The camshaft was tackled next. Ninety degree heads, offset cylinders, interleaved pushrods, firing order, direction of rotation - all these combine to make the scratch design of a V8 camshaft a challenging mental exercise.
First up was the selection of the camshaft's duration and lobe separation angle (LSA) which pretty much define the engine's starting and running characteristics. I decided upon a mild street cam with 260 degrees of duration and an LSA of 112 degrees and then created a model of its intake/exhaust lobe pair. Since the left and right banks require oppositely ordered lobes, two different pairs were created. While being careful to assign the correct lobe pair to each engine bank, the firing order was used to sequentially arrange the lobe pairs with each intake lobe being ******** 45 degrees from the one before it. A machined flat on the nose of the camshaft defined the arbitrary starting angle.
The flat tappet cam originally designed for this engine was modified to take advantage of the roller lifters. Since this was my first roller cam I was a bit conservative, but when compared with the original cam it will fully open the valves a little sooner and keep them fully open a little longer for the same duration and LSA.
The starting material for the camshaft was a nine inch piece of 5/8" ground/polished Stressproof. Its .624" measured diameter fit perfectly inside the block's .625" inner bearing bores, and so its bearing surfaces didn't require machining. The lobe blanks were manually turned on the lathe before the workpiece was moved to the Tormach where they were machined into lobes using a 4-axis rotary operation.
The camshaft was divided into four machining zones with two lobe pairs in each zone. The blanks were turned and the lobes machined in one zone before moving on to the next. A heavy steel disk set-screwed to the flat on the nose of the camshaft was used to re-reference the workpiece in each of the four milling setups. It also damped some of the machining vibrations. A shop-made fixture stabilized the portion of the camshaft sticking out of the fourth axis.
Each lobe was machined in three operations using a 4 flute 1/8" end mill with a .010" corner radius. The first two operations were roughing operations at fixed A axis angles of 0 degrees and 180 degrees. These operations left .005" excess stock for the rotary finishing operation. Total machining time per section was just under two hours.
The relief that's ground into the bottoms of cylindrical end mills left 'furrows' in the finished lobe surfaces. These marks don't happen when an end mill is normal to the surface it's cutting such as when a flat surface is machined. However, in order to prevent gouging in the rotary operation, the cutter was held slightly tilted to the lobe's continuously moving curved surface. Fortunately, the furrows were easily polished out with a strip of 800g paper glued to a flat stick. The marks were polished out while the camshaft was spinning in the lathe at about one rpm to reduce chances of inadvertently modifying the profiles.
Upon finishing the lobes, the rear of the camshaft was machined to accept the rear ball bearing and a block cover plate created for it. This completed the camshaft except for the custom helical gear needed to drive the distributor. That gear will become its own project later. For now, the valve cages seem to be the most logical next step. - Terry
First up was the selection of the camshaft's duration and lobe separation angle (LSA) which pretty much define the engine's starting and running characteristics. I decided upon a mild street cam with 260 degrees of duration and an LSA of 112 degrees and then created a model of its intake/exhaust lobe pair. Since the left and right banks require oppositely ordered lobes, two different pairs were created. While being careful to assign the correct lobe pair to each engine bank, the firing order was used to sequentially arrange the lobe pairs with each intake lobe being ******** 45 degrees from the one before it. A machined flat on the nose of the camshaft defined the arbitrary starting angle.
The flat tappet cam originally designed for this engine was modified to take advantage of the roller lifters. Since this was my first roller cam I was a bit conservative, but when compared with the original cam it will fully open the valves a little sooner and keep them fully open a little longer for the same duration and LSA.
The starting material for the camshaft was a nine inch piece of 5/8" ground/polished Stressproof. Its .624" measured diameter fit perfectly inside the block's .625" inner bearing bores, and so its bearing surfaces didn't require machining. The lobe blanks were manually turned on the lathe before the workpiece was moved to the Tormach where they were machined into lobes using a 4-axis rotary operation.
The camshaft was divided into four machining zones with two lobe pairs in each zone. The blanks were turned and the lobes machined in one zone before moving on to the next. A heavy steel disk set-screwed to the flat on the nose of the camshaft was used to re-reference the workpiece in each of the four milling setups. It also damped some of the machining vibrations. A shop-made fixture stabilized the portion of the camshaft sticking out of the fourth axis.
Each lobe was machined in three operations using a 4 flute 1/8" end mill with a .010" corner radius. The first two operations were roughing operations at fixed A axis angles of 0 degrees and 180 degrees. These operations left .005" excess stock for the rotary finishing operation. Total machining time per section was just under two hours.
The relief that's ground into the bottoms of cylindrical end mills left 'furrows' in the finished lobe surfaces. These marks don't happen when an end mill is normal to the surface it's cutting such as when a flat surface is machined. However, in order to prevent gouging in the rotary operation, the cutter was held slightly tilted to the lobe's continuously moving curved surface. Fortunately, the furrows were easily polished out with a strip of 800g paper glued to a flat stick. The marks were polished out while the camshaft was spinning in the lathe at about one rpm to reduce chances of inadvertently modifying the profiles.
Upon finishing the lobes, the rear of the camshaft was machined to accept the rear ball bearing and a block cover plate created for it. This completed the camshaft except for the custom helical gear needed to drive the distributor. That gear will become its own project later. For now, the valve cages seem to be the most logical next step. - Terry
!!! (hpcgears.com has the smallest I know of at 15-T 48-DP 45-deg, which I'm using in both my Duesenberg and Hansen engines)
