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Stewart Components Tech Tips |
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Tech Tip #5 - Radiators & External Plumbing
Radiators
Thicker radiators do have slightly more airflow
resistance than thinner radiators but the difference is minimal. A 4" radiator
has only approximately 10% more airflow resistance than a 2" radiator.
In past years, hot rodders and racers would sometimes install a thicker radiator
and actually notice decreased cooling. They erroneously came to the conclusion
that the air could not flow adequately through the thick radiator, and therefore
became fully heat-saturated before exiting the rear of the radiator core. The
actual explanation for the decreased cooling was not the air flow, but the
coolant flow. The older radiators used the narrow tube design with larger cross
section. Coolant must flow through a radiator tube at a velocity adequate to
create turbulence.
The turbulence allows the water in the center of the tube to be forced against
the outside of the tube, which allows for better thermal transfer between the
coolant and the tube surface. The coolant velocity actually decreases, and
subsequently its ability to create the required turbulence, in direct relation
to the increase in thickness. If the thickness of the core is doubled, the
coolant velocity is halved. Modern radiators, using wide tubes and less cross
section area, require less velocity to achieve optimum thermal transfer. The
older radiators benefited from baffling inside the tanks and forcing the coolant
through a serpentine configuration. This increased velocity and thus the
required turbulence was restored.
Radiators with a higher number of fins will cool better than a comparable
radiator with less fins, assuming it is clean. However, a higher fin count is
very difficult to keep clean. Determining the best compromise depends on the
actual conditions of operation.
Double pass radiators require 16x more pressure to flow the same volume of
coolant through them, as compared to a single pass radiator. Triple pass
radiators require 64x more pressure to maintain the same volume. Automotive
water pumps are a centrifugal design, not positive displacement, so with a
double pass radiator, the pressure is doubled and flow is reduced by
approximately 33%. Modern radiator designs, using wide/thin cross sections
tubes, seldom benefit from multiple pass configurations. The decrease in flow
caused by multiple passes offsets any benefits of a high-flow water pump.
Gross flow radiators are superior to upright radiators because the radiator cap
is positioned on the low pressure (suction) side of the system. This prevents
the pressure created by a high-flow water pump from forcing coolant past the
radiator cap at high RPM. As mentioned in the radiator cap section, an upright
radiator should be equipped with radiator cap with the highest pressure rating
recommended by the manufacturer. The system will still force coolant past the
cap at sustained high RPM.
External Plumbing
Street-driven vehicles seldom need auxiliary plumbing or
coolant lines. SBC race engines with aluminum cylinder heads usually require
extensive external plumbing to address two design problems:
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1. |
Aluminum heads have much smaller water
jackets than cast-iron heads because the external dimensions are similar,
but the ports are usually larger, the deck is thicker, and the material near
the rocker stands is thicker, all leaving less area in the water jackets.
This decreased internal area leaves less area in the water jackets. |
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2. |
The siamese center exhaust ports are a
design compromise that presents additional problems when aluminum heads are
used. The area near the center exhaust valves is thicker, thus allowing
providing less surface area for cooling. |
We recommend installing a pair of –10 AN lines that connect the rear of the
aluminum cylinder heads to the thermostat housing crossover in the front. This
step will help offset the smaller water jackets. A pair of -10AN lines
connecting the pressure side of the water pump with the area in the center of
the cylinder head (just below the exhaust ports) will offset the lack of surface
area due to the extra material. |
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©2004 Stewart Components. All rights reserved. |
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