Increasing the compression ratio of luftkopf #1 is long overdue. Aside from being one of the easiest ways of adding horses, the BMW 336 cam wants it badly.

The valve pockets in the piston domes have been deepened to accommodate the higher lift of the cam and I have often wondered what difference this would make to the compression ratio. Not much I suspect but enough to turn my curiosity into a vaguely unhealthy urge to measure it.

Also, having developed a sceptisim of ‘factory specifications’, if I’m to increase CR, I want confirmation of the starting point.

The result of the process as set out below was puzzling. I got a compression ratio for the bike of 8.2:1 when the bike is supposed to be 9.5:1 ! This translates to a whole 12cc’s of additional volume in the combustion chamber that shouldn’t be there! Certainly far more than can be explained by deepened piston pockets or valve recession etc.

Everything has been checked: Pistons, gaskets, heads measured to check that they are indeed ‘9.5’ items. I even went to the extent of using a completely different method of measuring CR in order to verify the first method. This second method showed close agreement with the first and can be found here.

So, my scepticisim of factory specifications is even more justified, but could BMW have duped us to such an extent! Please leave a comment you have had similar findings or can shed some light!

So here’s the first method that I used.  It’s a standard method which I tweeked so that it better suits airheads.

If you would like a spreadsheet that does all the math, please email me.

Compression ratio is most easily described as the ratio of the volume above the piston when it is at bottom dead center (BDC) to the volume above the piston at top dead center (TDC).

This is illustrated in the following diagram:

Compression_Ratio_1

The swept volume, Vs, is easily calculated but not so the complex volume Vtdc. This is worked out with a combination of mathematics and directly measuring a couple volumes with a burette and a suitable fluid.

After researching the various ways that people go about this, I came up with a variation which I think better suits the domed head of the airhead piston and is not too hard to carry out.

The pivital formula is Vtdc = Vg – Vph explained below:

compbustion chamber volume

a) Measuring Vcc

The combustion chamber volume, Vcc is measured directly with a burette. I used a square piece of clear acrylic (plexiglass) about 107mm x 107mm with a 7-8mm hole drilled about 20mm off one side as shown below. With a light smear of grease around the combustion chamber, the acrylic is pressed down firmly so that the grease is squished very thinly and creates a good seal.

The filling side of the head must be tilted up a few mm’s so that the chamber fills towards the hole without trapping any bubbles.

The burette is the cheaper acrylic type (100ml) and cost me $27.00. Graduations are 0.2ml. (The glass ones are over $100).

I used straight ATF because I had some on the shelf. But found it a little too viscous. It took some time for the film left on the sides of the emptied portion of burette to settle down to the bottom. After an hour, the level rose by 0.4ml… Other people have used spirits coloured with food dye.

Mind that fluid doesn’t leak past the valves – a light smear of grease around the valve peripheries would help.

Vcc was measured at 88.2ml (or cc’s) for both heads.

CR_head1
CR_head2
CR_head3

 

b) Measuring dh & gt

For deck height ‘dh’ I clamped the cylinder to the block using tubes on the studs, moved the piston to TDC and slid a squared off 0.1mm feeler gauge between the cylinder wall and piston so that it rested on the 1st compression ring. A carefully scribed line and vernier did the rest.

If you use this method, make sure you slide the gauge in line with the horizontal axis of the gudgeon pin (ie at 3 and 9 o’clock looking directly at the piston) as this is where piston rock is at a minimum. Also, prussian blue would have helped to make out the scribe line!

dh was measured as 6.8mm.

The gasket thickness ‘gt’ is measured at several locations with a micrometer or vernier caliper on the bore edge of a used, pre-squished gasket then averaged – I got 0.72mm

Now Vdh and Vgt can be calculated and added to Vcc to get Vg – see calcs below

dh_1
dh_2
dh_3

Compression_Ratio_3

 

2. Working out the piston head volume Vph

Measuring Vphr is done directly with the burette. A light smear of grease is put around the top compression ring and the piston driven up the cylinder until the piston top is perfectly flush with the top of the cylinder using an accurate straight edge.

At this point the piston head height ‘h’ (from 1st ring to dome top) can be measured in the same way as ‘dh’ above with a squared feeler gauge and scribed line. Thus h = 16.4mm was obtained.

The plexiglass plate is pressed down on its greasy bed with the hole side elevated by at least 5mm and the burette does its job Vphr was measured to be 42.0ml

(BTW: for those not familiar with the metric system, ml = cc)

All the raw data for calculations has now been collected.

 

Vphr_1
Vphr_2

 

 

3. Calculations
The calculations below reveal a compression ratio of……8.2 : 1 ?!

Here’s a spreadsheet calculator of the math: calculator (hit cancel if you get a login message)

 

Worked_example