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In the wedge, the friction against the sides is very great, at least equal to the force to be overcome, because the wedge retains any position to which it is driven; and therefore the resistance is doubled by the friction. But then the wedge has a great advantage over all the other powers, arising from the force of percussion or blow with which the back is struck, which is a force incomparably greater than any dead weight or pressure, such as is employed in other machines. And accordingly we find it produces effects vastly superior to those of any other power; such as the splitting and raising the largest and hardest rocks, the raising and lifting the largest ship, by driving a wedge below it, which a man can do by the blow of a mallet: and thus it appears that the small blow of a hammer, on the back of a wedge is incomparably greater than any mere pressure, and will overcome it.

OF THE SCREW.

83. THE SCREW is one of the six mechanical powers, chiefly used in pressing or squeezing bodies close, though sometimes also in raising weights.

The screw is a spiral thread or groove cut round a cylinder, and every where making the same angle with the length of it. So that if the surface of the cylinder, with this spiral thread on it, where unfolded and stretched into a plane, the spiral thread would form a straight inclined plane, whose length would be to its height, as the circumference of the cylinder, is to the distance between two threads of the screw : as is evident by considering that, in making one round, the spiral rises along the cylinder the distance between the two threads.

84. PROP. The energy of a power applied to turn a screw round, is to the force with which it presses upward or downward, setting aside the friction, as the distance between two threads, is to the circumference where the power is applied.

The screw being an inclined plane, or half wedge, whose height is the distance between two threads, and its base the circumference of the screw; and the force in the horizontal direction, being to that in the vertical one, as the lines perpendicular to them, namely, as the height of the plane, or distance of the two threads, is to the base of the plane, or circumference of the screw; therefore the power is to the pressure, as the distance of two threads is to that circumference. But, by means of a handle or lever, the gain in

power is increased in the proportion of the radius of the screw to the radius of the power, or length of the handle, or as their circumferences. Therefore, finally, the power is to the pressure, as the distance of the threads, is to the circumfe rence described by the power.

85. Corol. When the screw is put in motion; then the power is to the weight which would keep it in equilibrio, as the velocity of the latter is to that of the former; and hence their two momenta are equal, which are produced by multiplying each weight or power by its own velocity. So that this is a general property in all the mechanical powers, namely, that the momentum of a power is equal to that of the weight which would balance it in equilibrio; or that each of them is reciprocally proportional to its velocity.

SCHOLIUM.

86. Hence we can easily compute the force of any machine turned by a screw. Let the annexed figure represent a press driven by a screw, whose threads are each a quarter of an inch asunder: and let the screw be turned by a handle of 4 feet long, from A to B ; then, if the natural force of a man, by which he can lift,

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pull, or draw, be 150 pounds; and it be required to determine with what force the screw will press on the board at D, when the man turns the handle at A and B, with his whole force. Then the diameter AB of the power being 4 feet, or 48 inches, its circumference is 48 X 3-1416 or 150 nearly; and the distance of the threads being of an inch; therefore the power is to the pressure, as 1 to 603; but the power is equal to 150lb; theref. as 1: 603 :: 150: 90480; and consequently the pressure at D is equal to a weight of 90480 pounds, independent of friction.

87. Again, if the endless screw AB be turned by a handle AC of 20 inches, the threads of the screw being distant half an inch each; and the screw turns a toothed wheel E, whose pinion L turns another wheel F, and the pinion м of this another wheel G, to the pinion or barrel of which is hung a weight w; it is required to determine what weight the man will be able to raise, working at the handle c; supposing

the diameters of the wheels B
to be 18 inches, and those
of the pinions and barrel 2
inches; the teeth and pi-
nions being all of a size.

Here 20 x 3.1416 × 2 = 125-664, is the circumference of the power.

And 125-664 to, or 251-328 to 1, is the force of the screw alone.

Also, 18 to 2, or 9 to 1, being the proportion of the wheels to the pinions; and as there are three of them, therefore 93 to 13, or 729 to 1, is the power gained by the wheels.

Consequently 251.328 X 729 to 1, or 183218 to 1 nearly, is the ratio of the power to the weight, arising from the advantage both of the screw and the wheels.

A

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But the power is 150lb; therefore 150 x 183218, or 27482716 pounds, is the weight the man can sustain, which is equal to 12269 tons weight.

But the power has to overcome, not only the weight, but also the friction of the screw, which is very great, in some cases equal to the weight itself, since it is sometimes sufficient to sustain the weight, when the power is taken off.

88. Upon the same principle the advantage of any other combination of the mechanical powers may be computed: allowance, however, being always to be made for stiffness of cords, friction, and other causes of resistance.

ON THE CENTRE OF GRAVITY.

89. THE CENTRE OF GRAVITY of a body, or of a system of bodies, is a certain point within it, or connected with it, on which the body being freely suspended, it will rest in any

position, and that centre will always tend to descend to the lowest place to which it can get, when it is not the point of suspension.

90. PROP. If a perpendicular to the horizon, from the centre of gravity of any body, fall within the base of the body, it will rest in that position; but if the perpendicular fall out of the base, the body will not rest in that position, but will fall down.

E

C

D

ba

For, if CB be the perp. from the centre of gravity c, within the base: then the body cannot fall over towards A; because, in turning on the point a, the centre of gravity c would describe an arc which would rise from c to E; contrary to the nature of that centre, which only rests permanently when in the lowest place. For the same reason, the body will not fall towards D. And therefore it will stand in that position.

But if the perpendicular fall out of the base, as cb; then the body will fall over on that side because, in turning on the point a, the centre c descends by describing the descending arc ce.

91. Corol. 1. If a perpendicular, drawn from the centre of gravity, fall just on the extremity of the base, the body may stand; but any the least force will cause it to fall that way. And the nearer the perpendicular is to any side, or the narrower the base is, the easier it will be made to fall, or be pushed over that way; because the centre of gravity has the less height to rise: which is the reason that a globe is made to roll on a smooth plane by any the least force. But the nearer the perpendicular is to the middle of the base, or the broader the base is, the firmer the body stands.

92. Corol. 2. Hence if the centre of gravity of a body be supported, the whole body is supported. And the place of the centre of gravity may, in many inquiries, be accounted the place of the body; for into that point the whole matter of the body may be supposed to be collected, and therefore all the force also with which it endeavours to descend.

93. Corol. 3. From the property which the centre of gravity has, of tending to descend to the lowest point, is de. rived an easy mechanical method of finding that centre.

Thus, if the body be hung up by any point a, and a plumb line AB be hung by the same point, it will pass through the centre of gravity; because, that centre is not in the lowest point till it fall in the plumb line. Mark the line AB on it. Then hang the body up by any other point D, with a plumb line DE, which will also pass through the centre of gravity, for the same reason as before; and therefore that centre must be at c where the two plumb lines cross each other.

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94. Or, if the body be suspended by two or more cords, GF, GH, &c. then a plumb line from the point &, will cut the body in its centre of gravity c.

E

E

H

95. Likewise, because a body rests when its centre of gravity is supported, but not else; we hence derive another easy method of finding that centre mechanically. For, if the body be laid on the edge of a prism, or over one side of a table, and moved backward and forward till it rest, or balance itself; then is the centre of gravity just over the line of the edge. And if the body be then shifted into another position, and balanced on the edge again, this line will also pass by the centre of gravity; and consequently the intersection of the two will indicate the place of the centre itself.

The place of the centre of gravity may be investigated, from its analogy to the centre of parallel forces; but the following method is adopted here, as in some respects easier of comprehension.

96. PROP. The common centre of gravity c of any two bodies A, B, divides the line joining their respective centres, into two parts, which are reciprocally as the bodies.

That is, AC: BC: B: A.

For, if the centre of gravity c be supported, the two bodies A and B will be supported, and will

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