The Stovebolt Site Forums The Shop Area General Truck Talk Jim G’s SLURP Project – Posting 10: DYNO charts, & I need YOUR suggestions

Jim G’s SLURP Project – Posting 10: DYNO charts, and I need YOUR suggestions!

This posting is one in a series. If you have not yet read the earlier postings in the series, you’ll need to, as this posting won’t make much sense without having done so! Just do a search using the word “SLURP”.

In my last posting, I described how Red’s actual road weight is, after 53 years, almost exactly what GM claimed for him as manufactured.

In this posting, we are going to take a brief, but very critical look at the actual GM-published dyno charts for 1950s era trucks. Then, we’ll see how Red’s actual dyno chart compares to the factory numbers. Then I’m going to ask for YOUR help.

I have to warn you: you’ll be surprised just how modest the actual power output of 1950s trucks was when viewed in the cold hard reality of a dyno chart. Back then, pickup trucks weren’t built to accelerate impressively. They were built to work, and to work mostly at low speeds. Truck drivers only cruised at 60 mph in their dreams; most cruising was done at 45 mph or less, as the road infrastructure was simply not good enough to support higher sustained speeds. In addition, our forefathers were practical people, and the power curves of our forefathers were weighted towards high torque directly off idle, so that trucks carrying heavy farm loads, on unimproved ground, could get underway even uphill, from a standing idle start.

With that warning, let’s take a look at the first dyno chart below, which compares a sampling of the most prevalent engines found in 1950s Chevy trucks:

The 1948 216 cubic inch inline 6 used when the Advance-Design series was introduced

The 1954 235 cubic inch inline 6 that was standard equipment for the last couple years of AD series truck production. Note that this engine, souped up via a 3-carburetor intake, dual exhaust, and cam change to 150 gross hp, and renamed “Blue Flame”, also powered the 1953 and 1954 Corvette!

The 261 cubic inch inline 6 used from around 1954 to 1962 in heavier model Chevy trucks (not in pickups), and that everyone who has an AD pickup with 216 or 235 engine lusts after (a 261 bolts right in – if you can find one in decent or rebuildable condition)

The 302 cubic inch GMC inline 6 used in heavier model GMC trucks (not in pickups). I am including this one to show you how little difference there was between this “big truck” engine and the 261.

Note that Chevy did not offer a V8 in its pickups until 1955 2nd edition (the new Task Force series). That was also when the Corvette got the V8.

Take a good look at the first dyno chart with the “crank horsepower” power curves. Note:

- The STRONGEST engine of the 4 makes only 150 crank hp (unrealistic gross crank hp in fact, by today’s standards), and the weakest makes only 90

- 3 of these engines make their peak power by 3500 rpm, and only the “hotrod” 261 peaks higher (at 4000 rpm)

- The graph does not show it directly, but if you run the numbers using the fixed mathematical relationship between horsepower and torque, all these engines make their peak torque by 2000 rpm

- All these engines make incredibly strong torque right from idle speed – typically at least 80% of peak torque even at 500 rpm

- The hotrod 261 makes 60 more peak hp than the 216, and at higher rpm the gap between them hits 70 hp! These two engines are WORLDS apart

- The 261 is also very much stronger than the 235 – much more than the 11% displacement difference would suggest

- The 302 GMC is stronger than the 261 by a few horsepower up to about 3250, but then runs out of air while the 261 keeps going. Hotrodders assuming that the GMC offers much more power than the 261, because it is 16% larger in displacement, take note

- Note that all of these engines, in their original factory usage, run much higher engine rpm at 60 mph than modern engines do. For example, on the AD pickup trucks, 2700 to 2850 rpm is typical at 60 mph, with either manual or automatic transmission. This puts the engine in the “meat” of its powerband at highway speed

http://i252.photobucket.com/albums/hh16/JimGnitecki/Stoveboltdynochart-crankhp.jpg


Now take a look at rear wheel versus crank horsepower. Again, you might be shocked at how much lower these numbers are than in the “crank hp” chart. Chevy published detailed dyno charts (which I used to construct these composite charts), and included “crank” power curves (engine with NO accessories or exhaust restriction), and also “net” power curves (engine with standard accessories and simulated vehicle exhaust). What they failed to mention, except in section 10 page 7 of the “Chevrolet Truck Data Book”, subtitled “Specifications Catalog for Chevrolet Salesmen”, was that there was an additional 10% loss going through the transmission and rear axle – and that was the BEST case, where a manual versus automatic transmission was used.

Furthermore, the 10% drivetrain loss applies only to top gear where the drive through the manual transmission is 1 to 1. In 1st through 3rd gears, Chevy told the salesmen to use 15% loss.

With an automatic, the loss is of course far greater. On a modern automatic, the additional loss is about 9 to 10%, but that is with a transmission that has a modern torque converter. The early 1950s Hydra-Matic, like in Red, has far greater losses, due to a simple fluid coupling versus torque converter, and other shortfalls compared to a modern automatic.

This next chart shows the rear wheel power actually delivered, in top gear, with a manual transmission. Note that:

- NONE of the engines actually delivers more than 120 rear wheel horsepower, even with a manual transmission, and even in top gear. The 216 barely breaks 70 rwhp.

- The GMC 302 has proportionately less loss via accessories and drivetrain than the 261. I don’t know why this is so

http://i252.photobucket.com/albums/hh16/JimGnitecki/Stoveboltdynochart-rwhp.jpg

And, here is the exciting next chart – the one showing Red’s actual rear wheel power curve superimposed in bright red onto the chart.

Your first question might reasonably be, “Hey, I thought Red has some “goodies”, like the dual Carter Offenhauser intake, the split Fenton exhaust manifold, true dual exhaust, and an aftermarket cam (The Bulldog cam). Why is he barely beating out the stock 261, and only in a narrow rpm range?”
The answer is simple: First, his cam was selected by his previous owner for its torque, not its peak power (although the torque peak is at a “hotrod” 2700 rpm or so!). More importantly, Red has that early “fluid coupling” automatic transmission, that is costing him at LEAST an extra 10% driveline loss, probably more. In fact, GM proactively upped the power of its engines in automatic-equipped cars in the early 1950s for precisely this stated reason.

There are also two more reasons, which we’ll discuss below.

Note that even with the penalty of the automatic and a cam that peaks 500 rpm lower, Red is still the power king in this humorous comparison. Sort of like saying that Dustin Hoffman is taller than Tom Cruise.

However, when we look at the power curve for a modern Chevy SSR – even one with the weaker 300 crank horsepower engine versus the 400 hp LS2 engine – even AD superstar Red starts to look really pale. See how that purple SSR curve absolutely dwarfs every other curve on this chart?

The numbers beside Red’s curve and the SSR’s curve are the APPROXIMATE rear wheel horsepower at 60 mph (The software would not let me select precise points that were not included in the original data array used to build the graph).

http://i252.photobucket.com/albums/hh16/JimGnitecki/Stoveboltdynochart-rwhpplusRedplusS.jpg


And, next in all its glory, is Red’s individual dyno chart, complete with air-fuel ratio readings.

You can see that Red runs lean at full throttle. That 14 to 1 air-fuel ratio at full throttle should be more like 13 to 1 for best power and a more cool running engine. I’ll need to find a senior mechanic who remembers how to change the main jets in these Carter Webers and hasn’t yet retired . . .

I should also point out that the testing was done on a dyno that consistently tends to yield conservative numbers. For example, that dyno believes that the rear wheel horsepower of a 6-speed Corvette with LS7 427 cubic inch engine is only 407 rwhp STD or 400 SAE (the two standards differ due to different “standard” ambient condition assumptions), out of an engine that delivers 505 crank horsepower and has a manual transmission.

Disregard the text on the graph that says maximum torque was 203 rear wheel ft. lb. That was just the fluid coupling spiking when Daniel the dyno operator hit the gas. The real peak was 195 ft.lb. at the rear wheels, at a surprisingly high 2700 rpm.

Peak power was at 3700 rpm, but stays above 100 rwhp even at 4500 rpm, where we terminated the testing out of respect for the 53 year old drivetrain. This explains why Red can peg his 90 mph speedometer, while AD trucks with less generously endowed engines struggle at highway speeds.

http://i252.photobucket.com/albums/hh16/JimGnitecki/Reddynorun2008-01-09run2.jpg

Ok, so with results so underwhelming, why do these Advance-Design series trucks NOT feel really weak on the road?

The answer is in the shape of the power curves and in the gearing the designers specified.

The low rpm biased torque curve, with strong torque right off idle ensures that these trucks always have enough grunt to handle the load. The steep gearing – typically close to or even exceeding 3000 rpm at 60 mph – ensures that the trucks are right in the meat of the power curve at moderate highway speeds. In fact, Red runs 2825 rpm at 60 mph, and you can see he is making close to 111 hp at the rear wheels at that speed despite the automatic tranny.

To put that in perspective, ANY stock Chevrolet SSR – whether the 300 hp 03/04 version, or the 400 hp 05/06 version, with either manual or automatic transmission, and any recent Corvette, delivers far less than this kind of rear wheel power at 60 mph. The 300 hp 03/04 SSR version in fact delivers, as shown in the graph, only 64 rwhp at 60 mph (actually a bit less, as this 64 hp is at 2000 rpm, and the gearing results in only 1800 rpm at 60 mph). This is because the modern vehicles run very low engine rpm at 60 mph in a misguided CAFÉ-driven effort to squeeze out the best fuel mileage possible, even though the loss of mileage with 10 or 20% more rpm would be very modest (I have run the tests and have the data).

Red’s strong highway performance is evident on hilly 70 mph Highway 71 that connects our home in Spicewood with the city of Austin, Texas. There, Red is pretty oblivious to the steep hills. He NEVER downshifts from 4th to 3rd, even on the steepest hill where semi-trailer trucks crawl.

Keep in mind the historical perspective too. Remember, a 1953 or 1954 Corvette had a 150 (gross) hp version of the 235 cubic inch engine covered above, used a Powerglide automatic transmission, and was only 10% lighter (truly!) than a stock AD truck of the same model years. The Powermatic was a TWO-speed automatic, so it is conceivable that an enterprising hotrodder who installed a 261 in his AD pickup truck and kept the manual transmission, could have provided a heck of race to a Corvette owner!

Of course, the flip side of all this is that with his current powertrain, Red can’t really accelerate “briskly”. A weight to power ratio of 29 pounds per horsepower isn’t exactly a prescription for “lively” acceleration. In fact, I’m pretty sure that if I ever race my wife in her Honda Civic, she’ll win. 

Of course, we intend to fix that . . . via a new powertrain.

And here is where I need YOUR help. I need suggestions on what that new powertrain should be.

Now, every one of us is an individual, and places different emphasis on different factors when choosing a powertrain. In my case, I want to (a) honor the SLURP project parameters, and (b) I want to show some respect for both American automotive history and Red’s history. By (b), I mean try to come up with a powertrain that at least tips its hat to the approach that a 1950s or 1960s hotrodder might have taken, rather than simply saying “pick the first solution that looks like it will work regardless of how modern it might be”. A simple example of this is that we should prefer carburetion versus electronic fuel injection, and a cold air intake would look way wrong.

So, here are the ground preferences I’m starting with (subject to change of course if there are compelling reasons!):

- Simple and practical versus complex, with minimized maintenance and minimized opportunities for parts failure

- Lightweight within reason – a lighter powertrain not only reduces overall vehicle weight, but also would improve the current skewed weight distribution between front and rear

- NOT pretentious and not “bling”

- Retro superficial appearance within reason

- Carburetion would be preferred versus injection

- Automatic transmission for three reasons: simplifies the installation engineering, allows me to keep the priceless factory column shift (I just love it!), and enables seating 3 versus 2

- American engine and transmission – foreign is just plain wrong for this truck and this project

- GM versus Ford or Chrysler if possible, just because it’s sort of wrong to put a Ford or Chrysler into a Chevy!

- I’ve already determined via computer simulation that we need at LEAST 300 crank horsepower to attain the performance needed to qualify as a “street rod” in a modern street environment, even with Red’s low vehicle weight

- Reasonably small physical engine size, since I am trying to keep the original front crossmember, beam axle, steering setup, undented firewall, etc.

- Reasonably practical and minimized cost installation effort

- Choice of automatic transmission depends to an extent on power curve of the engine: overdrive (e.g. 700R4) if a “low revver”, and non-overdrive (e.g. Turbo Hydramatic) if a “high revver”, in order to prevent top gear “feebleness” at 60 mph

- MUST be suitable as a “daily driver”!!

- NO provisions needed for power brakes or power steering (both will remain manual), but we need to support air conditioning (hey, it’s Texas!)

- We need either more displacement or more rpm to make more power, and since displacement is cheaper than high rpm capability, higher displacement normally has a cost advantage. BUT the package must FIT into the vehicle honoring the above restrictions on size and ease of installation

- An engine type readily available in either salvage yards or in the used market is a big plus, since cost would be appreciably lower than an engine bought brand new, or one that needs to be specially built up. Budget constraints make a brand new engine a less attractive option

- Assume that Red will end up weighing about 3000 pounds or less. I say this with confidence, because I’ve already found 340 of the 490 pounds of reduction needed to hit 3000 pounds

Now, keep in mind that we don’t literally have to meet ALL the above preferences. We would like to meet as many as PRACTICAL, while keeping both cost and ease of implementation reasonable.

What do you suggest? Let me hear your ideas!

Jim G

p.s. Yes, I realize it is a pain to look at the analysis text while having to separately go to the graphs at Photobucket and print them out. This website's policy prohibits use of embedded graphics for bandwidth reasons. I need to abide by that limitation. jg

My suggestion is to sell the truck to someone who appreciates it the way it is.

I don't know how many of the slurp parameters it violates but I've always wondered how a chevy 348 transplant wood do in an advanced design truck.

Per Wikipedia:
"The "W" (i.e. the 348 and its 409 and then 427 derivatives)had a dry weight of approximately 665 lb (300 kg), depending on intake manifold and carburetion, and was a physically massive engine compared to its small block predecessor."

So, this engine would ADD weight and would almost surely be a bear to install into an AD truck!

Sure would be nostalgic though . . .

Jim G

So would a good running 235-250. And either would be simpler to install. I have to admit here, Jim, that you lose me with the sheer volume of information you provide, because an LS-1 has no place in a working truck - in my not-so-humble opinion - and SSR's do not interest me. You're doing an impressive amount of research, to be sure, but I can't see where some of the directions you are taking would be practical or advisable. Not for me. Then, too, there have been people who have occasionally expressed their belief that it is not actually all about me. Go, figure.

Cosmo!!

Less than one week ago, you said, right in my earlier posting:

"I hope this study ends up with a discourse in the lightest, most efficient engine for an AD truck, let's say the 4 cyl Mercedes that they're placing in the Freightliner 3/4, 1 ton vans"

and now, you say, just leave it alone???

What happened?

I DID warn you in my reply to your posting that each of us sees things a bit differently. I LOVE Red, but I would prefer a bit more power for our highway environment here in Texas.

By the way, Red IS my new daily driver. The SSR is going to be sold.

Jim G

Hotshoe36: I didn't think I would be asking anything "narrow" in asking folks for ideas on what engines might be simple, reasonably powerful, practically installable, somewhat retro or nostalgic in appearance, and relatively low weight!

Aren't we ALL looking for variants of this, with different individual degrees of emphasis on the various factors I mentioned???

You might be surprsied by some of the outcomes. For example, after I modified and sueprcharged my Chevy SSR's 5.3 liter (327 cubic inch) engine to 575 to 600 crank horsepower, AND regeared from 3.73 to 4.56, my gas mileage at 60 mph, on hilly Texas 4 lane highway is still OVER 20 mpg! And that's hauling 5100 pounds (includes the SSR, the blower, 1/2 tank gas, and me).

As for those LS series engines not ebing suitable for a work truck, are you aware that for several years now, ALL Chevy V8 pickup trucks use LS series engines variants? They are disgusied with different "initials" than "LS1" (like LM4, LQ, etc), but they are ALL LS series engines. Check it out.

If you read the history of the LS series, you will find that GM's target right from the beginning of design was a new TRUCK engine series that would be lighter and more powerful. The Corvette was merely the first usage because it is low volume, and GM did not want to install a brand new engine in its bread and butter vehicles (its trucks)the first year or two, until it had some actual "customer usage" experience with no unexopected failures. I'm not kidding. Read Will Handzel's book.

You guys on this board simultaneously "discovered" the almost perfect TRUCK - the AD series - when you discovered that neat Stovebolt engine. I like the Stovrebolt engine, but I LOVE the AD truck, and I keep imagining it with just a few mods that take out some old fashoned, unneeded weight (like 142 pounds of steel leaf springs for good ness sake!!) and add just a reasonable amount of engine power beyond what a Stovebolt can deliver and stay reliable.

I wouldn't make too many assumptions on where SLURP could end up. The AD truck is a wily old codger, full of surprises.


Jim G

How about a inline 292?
Doug

292 with a 200-r4 trans. Torquey motor, and with the right head mods makes good higher rpm power. dual carbs for looks and performance (4 bbl if you don't want the cool factor)

200 trans is plenty strong, lighter than the other ODs that will bolt to the standard chevy pattern, better gear ratios for your use and overall size is smaller/lighter.

You should wind up lighter overall than stock and with plenty of power, and if dressed right the six looks great.

This was someone else's logical conclusion.

I'll go for a tight, original, front end; and, an original all-new brake system; and, a 3.55 rear-end conversion; and, a Pertronix 6v electronic ignition; and, high-profile, truck radial tires; and, a 261 with dual-exhausts and dual standard carbs, and I'll cruise all day at 65-70 (done it), at 18+ mpg (with passing power to spare).

It's enjoyable to let someone drive my truck and then let them look under the hood and stare with dropped jaws at a period-correct engine with minor modifications.

Nonetheless, to each his/her own. I am enjoying reading your postings, Jim, but I think you are heading towards the truck in the link at the top of my post.

Tim

I am working on a simular project but I have not done near the research and don't have near the data.I don't have any ideas that will meet all your criteria but I am going to try and use a 3800 buick rwd out of a F body GM.I am new to this site and posted a forum about my project but got only one reply.If you like you can take a look at my post I wont bog yours down by repeating it.We have some of the same goals and your info will be helpfull to be if you dont mind comparing notes.I am not familiar with how this forum works,is it ok to converse through the forum or do I need to use personal email?

Tim: Naw, that Southern truck is way too modern. Look at that sissy interior in it!!

I want simplicity and metal.

Jim G

Wendell: We are probably looking at some of the same ideas. I considered the Buick 215 V8, which was later built by Rover in larger displacements up to 5.o liters. You cannot get enough power out of it I'm afraid. Even the larger Rover 4.8 liter version only gives 275 hp at the crank at max, and that's if you can use headers, whcih there might not be room for. You lose 25 hp or more if you have to go manifolds instead. And, that's the end of the development line - you are then maxxed out. And, the work to get one to that state is costly,as the sources are VERY limited.

The Pontiac 292 make a lot oif low rpm torque, BUT is also limited by its non-crossflow head to a max of about 250 crank hrosepower, unless you haev cubic money like Leo Santucci, and can build a crossflow head out of TWO smallbloack heads, and make enough power to push a Studebaker coupe to 10.02 and 136 mph in the quarter. LOTS of cost though, and definitiely not streetable.

I looked at a Pontiac 250 OHC inline six as well, and that is still technically a posibility, but since the maximum power ever produced by a factory version was 230 crank hp, and parts are VERY rare, and only 1 or 2 shops can build one, and the costs are HIGH, and the engine has a nasty habit of eating camshaft bearings that are milled right into the raw head (no inserts!), I am not sure if that leads to anywhere constructive.

Keep the ideas comning though. SOMETHING will connect.

Wendell: You can contact me at JimGnitecki@msn.com or 830-693-6860 to discuss!

Jim G

The jeep 4.0 inline 6 is another possibility. The engine design goes back to the sixties AMC 232.

A Tampa outfit is selling thru quadratec 4.6 stroker long blocks with 260 hp and 295 fp torque.

Here is the skinny on that Pontiac 250 cubic inch OHC engine as a possible solution, direct from Primatech, who specialzies in them:

"To meet your requirement of 300 crank horsepower, we would recommend a Stage 2 OHC Stroker. The stroker increases the CID from 250 to 271 or 275. With the stage 2 cam, some serious head porting and our OHC header, you should be able to get at least 315 FWHP on premium pump gas. Should you choose to run higher octane racing fuel, the HP number can go up - but that may be defeating the spirit of the rules. In order to exceed 400 HP, some form of forced induction would be required.

A normally aspirated. Turn-key, complete Stroker will run about $7500. Quite a bit more than the equivalent crate SBC. We have a customer running an OHC in his ’53 Sedan delivery. He is unable to run our header due to the body mount location in the engine area. Whether this is true or not of your ’55 pick-up remains to be seen. We can not predict your success with anyone else’s header(s).

Best regards,

Quenton Olson
Primatech Motorsports "

$7500 and busting a gut to hit the minimum 300 hp power level seems like a less than great solution. In addition, if this engine breaks, you don't get repairs or parts at the nearby GM dealer! Plus, these engines have a habit of eating camshafts with notable frequency, due to the way the OHC area is lubed.

Oh well, we asked and investigated, and that is what this step of the project is about.

Jim G

Hmm, 260 crank hp is a bit light in terms of target, and there is no practical opportunity with this solution for future building up to get more. I think I want either more right now, or at least the opportunity to get more later, if I am going to go to the trouble of engineering the engine swap!

Jim G

I'm like Desert Dog and Kenc. You didn't even mention the 292. Why? Too heavy or some other reason? What about a high performance 327 from about 1965? I think a carburetored one was available in a Corvette with about 340 hp. I had a '65 Impala SS with a 327/300 hp that ran good and got 20 mpg but the handling was so unaceptable that I only put about 11,000 miles on it before trading it off. I never again took my brothers' advice about what car to buy. Does the 350 that came out about 1967 meet your qualifications and is a small block 400 too heavy?. I am not a mechanic and have not devoted any study to the subject; just mentioning what seems to me to be viable answers that would give good performance and good gas mileage.

Have you looked into the inline 6 that GM is using in the current Trailblazer? I believe production started somewhere around 1998. It should fit physically into your truck, unlike a V8, and only comes coupled to an outo trans, your preference. I can't remember the specs on it, but the hp/tq is something like 250/275. These came out just after I sold my first tractor, a 55.1. I would have loved to drop one in. They are fuel injected, which adds some complication to the issue, but I believe well worth it in the end.

Devin

The 292 cannot be built to 300 crank hp without a set of VERY costly custommade crossflow heads. When I say costly, I mean COSTLY. The second disadvantage is that there is no weight reduction over the 261.

The Chevy smallblock is defintiely in the running, and a strong contender. Its just that if I go that route, I would rather buy a more RECENT model that can be made to look like the older ones via suitable rocker covers, carb setup, etc. But yes, the smallblock is defintiely in the running.

The 400 smallblock, or the 383 stroker smallblock, have even more torque than a 350, and no increase in weight. Their only disadvantage is higher cost than the 350. Very much in the running, depending upon cost available to me!

Devin: I would REALLY like this engine, if it did not require a complete computer, wiring harness, and army of sensors. That extra complexity is way outisde the SLURP mission statement. IF someone supported this engine in a carbureted versus injected mode, I would probably look at it seriously, even though it would require some work (cam change at least) to get to the minimum 300 crank horsepower on my wants list.

Jim G