Section 59.—PROPULSION.

Plate 62Larger plate.

Larger plate.

1112. Indiarubber sheet jointfor the tubes of condensers, the rubber being pressed around the tube joints by a plate with projecting rings. SeePlate,page 139.

1113.V-ring metallic gland packing.SeePlate,page 139.

Joints of plane surfaces are usually made with red-lead for steam and water; asbestos, millboard, and sometimes rubber insertion, tape, paper, or wire gauze for steam, water, air, &c.

(See alsoSections 60, and12.)

On land, vehicles, &c., may be propelled by:

a.Any enginehaving contained in itself its source of power; such as a steam engine, compressed-air engine, electric motor, &c.b.Any fixed source of power,the moving vehicle being connected to it by: 1, a rope or chain; 2, a tube; 3, an electric wire or other electric connection.c.By gravitationdown an inclined or vertical road. SeeSection 69.d.By wind power,using sails or windmill. SeeSection 95.e.Animal power.

Any enginehaving contained in itself its source of power; such as a steam engine, compressed-air engine, electric motor, &c.

Any fixed source of power,the moving vehicle being connected to it by: 1, a rope or chain; 2, a tube; 3, an electric wire or other electric connection.

By gravitationdown an inclined or vertical road. SeeSection 69.

By wind power,using sails or windmill. SeeSection 95.

Animal power.

a.Any enginehaving contained in itself its source of power; such as a steam engine, compressed-air engine, electric motor, &c.

b.Any fixed source of power,the moving vehicle being connected to it by: 1, a rope or chain; 2, a tube; 3, an electric wire or other electric connection.

c.By gravitationdown an inclined or vertical road. SeeSection 69.

d.By wind power,using sails or windmill. SeeSection 95.

e.Animal power.

On water, vessels are propelled by:

a.Wind.b.Steamor other heat engine.c.Wave motion.d.Natural currents,tides.e.Animal power.

Wind.

Steamor other heat engine.

Wave motion.

Natural currents,tides.

Animal power.

a.Wind.b.Steamor other heat engine.c.Wave motion.d.Natural currents,tides.e.Animal power.

a.Wind.

b.Steamor other heat engine.

c.Wave motion.

d.Natural currents,tides.

e.Animal power.

In air, balloons have been propelled by:

a.Wind.b.Some kind of engine power.c.Hand power.

Wind.

Some kind of engine power.

Hand power.

a.Wind.b.Some kind of engine power.c.Hand power.

a.Wind.

b.Some kind of engine power.

c.Hand power.

But the two latter sources must be at present considered almost impracticable.

On land:

a.Steam or other engine and boileron the moving vehicle.b.A reservoir of compressed airor gas, driving an engine on the vehicle.c.An electric batteryor accumulator, driving an engine on the vehicle.d.Rope railway:the rope may be driven by any kind of engine.e.Endless ropetransmission. SeeSection 66.f.Inclined or vertical hoists.SeeSection 69.g.Ice vessels,or yachts, propelled by wind and sails, windmills, &c. SeeSection 95.h.Velocipedesof all kinds, hand power lifts and hoists. SeeSection 69.

Steam or other engine and boileron the moving vehicle.

A reservoir of compressed airor gas, driving an engine on the vehicle.

An electric batteryor accumulator, driving an engine on the vehicle.

Rope railway:the rope may be driven by any kind of engine.

Endless ropetransmission. SeeSection 66.

Inclined or vertical hoists.SeeSection 69.

Ice vessels,or yachts, propelled by wind and sails, windmills, &c. SeeSection 95.

Velocipedesof all kinds, hand power lifts and hoists. SeeSection 69.

a.Steam or other engine and boileron the moving vehicle.

b.A reservoir of compressed airor gas, driving an engine on the vehicle.

c.An electric batteryor accumulator, driving an engine on the vehicle.

d.Rope railway:the rope may be driven by any kind of engine.

e.Endless ropetransmission. SeeSection 66.

f.Inclined or vertical hoists.SeeSection 69.

g.Ice vessels,or yachts, propelled by wind and sails, windmills, &c. SeeSection 95.

h.Velocipedesof all kinds, hand power lifts and hoists. SeeSection 69.

On water, vessels are propelled by:

a.Sails.b.Steamships,by screw, paddle-wheel, stern wheel, water jet, and steam jet.c.Wave engine.d.Barges and raftsusually employ tidal motion only.e.Rowing boats,&c., hand power paddle and screw boats, horse towage.

Sails.

Steamships,by screw, paddle-wheel, stern wheel, water jet, and steam jet.

Wave engine.

Barges and raftsusually employ tidal motion only.

Rowing boats,&c., hand power paddle and screw boats, horse towage.

a.Sails.

b.Steamships,by screw, paddle-wheel, stern wheel, water jet, and steam jet.

c.Wave engine.

d.Barges and raftsusually employ tidal motion only.

e.Rowing boats,&c., hand power paddle and screw boats, horse towage.

In air, balloons are propelled by:

a.Wind,acting on the inflated balloon, or on an umbrella-shaped or other sail; also on the under side of inclined planes of large area.b.Balloonsof elongated form have been propelled by an engine placed in the car, driving either a large screw propeller or wings.c.Various attempts have been made to work flying machines (generally having some form of wings) by the power of a man’s hands and feet, with very little success.

Wind,acting on the inflated balloon, or on an umbrella-shaped or other sail; also on the under side of inclined planes of large area.

Balloonsof elongated form have been propelled by an engine placed in the car, driving either a large screw propeller or wings.

Various attempts have been made to work flying machines (generally having some form of wings) by the power of a man’s hands and feet, with very little success.

a.Wind,acting on the inflated balloon, or on an umbrella-shaped or other sail; also on the under side of inclined planes of large area.b.Balloonsof elongated form have been propelled by an engine placed in the car, driving either a large screw propeller or wings.c. Various attempts have been made to work flying machines (generally having some form of wings) by the power of a man’s hands and feet, with very little success.

a.Wind,acting on the inflated balloon, or on an umbrella-shaped or other sail; also on the under side of inclined planes of large area.

b.Balloonsof elongated form have been propelled by an engine placed in the car, driving either a large screw propeller or wings.

c. Various attempts have been made to work flying machines (generally having some form of wings) by the power of a man’s hands and feet, with very little success.

It is assumed that all physical energy is derived more or less directly from the sun, whose rays combine: 1, heat; 2, light; 3, actinic or chemical power.

Heatmay be obtained:

a.By direct use of the sun’s rays.b.From any combustible material.c.From chemical reaction.

By direct use of the sun’s rays.

From any combustible material.

From chemical reaction.

a. By direct use of the sun’s rays.b. From any combustible material.c. From chemical reaction.

a. By direct use of the sun’s rays.

b. From any combustible material.

c. From chemical reaction.

Lightdoes not separately develop power.

Chemical reactionsare employed to develop heat, combustion, contraction, or expansion, as means of developing power.

From the foregoing elementary physical sources the following are the practical sources of our power for mechanical purposes.

These are employed in producing power by the following apparatus ormotors:—

Electric motorsdriven from a dynamo, battery, or accumulator.

Magnetic powercannot be employed continuously as a motor, as it gives out only as much as it receives.

Tidal motioncan be utilised to drive any kind of wheel, see Water Wheels,Section 90. It can also be stored in a reservoir, driving a water engine as it flows in and out on the flood and ebb; or a floating vessel may, by its rise and fall, communicate motion to machines.

Falling water;for machines employed to utilise, see Water Wheels,Section 90; Turbines, Water-pressure Engines, &c.,Section 93.

Descending weightsmust first of course be raised, absorbing as much power in raising as they give out in falling, neglecting friction. Clockwork; water; or compression of a spring (seeSection 80); multiplying pulleys (seeSection 42), are the apparatus employed to utilise this form of energy.

Wave motionis too uncertain and erratic to be a practicable source of power. Rocking air-compressing chambers, rocking pumps, &c., have obtained some small measure of success.

Wind,windmills. SeeSection 95.

Expansion of air and gases.Ascending currents of hot air from a fire are used to drive a light screw motor, fan, &c. Hot-air engines, see Ryder’s patent and numerous others, which depend upon alternate expansion and contraction of air by heating and cooling. Air compressed in an accumulator or reservoir is employed to give motion to multiplying pulleys or an air engine.

Expansion of liquids,other than water (by heat), into the gaseous form. Engines in which the fuel is burnt under pressure and the total products of combustion employed (with or without steam) to drive a motor.

Steamis in reality one of the last-mentioned sources of power; it is employed by direct pressure on a piston or ram (seeSection 32); or to produce direct rotary motion (seeSection 75); also in the jet pump,No. 801; or injector (seeSection 45); or by direct pressure on a body of water contained in a closed vessel, as in the pulsometer, steam accumulator, &c.

Explosivesare substances which, by application of flame, heat, percussion, &c., suddenly assume the gaseous form, thus increasing their bulk many hundred times, usually in a small fraction of a second of time. A second class comprise explosive mixtures of gases, such as hydrogen, and oxygen, carburetted hydrogen, and air. Some attempts have been made to employ explosive substances to drive engines in various ways, but with no permanent success. The second class of explosive mixtures of gases are largely employed in the gas engine, petroleum engine, and their varieties.

Fuels, hydrocarbons,&c., are employed to evaporate water into steam; to expand air or other gases, or convert liquids into gases; and also by vaporisation to supply gas for use in some forms of gas engine.

1114. Vertical direct-acting,with either ram pump, ram and piston pump, or piston only. SeeSection 56.

1115. Slot and crank motion,a variety of the last named. Of course any other kind of crank driving can be employed. SeeSection 10.

The frame standards are frequently used as air vessels or valve chests.

1116. Direct-acting ram pump,with fly-wheel worked off crosshead pin.

1117. Direct-acting,with yoke crosshead; much used in the northern counties. The standards form air vessels and valve boxes, and they are made both of the piston and ram types.

1118. Three-cylinder,with yoke crosshead. Either the centre cylinder or the two side ones can be used as the steam motor cylinders, or the pumps.

1119. The ordinary direct-acting engine,with either steam-moved or tappet valves, see Tangye’s “Special,” the “Coalbrookdale,” and others, in which the slide valve is operated by pistons controlled by auxiliary tappet valves on the same principle asNo. 1506.

1120. Direct-acting,with crosshead and guide bars between the cylinders.

1121. Two modifications ofNo. 1120.

1123. Direct-acting,with rocking lever valve motion; see the “Worthington” and other “Duplex” pumps, in which two engines are combined so that one works the valve of the other.

1122,1124, &1125. Other forms of direct-acting engines.

1126. Horizontal compound direct-acting.The high-pressure cylinder, low-pressure ditto, and receiver are side by side, and the air pump and main pump in line with the steam cylinders.

Plate 63Larger plate.

Larger plate.

1127. Horizontal pumping engine,with yoked crossheads and crank in centre.

1128&1129. Horizontal compound lever engines.

1130. Davey’s patent vertical compound beam mining pump.

The Cornish beam pumping engine is too well known to need illustration.

In mining pumps the pump rod has occasionally been made of iron pipe and employed as the rising main.

1131. Geared pumping engine,with steam cylinder and pump side by side; the speed of the steam piston is reduced on the pump by spur gearing.

1132. The common ratchet-wheel and pawl,or detent.

1133. Ditto,with compound pawls to check angular motion less than the pitch of the teeth.

1134. Locking pawl.

1135. Strut-action pawl.

1136. Indiarubber ball pawl;sometimes a solid roller is substituted for the indiarubber ball.

1137. Reverse ratchets,for continuous feed from an oscillating arm.

1138. Ball and socket ratchet,will work at an angle.

1139. Pawl,used with ordinary spur teeth, and sometimes made reversible (see dotted lines), to drive the opposite way.

1140. Ratchet bosses.

1141. Silent pawl;the pawl is lifted out of gear while reversing by the motion of the toggle joint and lever.

1142. Crown ratchet and pawl.

1143. Application ofNo. 1136as a silent feed motion.

1144. Click and detent continuous feed motion.

1145. Hare’s foot ratchet motionwith detent.

1146. Silent feed.The jaw grips the rim of wheel when moving in one direction and runs loose the other way.

1147. Reciprocatinginto intermittent rotary motion.

Plate 64Larger plate.

Larger plate.

1148. Reciprocating circular motioninto intermittent circular ditto, Kaiser’s patent.

1149. Continuous circular motioninto intermittent ditto, Kaiser’s patent. The wheelAis locked by the ringCwhile the fingerBis out of gear, the ring then passing between the teeth ofA.

1150. Cam-ring intermittent feed motion.

1151. Modification of the last named;in both the wheel is locked during the dead movement of the cam by the flange passing between the teeth.

1152. Slot wheel and pin gear.

1153. Segment-wheel intermittent feed motion;locked during the dead movement of driving wheel.

1154. The pawl is lifted out of gearat each revolution of the pin wheelAand the ratchet moved one or more teeth.

1155. Double pawls and linksfor continuous feed motion.

1156. The camAis eccentric to the wheelB, and slips out of gear at any required point while the driving wheel makes a partial revolution.

1157. Spring-pawl feed motion;the large wheel with pawl attached drives the ratchet wheel.

1158. Rocking lever and double pawlsfor raising a rack.

1159. Internal pawls,dropping into gear by gravitation.

1160. The pawl is lifted out of gearby the act of putting the handle on the square end of shaft, the handle having a boss shaped so as to lift the pawl.

1161. Star wheel and fixed pawlfor conveying intermittent motion to screw on revolving disc; used for boring-bars, slide rests, &c.

1162. Pendulum and ratchet escapement.

1163. Cylinder escapement.

1164. Pendulum and double ratchet wheel escapement.

1165. Enlarged plan of cylinder escapement.

1166. Lever escapement.

1167. Double pawl and pin wheel escapement.

1168. Three-leg pendulum escapement.

1169. Self-sustaining ratchet motion.Pulling the cordAthrows the pawl out of gear by the straightening of the cord forcing back the bent pawl lever.

1170. Verge escapement.

1171. Intermittent circular motionby revolving pawl and detent.

Plate 65Larger plate.

Larger plate.

1172. Spanner ratchet;a simple spanner having a pin near one end of one of the jaws which slips into the teeth of the ratchet wheel.

1173.Vpawl;operates by wedging itself between theVflanges.

1174. Gravity pawls and ratchet wheel.

1175. Ratchet wheel,used to govern the striking gear of a clock.

1176. The pawl is hinged to the jointed end of the lever,and is pulled out of gear by the return movement of the rod—silent feed.

1177. Pawl and rack.

1178. Roller and inclined segmental recessfor silent feed motion.

1179. Gripping pawls and ringfor silent feed motion.

Snail ratchet,No. 725.

The ordinary Screw press and Hydraulic press are well-known machines.

1180. Rack and screw press.

1181. Power press or stamp,with double crank movement worked from below.

1182. Dick’s anti-friction press,with rolling contacts throughout.

1183. Hydraulic press,with dies for lead pipe making; a similar press is used for making earthenware drain and flue pipes, the material being forced out of an annular orifice.

1184. Wedge press.

1185. Ster-hydraulic press;a strand or rope is wound upon a barrel inside the cylinder, thus displacing the water and raising the ram.

1186. Screw fly press.

1187. Combined screw and hydraulic press.The screw is worked down by hand until the pressure becomes too great for hand power, when the pressing is finished by the hydraulic ram.

1188. Revolving dies.

1189. The “Boomer” double-screw toggle press,with increasing pressure as the press follower descends.

1190. Revolving toggle press,with similar capabilities but more restricted movement.

1191. Sector and link pressfor increasing pressure.

Plate 66Larger plate.

Larger plate.

1192. Press dies,with sliding plate for discharging.

1193. Screw and toggle press;a modification ofNo. 1189.

1194. Double ram hydraulic pressfor two pressures; the small ram is employed to give the first pressure, the large ram then finishes the pressing.