ignition advance

[sidecar]

Pete,
The recommendations I got from very reliable sources was with a road tuned 3.5/3.9 that you need 10 degrees at 1000RPM and all in 34 degrees at 3500RPM

Yes, these are pretty much the figures I use, but I'm using megasquirt to control things. (much easier that faffing with advance springs!).

Even though I run 10 deg @1000rpm, I actually advance the timing below 1000rpm (to 20BTDC @500rpm), so that I get a better idle and cooler exhaust manifolds. Something that obviously 'aint possible with clockwork timing!

Jeff

Hi Jeff,

How dare you show disrespect to our meccano dizzies!


Your idea of advancing the ignition below 1000 rpm is a good one and may help prevent stalling.


I bet two springs cost less than your megasquirt?


Anyway, its all good stuff,

Regards,

Pete

[jefferybond]

I bet two springs cost less than your megasquirt?

Indeed! I actually ran a stock 35DE8 dizzy before the megasquirt, and it was OK, but I could never get it set up to give max power AND no pinking at low revs. It was always one or the other! The springs were probably knackered though.

Jeff

[Paul B]

Even though I run 10 deg @1000rpm, I actually advance the timing below 1000rpm (to 20BTDC @500rpm), so that I get a better idle and cooler exhaust manifolds. Something that obviously 'aint possible with clockwork timing!

Jeff

The vacuum advance does that for you anyway doesn't it?

[sidecar]

Even though I run 10 deg @1000rpm, I actually advance the timing below 1000rpm (to 20BTDC @500rpm), so that I get a better idle and cooler exhaust manifolds. Something that obviously 'aint possible with clockwork timing!

Jeff

The vacuum advance does that for you anyway doesn't it?

The vac advance should have no effect at tickover, well not if its connected to a "timed" port. Most people say disconnect it whilst setting up the static timing just as a precaution. Whilst setting up my timing at 1000 rpm I had my vac disconnected, when I connected it the timing did not advance at all. The vac port is only exposed to the vacuum as the throttle is cracked open, at which point the advance kicks in pretty hard.

Pete

[CastleMGBV8]

Pete,

Any idea how much additional advance the vacuum can provides?

Kevin.

[jefferybond]

Pete,

Any idea how much additional advance the vacuum can provides?

Kevin.

It'll probably be in the 20-25 degrees range.

Jeff

[sidecar]

Pete,

Any idea how much additional advance the vacuum can provides?

Kevin.

Hi kevin,

I never bothered to measure mine as it only applies when the throttle is just cracked open. The VE is so poor in this state that no mount of advance would cause the engine to pink. (In my opinion!).

I'm sure that Jeff is close to the mark with his figures.


I did set up my mates dizzy the other day and it looked like the vac added about 15-20 degrees but thats a bit of a guess. It does kick in quite hard just off tick over when connected to the timed port of a webber 500.

I was thinking that this might be a bit too harsh if you were running say 12 degrees static, I might put some sort of restrictor (a small main jet from a motorbike) in the tube so that the vac does work but takes a little longer to fully kick in. The problem might be that it does not come off quick enough when the throttle is booted. It is tooooooo cold to mess about with such things at this time of year!

I think that some Rovers had a advice like this fitted as standard!

Pete

Pete

[CastleMGBV8]

Pete,

I agree much too bloody cold to be in an unheated garage, a heated 4 car garage is on my wish list if I win the lottery!

I must admit 20-25degrees of vac advance surprises me, but I have no information that it is not correct. The guy who gave me the initial advice regarding recurving the dizzy, Jeff Schlemmer in the states who rebuilds lots of distributors for the 215 Buick and Rovers suggests a vac advance of 5-7 degrees absolute maximum. believe the problem is that if you come off the throttle at high RPM when mechanical advance is at max the vac cuts in and can cause problems, this may explain why some vac advance systems had a delay unit built in to avoid a sudden over advance.

Whether you can buy vac cans with different advance or modify them I don't know or poss buy delay units, I'll check Rimmer Bros to see if they list them.

Compliments of the season,

Kevin.

[Paul B]

Even though I run 10 deg @1000rpm, I actually advance the timing below 1000rpm (to 20BTDC @500rpm), so that I get a better idle and cooler exhaust manifolds. Something that obviously 'aint possible with clockwork timing!

Jeff

The vacuum advance does that for you anyway doesn't it?

The vac advance should have no effect at tickover, well not if its connected to a "timed" port. Most people say disconnect it whilst setting up the static timing just as a precaution. Whilst setting up my timing at 1000 rpm I had my vac disconnected, when I connected it the timing did not advance at all. The vac port is only exposed to the vacuum as the throttle is cracked open, at which point the advance kicks in pretty hard.

Pete

Good point. I came across a very interesting article stating that vacuum advance should ALWAYS be attached to a full time manifold vacuum, and I did this religiously for several year, several cars, but I found on my Morris hot rod that I had an annoying misfire, and popping from the exhaust at idle and low rpms.

I spent an age trying to find it, even bought a new Weber 500 and an Edelbrock manifold, £500, bought a used distributor, a new coil, amp etc. I asked about it on this very forum several times over the period of six months or more.

Then I swapped my vacuum back to the timed port, and the misfire disappeared

Here's the article I got the idea from, quite an interesting read, but a little long:


TIMING AND VACUUM ADVANCE

The most important concept to understand is that lean mixtures, such as at idle and steady highway cruise, take longer to burn than rich mixtures; idle in particular, as idle mixture is affected by exhaust gas dilution. This requires that lean mixtures have "the fire lit" earlier in the compression cycle (spark timing advanced), allowing more burn
time so that peak cylinder pressure is reached just after TDC for peak efficiency and reduced exhaust gas temperature (wasted combustion energy). Rich mixtures, on the other hand, burn faster than lean mixtures, so they need to have "the fire lit" later in the compression cycle (spark timing retarded slightly) so maximum cylinder pressure is
still achieved at the same point after TDC as with the lean mixture, for maximum efficiency.

The centrifugal advance system in a distributor advances spark timing purely as a function of engine rpm (irrespective of engine load or operating conditions), with the amount of advance and the rate at which it comes in determined by the weights and springs on top of the auto cam mechanism. The amount of advance added by the distributor, combined with initial static timing, is "total timing" (i.e., the 34-36 degrees at
high rpm that most SBC's like). Vacuum advance has absolutely nothing to do with total timing or performance, as when the throttle is opened, manifold vacuum drops essentially to zero, and the vacuum advance drops out entirely; it has no part in the "total timing" equation.

At idle, the engine needs additional spark advance in order to fire that lean, diluted mixture earlier in order to develop maximum cylinder pressure at the proper point, so the vacuum advance can (connected to manifold vacuum, not "ported" vacuum - more on that aberration later) is activated by the high manifold vacuum, and adds about 15 degrees of
spark advance, on top of the initial static timing setting (i.e., if your static timing is at 10 degrees, at idle it's actually around 25 degrees with the vacuum advance connected). The same thing occurs at steady-state highway cruise; the mixture is lean, takes longer to burn, the load on the engine is low, the manifold vacuum is high, so the vacuum advance is again deployed, and if you had a timing light set up so you could see the balancer as you were going down the highway, you'd see about 50 degrees advance (10 degrees initial, 20-25 degrees from the centrifugal advance, and 15 degrees from the vacuum advance) at steady-state cruise (it only takes about 40 horsepower to cruise at
50mph).

When you accelerate, the mixture is instantly enriched (by the accelerator pump, power valve, etc.), burns faster, doesn't need the additional spark advance, and when the throttle plates open, manifold vacuum drops, and the vacuum advance can returns to zero, retarding the spark timing back to what is provided by the initial static timing plus the centrifugal advance provided by the distributor at that engine rpm; the vacuum advance doesn't come back into play until you back off the gas and manifold vacuum increases again as you return to steady-state cruise, when the mixture again becomes lean.

The key difference is that centrifugal advance (in the distributor auto cam via weights and springs) is purely rpm-sensitive; nothing changes it except changes in rpm. Vacuum advance, on the other hand, responds to engine load and rapidly-changing operating conditions, providing the correct degree of spark advance at any point in time based
on engine load, to deal with both lean and rich mixture conditions. By today's terms, this was a relatively crude mechanical system, but it did a good job of optimizing engine efficiency, throttle response, fuel economy, and idle cooling, with absolutely ZERO effect on wide-open throttle performance, as vacuum advance is inoperative under wide-open throttle conditions. In modern cars with computerized engine controllers, all those sensors and the controller change both mixture and spark timing 50 to 100 times per second, and we don't even HAVE a distributor any more - it's all electronic.

Now, to the widely-misunderstood manifold-vs.-ported vacuum aberration. After 30-40 years of controlling vacuum advance with full manifold vacuum, along came emissions requirements, years before catalytic converter technology had been developed, and all manner of crude band-aid systems were developed to try and reduce hydrocarbons and
oxides of nitrogen in the exhaust stream. One of these band-aids was "ported spark", which moved the vacuum pickup orifice in the carburetor venturi from below the throttle plate (where it was exposed to full manifold vacuum at idle) to above the throttle plate, where it saw no manifold vacuum at all at idle. This meant the vacuum advance was
inoperative at idle (retarding spark timing from its optimum value), and these applications also had VERY low initial static timing (usually 4 degrees or less, and some actually were set at 2 degrees AFTER TDC). This was done in order to increase exhaust gas temperature (due to "lighting the fire late") to improve the effectiveness of the "afterburning" of hydrocarbons by the air injected into the exhaust manifolds by the A.I.R. system; as a result, these engines ran like crap, and an enormous amount of wasted heat energy was transferred through the exhaust port walls into the coolant, causing them to run hot at idle - cylinder pressure fell off, engine temperatures went up, combustion efficiency went down the drain, and fuel economy went down with it.

If you look at the centrifugal advance calibrations for these "ported spark, late-timed" engines, you'll see that instead of having 20 degrees of advance, they had up to 34 degrees of advance in the distributor, in order to get back to the 34-36 degrees "total timing" at high rpm wide-open throttle to get some of the performance back. The vacuum
advance still worked at steady-state highway cruise (lean mixture = low emissions), but it was inoperative at idle, which caused all manner of problems - "ported vacuum" was strictly an early, pre-converter crude emissions strategy, and nothing more.

What about the Harry high-school non-vacuum advance polished billet "whizbang" distributors you see in the Summit and Jeg's catalogs? They're JUNK on a street-driven car, but some people keep buying them because they're "race car" parts, so they must be "good for my car" - they're NOT. "Race cars" run at wide-open throttle, rich mixture, full
load, and high rpm all the time, so they don't need a system (vacuum advance) to deal with the full range of driving conditions encountered in street operation. Anyone driving a street-driven car without manifold-connected vacuum advance is sacrificing idle cooling, throttle response, engine efficiency, and fuel economy, probably because they
don't understand what vacuum advance is, how it works, and what it's for - there are lots of long-time experienced "mechanics" who don't understand the principles and operation of vacuum advance either, so they're not alone.

Vacuum advance calibrations are different between stock engines and modified engines, especially if you have a lot of cam and have relatively low manifold vacuum at idle. Most stock vacuum advance cans aren't fully-deployed until they see about 15" Hg. Manifold vacuum, so those cans don't work very well on a modified engine; with less than 15"
Hg. at a rough idle, the stock can will "dither" in and out in response to the rapidly-changing manifold vacuum, constantly varying the amount of vacuum advance, which creates an unstable idle. Modified engines with more cam that generate less than 15" Hg. of vacuum at idle need a vacuum advance can that's fully-deployed at least 1", preferably 2" of vacuum less than idle vacuum level so idle advance is solid and stable; the
Echlin #VC1810 advance can (about $10 at NAPA) provides the same amount
of advance as the stock can (15 degrees), but is fully-deployed at only 8" of vacuum, so there is no variation in idle timing even with a stout cam.

For peak engine performance, driveability, idle cooling and efficiency in a street-driven car, you need vacuum advance, connected to full manifold vacuum.

[sidecar]

Pete,

I agree much too bloody cold to be in an unheated garage, a heated 4 car garage is on my wish list if I win the lottery!

I must admit 20-25degrees of vac advance surprises me, but I have no information that it is not correct. The guy who gave me the initial advice regarding recurving the dizzy, Jeff Schlemmer in the states who rebuilds lots of distributors for the 215 Buick and Rovers suggests a vac advance of 5-7 degrees absolute maximum. believe the problem is that if you come off the throttle at high RPM when mechanical advance is at max the vac cuts in and can cause problems, this may explain why some vac advance systems had a delay unit built in to avoid a sudden over advance.

Whether you can buy vac cans with different advance or modify them I don't know or poss buy delay units, I'll check Rimmer Bros to see if they list them.

Compliments of the season,

Kevin.

Hi Kevin,

The vac advance definately adds more than 7 degress as standard, I'm sure that you could make some sort of adjustable stopper inside the dizzy to control how much it could add. Just how much you need is something that I don't know.

I do know that my car does run better at tickover with more than the standard 8 degrees but would hesitate a bit as I pulled away, I guess this was because of too much vac, or at least it kicking in too hard, too quickly.
I can't rememeber what springs were fitted when it was doing this so it may have had the crappy Rover ones in. When the weather picks up this is something have I'm going to spend some time fiddling with.

Merry Chrimbo to you!

Regards,

Pete.

[sidecar]

Good point. I came across a very interesting article stating that vacuum advance should ALWAYS be attached to a full time manifold vacuum, and I did this religiously for several year, several cars, but I found on my Morris hot rod that I had an annoying misfire, and popping from the exhaust at idle and low rpms.

I spent an age trying to find it, even bought a new Weber 500 and an Edelbrock manifold, £500, bought a used distributor, a new coil, amp etc. I asked about it on this very forum several times over the period of six months or more.

Then I swapped my vacuum back to the timed port, and the misfire disappeared

Here's the article I got the idea from, quite an interesting read, but a little long:


TIMING AND VACUUM ADVANCE

The most important concept to understand is that lean mixtures, such as at idle and steady highway cruise, take longer to burn than rich mixtures; idle in particular, as idle mixture is affected by exhaust gas dilution. This requires that lean mixtures have "the fire lit" earlier in the compression cycle (spark timing advanced), allowing more burn
time so that peak cylinder pressure is reached just after TDC for peak efficiency and reduced exhaust gas temperature (wasted combustion energy). Rich mixtures, on the other hand, burn faster than lean mixtures, so they need to have "the fire lit" later in the compression cycle (spark timing retarded slightly) so maximum cylinder pressure is
still achieved at the same point after TDC as with the lean mixture, for maximum efficiency.

The centrifugal advance system in a distributor advances spark timing purely as a function of engine rpm (irrespective of engine load or operating conditions), with the amount of advance and the rate at which it comes in determined by the weights and springs on top of the auto cam mechanism. The amount of advance added by the distributor, combined with initial static timing, is "total timing" (i.e., the 34-36 degrees at
high rpm that most SBC's like). Vacuum advance has absolutely nothing to do with total timing or performance, as when the throttle is opened, manifold vacuum drops essentially to zero, and the vacuum advance drops out entirely; it has no part in the "total timing" equation.

At idle, the engine needs additional spark advance in order to fire that lean, diluted mixture earlier in order to develop maximum cylinder pressure at the proper point, so the vacuum advance can (connected to manifold vacuum, not "ported" vacuum - more on that aberration later) is activated by the high manifold vacuum, and adds about 15 degrees of
spark advance, on top of the initial static timing setting (i.e., if your static timing is at 10 degrees, at idle it's actually around 25 degrees with the vacuum advance connected). The same thing occurs at steady-state highway cruise; the mixture is lean, takes longer to burn, the load on the engine is low, the manifold vacuum is high, so the vacuum advance is again deployed, and if you had a timing light set up so you could see the balancer as you were going down the highway, you'd see about 50 degrees advance (10 degrees initial, 20-25 degrees from the centrifugal advance, and 15 degrees from the vacuum advance) at steady-state cruise (it only takes about 40 horsepower to cruise at
50mph).

When you accelerate, the mixture is instantly enriched (by the accelerator pump, power valve, etc.), burns faster, doesn't need the additional spark advance, and when the throttle plates open, manifold vacuum drops, and the vacuum advance can returns to zero, retarding the spark timing back to what is provided by the initial static timing plus the centrifugal advance provided by the distributor at that engine rpm; the vacuum advance doesn't come back into play until you back off the gas and manifold vacuum increases again as you return to steady-state cruise, when the mixture again becomes lean.

The key difference is that centrifugal advance (in the distributor auto cam via weights and springs) is purely rpm-sensitive; nothing changes it except changes in rpm. Vacuum advance, on the other hand, responds to engine load and rapidly-changing operating conditions, providing the correct degree of spark advance at any point in time based
on engine load, to deal with both lean and rich mixture conditions. By today's terms, this was a relatively crude mechanical system, but it did a good job of optimizing engine efficiency, throttle response, fuel economy, and idle cooling, with absolutely ZERO effect on wide-open throttle performance, as vacuum advance is inoperative under wide-open throttle conditions. In modern cars with computerized engine controllers, all those sensors and the controller change both mixture and spark timing 50 to 100 times per second, and we don't even HAVE a distributor any more - it's all electronic.

Now, to the widely-misunderstood manifold-vs.-ported vacuum aberration. After 30-40 years of controlling vacuum advance with full manifold vacuum, along came emissions requirements, years before catalytic converter technology had been developed, and all manner of crude band-aid systems were developed to try and reduce hydrocarbons and
oxides of nitrogen in the exhaust stream. One of these band-aids was "ported spark", which moved the vacuum pickup orifice in the carburetor venturi from below the throttle plate (where it was exposed to full manifold vacuum at idle) to above the throttle plate, where it saw no manifold vacuum at all at idle. This meant the vacuum advance was
inoperative at idle (retarding spark timing from its optimum value), and these applications also had VERY low initial static timing (usually 4 degrees or less, and some actually were set at 2 degrees AFTER TDC). This was done in order to increase exhaust gas temperature (due to "lighting the fire late") to improve the effectiveness of the "afterburning" of hydrocarbons by the air injected into the exhaust manifolds by the A.I.R. system; as a result, these engines ran like crap, and an enormous amount of wasted heat energy was transferred through the exhaust port walls into the coolant, causing them to run hot at idle - cylinder pressure fell off, engine temperatures went up, combustion efficiency went down the drain, and fuel economy went down with it.

If you look at the centrifugal advance calibrations for these "ported spark, late-timed" engines, you'll see that instead of having 20 degrees of advance, they had up to 34 degrees of advance in the distributor, in order to get back to the 34-36 degrees "total timing" at high rpm wide-open throttle to get some of the performance back. The vacuum
advance still worked at steady-state highway cruise (lean mixture = low emissions), but it was inoperative at idle, which caused all manner of problems - "ported vacuum" was strictly an early, pre-converter crude emissions strategy, and nothing more.

What about the Harry high-school non-vacuum advance polished billet "whizbang" distributors you see in the Summit and Jeg's catalogs? They're JUNK on a street-driven car, but some people keep buying them because they're "race car" parts, so they must be "good for my car" - they're NOT. "Race cars" run at wide-open throttle, rich mixture, full
load, and high rpm all the time, so they don't need a system (vacuum advance) to deal with the full range of driving conditions encountered in street operation. Anyone driving a street-driven car without manifold-connected vacuum advance is sacrificing idle cooling, throttle response, engine efficiency, and fuel economy, probably because they
don't understand what vacuum advance is, how it works, and what it's for - there are lots of long-time experienced "mechanics" who don't understand the principles and operation of vacuum advance either, so they're not alone.

Vacuum advance calibrations are different between stock engines and modified engines, especially if you have a lot of cam and have relatively low manifold vacuum at idle. Most stock vacuum advance cans aren't fully-deployed until they see about 15" Hg. Manifold vacuum, so those cans don't work very well on a modified engine; with less than 15"
Hg. at a rough idle, the stock can will "dither" in and out in response to the rapidly-changing manifold vacuum, constantly varying the amount of vacuum advance, which creates an unstable idle. Modified engines with more cam that generate less than 15" Hg. of vacuum at idle need a vacuum advance can that's fully-deployed at least 1", preferably 2" of vacuum less than idle vacuum level so idle advance is solid and stable; the
Echlin #VC1810 advance can (about $10 at NAPA) provides the same amount
of advance as the stock can (15 degrees), but is fully-deployed at only 8" of vacuum, so there is no variation in idle timing even with a stout cam.

For peak engine performance, driveability, idle cooling and efficiency in a street-driven car, you need vacuum advance, connected to full manifold vacuum.

Hi Paul,

That is one long post! I hope that Cut and Paste works!

What the guy has to say is very interesting but I'm not sure that all of it is correct. For starters I don't run my motor lean at tickover, I don't think that it will pick up well if I do, I know that the webber 500 manual states that you should turn the screws in so that the revs fall at tickover 20 rpm or so (i.e leaner than what the engine really wants) but I did not do this although I will have to wind them in at MOT time! Most of the stuff that I've read recons that the only time the mixture should be lean is when cruising about, which is exactly the time when there is a high manifold vacuum so the vac kicks in.

The guy recons that rich mixtures burn fast, this just ain't true both lean and rich mixtures burn slower than just off lean-stoichiometric.

I'm not sure how you could set the rover dizzy up if you used a non timed port. You would end up with all the advance at tickover being generated by the vac canister, when the vac disappeared as you booted the throttle I bet it would end up firing ADTC before the mechanical advance had a chance to kick in, this would be no good at all!

I guess the final thing is that you found out that your motor would not run well with the setup that the article suggested!

Anyway all this type of stuff is one of the things that makes owning a V8 lump interesting!


Regards,

Pete

[sidecar]

I've been out in the garage with my strobe, this is what I found:-

I'm running 8 degrees static at 800 rpm but this increases to 10 degrees at 1000 rpm so the silver realsteel springs start to add advance right off tickover.

My vac makes no difference at tickover but kicks in hard at about 1500 rpm (Or when the throttle is opened enough to get the revs up to 1500 rpm), it adds at least 15 degrees. The total advance was around 30 odd once the vac has kicked in. This must be made up off the 8 static + whatever the mechanical has added (maybe 4-6 ?) and the rest must be the vac.
I know that I run about 35 total when running flat out with the throttle wide open but I did not test that in the garage!


It looks like a delay in the vac would be a good idea!

Regards,

Pete

[blitzracing]

I did a bit of expermenting on how to detect knock when altering the timing. Modern knock sensors are nothing more than crude microphones, so you can feed the output directly into a small amplifier ( Like you get in PC speakers). I used a Vauxhall sensor bolted to the head and a pair of "over ear" headphones. You can then clearly hear the knock long before its a dangerious problem, and above the exhaust and road noise. You do look a bit of a prat road testing however!

Mark

[Paul B]

I've been out in the garage with my strobe, this is what I found:-

I'm running 8 degrees static at 800 rpm but this increases to 10 degrees at 1000 rpm so the silver realsteel springs start to add advance right off tickover.

My vac makes no difference at tickover but kicks in hard at about 1500 rpm (Or when the throttle is opened enough to get the revs up to 1500 rpm), it adds at least 15 degrees. The total advance was around 30 odd once the vac has kicked in. This must be made up off the 8 static + whatever the mechanical has added (maybe 4-6 ?) and the rest must be the vac.
I know that I run about 35 total when running flat out with the throttle wide open but I did not test that in the garage!


It looks like a delay in the vac would be a good idea!

Regards,

Pete

I found that the mech advance only added about 18 to the overall advance, without the vacuum attached. This is normal with most Rover dizzies, and needs fixing to get best performance.

[sidecar]

I've been out in the garage with my strobe, this is what I found:-

I'm running 8 degrees static at 800 rpm but this increases to 10 degrees at 1000 rpm so the silver realsteel springs start to add advance right off tickover.

My vac makes no difference at tickover but kicks in hard at about 1500 rpm (Or when the throttle is opened enough to get the revs up to 1500 rpm), it adds at least 15 degrees. The total advance was around 30 odd once the vac has kicked in. This must be made up off the 8 static + whatever the mechanical has added (maybe 4-6 ?) and the rest must be the vac.
I know that I run about 35 total when running flat out with the throttle wide open but I did not test that in the garage!


It looks like a delay in the vac would be a good idea!

Regards,

Pete

I found that the mech advance only added about 18 to the overall advance, without the vacuum attached. This is normal with most Rover dizzies, and needs fixing to get best performance.

Hi Paul,

The two dizzys that I've measured off the engine using a protractor both added more that 18 degrees. They had "14" stamped on part of the mech advance bob weights, this translated to 28 degrees at the crank. When you add the 8 degrees standard static to this you get the 34 degrees max that a standard 3.5l engine will run. The problem is that 8 static is rubbish!

I've now done a bit more work on my dizzy, it runs 14 static, 36 total all in at about 3k. I've made a mechanical stopper to reduce the total vac advance that can be added. I measured it to be 17 degrees but have reduced this to 10. I've only been out for a quick spin but the motor seems more "grunty".

The engine fires up alot quicker on the starter now as well.

The dizzys that you've looked at could easily be different to the ones that I've worked on and therefore may have had less mechanical advance.

Cheers,

Pete