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PART II - ELECTRICITY
CHAPTER V - THE DYNAMO; WHAT IT DOES, AND HOW
Electricity compared to the heat and light of the Sun—The simple dynamo—The amount of electric energy a 
dynamo will generate—The modern dynamo—Measuring power in terms of electricity—The volt—The ampere—
The ohm—The watt and the kilowatt—Ohm's Law of the electric circuit, and some examples of its application—
Direct current, and alternating current—Three types of direct-current dynamos: series, shunt, and compound.

What a farmer really does in generating electricity from water that would otherwise run to waste in his brook, is to 
install a private Sun of his own—which is on duty not merely in daylight, but twenty-four hours a day; a private Sun 
which is under such simple control that it shines or provides heat and power, when and where wanted, simply by 
touching a button.

This is not a mere fanciful statement. When you come to look into it you find that electricity actually is the life-giving 
power of the Sun's rays, so transformed that it can be handily conveyed from place to place by means of wires, and
controlled by mechanical devices as simple as the spigot that drains a cask.

Nature has the habit of traveling in circles. Sometimes these circles are so big that the part of them we see looks 
like a straight line, but it is not. Even parallel lines, according to the mathematicians, "meet in infinity." Take the 
instance of the water wheel which the farmer has installed under the fall of his brook. The power which turns the 
wheel has the strength of many horses. It is there in a handy place for use, because the Sun brought it there. The 
Sun, by its heat, lifted the water from sea-level, to the pond where we find it—and we cannot get any more power 
out of this water by means of a turbine using its pressure and momentum in falling, than the Sun itself expended in 
raising the water against the force of gravity.

Once we have installed the wheel to change the energy of falling water into mechanical power, the task of the 
dynamo is to turn this mechanical power into another mode of motion—electricity. And the task of electricity is to 
change this mode of motion back into the original heat and light of the Sun—which started the circle in the 
beginning.

Astronomers refer to the Sun as "he" and "him" and they spell his name with a capital letter, to show that he 
occupies the center of our small neighborhood of the universe at all times.

Magnets and Magnetism
The dynamo is a mechanical engine, like the steam engine, the water turbine or the gas engine; and it converts the 
mechanical motion of the driven wheel into electrical motion, with the aid of a magnet. Many scientists say that the 
full circle of energy that keeps the world spinning, grows crops, and paints the sky with the Aurora Borealis, begins 
and ends with magnetism—that the sun's rays are magnetic rays. Magnetism is the force that keeps the compass 
needle pointing north and south. Take a steel rod and hold it along the north and south line, slightly inclined 
towards the earth, and strike it a sharp blow with a hammer, and it becomes a magnet—feeble, it is true, but still a 
magnet.

Take a wire connected with a common dry battery and hold a compass needle under it and the needle will 
immediately turn around and point directly across the wire, showing that the wire possesses magnetism encircling it 
in invisible lines, stronger than the magnetism of the earth.

A direct-current dynamo or motor, showing details of construction

(Courtesy of the Crocker-Wheeler Company)

Insulate this wire by covering it with cotton thread, and wind it closely on a spool. Connect the two loose ends to a 
dry battery, and you will find that you have multiplied the magnetic strength of a single loop of wire by the number 
of turns on the spool—concentrated all the magnetism of the length of that wire into a small space. Put an iron core 
in the middle of this spool and the magnet seems still more powerful. Lines of force which otherwise would escape 
in great circles into space, are now concentrated in the iron. The iron core is a magnet. Shut off the current from 
the battery and the iron is still a magnet—weak, true, but it will always retain a small portion of its magnetism. Soft 
iron retains very little of its magnetism. Hard steel retains a great deal, and for this reason steel is used for 
permanent magnets, of the horseshoe type so familiar.

A Simple Dynamo
A dynamo consists, first, of a number of such magnets, wound with insulated wire. Their iron cores point towards 
the center of a circle like the spokes of a wheel; and their curved inner faces form a circle in which a spool, wound 
with wire in another way, may be spun by the water wheel.

Now take a piece of copper wire and make a loop of it. Pass one side of this loop in front of an electric magnet.

As the wire you hold in your hands passes the iron face of the magnet, a wave of energy that is called electricity 
flows around this loop at the rate of 186,000 miles a second—the same speed as light comes to us from the 
sun. As you move the wire away from the magnet, a second wave starts through the wire, flowing in the opposite 
direction. You can prove this by holding a compass needle under the wire and see it wag first in one direction, then 
in another.

A wire "cutting" the lines of force of an electro-magnet

This is a simple dynamo. A wire "cutting" the invisible lines of force, that a magnet is spraying out into the air, 
becomes "electrified." Why this is true, no one has ever been able to explain. The amount of electricity—its capacity
for work—which you have generated with the magnet and wire, does not depend alone on the pulling power of that 
simple magnet. Let us say the magnet is very weak—has not enough power to lift one ounce of iron. Nevertheless, 
if you possessed the strength of Hercules, and could pass that wire through the field of force of the magnet many 
thousands of times a second, you would generate enough electricity in the wire to cause the wire to melt in your 
hands from heat.

Cross-section of an armature revolving in its field

This experiment gives the theory of the dynamo. Instead of passing only one wire through the field of force of a 
magnet, we have hundreds bound lengthwise on a revolving drum called an armature. Instead of one magnetic 
pole in a dynamo we have two, or four, or twenty according to the work the machine is designed for—always 
in pairs, a North pole next to a South pole, so that the lines of force may flow out of one and into another, instead 
of escaping in the surrounding air. If you could see these lines of force, they would appear in countless numbers 
issuing from each pole face of the field magnets, pressing against the revolving drum like hair brush bristles—
trying to hold it back. This drum, in practice, is built up of discs of annealed steel, and the wires extending 
lengthwise on its face are held in place by slots to prevent them from flying off when the drum is whirled at high 
speed. 

Forms of annealed steel discs used in armature construction

The drum does not touch the face of the magnets, but revolves in an air space. If we give the electric impulses 
generated in these wires a chance to flow in a circuit—flow out of one end of the wires, and in at the other, the 
drum will require more and more power to turn it, in proportion to the amount of electricity we permit to flow. Thus, if 
one electric light is turned on, the drum will press back with a certain strength on the water wheel; if one hundred 
lights are turned on it will press back one hundred times as much. Providing there is enough power in the water 
wheel to continue turning the drum at its predetermined speed, the dynamo will keep on giving more and more 
electricity if asked to, until it finally destroys itself by fire. You cannot take more power, in terms of electricity, out of 
a dynamo that you put into it, in terms of mechanical motion. In fact, to insure flexibility and constant speed at all 
loads, it is customary to provide twice as much water wheel, or engine, power as the electrical rating of the
dynamo.

An armature partly wound, showing slots and commutator

We have seen that a water wheel is 85 per cent efficient under ideal conditions. A dynamo's efficiency in translating 
mechanical motion into electricity, varies with the type of machine and its size. The largest machines attain as high 
as 90 per cent efficiency; the smallest ones run as low as 40 per cent.

Measuring Electric Power
The amount of electricity any given dynamo can generate depends, generally speaking, on two factors, i.e., (1) the 
power of the water wheel, or other mechanical engine that turns the armature; and (2) the size (carrying capacity) 
of the wires on this drum.

Strength, of electricity, is measured in amperes. An ampere of electricity is the unit of the rate of flow and may be 
likened to a gallon of water per minute.

In surveying for water-power, in Chapter III, we found that the number of gallons or cubic feet of water alone 
did not determine the amount of power. We found that the number of gallons or cubic feet multiplied by the 
distance in feet it falls in a given time, was the determining factor—pounds (quantity) multiplied by feet per second
—(velocity).

Showing the analogy of water to volts and amperes of electricity

The same is true in figuring the power of electricity. We multiply the amperes by the number of electric impulses 
that are created in the wire in the course of one second. The unit of velocity, or pressure of the electric current is 
called a volt. Voltage is the pressure which causes electricity to flow. A volt may be likened to the velocity in feet 
per second of water in falling past a certain point. If you think a moment you will see that this has nothing to do with 
quantity. A pin-hole stream of water under 40 pounds pressure has the same velocity as water coming from a 
nozzle as big as a barrel, under the same pressure. So with electricity under the pressure of one volt or one 
hundred volts.

One volt is said to consist of a succession of impulses caused by one wire cutting 100,000,000 lines of magnetic 
force in one second. Thus, if the strength of a magnet consisted of one line of force, to create the pressure of one 
volt we would have to "cut" that line of force 100,000,000 times a second, with one wire; or 100,000 times a second 
with one thousand wires. Or, if a magnet could be made with 100,000,000 lines of force, a single wire cutting those 
lines once in a second would create one volt pressure. In actual practice, field magnets of dynamos are worked at 
densities up to and over 100,000 lines of force to the square inch, and armatures contain several hundred 
conductors to "cut" these magnetic lines. The voltage then depends on the speed at which the armature is driven. 
In machines for isolated plants, it will be found that the speed varies from 400 revolutions per minute, to 1,800, 
according to the design of dynamo used.

Pressure determines volume of flow in a given time

Multiplying amperes (strength) by volts (pressure), gives us watts (power). Seven hundred and forty-six watts of 
electrical energy is equal to one horsepower of mechanical energy—will do the same work. Thus an electric current 
under a pressure of 100 volts, and a density of 7.46 amperes, is one horsepower; as is 74.6 amperes, at 10 volts 
pressure; or 746 amperes at one volt pressure. For convenience (as a watt is a small quantity) electricity is 
measured in kilowatts, or 1,000 watts. Since 746 watts is one horsepower, 1,000 watts or one kilowatt is 1.34 
horsepower. The work of such a current for one hour is called a kilowatt-hour, and in our cities, where electricity is 
generated from steam, the retail price of a kilowatt-hour varies from 10 to 15 cents.

Now as to how electricity may be controlled, so that a dynamo will not burn itself up when it begins to generate.

Again we come back to the analogy of water. The amount of water that passes through a pipe in any given time, 
depends on the size of the pipe, if the pressure is maintained uniform. In other words the resistance of the pipe to 
the flow of water determines the amount. If the pipe be the size of a pin-hole, a very small amount of water will 
escape. If the pipe is as big around as a barrel, a large amount will force its way through. So with electricity. 
Resistance, introduced in the electric circuit, controls the amount of current that flows. A wire as fine as a hair will 
permit only a small quantity to pass, under a given pressure. A wire as big as one's thumb will permit a 
correspondingly greater quantity to pass, the pressure remaining the same. The unit of electrical resistance is 
called the ohm—named after a man, as are all electrical units.

Ohm's Law

The ohm is that amount of resistance that will permit the passage of one ampere, under the pressure of one volt. It 
would take two volts to force two amperes through one ohm; or 100 volts to force 100 amperes through the 
resistance of one ohm. From this we have Ohm's Law, a simple formula which is the beginning and end of all 
electric computations the farmer will have to make in installing his water-power electric plant. Ohm's Law tells us 
that the density of current (amperes) that can pass through a given resistance in ohms (a wire, a lamp, or an 
electric stove) equals volts divided by ohms—or pressure divided by resistance. This formula may be written in 
three ways, thus:

					C = E/R, or R = E/C or, E = C × R.

Or to express the same thing in words, current equals volts divided by ohms; ohms equals volts divided by current; 
or volts equals current multiplied by ohms. So, with any two of these three determining factors known, we can find 
the third. As we have said, this simple law is the beginning and end of ordinary calculations as to electric current, 
and it should be thoroughly understood by any farmer who essays to be his own electrical engineer. Once 
understood and applied, the problem of the control of the electric current becomes simple a b c.

Examples of Ohm's Law
Let us illustrate its application by an example. The water wheel is started and is spinning the dynamo at its rated 
speed, say 1,500 r.p.m. Two heavy wires, leading from brushes which collect electricity from the revolving 
armature, are led, by suitable insulated supports to the switchboard, and fastened there. They do not touch each 
other. 

Dynamo mains must not be permitted to touch each other under any conditions. They are separated by say four 
inches of air. Dry air is a very poor conductor of electricity. Let us say, for the example, that dry air has a resistance 
to the flow of an electric current, of 1,000,000 ohms to the inch—that would be 4,000,000 ohms. How much 
electricity is being permitted to escape from the armature of this 110-volt dynamo, when the mains are separated 
by four inches of dry air? Apply Ohm's law, C equals E divided by R. E, in this case is 110; R is 4,000,000; 
therefore C (amperes) equals 110/4,000,000—an infinitesimal amount—about .0000277 ampere.

Let us say that instead of separating these two mains by air we separated them by the human body—that a man 
took hold of the bare wires, one in each hand. The resistance of the human body varies from 5,000 to 10,000 
ohms. In that case C (amperes) equals 110/5,000, or 110/10,000—about 1/50th, or 1/100th of an ampere. This 
illustrates why an electric current of 110 volts pressure is not fatal to human beings, under ordinary circumstances. 
The body offers too much resistance. But, if the volts were 1,100 instead of the usual 110 used in commercial and 
private plants for domestic use, the value of C, by this formula at 5,000 ohms, would be nearly 1/5th ampere. To 
drive 1/5th ampere of electricity through the human body would be fatal in many instances. The higher the voltage, 
the more dangerous the current. In large water-power installations in the Far West, where the current must be 
transmitted over long distances to the spot where it is to be used, it is occasionally generated at a pressure of 
150,000 volts. Needless to say, contact with such wires means instant death. Before being used for commercial or 
domestic purposes, in such cases, the voltage is "stepped down" to safe pressures—to 110, or to 220, or to 550 
volts—always depending on the use made of it.

Now, if instead of interposing four inches of air, or the human body, between the mains of our 110-volt dynamo, we 
connected an incandescent lamp across the mains, how much electricity would flow from the generator? An 
incandescent lamp consists of a vacuum bulb of glass, in which is mounted a slender thread of carbonized fibre, or 
fine tungsten wire. To complete a circuit, the current must flow through this wire or filament. In flowing through it, 
the electric current turns the wire or filament white hot—incandescent—and thus turns electricity back into light, 
with a small loss in heat. In an ordinary 16 candlepower carbon lamp, the resistance of this filament is 220 ohms. 
Therefore the amount of current that a 110-volt generator can force through that filament is 110/220, or ½ ampere.

Armature and field coils of a direct current dynamo

One hundred lamps would provide 100 paths of 220 ohms resistance each to carry current, and the amount 
required to light 100 such lamps would be 100 × ½ or 50 amperes. Every electrical device—a lamp, a stove, an 
iron, a motor, etc.,—must, by regulations of the Fire Underwriters' Board be plainly marked with the voltage of the 
current for which it is designed and the amount of current it will consume. This is usually done by indicating its 
capacity in watts, which as we have seen, means volts times amperes, and from this one can figure ohms, by the 
above formulas.

A Short Circuit
We said a few paragraphs back that under no conditions must two bare wires leading from electric mains be 
permitted to touch each other, without some form of resistance being interposed in the form of lamps, or other 
devices. Let us see what would happen if two such bare wires did touch each other. Our dynamo as we discover 
by reading its plate, is rated to deliver 50 amperes, let us say, at 110 volts pressure. Modern dynamos are rated 
liberally, and can stand 100% overload for short periods of time, without dangerous overheating. Let us say that 
the mains conveying current from the armature to the switchboard are five feet long, and of No. 2 B. & S. gauge 
copper wire, a size which will carry 50 amperes without heating appreciably. The resistance of this 10 feet of No. 2 
copper wire, is, as we find by consulting a wire table, .001560 ohms. If we touch the ends of these two five-foot 
wires together, we instantly open a clear path for the flow of electric current, limited only by the carrying capacity of 
the wire and the back pressure of .001560 ohms resistance. Using Ohm's Law, C equals E divided by R, we find 
that C (amperes) equals 110/.001560 or 70,515 amperes!

A direct current dynamo

Unless this dynamo were properly protected, the effect of such a catastrophe would be immediate and probably 
irreparable. In effect, it would be suddenly exerting a force of nearly 10,000 horsepower against the little 10 
horsepower water wheel that is driving this dynamo. The mildest thing that could happen would be to melt the feed-
wire or to snap the driving belt, in which latter case the dynamo would come to a stop. If by any chance the little 
water wheel was given a chance to maintain itself against the blow for an instant, the dynamo, rated at 50 amperes, 
would do its best to deliver the 70,515 amperes you called for—and the result would be a puff of smoke, and a 
ruined dynamo. This is called a "short circuit"—one of the first "don'ts" in handling electricity.

As a matter of fact every dynamo is protected against such a calamity by means of safety devices, which will be 
described in a later chapter—because no matter how careful a person may be, a partial short circuit is apt to occur. 
Happily, guarding against its disastrous effects is one of the simplest problems in connection with the electric plant.

Direct Current and Alternating Current
When one has mastered the simple Ohm's Law of the electric circuit, the next step is to determine what type of 
electrical generator is best suited to the requirements of a farm plant.

In the first place, electric current is divided into two classes of interest here—alternating, and direct.

We have seen that when a wire is moved through the field of a magnet, there is induced in it two pulsations—first in 
one direction, then in another. This is an alternating current, so called because it changes its direction. If, with our 
armature containing hundreds of wires to "cut" the lines of force of a group of magnets, we connected the 
beginning of each wire with one copper ring, and the end of each wire with another copper ring, we would have 
what is called an alternating-current dynamo. Simply by pressing a strap of flexible copper against each revolving 
copper ring, we would gather the sum of the current of these conductors. Its course would be represented by the 
curved line in the diagram, one loop on each side of the middle line (which represents time) would be a cycle. The 
number of cycles to the second depends on the speed of the armature; in ordinary practice it is usually twenty-five 
or sixty. Alternating current has many advantages, which however, do not concern us here. Except under very rare 
conditions, a farmer installing his own plant should not use this type of machine.

Diagram of alternating and direct current

If, however, instead of gathering all the current with brushes bearing on two copper rings, we collected all the 
current traveling in one direction, on one set of brushes—and all the current traveling in the other direction on 
another set of brushes,—we would straighten out this current, make it all travel in one direction. Then we would 
have a direct current. A direct current dynamo, the type generally used in private plants, does this. Instead of 
having two copper rings for collecting the current, it has a single ring, made up of segments of copper bound 
together, but insulated from each other, one segment for each set of conductors on the armature. This ring of 
many segments, is called a commutator, because it commutates, or changes, the direction of the electric impulses, 
and delivers them all in one direction. In effect, it is like the connecting rod of a steam engine that straightens out 
the back-and-forth motion of the piston in the steam cylinder and delivers the motion to a wheel running in one 
direction.

Such a current, flowing through a coil of wire would make a magnet, one end of which would always be the north 
end, and the other end the south end. An alternating current, on the other hand, flowing through a coil of wire, 
would make a magnet that changed its poles with each half-cycle. It would no sooner begin to pull another magnet 
to it, than it would change about and push the other magnet away from it, and so on, as long as it continued to flow. 
This is one reason why a direct current dynamo is used for small plants. Alternating current will light the same 
lamps and heat the same irons as a direct current; but for electric power it requires a different type of motor.

Types of Direct Current Dynamos
Just as electrical generators are divided into two classes, alternating and direct, so direct current machines are 
divided into three classes, according to the manner in which their output, in amperes and volts, is regulated. They 
differ as to the manner in which their field magnets (in whose field of force the armature spins) are excited, or made 
magnetic. They are called series, shunt, and compound machines.

The Series Dynamo
By referring to the diagram, it will be seen that the current of a series dynamo issues from the armature mains, and 
passes through the coils of the field magnets before passing into the external circuit to do its work. The residual 
magnetism, or the magnetism left in the iron cores of the field magnets from its last charge, provides the initial 
excitation, when the machine is started. As the resistance of the external circuit is lowered, by turning on more and 
more lights, more and more current flows from the armature, through the field magnets. Each time the resistance is 
lowered, therefore, the current passing through the field magnets becomes more dense in amperes, and makes 
the field magnets correspondingly stronger.

We have seen that the voltage depends on the number of lines of magnetic force cut by the armature conductors in a given time. If the speed remains constant then, and the magnets grow stronger and stronger, the voltage will rise in a straight line. When no current is drawn, it is 0; at full load, it may be 100 volts, or 500, or 1,000 according to the machine. This type of machine is used only in street lighting, in cities, with the lights connected in "series," or one after another on the same wire, the last lamp finally returning the wire to the machine to complete the circuit. This type of dynamo has gained the name for itself of "mankiller," as its voltage becomes enormous at full load. It is unsuitable, in every respect, for the farm plant. Its field coils consist of a few turns of very heavy wire, enough to carry all the current of the external circuit, without heating.
Connections of a series dynamo

The Shunt Dynamo

The shunt dynamo, on the other hand, has field coils connected directly across the circuit, from one wire to another, instead of in "series." These coils consist of a great many turns of very fine wire, thus introducing resistance into the circuit, which limits the amount of current (amperes) that can be forced through them at any given voltage. As a shunt dynamo is brought up to its rated speed, its voltage gradually rises until a condition of balance occurs between the field coils and the armature. There it remains constant. When resistance on the external circuit is lowered, by means of turning on lamps or other devices, the current from the armature increases in working power, by increasing its amperes. Its voltage remains stationary; and, since the resistance of its field coils never changes, the magnets do not vary in strength.

Connections of a shunt dynamo

The objection to this type of machine for a farm plant is that, in practice, the armature begins to exercise a 
de-magnetizing effect on the field magnets after a certain point is reached—weakens them; consequently the 
voltage begins to fall. The voltage of a shunt dynamo begins to fall after half-load is reached; and at full load, it has 
fallen possibly 20 per cent. A rheostat, or resistance box on the switchboard, makes it possible to cut out or switch 
in additional resistance in the field coils, thus varying the strength of the field coils, within a limit of say 15 per cent, 
to keep the voltage constant. This, however, requires a constant attendance on the machine. If the voltage were 
set right for 10 lights, the lights would grow dim when 50 lights were turned on; and if it were adjusted for 50 lights, 
the voltage would be too high for only ten lights—would cause them to "burn out."

Shunt dynamos are used for charging storage batteries, and are satisfactory for direct service only when an 
attendant is constantly at hand to regulate them.

The Compound Dynamo
The ideal between these two conditions would be a compromise, which included the characteristics of both series 
and shunt effects. That is exactly what the compound dynamo effects.

A compound dynamo is a shunt dynamo with just enough series turns on its field coils, to counteract the 
de-magnetizing effect of the armature at full load. A machine can be designed to make the voltage rise gradually, 
or swiftly, by combining the two systems. For country homes, the best combination is a machine that will keep the 
voltage constant from no load to full load. A so-called flat-compounded machine does this. In actual practice, this 
voltage rises slightly at the half-load line—only two or three volts, which will not damage the lamps in a 110-volt 
circuit.

The compound dynamo is therefore self-regulating, and requires no attention, except as to lubrication, and the incidental care given to any piece of machinery. Any shunt dynamo can be made into a compound dynamo, by winding a few turns of heavy insulated wire around the shunt coils, and connecting them in "series" with the external circuit. How many turns are necessary depends on conditions. Three or four turns to each coil usually are sufficient for "flat compounding." If the generating plant is a long distance from the farm house where the light, heat, and power are to be used, the voltage drops at full load, due to resistance of the transmission wires. To overcome this, enough turns can be wound on top of the shunt coils to cause the voltage to rise at the switchboard, but remain stationary at the spot where the current is used. The usual so-called flat-compounded dynamo, turned out by manufacturers, provides
Connections of a compound dynamo  for constant voltage at the switchboard.

Such a dynamo is eminently fitted for the farm electric plant. Any other type of machine is bound to cause constant 
trouble and annoyance.

End of Excerpt.
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