Piston valves are one form of valve used to control the flow of steam within a steam engine or locomotive. They control the admission of steam into the cylinders and its subsequent exhausting, enabling a locomotive to move under its own power.
In the 19th century, steam locomotives used slide valves to control the flow of steam into and out of the cylinders. In the 20th century, slide valves were gradually superseded by piston valves, particularly in engines using superheated steam. There were two reasons for this:
- It is difficult to lubricate slide valves adequately in the presence of superheated steam
- With piston valves, the steam passages can be made shorter. This, particularly following the work of André Chapelon, reduces resistance to the flow of steam and improves efficiency
The usual locomotive valve gears such as Stephenson, Walschaerts, and Baker valve gear, can be used with either slide valves or piston valves. Where poppet valves are used, a different gear, such as Caprotti valve gear may be used, though standard gears as mentioned above were used as well, by Chapelon and others.
The Swannington incline winding engine on the Leicester and Swannington Railway, manufactured by The Horsely Coal & Iron Company in 1833, shows a very early use of the piston valve. Piston valves had been used a year or two previously in the horizontal engines manufactured by Taylor & Martineau of London, but did not become general for stationary or locomotive engines until the end of the 19th century.
When on the move, a steam locomotive requires steam to enter the piston at a controlled rate. This entails controlling the admission and exhaustion of steam to and from the cylinders. Steam enters and leaves the valve through a steam port, usually at the middle position of the piston valve. Where the valve is in contact with the steam ports, a consideration of the "lap" and "lead" is required.
The "Lap" is the amount by which the valve overlaps each steam port at the middle position of each valve. However, there are two different types of "Lap."
The first kind is the "steam lap," which is the amount by which the valve overlaps the port on the live steam side of the cylinder. Secondly, there is the "exhaust lap," which is the amount by which the valve overlaps the port on the exhaust side of the cylinder. "Exhaust lap" is generally given to slow-running locomotives. This is because it allows the steam to remain in the cylinder for the longest possible amount of time before being expended as exhaust, therefore increasing efficiency. shunter locomotives tended to be equipped with this addition.
The "Negative exhaust lap", also commonly termed "exhaust clearance," is the amount the port is open to exhaust when the valve is in mid-position, and this is used on many fast-running locomotives to give a free exhaust. The amount seldom exceeds 1/16 in. when exhaust clearance is given; the cylinder on both sides of the piston is open to exhaust at the same time when the valve is passing through the mid-position, which is only momentary when running.
The "lead" of the valve is the amount by which the steam port is open when the piston is static at front or back dead centre. Pre-admission of steam fills the clearance space between the cylinder and piston and ensures maximum cylinder pressure at the commencement of the stroke. "Lead" is particularly necessary on locomotives designed for high speeds, under which conditions the valve events are taking place in rapid succession.
Long-travel piston valves allow the use of large steam ports to ease the flow of steam into, and out of, the cylinder.
Calculating valve events
Given the valve's lap, lead, and travel, at what point in the piston's stroke does the valve open and close, to steam and to exhaust?
Calculating an exact answer to that question before computers was too much work. The easy approximation (used in Zeuner's and Realeaux's diagrams) is to pretend that both the valve and the piston have a sine-wave motion (as they would, if the main rod were infinitely long). Then, for instance, to calculate the percent of the piston's stroke at which steam admission is cut off:
- Calculate the angle whose cosine is twice the lap divided by the valve travel
- Calculate the angle whose cosine is twice the (lap plus lead), divided by the valve travel
Add the two angles and take the cosine of their sum; subtract 1 from that cosine and multiply the result by -50.
As built the Pennsylvania's I1s 2-10-0 had lap 2 inches, lead 1/4 inch and valve travel 6 inches in full gear. In full gear the two angles are 48.19 deg and 41.41 deg and the maximum cutoff comes out 49.65% of the piston stroke.
- Clinker, C.R. (1977) The Leicester & Swannington Railway Bristol: Avon Anglia Publications & Services. Reprinted from the Transactions of the Leicestershire Archaeological Society Volume XXX, 1954.
- Information plaque on the Swannington engine, National Railway Museum, York.
- Garratt, C. & Wade-Matthews, M.: The Ultimate Encyclopedia of Steam & Rail (London: Hermes Publishing Company, Ltd., 1998) ISBN 1-84038-088-8