Reciprocating piston stationary engine. This was the common mill engine of the mid 19th century. Note the
slide valve with concave, almost D-shaped, underside. showing the four events in a double piston stroke. See: Monitoring and control (above) In most reciprocating piston engines, the steam reverses its direction of flow at each
stroke (counterflow), entering and exhausting from the same end of the cylinder. The complete engine cycle occupies one rotation of the crank and two piston strokes; the cycle also comprises four
events – admission, expansion, exhaust, compression. These events are controlled by valves often working inside a
steam chest adjacent to the cylinder; the valves distribute the steam by opening and closing steam
ports communicating with the cylinder end(s) and are driven by
valve gear, of which there are many types. The simplest valve gears give events of fixed length during the engine cycle and often make the engine rotate in only one direction. Many however have a reversing
mechanism which additionally can provide means for saving steam as speed and momentum are gained by gradually "shortening the
cutoff" or rather, shortening the admission event; this in turn proportionately lengthens the expansion period. However, as one and the same valve usually controls both steam flows, a short cutoff at admission adversely affects the exhaust and compression periods which should ideally always be kept fairly constant; if the exhaust event is too brief, the totality of the exhaust steam cannot evacuate the cylinder, choking it and giving excessive compression (
"kick back"). In the 1840s and 1850s, there were attempts to overcome this problem by means of various patent valve gears with a separate, variable cutoff
expansion valve riding on the back of the main slide valve; the latter usually had fixed or limited cutoff. The combined setup gave a fair approximation of the ideal events, at the expense of increased friction and wear, and the mechanism tended to be complicated. The usual compromise solution has been to provide
lap by lengthening rubbing surfaces of the valve in such a way as to overlap the port on the admission side, with the effect that the exhaust side remains open for a longer period after cut-off on the admission side has occurred. This expedient has since been generally considered satisfactory for most purposes and makes possible the use of the simpler
Stephenson,
Joy, and
Walschaerts motions.
Corliss, and later,
poppet valve gears had separate admission and exhaust valves driven by
trip mechanisms or
cams profiled so as to give ideal events; most of these gears never succeeded outside of the stationary marketplace due to various other issues including leakage and more delicate mechanisms.
Compression Before the exhaust phase is quite complete, the exhaust side of the valve closes, shutting a portion of the exhaust steam inside the cylinder. This determines the compression phase where a cushion of steam is formed against which the piston does work whilst its velocity is rapidly decreasing; it moreover obviates the pressure and temperature shock, which would otherwise be caused by the sudden admission of the high-pressure steam at the beginning of the following cycle.
Lead in the valve timing The above effects are further enhanced by providing
lead: as was later discovered with the
internal combustion engine, it has been found advantageous since the late 1830s to advance the admission phase, giving the valve
lead so that admission occurs a little before the end of the exhaust stroke in order to fill the
clearance volume comprising the ports and the cylinder ends (not part of the piston-swept volume) before the steam begins to exert effort on the piston.
Uniflow (or unaflow) engine .The
poppet valves are controlled by the rotating
camshaft at the top. High-pressure steam enters, red, and exhausts, yellow. Uniflow engines attempt to remedy the difficulties arising from the usual counterflow cycle where, during each stroke, the port and the cylinder walls will be cooled by the passing exhaust steam, whilst the hotter incoming admission steam will waste some of its energy in restoring the working temperature. The aim of the uniflow is to remedy this defect and improve efficiency by providing an additional port uncovered by the piston at the end of each stroke making the steam flow only in one direction. By this means, the simple-expansion uniflow engine gives efficiency equivalent to that of classic compound systems with the added advantage of superior part-load performance, and comparable efficiency to turbines for smaller engines below one thousand horsepower. However, the thermal expansion gradient uniflow engines produce along the cylinder wall gives practical difficulties..
Turbine engines , used in a
power plant A steam turbine consists of one or more
rotors (rotating discs) mounted on a drive shaft, alternating with a series of
stators (static discs) fixed to the turbine casing. The rotors have a propeller-like arrangement of blades at the outer edge. Steam acts upon these blades, producing rotary motion. The stator consists of a similar, but fixed, series of blades that serve to redirect the steam flow onto the next rotor stage. A steam turbine often exhausts into a
surface condenser that provides a vacuum. The stages of a steam turbine are typically arranged to extract the maximum potential work from a specific velocity and pressure of steam, giving rise to a series of variably sized high- and low-pressure stages. Turbines are only efficient if they rotate at relatively high speed, therefore they are usually connected to reduction gearing to drive lower speed applications, such as a ship's propeller. In the vast majority of large electric generating stations, turbines are directly connected to generators with no reduction gearing. Typical speeds are 3600 revolutions per minute (RPM) in the United States with 60 Hertz power, and 3000 RPM in Europe and other countries with 50 Hertz electric power systems. In nuclear power applications, due to enormous size, the turbines typically run at half these speeds, 1800 RPM and 1500 RPM. A turbine rotor is also only capable of providing power when rotating in one direction. Therefore, a reversing stage or gearbox is usually required where power is required in the opposite direction. Steam turbines provide direct rotational force and therefore do not require a linkage mechanism to convert reciprocating to rotary motion. Thus, they produce smoother rotational forces on the output shaft. This contributes to a lower maintenance requirement and less wear on the machinery they power than a comparable reciprocating engine. '' – the first
steam turbine-powered ship The main use for steam turbines is in
electricity generation (in the 1990s about 90% of the world's electric production was by use of steam turbines)
Rotary steam engines It is possible to use a mechanism based on a
pistonless rotary engine such as the
Wankel engine in place of the cylinders and
valve gear of a conventional reciprocating steam engine. Many such engines have been designed, from the time of James Watt to the present day, but relatively few were actually built and even fewer went into quantity production; see link at bottom of article for more details. The major problem is the difficulty of sealing the rotors to make them steam-tight in the face of wear and
thermal expansion; the resulting leakage made them very inefficient. Lack of expansive working, or any means of control of the
cutoff, is also a serious problem with many such designs. By the 1840s, it was clear that the concept had inherent problems and rotary engines were treated with some derision in the technical press. However, the arrival of electricity on the scene, and the obvious advantages of driving a dynamo directly from a high-speed engine, led to something of a revival in interest in the 1880s and 1890s, and a few designs had some limited success.. Of the few designs that were manufactured in quantity, those of the Hult Brothers Rotary Steam Engine Company of Stockholm, Sweden, and the spherical engine of
Beauchamp Tower are notable. Tower's engines were used by the
Great Eastern Railway to drive lighting dynamos on their locomotives, and by the
Admiralty for driving dynamos on board the ships of the
Royal Navy. They were eventually replaced in these niche applications by steam turbines. rotates due to the steam escaping from the arms. No practical use was made of this effect.
Rocket type The
aeolipile represents the use of steam by the
rocket-reaction principle, although not for direct propulsion. In more modern times there has been limited use of steam for rocketry – particularly for rocket cars. Steam rocketry works by filling a pressure vessel with hot water at high pressure and opening a valve leading to a suitable nozzle. The drop in pressure immediately boils some of the water and the steam leaves through a nozzle, creating a propulsive force.
Ferdinand Verbiest's carriage was powered by an aeolipile in 1679. == Safety ==