- Joined
- Apr 27, 2012
- Points
- 100
Understanding Torque & Horsepower
Torque and HP are the primary measurements used to describe the power output of an engine. Torque is expressed in ft/lbs and is a measure of the engine’s twisting force exerted on the crankshaft from combustion. Horsepower, which is derived from torque, is specifically a measure of how much torque the engine produces in one minute divided by 5252. Therefore, the HP formula is:
HP = Torque x RPM (Revolutions per Minute) ÷ 5252
Both HP and Torque are measured either at the Flywheel using an Engine Dynamometer or at the rear wheels using a Chassis Dyno.
How MM Engines Generate Power
Basic engine components are the block (pistons, rods, crankshaft) topped off with the head (cam/s, valves, valve train parts, etc).
The fill capacity (air and fuel mixture) of the Block’s cylinders, is what provides Torque while it’s the Head’s air intake that governs HP.
We use five techniques for modifying engine power! The first three occur in the block and the last two in the head.
1. Lighter Reciprocating Mass (piston, piston pin & rod)
2. Larger Displacement
3. Increased Compression Ratio
4. Improved Head Flow
5. More Camming
1. Lighter Reciprocating Mass
Weight is the enemy of acceleration! For example, in a BMW E36 M3 engine, turning 7000 rpm, the piston starts from the top, accelerating to 100 mph by 75° after TDC, then starts to decelerate and stops at the bottom. The piston starts and stops 14,000 times a minute over a distance no wider than your fist, 3.5″ or 89.6mm. The reciprocating mass squares with RPM. For instance, from 2000 RPM’s to 4000 RPM’s, the RPMs are doubled but the engine recognizes a FOURFOLD increase in the Reciprocating Mass! If the RPM’s are doubled again to 8,000, the Reciprocating Mass is 16 times greater than at 2000 RPM’s. This is why we take Reciprocating Mass so seriously and strive to reduce it’s weight through lighter components. The Reciprocating Mass in our engines is 15% – 40% lighter than stock. This reduction spools up the crank quicker and increases the reliability of the engine – less reciprocating weight (piston and rod going up and down) to tear up the engine over time.
2. Larger Displacement
Larger displacement is accomplished by boring the block and increasing the crankshaft stroke. Displacement is a direct ratio of torque output meaning, a 10% increase in displacement results in a 10% increase in torque. Boring an engine is usually the most cost-effective way to increase displacement without increasing piston speed – which increases wear. Boring a cylinder out by 1mm, equals adding 2mm to the crankshaft stroke. At MM, we typically stroke an engine by installing a crankshaft with a longer stroke. In a few cases, we offset grind the crank.
3. Increased Compression Ratio
A simplified definition for Compression Ratio is: a measure of the entire Cylinder Volume plus the Combustion Chamber Volume divided by the Combustion Chamber Volume. Increasing the intensity of the combustion chamber explosion is accomplished by increasing the compression ratio. At Metric Mechanic, we normally increase the Compression Ratio by 1.5 to 2 points. For example, in a stock M3, CR is 10.5:1* and we take it up to 12.1 CR. *Note: BMW states that the stock M3 CR is 10.5:1 but when we CC it out, we get a real 9.5:1 and we take it up to what measures out at a real 11.1. Since we typically discover an approximate 8% variance increase in all BMW Compression Ratios, we used their calculating method in stating the M3 goes from 10.5:1 to 12.1. We don’t know but have suspected that they are calculating a carboning-up factor in the combustion chamber which would eventually increase the compression. For street driving, all our engines are designed to operate with 91 Octane. During Driver’s Schools, we recommend adding 1 gallon of 105 Octane Race Fuel per 3 to 4 gallons of 91 Octane Pump Gas. The objective here is to avoid detonation under extreme driving conditions.
4. Improved Head Flow
Porting the head allows for more fuel and air to flow past the intake valves at a given lift, for greater cylinder filling. Our cylinder head flow increases are as follows:
· M10 18% – 24% flow increase over the stock head
· M30 16% flow increase over the stock head
· M20 16% flow increase over stock the head
· S14/S38 16% – 26% flow increase over the stock head
· M42/M44 6% flow increase over the stock head*
· M50/S52 6% flow increase over the stock head*
· M54 6% flow increase over the stock head*
*Newer engines have an optimal port size of about 85% of the valve head and come from the factory machine ported, leaving less room for improvement.
Generally speaking, the cylinder filling and power gains will be about 1/2 the air flow increase of the ported head. For example, a 20% flow increase would equal a 10% increase in cylinder filling and power.
5. More Camming
We regard the camshaft as the crux of the entire engine. When designed right, it co-ordinates all other engine components to work optimally. Displacement, head flow, compression and driveability requirements, all factor into the camshaft profile design. Driveability requirements are determined by the owner’s driving style and how they use their BMW. A Metric Mechanic Sport Engine is designed for enthusiastic street driving whereas a Rally Engine covers that of course, but is also ready for Drivers Schools, Autocrossing and other driving events. They both have smooth idling qualities (with or without AC on) at 700 to 750 RPM, will work with the fuel injection idle circuit, and pass emissions testing anywhere in the world (in our experience so far). We meet these requirements by designing our camshafts to NOT exceed the overlap of the stock factory cams.
Our Sport and Rally Engines are build with a wide power band. Generally these engines make within 85% of their peak torque from 3000 to 3500 RPMs up to 6500 to 7000 RPM. This is done by running an intake lobe that is larger than the exhaust lobe. The Intake Lobe controls the upper RPM HP range whereas the Exhaust Lobe controls the low to mid-range torque. In 1988 we made a departure from the conventional practice of using identical intake and exhaust lobes and started designing the cam with a larger intake lobe than exhaust – a practice we continue to this day. Interestingly, BMW began this same strategy in 1995 with the E36 M3 Engine. Previously, the M50tu engine had Intake and Exhaust Lobes of 224° /9.0 Lift. In 1995 M3 S50 engine had a large Intake Lobe increase up to 252° / 10.3 Lift. The Exhaust Lobe was mildly increased to 234° at 9.7 Lift. Both the M50tu and the S50 Engine had 25° of Vanos (Variable Valve Timing) on the Intake Cam.
In Summary
These five areas (Reciprocating Mass, Displacement, Compression Ratio, Head Flow and Camming) are the keys to unlocking the power output of our Normally Aspirated or Boosted Engines.
Torque and HP are the primary measurements used to describe the power output of an engine. Torque is expressed in ft/lbs and is a measure of the engine’s twisting force exerted on the crankshaft from combustion. Horsepower, which is derived from torque, is specifically a measure of how much torque the engine produces in one minute divided by 5252. Therefore, the HP formula is:
HP = Torque x RPM (Revolutions per Minute) ÷ 5252
Both HP and Torque are measured either at the Flywheel using an Engine Dynamometer or at the rear wheels using a Chassis Dyno.
How MM Engines Generate Power
Basic engine components are the block (pistons, rods, crankshaft) topped off with the head (cam/s, valves, valve train parts, etc).
The fill capacity (air and fuel mixture) of the Block’s cylinders, is what provides Torque while it’s the Head’s air intake that governs HP.
We use five techniques for modifying engine power! The first three occur in the block and the last two in the head.
1. Lighter Reciprocating Mass (piston, piston pin & rod)
2. Larger Displacement
3. Increased Compression Ratio
4. Improved Head Flow
5. More Camming
1. Lighter Reciprocating Mass
Weight is the enemy of acceleration! For example, in a BMW E36 M3 engine, turning 7000 rpm, the piston starts from the top, accelerating to 100 mph by 75° after TDC, then starts to decelerate and stops at the bottom. The piston starts and stops 14,000 times a minute over a distance no wider than your fist, 3.5″ or 89.6mm. The reciprocating mass squares with RPM. For instance, from 2000 RPM’s to 4000 RPM’s, the RPMs are doubled but the engine recognizes a FOURFOLD increase in the Reciprocating Mass! If the RPM’s are doubled again to 8,000, the Reciprocating Mass is 16 times greater than at 2000 RPM’s. This is why we take Reciprocating Mass so seriously and strive to reduce it’s weight through lighter components. The Reciprocating Mass in our engines is 15% – 40% lighter than stock. This reduction spools up the crank quicker and increases the reliability of the engine – less reciprocating weight (piston and rod going up and down) to tear up the engine over time.
2. Larger Displacement
Larger displacement is accomplished by boring the block and increasing the crankshaft stroke. Displacement is a direct ratio of torque output meaning, a 10% increase in displacement results in a 10% increase in torque. Boring an engine is usually the most cost-effective way to increase displacement without increasing piston speed – which increases wear. Boring a cylinder out by 1mm, equals adding 2mm to the crankshaft stroke. At MM, we typically stroke an engine by installing a crankshaft with a longer stroke. In a few cases, we offset grind the crank.
3. Increased Compression Ratio
A simplified definition for Compression Ratio is: a measure of the entire Cylinder Volume plus the Combustion Chamber Volume divided by the Combustion Chamber Volume. Increasing the intensity of the combustion chamber explosion is accomplished by increasing the compression ratio. At Metric Mechanic, we normally increase the Compression Ratio by 1.5 to 2 points. For example, in a stock M3, CR is 10.5:1* and we take it up to 12.1 CR. *Note: BMW states that the stock M3 CR is 10.5:1 but when we CC it out, we get a real 9.5:1 and we take it up to what measures out at a real 11.1. Since we typically discover an approximate 8% variance increase in all BMW Compression Ratios, we used their calculating method in stating the M3 goes from 10.5:1 to 12.1. We don’t know but have suspected that they are calculating a carboning-up factor in the combustion chamber which would eventually increase the compression. For street driving, all our engines are designed to operate with 91 Octane. During Driver’s Schools, we recommend adding 1 gallon of 105 Octane Race Fuel per 3 to 4 gallons of 91 Octane Pump Gas. The objective here is to avoid detonation under extreme driving conditions.
4. Improved Head Flow
Porting the head allows for more fuel and air to flow past the intake valves at a given lift, for greater cylinder filling. Our cylinder head flow increases are as follows:
· M10 18% – 24% flow increase over the stock head
· M30 16% flow increase over the stock head
· M20 16% flow increase over stock the head
· S14/S38 16% – 26% flow increase over the stock head
· M42/M44 6% flow increase over the stock head*
· M50/S52 6% flow increase over the stock head*
· M54 6% flow increase over the stock head*
*Newer engines have an optimal port size of about 85% of the valve head and come from the factory machine ported, leaving less room for improvement.
Generally speaking, the cylinder filling and power gains will be about 1/2 the air flow increase of the ported head. For example, a 20% flow increase would equal a 10% increase in cylinder filling and power.
5. More Camming
We regard the camshaft as the crux of the entire engine. When designed right, it co-ordinates all other engine components to work optimally. Displacement, head flow, compression and driveability requirements, all factor into the camshaft profile design. Driveability requirements are determined by the owner’s driving style and how they use their BMW. A Metric Mechanic Sport Engine is designed for enthusiastic street driving whereas a Rally Engine covers that of course, but is also ready for Drivers Schools, Autocrossing and other driving events. They both have smooth idling qualities (with or without AC on) at 700 to 750 RPM, will work with the fuel injection idle circuit, and pass emissions testing anywhere in the world (in our experience so far). We meet these requirements by designing our camshafts to NOT exceed the overlap of the stock factory cams.
Our Sport and Rally Engines are build with a wide power band. Generally these engines make within 85% of their peak torque from 3000 to 3500 RPMs up to 6500 to 7000 RPM. This is done by running an intake lobe that is larger than the exhaust lobe. The Intake Lobe controls the upper RPM HP range whereas the Exhaust Lobe controls the low to mid-range torque. In 1988 we made a departure from the conventional practice of using identical intake and exhaust lobes and started designing the cam with a larger intake lobe than exhaust – a practice we continue to this day. Interestingly, BMW began this same strategy in 1995 with the E36 M3 Engine. Previously, the M50tu engine had Intake and Exhaust Lobes of 224° /9.0 Lift. In 1995 M3 S50 engine had a large Intake Lobe increase up to 252° / 10.3 Lift. The Exhaust Lobe was mildly increased to 234° at 9.7 Lift. Both the M50tu and the S50 Engine had 25° of Vanos (Variable Valve Timing) on the Intake Cam.
In Summary
These five areas (Reciprocating Mass, Displacement, Compression Ratio, Head Flow and Camming) are the keys to unlocking the power output of our Normally Aspirated or Boosted Engines.
