Its likely you are experiencing some Knock Ewe but the GM 7 in stock form needs greater protection and has to detect Knock long before its heard by ear.

I dont think you are running GM ecu.... but if your engine is stock internals... ie Flat pistons and GM LS heads (fast burn) then there is no point running much past 26-27 degress of advance on a stock engine from 3000-7000rpm..... have seen this on the dyno, very tiny improvements if any through the whole rev range and not worth it.. the torque goes flat/ backwards with advance.
Just be very careful in testing..... most maps, even the GM stock are set rich at WOT/ high RPM... but you can cause much damage at WOT low-mid rpm, expecially if things are a little hot to begin with. If you do get some serious detonation and it marks the pistons/ head chambers, this only makes the engine more detonation sensitive .. (high-sharp hot spots in the combustion space)

G luck.

Is that advancing the ignition angle 'toward' or away from tdc Max ?.... advance moves it away from tdc, retard is toward or closer I think....
....Intended clarity for the newbies as opposed to nit-picking..

Rgds.

Mere typo's....

Am working with some top, race two stroke boys at the min (in a general interest-development capacity)... trying to convince them to work on chamber design / ignition advance reduction etc.. Only a minority are on side but they are already getting results...
..... fast burn head/chamber, flatter piston and less ignition advance is the way to economy and performance... less mass in fuel carried etc etc... all good stuff !

Sorry, but that's not the case.

The intensity of the knock, both in terms of the rate of rise of knocking pressure, and it terms of it's duration (crank angle) is directly related to the heat release over that knock event. Hence, the "Louder" the knocking the more greater the potential damage. Every engine has a different threshold for damage and this threshold also is proportional to engine speed (because cycles happen faster).

Typically on an OEM mapped road car engine you would do the following:

<2krpm: limit is set by the knocking pressure that is just inaudible in the passenger cabin. At these low speeds there is sufficient time for any localised hot spots due to knock being quenched before significant damage occurs. Audible "pinking" is a customer quality issue.

>2krpm & < 5krpm: Likely to be the most knock limited engine operation zone, but engine combustion noise will be louder here, so generally the knock will not be as obvious in the passenger cabin as at low speed. Typical engines will be mapped to a 3-5bar knocking pressure in order to achieve maximum torque output. Cylinder specific KCS really helps here because you can retard only the knocking cylinders.

>5.5krpm: The danger zone as engine combustion and mechanical noise will be almost totally obscuring the knocking spectrum. However most road cars engines are not knock limited at high rpm. Most OEMS will have a very low peak knocking pressure limit here to protect the engine (knock can be damaging at this high rpm)


Now for a race car, where you don't care what it sounds like to the driver, you can run the engine into some pretty aggressive knock and still survive. Again this needs to be determined for any given engine. Just because some knock is present does not mean the engine will be damaged. Generally most race engines with a decent KCS will be deliberately run into detonation equally on all cylinders in order to make the highest output.

The problem with the usual aftermarket knock amplifiers are you simply have no idea of the actual knocking pressure for any given "Volume" of knock, and also you have no idea of when it is occuring (in terms of crank angle) and on what cylinders etc.

If you take a highly boosted engine (say a WRC spec one, which is highly knock limited due to the inlet restrictor massively increasing EBP and hence hot in-cylinder residuals) you would find at a cylinder specific crank angle windowed and signal band pass filtered knock system will be able to keep all cylinders at an optimum knocking pressure. A "manual" spark cal could potentially keep the most knock limited cylinder at the same knock intensity but not all of the cylinders. Finally, your manual cal has to be absolutely perfect wrt compensating for any changes in boundary conditions (temps, pressures, fuel quality, sensor drift etc etc) otherwise you risk engine damage because you are flying so close to the knock intensity limit for damage.

(the big issue for many years in WRC however has been reliably sensing knock intensity via an acoustic sensor. In a WRC car there is so much background noise from the transmission (or even gravel hitting the sum!) etc that the signal to noise ratio is very poor.)

Whatever that Nock box seems pretty cool.

Just look at my thread on the stand alone knock retard unit, it will safeguard this issue

It should also be noted that generally detonation does not actually kill engines. What happens is audible detonation (explosive sympathetic burning of the air charge at the chamber extremities before the main flame front arrives) causes localise hot spots which lead to inaudible pre-ignition.

This pretty much ignites the fuel as it is injected (effectively it diesels) resulting in massive uncontrolled heat release, which occurs early and hence at large chamber volumes (the piston is still well down the bore). Hence there are no characteristic "knocking" pressure waves to hear. An engine that enters pre-ignition generally overheats it's piston crowns, that then expand excessively, and usually then pick-up on the bore. The added friction from the pick-up finishes things off nicely, adding more heat and leading to a runaway situation when the cylinder will pre-ignite on every compression event as the fuel is added. This continues until the engine siezes, the crown comes off the piston, or typically when the exhaust valve also fails and gets smashed into the piston (burning the charge at low compression ratios (super early burn) means there is little or no expansion availible to cool the post burn charge, this sends EGT's rocketing up, and usually leads to a thermal failure of the exhaust valve.
At this point, most race drivers finally notice and lift off......... ;-)

But just to remind... the stock LS series are generally large bore N/A, built as light as possible production units.... when not fitted with uprated aftermarket parts the pistons are quite a weak area.... liners too on 7's as they are frequently quite thin in places and do crack at the top (due production inconsistances/tolerances).. getting a 7ltr 520hp 2 valve V8 to return 25-27 mpg and operate flawlessly between 1200 and 7000 rpm has not been done with the most knock resistant components.... tis all relatively light and thinned down in there Gents but works well when combined with the capable GM ECU/EMS.
So despite all the great responses here Uwe do go easy on the road /ear set-up if you are currently running an ECU without knock protection on stock parts...
Good topic and tech replies.

Yes it was in the ST185. My friend used to sit next to Carlos During some tuning seasons I'm so jealous and they Paid him to......

I hope you're not running closed loop when you're fiddeling around with ecu settings. It doesn't help, and can setup your fueltables generated by the closed loop feedback, at least that's how the more advanced ecu's work. It will give a lot of confusion in the readouts, because the ecu will try to compensate, and it doesn't know that you moved the goalposts.
Why would you want to run closed loop anyway, apart from the legal requiremnts set by TÜV in order to get your green 4 sticker. It should only be functional under constant load and up to about 3500 rpm.

Again I try to put things simple and not too complex for the amateurs, which I count myself too.