steam

Stirling Cycle Engines

The Stirling engine is a closed cycle
external combustion engine. It was
patented in 1817 by the Reverend
Robert Stirling - a Scottish
clergyman.

It incorporates several key features
which can make it a very efficient heat
engine - but only at a high engine cost.

The true Stirling engine incorporates a
heat store known as the regenerator,
which stores heat energy during one
part of the cycle and then releases it
later. This all helps to save the amount
of heat which is needed to run the
engine - thus making it overall more
fuel efficient.

An engine without a regenerator is
generally known as a Hot Air Engine.

Simpler Hot Air engines were
commonplace around 1880 to 1920,
but fell from fashion as the electric
motor took over for water pumping
and driving machinery..

There were several main
manufacturers, Rider-Ericsson,
Robinson, Dennay, Bremen, Essex,
Heinricci and many more.

Stirling and hot air engines are
characterised by their low noise,
smooth running and the ability to run on
any source of heat.

Today If you want to buy al Stirling
engine you will have to contact
Whispertech in Canterbury, New
Zealand, as they are almost the sole
manufacturer of practical, properly
engineered 1kW Stirling engine
powered generator sets.

A Whispergen will currently set you
back Â£8000 or US$11,000 but it
will replace your central heating
system, recharge your electric car
overnight and provide power, lighting
hot water and warmth all in a box
smaller than a European fridge.

Welcome to the Engines Page!

This page reflects some of my interests in
external combustion heat engines
eventually leading towards modern steam
cars using external combustion engines.

These include Stirling Engines, Steam
Engines and other alternatives to the
internal combustion engine - such as open
cycle (Ericsson) engines, gas turbines and
reciprocating Brayton cycle engines.

In the last 100 years we have become too
reliant on the ubiquitous internal
combustion engine which in turn relies on
high grade refined petroleum fuels for its
operation.

This page and the linked pages, try to offer
some basic information about other types
of heat engine which will literally run on
any source of heat, be it solar, geothemal,
gas, wood, coal, biomass or buffalo dung.

From garbage, to used engine oil the
external combustion engine can be made
to run on any fuel.

As well some of my own ideas and articles
I will try to point the interested reader
towards informative sites, where
information is available to a much greater
depth than my humble homepage can offer.

You can find some of these links on the
Wastewatts Links Page

Many pages are published by like minded
amateurs based on their experiences of
challenging mainstream practices or just
building engines for fun. Did I mention that
I have watched a television powered by
charcoal?

So read on with an open mind, for
tomorrow you will get into you car, and
burn high grade petroleum at a rate of at
least 15,000 BTU/hr expelling
10,000BTU/hr straight out to the
atmosphere, when all the time it could be
doing some good.

Manson Cycle Engines

These engines were devised in 1952 by
A.D. Manson and are a cousin of the
Stirling engine.
You can read the original article here.

They use the expansion an contraction of
air to produce mechanical work, but unlike
the Stirling, they do not require a separate
linkage to drive the displacer, as it is fixed
to the top of the power piston and moves
with it.

The power piston is fitted with ports which
open at TDC and BDC and allow a fresh
charge of air to be admitted from the
atmosphere at the top of each stroke - in
this respect they are open cycle external
combustion engines.

They are attractive because of their sheer
simplicity, few moving parts and relatively
simple to build.

I expect they would have applications in
the Developing World for pumping water,
turning light machinery or generating
modest quantities of electricity possibly for
a small village community.

As such they will run on any source of
heat, and can incorporate salvaged
automotive parts.

Transferator Engines New 2004

I am currently working on a variant of the
Manson - which is called the
Transferator Engine. It is even simpler
and incorporates improved heat
exchangers to make it more efficient. It
is easily constructed from stainless steel
cooking containers and may welll have
applications for water puming and
electricity generation in the Developing
World.

Steam engines were the main industrial
prime mover up until WWII, and steam
ships with reciprocating engines continued
right up until the 1970s. Some parts of the
world still rely on steam for their rail
transport, and a very high percentage of
all the electricity generated in the world,
uses steam, somewhere in the generation
process.

Steam has always been considered to be
a heavy, cumbersome technology and not
easily controlled - but it does not need to
be that way.

Since about 1900, pioneers of lightweight
steam technology have produced
advanced high speed engines, using flash
steam generation to produce very
compact powerful engines. In the 1930's,
racing hydroplane enthusiasts produced
model engines, with thimble sized pistons,
which would rev to 8000rpm and
produce over a horsepower. These
competed directly with the model spark
ignition petrol engine which were just
starting to appear.

In the 1920s and 30s, Abner Doble
produced a revolutionary steam car,
which could out perform any gasoline
powered car on the road, and yet return
over 30mpg.

There could well be an rennaissance in
lightweight steam technology in the form
of steam-electric hybrid cars. Steam
technology controlled efficiently with
modern electronics could well be a
winning technology.

These usually use the expansion of a
heated gas working against a piston or
turbine to produce mechanical work.

Air expands when heated, and if
constrained by a piston, it will do work
on that piston causing it to move. This
is a simple fact and it doesen't matter if
you are in Monson Road or on the
Moon, a heat engine can be devised
around this basic physical principle.

Stirling engines operate on the basis of
having a fixed amount of air sealed
within the engine and are known as
closed cycle hot air engines. The air is
alternately heated then cooled by
moving it from the hot side of the
engine to the cold side by means of a
displacer and the resulting rises and
falls in internal pressure do work
against a piston. The reciprocating
motion of the piston is converted by
means of a connecting rod and
crankshaft produce rotary motion. The
displacer is driven by an additional
linkage from the crankshaft and
generally produces no work itself.

Other types of engine exist, where the
air is not trapped inside the engine but
is discharged at the end of each stroke
and a fresh charge taken in. These are
known as open-cycle engines. Open
cycle hot air engines have been
proposed and built by many engineers
over the years. One of the most prolific
was John Ericsson who's name has
been perpetuated in the Ericsson cycle
engine.

For a potted history of John
Ericsson's life see Bob Sier's
excellent short biography.