Engine Balancing

Our Engine Balancing Equipment

Engine balancing goes hand-in-hand with performance engine building. Engine balancing reduces internal loads & vibrations that stress metal and may eventually lead to component failure. But is it worth the time & effort for mild performance applications, everyday passenger car engines or low-buck rebuilds?

From a technical point of view, every engine regardless of the application or its selling price can benefit from balancing. A smoother-running engine is also a more powerful engine. Less energy is wasted by the crank as it thrashes about in its bearings, which translates into a little more usable power at the flywheel. Reducing engine vibration also reduces stress on motor mounts & external accessories, and in big over-the-road trucks, the noise & vibration the driver has to endure mile after mile.

Though all engines are balanced from the factory (some to a better degree than others), the original balance is lost when the pistons, connecting rods or crankshaft are replaced or interchanged with those from other engines. The factory balance job is based on the reciprocating weight of the OE pistons & rods. If any replacements or substitutions are made, there’s no guarantee the new or reconditioned parts will match the weights of the original parts closely enough to retain the original balance. Most aftermarket replacement parts are "balanced" to the average weight of the OEM parts, which may or may not be close enough to maintain a reasonable degree of balance inside the engine. Aftermarket crank kits are even worse and can vary considerably because of variations within engine families.

If the cylinders are worn and a block needs to be bored to oversize, the larger replacement pistons may be heavier than the original ones. Some piston manufacturers take such differences into account when engineering replacement pistons & try to match "average" OE weights. But others do not. Most high performance pistons are designed to be lighter than the OE pistons to reduce reciprocating weight for faster acceleration & higher rpm. Consequently, when pistons & rods are replaced there’s no way of knowing if balance is still within acceptable limits unless you check it.

If you’re building a stock engine for a passenger car or light truck that will spend most of its life loafing along at low rpm, your customer might question the value of balancing such an engine. But if you the customer value durability & smooth operation, the decision to balance should not be to difficult.

On the other hand, if you’re building a performance engine, a stroker engine or an engine that’s expected to turn a lot of rpms or run a lot of miles, balancing is an absolute must. No engine is going to survive long at high rpms if it’s out of balance. And no engine is going to last in a high mileage application if the crank is bending & flexing because of static or dynamic imbalances.

Forces In Action

The centripetal force created by a crankshaft imbalance will depend upon the amount of imbalance & distance from the axis of rotation (which is expressed in units of grams, ounces or ounce-inches). A crankshaft with only two ounce-inches of imbalance at 2,000 rpm will be subjected to a force of 14.2 lbs. At 4,000 rpm, the force grows to 56.8 lbs.! Double the speed again to 8,000 rpm and the force becomes 227.2 lbs.

This may not sound like much when you consider the torque loads placed upon the crankshaft by the forces of combustion. But centripetal imbalance is not torque twisting the crank. It is a sideways deflection force that tries to bend the crank with every revolution. Depending on the magnitude of the force, the back & forth flexing can eventually pound out the main bearings or induce stress cracks that can cause the crank to snap.

Centripetal force should not be confused with "centrifugal" force, which is the tendency of an object to continue in a straight trajectory when released while rotating. Let go of the rope while you’re twirling the brick & the brick will fly off in a straight line (we don’t recommend trying this because its difficult to control the trajectory of the brick).

Back to centripetal force. As long as the amount of centripetal force is offset by an equal force in the opposite direction, an object will rotate with no vibration. Tie a brick on each end of a yardstick & you can twirl it like a baton because the weight of one brick balances the other. If we’re talking about a flywheel, the flywheel will spin without wobbling as long as the weight is evenly distributed about the circumference. A heavy spot at any one point, however, will create a vibration because there’s no offsetting weight to balance out the centripetal force.

This brings us to another law of physics. Every object wants to rotate about its own center of gravity. Toss a chunk of irregular shaped metal into the air while giving it a spin and it will automatically rotate about its exact center of gravity. If the chunk of metal happens to be a flywheel, the center of gravity should be the the flywheel’s axis. As long as the center of gravity for the flywheel & the center of rotation on the crankshaft coincide, the flywheel will spin without vibrating.

But if there’s a heavy spot on the flywheel, or if the flywheel isn’t mounted dead center on the crank, the center of gravity and axis of rotation will be misaligned & the resulting imbalance will create a vibration.

Applied Physics

With inline four & six cylinder engines, and flat horizontally opposed fours & sixes (like Porsche and Subaru), all pistons move back & forth in the same plane and are typically phased 180° apart so crankshaft counterweights are not needed to balance the reciprocating components. Balance can be achieved by carefully weighing all the pistons, rods, wrist pins, rings & bearings, then equalizing them to the lightest weight.

On V6, V8, V10 and V12 engines, it’s a different story because the pistons are moving in different planes. This requires crankshaft counterweights to offset the reciprocating weight of the pistons, rings, wrist pins and upper half of the connecting rods.

Internal or External

If you’re rebuilding an engine that is internally balanced, the flywheel & damper have no effect on engine balance and can be balanced separately. But with externally balanced engines, the flywheel & damper must be mounted on the crank prior to balancing.

You should find out what type of engine balance you have (internal or external), and be cautious about indexing the position of the flywheel if you have to remove it later for resurfacing. Owners of externally balanced engines should also learn about installing different flywheels or harmonic dampers and how it can upset balance.

Balance Shafts
In recent years, the auto makers have added balance shafts to many four & six cylinder engines to help cancel out crankshaft harmonics. The counter-rotating balance shaft helps offset vibrations in the crank created by the firing sequence of the engine.

On these motors, make sure the balance shaft is correctly "phased" or timed to the rotation of the crank. If the shaft is out of sync, it will amplify rather than diminish engine vibrations.

Balance shafts are not a substitute for normal engine balancing, nor do they reduce the vibration & stress the crankshaft itself experiences as it turns.

Balancing Act

Next the rods are weighed, but only one end at a time. A special support is used so that the big ends of all the rods can be weighed & compared, then the little ends. As with the pistons, weights are equalized by grinding away metal to within 0.5 grams. It’s important to note that the direction of grinding is important. Rods should always be ground in a direction perpendicular to the crankshaft & wrist pin, never parallel. If the grinding scratches are parallel to the crank, they may concentrate stress causing hairline cracks to form.

On V6 and V8 engines, the 60 or 90 degree angle between the cylinder banks requires the use of "bobweights" on the rod journals to simulate the reciprocating mass of the piston & rod assemblies. Inline four and six cylinder crankshafts do not require bobweights. To determine the correct weight for the bobweights, the full weight of a pair of rod bearings and the big end of the connecting rod, plus half the weight of the little end of the rod, piston, rings, wrist pin (and locks if full floating) plus a little oil are added together (100 percent of the rotating weight plus 50 percent of the reciprocating weight). The correct bobweights are then assembled & mounted on the crankshaft rod journals.

The crankshaft is then placed on the balancer & spun to determine the points where metal needs to be added or removed. The balancer indexes the crank and shows the exact position and weight to be added or subtracted. The electronic brain inside the balancer head does the calculations and displays the results. The machines we have use graphical displays that make it easy to see exactly where the corrections are needed.

If the crank is heavy, metal is removed by drilling or grinding the counterweights. Drilling is usually the preferred means of lightening counterweights, and a balancer that allows the crank to be drilled while still on the machine can be a real time saver.

If the crank is too light, which is usually the case on engines with stroker cranks or those that are being converted from externally balanced to internally balanced, heavy metal (a tungsten alloy that is 1.5 times as heavy as lead) is added to the counterweights. This is usually done by drilling the counterweights, then press fitting and welding the heavy metal plugs in place. An alternate technique is to tap the hole and thread a plug into place. Drilling the holes sideways through the counterweights parallel to the crank rather than perpendicular to the crank is a technique many prefer because it prevents the metal from being flung out at high rpm.

After drilling, the crankshaft is again spun on the balancer to determine if additional corrections are required. If the crank is for an externally balanced engine (such as a big block Chevy), the balancing will be done with the flywheel and damper installed. On internally balanced engines, the flywheel and damper can be balanced separately, or installed on the crank and balanced as an assembly once the crank itself has been balanced.

New machinery has been introduced that both simplifies the balancing process and increases the accuracy of the job. Electronic equipment that allows accurate measurement of not only the amount of unbalance force, but also accurately reports the unbalanced vector position is now available to engine rebuilders. Typically, balancing machines have assumed that the unbalance force was equally opposed, so they would require the technician to correct the excessive amounts of unbalance on the excess side to the point of making them equal. Technicians have had to ‘stair-step’ the corrections equally until the final tolerance was attained.

Technology such as that in the Hines HC 500 eliminates this requirement. Software and hardware are combined to allow radical differences to be reported at each end of the crankshaft (including any rotational positioning or vector position of the unbalanced force). Because the position and unbalance amounts are reported correctly the technician can make changes to the crankshaft with confidence that he will not over shoot the correction. In most cases the required cycles of analysis and correction are reduced by 80 to 90 percent.

The unbalance amount and position are imported into a special computer program called "Heavy Metal Analysis" (HMA). This program allows the technician to plot the position and amount of material that will be required to correct the crankshaft. The program lets rebuilders create multiple scenarios based on rotation and radius position, weight amounts and sizes of Mallory – all of which can be simulated without having to cut the first chip.

How Long?

Though a balancing accuracy of plus or minus one gram is typically good enough for most production street engines, many balancers today can achieve balancing accuracies in the tenths or even hundredths of a gram!

The most time-consuming part of the job is weighing and matching the pistons and rods. A four cylinder engine takes half as much time for this step as a V8. The next most time consuming part is making up the bobweights for a V6 or V8. This step isn’t needed with a straight six or four. The actual setup on the machine takes only a few minutes, and the initial spin and readings take only a couple of minutes more. The time required to perform the necessary weight corrections will depend on the crank (weight removal goes much faster than adding weight). And if you’ve done your work carefully, the final spin will require no further corrections because the balance will be right on the mark.

Prices

Most shops charge $150 to $225 to balance a V8. If heavy metal is required, add $40 to $75 per slug. Some shops charge less to balance engines, but these tend to be shops that are trying to compete in the budget rebuild market, not the performance market.

At RPM Machine we charge $185.00 for a standard V/8 and $195.00 for a V/6 (2 more bob weights). This price will take care of balancing a rotating assembly up to 40 grams out of balance. For peformance race engines and stroker assemblies that are farther out than this a price per hour will charged.

For more information or to schedule your engine for balancing please feel free to give us a call at 1-888-732-1595 and we look forward to helping you.