as is possible with the panel shape, is essential. Typically, only small high crown panels, (such as repair sections) or large low crown panels (such as roofs), are made in one piece. Large low crown panels need two skilled craftsmen to support the weight of the panel.
Limitations Using an English wheel presents five key limitations: • The thickness of the sheet that can be handled • Fitting the work piece in the machine’s 'throat' • The size of workpiece that can be physically handled • The risk of over stretching/thinning an over-large high crown panel or section • The work involved and level of difficulty increases disproportionately with the size of the panel or section These limitations result in large high crown panels such as wings and fenders often being made in many pieces, then welded together usually by one of two processes:
TIG welding (Tungsten Inert Gas) produces less heat distortion, but produces a harder, more brittle weld that may cause problems when
planishing/smoothing by hand, or in the wheeling machine.
Oxy-acetylene welding joints don't have this drawback, provided they are allowed to cool to room temperature in air, but do produce more heat distortion. Panel joints may be achieved using
autogenous welding – that is welding without filler rod (
Oxy-acetylene or
TIG processes), this is useful when finally smoothing the
welding joints as it reduces the amount of filing/grinding/linishing needed or almost eliminates it altogether. It also, more importantly, reduces heat distortion of the surface contour, which must be corrected on the wheel or with hammer and dolly.
Finishing The final panel fabrication process, after achieving the correct surface contour, is some kind of
edge treatment, such as
flanging (sheet metal) or
wire edging. This finishes and strengthens the edge. Typically, there is too much or too little metal in the flange, which pulls the panel out of shape after the flange is turned—so it must be stretched or shrunk to correct the surface shape. This is most easily done using Eckold shrinking and stretching, but can be done using
heat shrinking or
cold shrinking, by tucking and beating the tucked metal into itself, or by using a cold shrinking hammer and dolly. Stretching or shrinking the flange requires a correct profile hammer and dolly. The hammer and dolly must match the desired flange shape at the point of contact through the flange, (known as ringing the dolly) with the hammer. A lot of shrinking or stretching work hardens the flange and can cause cracks and tears. While these can be welded, it is much better to anneal the metal before this happens to restore its workability. An English wheel is a better tool for a skilled craftsman for low-crown applications than manually
hammering. Planishing manually using dollies and slapper files or planishing hammer, after hammer forming is very labour-intensive. Using a pear shaped mallet and sandbag to stretch the sheet metal (
sinking), or by
raising on a stake, speeds up the fabrication of higher crown sections. (A stake is a dolly, that can be much larger than hand held dollys, typically with a tapering square cross section casting underneath it. This is to mount it in a bench vice or a matching female hole in a beak anvil as used by blacksmiths and farriers.) A
pneumatic hammer or power hammer is faster still. The English wheel is very effective when used for
planishing (for which it was originally patented in England) to a smooth final finish after these processes. ==References==