Transmission of Forces Through Liquids

layers due to cooling. The cooling tends to increase the density of the air. Atmospheric pressures are quite large, but in most instances practically the same pressure is present on all sides of objects so that no single surface is subjected to a great load. Atmospheric pressure acting on the surface of a liquid (fig. 2-3, view A) is transmitted equally throughout the liquid to the walls of the container, but is balanced by the same atmospheric pressure acting on the outer walls of the container. In view B of figure 2-3, atmospheric pressure acting on the surface of one piston is balanced by the same pressure acting on the surface of the other piston. The different areas of the two surfaces make no difference, since for a unit of area, pressures are balanced. TRANSMISSION OF FORCES THROUGH LIQUIDS When the end of a solid bar is struck, the main force of the blow is carried straight through the bar to the other end (fig. 2-4, view A). This happens because the bar is rigid. The direction of the blow almost entirely determines the direction of the transmitted force. The more rigid Figure 2-4.—Transmission of force: (A) solid; (B) fluid. the bar, the less force is lost inside the bar or transmitted outward at right angles to the direction of the blow. When a force is applied to the end of a column of confined liquid (fig. 2-4, view B), it is transmitted straight through to the other end and also equally and undiminished in every direction throughout the column—forward, backward, and sideways—so that the containing vessel is literally filled with pressure. An example of this distribution of force is illustrated in figure 2-5. The flat hose takes on Figure 2-3.—Effects of atmospheric pressure. Figure 2-5.—Distribution of force. 2-3