Elements of MechanicsA.S. Barnes & Company, 1866 |
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Page 94
... vessels ; the force of magnetic attraction and repulsion , as shown in the magnetic telegraph and various magnetic machines ; the elastic force of springs , as shown in watches and various other machines . Of these motors , the most ...
... vessels ; the force of magnetic attraction and repulsion , as shown in the magnetic telegraph and various magnetic machines ; the elastic force of springs , as shown in watches and various other machines . Of these motors , the most ...
Page 176
... vessel 7 or 8 inches deep , and having 6.8 in . of this depth filled with mercury . The exact quantity of mercury being dependent on the weight and expansibility of the other parts of the pendulum , must be determined by experiment in ...
... vessel 7 or 8 inches deep , and having 6.8 in . of this depth filled with mercury . The exact quantity of mercury being dependent on the weight and expansibility of the other parts of the pendulum , must be determined by experiment in ...
Page 208
... vessel of water be made to revolve about a vertical axis , the interior particles will recede from the axis on account of the centrifugal force , and will be heaped up about the sides of the vessel , imparting a concave form to the ...
... vessel of water be made to revolve about a vertical axis , the interior particles will recede from the axis on account of the centrifugal force , and will be heaped up about the sides of the vessel , imparting a concave form to the ...
Page 237
... vessel , is normal to that sur- face ; for if it were not , we might resolve it into two compo- nents , one normal to the surface , and the other tangential ; the effect of the former would be destroyed by the resistance of the vessel ...
... vessel , is normal to that sur- face ; for if it were not , we might resolve it into two compo- nents , one normal to the surface , and the other tangential ; the effect of the former would be destroyed by the resistance of the vessel ...
Page 238
... of the surface of a vessel containing a heavy fluid is equal to the weight of a prism of the fluid whose base is equal to that surface , and shose altitude is equal to its depth below the 238 MECHANICS . Pressure due to Weight.
... of the surface of a vessel containing a heavy fluid is equal to the weight of a prism of the fluid whose base is equal to that surface , and shose altitude is equal to its depth below the 238 MECHANICS . Pressure due to Weight.
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Common terms and phrases
acceleration due algebraic sum angular velocity atmosphere axes axis of suspension axle body called centre of gravity centrifugal force cistern coefficient column components cord cubic cubic foot curve cylinder denote the angle direction distance elementary entire equal Equation equilibrium feet fluid force applied force of gravity forces acting friction Hence horizontal hydrometer inclined plane inertia instrument length lever arm liquid machine manometer mass mercury moment of inertia motion moving force orifice parallel parallelogram of forces particles passing pendulum perpendicular pipe piston point of application position power and resistance pressure principle principle of moments pulley pump quantity radius radius of gyration represent respect resultant rope rotation screw SOLUTION specific gravity steam Substituting suppose temperature tension tion triangle tube upper surface vertical vessel vibration volume weight wheel whence whilst
Popular passages
Page 237 - ... and altitude equal to the depth of the centre of gravity of the surface below the surface of the fluid.
Page 182 - ... plus the product of the area and the square of the distance between the axes.
Page 221 - This electromotive force may be resolved into two components, one parallel and the other perpendicular to I, as shown, for example, in Fig.
Page 27 - That is, if two forces are represented in direction and intensity by the adjacent sides of a parallelogram, their resultant will be represented in direction and intensity by that diagonal which passes through their point of intersection.
Page 315 - ... is equal to the weight of a column of water whose base is the section of the piston, and whose height is the distance of the level of the water in the barrel AC, above the level in the reservoir.
Page 66 - ... the straight line drawn from the vertex to the middle point of the base.
Page 39 - Lami's Theorem. If three forces acting on a particle keep it in equilibrium, each is proportional to the sine of the angle between the other two.
Page 42 - Hence, the moment of the resultant of two forces is equal to the algebraic sum of the moments of the forces taken separately. 53. Forces Acting at Different Points. Parallel Forces.— We have thus far considered forces acting upon a single particle, or upon one point of a body. If, how- Fia 33...
Page 60 - Properties of Areas If a body remains in equilibrium under a system of forces, the following conditions obtain: 1 The algebraic sum of the components of the forces in any given direction is zero. 2 The algebraic sum of the moments of the forces with respect to any given axis is zero. The above statements are verbal expressions of the equations of equilibrium. In the absence of any notes to the contrary, a clockwise moment is considered positive; a counterclockwise moment, negative GRAPHICAL ANALYSIS...
Page 159 - W oo /, and therefore r varies directly as the length and inversely as the square root of the tension.