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Chevrolet Inline-6 Engine 1929-1962: How to Rebuild
Chevrolet Inline-6 Engine 1929-1962: How to Rebuild
Chevrolet Inline-6 Engine 1929-1962: How to Rebuild
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Chevrolet Inline-6 Engine 1929-1962: How to Rebuild

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Chevrolet’s inline 6-cylinder, affectionately known as the “Stovebolt,” was produced and applied to Chevrolet-powered automobiles from 1929 through 1962. Its effectiveness and simplicity greatly contributed to the lengthy duration of its life span, with the engine still being created in some capacity into 2009.

Deve Krehbiel of devestechnet.com has taken his decades of knowledge on the inline-6 and created the ultimate resource on rebuilding the Stovebolt Chevrolet powerplant. Using color photography with step-by-step sequencing, Deve takes you through the disassembly, rebuild, and reassembly of these engines, including rebuilding the carburetor, distributor, and intake/exhaust systems. Tech Tips highlight areas that can be overlooked, such as proper cleaning and determining if a part is reusable, and an appendix provides information on decoding casting numbers.

With millions of Chevrolets built with an inline-6 engine, there’s no shortage of candidates for a rebuild. With Chevrolet Inline-6 Engine: How to Rebuild, you will now have the perfect complementary tool to walk you through the entire engine-rebuilding process.

LanguageEnglish
PublisherS-A Design
Release dateNov 15, 2018
ISBN9781613255087
Chevrolet Inline-6 Engine 1929-1962: How to Rebuild
Author

Deve Krehbiel

Deve is a vintage Chevy pickup enthusiast and spends his free time making how-to articles and designing add-on kits for this vintage Chevy engines. DTN, or Deve’s Technical Network was created to help bring other enthusiasts together to brainstorm new ideas, new solutions, and help everyone obtain a better understanding of this wonderful pastime. For every kit he creates, he makes sure to document how you can make that same kit yourself without any money changing hands.

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    Chevrolet Inline-6 Engine 1929-1962 - Deve Krehbiel

    CHAPTER 1

    ENGINE IDENTIFICATION

    Whether you are looking to purchase a Stovebolt for your project or already have one, the most important first step is identifying everything you can about the engine. This will serve you well when ordering parts and perusing parts at swap meets. Again, the desirable years are 1954–1962 with the 1958–1962 being the most desirable because of all the lessons learned by Chevrolet through the years. I encourage you to hold out for those years and purchase the newer engines wherever possible; however, there is more to an engine than its birth date.

    Casting Numbers

    The first place to start when researching information on an engine is a list of GM casting numbers in the appendix. It is an accumulation of data that has been updated over the years, so you should have no problem finding your Stovebolt in the list.

    On the distributor side of the engine there is a treasure trove of information about the engine. Casting numbers appear just below and to the right of the distributor on the passenger’s side. They are notoriously hard to read, and people sometimes mistake a 3 for an 8. Clean the area thoroughly and use a bright flashlight. This is usually a seven-digit number and each letter/number is about 1/2 inch tall. A little engine degreaser and a wire brush often makes reading the casting number easier.

    You may find road grime and buildup that fills in the numbers. You can use a good engine degreaser on a shop towel to clean around these numbers. It’s worth the trouble. Be sure to write down these numbers. Later, when you need parts, you will be glad you did.

    Under the hood, the distributor’s vacuum advance can often obstruct the view. It’s easier to confirm this number from underneath the vehicle. This is the engine’s main casting number.

    Here, CON3 indicates the conveyor number that the engine came from. The numbers beside it are important for the exact date that the engine was manufactured. Also, of interest here are the captains bars above the starter. Most of the time, with few exceptions, this indicates that the engine is a 261.

    The next numbers you need are the ones just below the starter on the passenger’s side: the conveyor number. Beside that is a usually four-digit letter/number combination separated with spaces like this: X XX X. For example, the first X is a letter from A through L (A for January through L for December). The center two digits represent the day of the month. The final digit represents the year that the engine was made within the years represented by the casting numbers below and to the right of the distributor.

    The next set of helpful numbers are on the flat part of the distributor deck. This machined area has serial numbers stamped into it. If you have looked very carefully and found no numbers, chances are that your block is classified as a replacement block and has no numbers stamped on that deck.

    The flat part where the distributor is mounted is the deck; it was used to stamp the particulars concerning the original vehicle where this engine was originally installed. This information makes a difference in obtaining parts because most cars had hydraulic lifters and trucks had solids.

    The characters you are looking for are stamped (about 1/4 inch high) and usually have a letter followed by three numbers and ending with another letter (or two). The first letter is almost always F because most GM engines were made in Flint, Michigan. The following numbers represent the month followed by the day of the month. The final letters denote the vehicle in which the engine was originally installed.

    Serial Numbers

    A stamped serial number appears on the flat part of the distributor deck. The first letter is either F for Flint, Michigan, or T for Tonawanda, New York. These were the two locations where engines were manufactured at the time. The numbers following the F or T designate the calendar month and the date the engine was produced. The remaining letters are in accordance with the type and series of the vehicle. This helps to tie the vehicle together with the engine. Regular production orders (RPOs) were standard orders that could include many variables, and Chevrolet had several of them that were popular with dealers. (The appendix includes the car and truck listings for 1954–1962.)

    Head Casting Numbers

    The head also has important casting numbers. In my research, I found very little information for heads manufactured between 1954 and 1962, but I found the three most popular. The head casting number is located outside the valve cover in plain sight on the driver’s side. If you have heard that the new-style 235 gets better compression numbers with an 848 head and that’s important to you, look for those as the last three numbers of that casting number.

    Without removing the valve cover, the head’s casting number is clearly stamped just before the carburetor. The rest of the head’s information can be obtained by removing the cover. This is one of those infamous high-compression 848s.

    Here are the head casting numbers that I can verify, so this is a short list:

    •  3835913 1954–1955 235 engine

    •  3836848 1956–1962 235 engine

    •  3836850 1956–1962 261 engine

    The acorn nuts have a rubber grommet under them with a metal washer. Notice the slits in the valve cover that allowed underhood road grime into the engine. It’s best to close those up and use a vented cap.

    With the casting information, you should be able to decipher everything General Motors recorded about your engine. This is invaluable in determining what engine parts you need for your rebuild.

    Visual Differences

    You see a few telltale differences when perusing listings of engines during the purchase or selection process. These differences help you determine the correct Stovebolt era in which the engine was made.

    Below the distributor is the casting number, 3764476. This engine was built between 1959 and 1962. Just above the starter is CON3 (the third conveyor at the factory) and B 28 9. The first letter corresponds to its month, A through L (A for January, L for December). B is February, 28 is the day of the month, and 9 is the year. We now know this engine was built on February 28, 1959.

    Now let’s look at the serial number that is stamped on the flat part of the distributor deck. That number is F302B. The F means that the engine was made in Flint, Michigan. The 3 indicates the third month, March. The 02 signifies the day of month. The B stands for the model/series of the car engine with Powerglide (hydraulic lifters).

    So, March 2, 1959, is the date! When you stop to think about it, the line must have been busy at the time because the serial number only lagged the casting of the engine by two to three days.

    The head follows a similar numbering scheme. On the driver’s side on the outside, not covered by the valve cover, is the casting number; in this case 3836848. It indicates that the head was made between 1955 and 1962 and was used on cars and trucks. Just inside the valve cover in almost the same location is another clue: CON9 (the ninth conveyor at the factory), and about four springs to the right of that is another number H 3 0, which is the date that the head was made, August 3, 1960.

    So, this probably isn’t the head that originally came with the engine, unless the engine sat on a shelf for about 18 months. When you see a casting number ending in 848, you know you have the highest-compression head Chevrolet made for that engine. ■

    The year 1953 was a transition for Chevrolet. In early 1953, cars were equipped with the older-style engine; in the latter part of the year, some were equipped with the newer style as the factory ran out of old parts. The factory did not start everything new at the beginning of a year. So, some 1953 cars had the new engine, some did not. As far as I can tell, all 1953 trucks came with the old-style engine. This is why I use pre- and post-1953 to describe these engines. ■

    The coil was mounted in the center of the engine until late 1953. At that time, Chevrolet located the coil between cylinders number-4 and number-5. This is a 1950 216. You know it’s an earlier engine by the long side cover, short cap distributor, and acorn nuts holding down the valve cover from the top.

    Notice the space between the center of the harmonic balancer and the center of the fan. It is considerably more than the post-1953 engines. Prior to 1953 all the engines had 5/8-inch-wide belt pulleys.

    Pre-1954 216/235 Engines with Babbit Bearings

    •  Two acorn nuts on the top of the valve cover holding on the valve cover

    •  A side cover that extends from above the spark plugs, all the way down to the oil pan

    •  A water pump arrangement that centers the fan on the radiator (this is on the vehicles that the engine came with due to a taller radiator)

    •  A short cap distributor

    •  A horn mount on the intake manifold

    1954–1962 Engines with Modern Insert Bearings

    •  Four screws at the base of the valve cover to hold it down

    •  A short side cover

    •  A lower-set water pump

    •  A tall-cap distributor

    There are other much-less-noticeable differences, such as carb style, generator, and starter differences, but these are the best identifiers of the era of the engine.

    The short cap distributor cannot use a tall cap because the internal shaft is too short. This prohibits installing HEI, but other than that, the distributors are interchangeable.

    Post-1953 intake manifolds have the knob sticking out for mounting the horn, just no holes drilled.

    It is easy to put an older-style valve cover on a new-style engine because the rocker assembly bolts are in the same place. It is not recommended, however, because they tended to leak more. If you want to preserve the shape of the holes, be sure to add reinforcements.

    Engine Condition

    The project engine for this book was completely unknown to me. It was sitting in a garage, all taken apart in boxes. I had no idea where each specific lifter was located when it was running nor the condition of the engine. This was good for documenting because you can’t take anything for granted.

    In your case, you might have a good reason for rebuilding it. One good indication that an engine needs a rebuild is excessive blow-by. This is obvious by the amount of visible smoke that comes out of the valve cover cap. There shouldn’t be any. This could be valve adjustment, worn piston rings, or worn cylinders. Another obvious sign of wear is low oil pressure at idle.

    Compression Testing

    If you have a desire to know the overall health of your engine, a good place to start is with checking the compression. A few things contribute to low compression, such as piston ring wear and valve issues. Purchase a compression gauge kit. It will come with all the connectors and fittings that you need. The following is a quick procedure that works well.

    The side cover is much shorter, starting below the spark plugs, than in previous years. This is a better design. Chevrolet made many subtle changes between 1938 and 1962.

    With the ignition switch off, remove all the spark plugs and the distributor cap. Prop the throttle wide open to get the most accurate reading. Screw the fitting into the number-1 spark plug hole until the rubber O-ring squashes just a bit. Turn the engine over (with the starter) long enough for the compression gauge to register the compression number of the cylinder. Keep cranking until the gauge needle stops rising. This is important. Record the number, release the gauge’s pressure (small pushbutton on the gauge), and do it again to make sure it’s reading very close. Do this on every cylinder, one at a time.

    They need to be within 5 percent of one another. Any numbers above 95 psi means that the engine is okay and will run well. Compression as low as 65 psi should be okay but may smoke and idle poorly. With a new engine, they are in the 130 range.

    The tall-cap distributor has a taller cap and a taller internal shaft. Also, the rotor is taller, so those parts are not interchangeable with the pre-1953 distributors.

    On the 261 engine I recently worked on, the measurements were number-1, 140; number-2, 137; number-3, 138; number-4, 137; number-5, 137; and number-6, 138.

    Flywheel Identification

    The flywheel is something you don’t automatically think of as a big deal; however, these engines are in the transition years, so be careful. Chevrolet introduced the 12-volt system in 1955. Prior to 1955, everything was 6 volts. Why this matters is because the 6-volt starter had a different gear pattern, and the flywheel had 134 teeth on the 6-volt starter version while the 12-volt version of the same flywheel has 168 teeth.

    To add to the confusion, the starter gears both have the same number of teeth, but the pitch is different. I am really talking about the flywheels’ ring gear; however, unless you want to remove and replace a ring gear, the difference is insignificant. Be sure to count the teeth on the flywheel so you know which starter to purchase.

    The flywheel’s ring gear is the issue here. It is relatively easy with heat to remove a ring gear, but finding a replacement is the problem. Most of us just replace the entire flywheel when necessary. Don’t skip over the fact that you can turn the ring gear around to get fresh gear meat for the starter.

    Due to the concern of unwanted combustion, make sure the ignition is off or the distributor cap is removed before attempting anything that requires removal of a spark plug. Safety first always!

    Even if someone has upgraded your vehicle to 12 volts, it may still use a 6-volt starter. I prefer the 6-volt starter because to carry double the current of 12 volts, the windings are beefier. You won’t hurt a 6-volt starter if you use it for the normal short periods of time it was designed for.

    Is It a Rebuild Candidate?

    Here I am talking about the quality of the engine candidate. Is it worth the considerable expense to rebuild? Do you see visible cracks in the water jacket or anywhere else? Do you have any documentation that would lead you to understand the cylinder bore size that was done at the last rebuild?

    The best years for Stovebolts are 1958–1962. Think of Chevrolet as a company with technology that is constantly evolving. The Holy Grail of Stovebolts is the 1958–1962 261 engine. It is the same physical size as the 235 with about 40 more horsepower due to its larger displacement. It also has native full-flow oil filtering. Keep in mind that any Stovebolt after 1953 is considered the best 6-cylinder engine for that vintage. Another major factor is engine wear. You do not want to purchase an engine that is bored .060 over because it is reaching the end of its life. You also do not want to purchase an engine with cracks or casting issues. ■

    Sometimes the piston has a number stamped on the top face of it. You discover something very important when you remove the head of an unknown engine. You should wire brush away the carbon and dirt from the center of the top of the piston. A number such as .010, .020, .030, etc., stamped on the piston, tells you the last cylinder bore size. If it reads .060, you are getting very close to the last bore size that is available for these cylinders. This may be a prohibitive factor for you because it costs just as much to do the first overbore as it does to do the last.

    Organization Is Key

    The engine for this specific rebuild has hydraulic lifters. I like that, even knowing that an argument could be made that they cost horsepower because the engine is very quiet and runs very smoothly without much adjustment. In the box of engine parts, I found the 12 lifters for this project. Three of them are missing the retainer springs and the caps, and there is stuff all over the bottom of the box.

    A compression tester costs about $25 at your local tool store, and it is well worth it so you know you have good compression. In the United States, the inside scale is used because you are reading PSI.

    Because hydraulic lifters are expensive, I’d like to save them. After a little research, I learned that I could take them to a machine shop and have them surfaced so that they run against the cam as good as new. I will not use them if the machine shop expert recommends that I buy new ones.

    Since I am doing a complete rebuild and do not care about the current timing of the engine, I removed the head, distributor, plug wires, spark plugs, coil, road tube, starter, generator or alternator, water pump, carburetor, intake and exhaust manifold, valve cover, and lifter side cover. I organized these subsystems carefully, keeping the hardware separate. I separated the hardware, putting things in labeled bags. And the fun soon begins!

    CHAPTER 2

    TOOLS AND ENGINE CLEANING

    You don’t need anything this fancy, but the roll-cart on the right contains a battery, a set of gauges, a fuel delivery system, and a safety switch for rolling up to any project and providing the necessary power. See devestechnet.com/Home/StartKartPlans for the plans to make your own version.

    There are many tools required for this job. As I address each system, I will add to it. One important tool for this job is the shop manual for the year of your engine. Remember, the shop manual for your vehicle may be different from the one for the engine if the engine has been replaced. You can purchase a copy of the shop manual from many sources.

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