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Instruction Sheet

012-06870B

Low Delta T Stirling Engine

SE-8576A

800-772-8700 techsupp@pasco.com www.pasco.com

Introduction

The PASCO SE-8576A Low Delta T Stirling Engine is a

jewel-like engine. Because of its precision components and

careful construction, it can operate on temperature differ-

ences as small as four degrees celsius (4 °C).

For example, when the room temperature is 22.2 °C (72 °F)

or cooler, the heat from a warm hand is enough to power the

engine.

Stirling engines can be very efficient with some designs

attaining efficiencies up to 50% of the Carnot Cycle effi-

ciency. The Carnot Cycle determines the maximum theoreti-

cal efficiency of a heat engine according to the formula:

where the temperature is measured in absolute degrees

(kelvin (K) or rankine).

Operation

The Low Delta T Stirling Engine operates as follows:

The bottom plate of the engine along with the clear acrylic

cylinder, the top plate, and the graphite power piston make

up a sealed system. When the air inside this system changes

temperature, so does the pressure.

Inside the clear acrylic cylinder is a large white foam dis-

placer. This displacer looks like a piston, but it has a

3.125 mm (1/8” inch) gap around its outer edge. Air never

pushes on the displacer; it flows around the displacer.

The engine can begin working when either the bottom plate

or the top plate is heated or cooled to a temperature at least

4 °C warmer or cooler than the other plate. A gentle spin on

the flywheel is needed to start the engine.

As the foam displacer moves away from the warm side of the

engine, air flows around the edge of the displacer toward the

warm side and is heated. When the air is heated, it expands,

which increases the pressure inside the entire engine. This

increase in air pressure pushes up on the graphite power pis-

ton.

Next, the energy stored in the flywheel moves the displacer

closer to the warm side of the engine, and the air once again

flows around the edge of the displacer toward the cool side

of the engine.

When the air is cooled, it contracts, and the pressure drops

throughout the engine. The pressure inside the engine

becomes less than the pressure outside, and the graphite

power piston is pushed down. The displacer moves back

toward the cool side, the air is displaced toward the warm

side, and the cycle starts all over again.

The foam displacer only moves the air back and forth from

the warm side to the cool side of the engine. It does not do

any work on the crankshaft. In other words, the connecting

temp hot - temp cold

temp hot

--------------------------------------------------

% efficiency=

Flywheel

Crankshaft

Graphite

power piston

Foam

displacer

Connecting

rod

Connecting

rod

IMPORTANT:

Do Not Oil

Summary of content (3 pages)

PAGE 1
Instruction Sh eet 012-06870B ® Low Delta T Stirling Engine SE-8576A Introduction The PASCO SE-8576A Low Delta T Stirling Engine is a jewel-like engine. Because of its precision components and careful construction, it can operate on temperature differences as small as four degrees celsius (4 °C). For example, when the room temperature is 22.2 °C (72 °F) or cooler, the heat from a warm hand is enough to power the engine.
PAGE 2
Low Delta T Stirling Engine SE-8576A rod to the displacer could be a string and the engine would still work. REVOLUTION CONTRACTION COLD AIR HEATING HOT AIR Troubleshooting Generally there are three reasons why Stirling engines fail to run: too much friction, air leaks, or inadequate thermal transfer. The most likely reason for the Low Delta T Stirling Engine to fail to run is inadequate thermal transfer. If the engine will not run, try the following: Put 2.
PAGE 3
Low Delta T Stirlin g Engine efficiency of an engine. No engine can exceed the Carnot efficiency. (The second law of thermodynamics says you can’t get out more than you put in; you can only break even.) It takes good engineering and complex machines to achieve a significant fraction of the Carnot efficiency. Real Stirling engines can reach 50 percent of the maximum theoretical value, which is a very high percentage.