Editing 383/388 Chevy stroker
(
diff
)
← Older revision
|
Latest revision
(
diff
) |
Newer revision →
(
diff
)
Jump to:
navigation
,
search
{{youcanedit}} ==Overview== A 383 is a 350 block bored +0.030" with a 3.750" crank. A 388 is a 350 block bored +0.060" with a 3.750" crank. The 383/388 SBC stroker has become one of the most popular engines in the history of the small block Chevy. The only engine that surpasses it in volume is the 350/355 SBC. The following article will help the new engine builder to better understand the details involved in building this powerplant. ==SBC dimensions== ===Block deck height=== All small block Chevy blocks are manufactured with the same measurement from the centerline of the main bearing bores to the deck where the cylinder heads bolt on. This measures 9.025" nominal. A nominal dimension is the targeted dimension, the actual dimension may vary a small amount from this, say +/- 0.005". This 9.025" dimension is called the '''''block deck height''''' (or just "deck height"). ==Parts stack height== When the various parts that make up the reciprocating assembly are selected, these parts have to fit into the SBC deck height dimension of ~9.025". When calculating the stack of parts that make up the reciprocating assembly, use the radius of the stroke, which is the same thing as 1/2 of the stroke, because only 1/2 of the crankshaft stroke swings ''above'' the crankshaft centerline. So for a stock 350 Chevy having a stroke of 3.48", use 1/2 of the stroke (3.480" times .5 = 1.74") to start putting the stack of parts together that will fit into the block. In a running engine, the oil clearance will create a slightly longer stack- a 0.003" rod bearing oil clearance will add something slightly less than 0.003". In this article, oil clearance will NOT be added into the stack height. If desired the oil clearance may be added; easiest way to do this would be to either add the oil clearance to the rod length, or simpler yet, just add the oil clearance after the stack height is calculated. The added height from the oil clearance would only be an issue if the engine is being built with a marginal amount of quench (<0.035" for steel rods); if built with the "ideal" 0.040" quench, the oil clearance can be basically ignored. Another consideration is piston "rock". At TDC as the piston transitions from upward to downward movement, the piston will tip on its wrist pin. This causes one edge of the piston to be a small amount higher than the other edge. The exact amount will vary with how much piston to wall clearance there is; more clearance means more piston rock. Forged pistons generally have a looser piston to wall clearance than cast pistons, but newer design forged pistons have tighter clearances than was used in days gone by. This is another thing that's basically accounted for if a 0.040" quench distance is maintained. Only if less than 0.035" would this possible be an issue. The bottom line to all this is it's best to maintain an adequate quench figure of 0.040". There's nothing to be gained by going tighter, and a 0.040" quench distance will avoid unseen problems for the most part. If the quench is less than 0.040", be sure to double check clearances to be sure there is no contact between the piston and head- for obvious reasons. ==Piston compression height and piston deck height== Next, if using a standard 5.7" rod length, use a piston with a 1.560" piston compression height (measured from the centerline of the wrist pin to the top of the piston crown). Now, if we add up all the dimensions of our "stack" components, we find that we have room in the block for them, plus a little extra which will be between the crown of the piston and the block deck. 1.740" + 5.703" + 1.560" = 9.00". So, if there is 9.025" available and the stack is only 9.00", that leaves 0.025" space above the piston crown with the piston at top dead center (TDC). This space is called the '''''piston deck height''''' (not to be confused with ''block'' deck height). ==Stroke/rod/piston combos== To stroke the SBC 350 to 383 cid requires a crankshaft having a stroke of 3.750". This can be a production SBC 400 Chevy crankshaft with the main journals turned down from 2.65" to 2.45" to allow the 3.750" stroke crankshaft to fit into the main bearing saddles of a 350 block. Or it can be a specialty aftermarket crankshaft that has been manufactured with the 350 main journal size that will fit into the 350 block with no machine work at all. Now, we have a choice to make. The radius of the 3.750" stroke crank is 1.875" (3.750" times .5 = 1.875"). Common sense will tell you that if you retain the 5.7" rod length and the 1.560" piston compression height, that the additional length of the radius of the crank will push the piston out of the top of the bore at top dead center. (1.875" stroke radius + 5.7" rod length + 1.560" piston compression height = 9.135"). This puts the piston crown 0.110" ''above'' the block deck (remember, our block deck height is 9.025"). This much piston protruding from the bore would prevent the head from being bolted on, so something has to be changed to shorten the stack height so the parts will fit into the block. Most often this problem is solved by using a piston having a shorter compression height to compensate for the stroke increase. Using a shorter rod is not the desired way to make the change. Besides the unwanted change in the rod/stroke ratio and the side loading of the piston to the cylinder wall, using a shorter rod can cause the skirt of the piston to strike the counterweights of the crankshaft with the piston at bottom dead center. So instead of a shorter rod like the 5.565" factory SBC 400 rod, it is preferred to use at least the 5.7" rod combined with a piston made for this application having a compression height of 1.425". Now, the stack looks like this: 1.875" + 5.7" + 1.425" = 9.00" with a 0.025" piston deck height. This combination has been shown to work very well. Another way to do this is to use a longer 6.00" rod combined with a piston having a 1.125" compression height. So, 1.875" + 6.000" + 1.125" = 9.000". The piston deck height is still 0.025" with this combination of parts. Using a 6" rod also has advantages if internally balancing is going to be done; there's more room for the crankshaft counterweights. Some builders prefer not to use a 6" rod, their thinking being the pin intruded into the oil ring groove, meaning pinned rings or support rails must be used to allow the oil control ring package to do its job, and the added complexity isn't worth the possible advantages from a higher rod/stroke ratio and/or lighter pistons, etc. However, Ross offers a 383 stroker piston with a 1.120" compression height that doesn't require rail supports. The least expensive way to build a 383 stroker is to use an externally-balanced 400 harmonic balancer and a 400 flexplate/flywheel. Yet another option, although one of the least popular, is to use the stock SBC 400 rod with a 350 SBC piston. The stack of parts looks like: 1.875" + 5.565" + 1.56 = 9.00". The main complaint about using this combo is the rod length. ==Clearances== ===Rod to cam=== The rods that are most likely to be too clost to, or to contact the cam are cylinder numbers 1, 2, 5, and 6. Using a reduced base circle cam will not necessarily help- the clearances have to be physically checked for all the rods. ==A word on rod/stroke ratios== Most SBC engine builders agree the 5.565" rod/3.75" stroke ratio is borderline unacceptable at 1.48:1. For comparisons sake, a stock SBC 350 has a ratio of 1.64:1, and the 6" rod 383 stroker is at 1.6:1. The SBC 302 rod/stroke ratio is 1.9:1. It is generally thought that a ratio of 1.5:1 to 1.55:1 is about as low of a rod/stroke ratio that should be used in a performance build that will redline at 5500 rpm or more. ==Aftermarket parts combos== A popular parts combo for a 383/388 stroker is the Scat cast steel crankshaft and Scat I-beam forged Pro Stock rods. The Scat counterweights will clear the pistons using a 5.7" rod and the rods will clear the cam, so no grinding on the rods for cam clearance will be necessary. You may need to do a little grinding on the inside of the block at the pan rail to clear the big end of the rod, but it will be minimal. ==[[Quench]]== [[File:Squishband.jpg|thumb|350px||]] One way to arrive at a ~0.040" quench distance is to cut the block decks to zero piston deck height and to use a head gasket that compresses to around 0.040". This allows a quench (or squish, or "squench") measurement of 0.040". Squish is the high speed jetting of fuel air mixture from the dead zone opposite the combustion chamber. When the piston approaches top dead center, the clearance between the crown of the piston and the underside of the cylinder head diminishes to just short of a collision. This squeezes or "squishes" the mixture that is there, across the cylinder toward the spark plug. This high-speed jetting of the mixture not only eliminates any dead spots in the chamber, but also creates turbulence to achieve a more homogeneous mixing of the fuel/air mixture so that there are no lean or rich areas in the chamber. When using steel rods on a street/strip performance engine, having a tight squish of 0.035" minimum to 0.045"-0.050" will allow a high performance street/strip motor to run on pump gas without detonation, providing that all the other important areas are also covered, like the static and dynamic compression ratios. <br style="clear: both" /> [[Category:Engine]] [[Category:GM]]
|
Editing help
(opens in new window)
Template:Rounded
(
edit
)
Template:Youcanedit
(
view source
)
Personal tools
Log in / create account
Namespaces
Page
Discussion
Variants
Views
Read
Edit
View history
Actions
Search
Navigation
Main Page
Recent changes
Random page
Help
All articles
Start a new article
Hotrodders forum
Categories
Best articles
Body and exterior
Brakes
Cooling
Electrical
Engine
Fasteners
Frame
Garage and shop
General hotrodding
Identification and decoding
Interior
Rearend
Safety
Steering
Suspension
Tires
Tools
Transmission
Troubleshooting
Wheels
Toolbox
What links here
Related changes
Special pages
Terms of Use
Copyright
Privacy Policy
Your Privacy Choices
Manage Consent