{"id":953,"date":"2020-04-18T12:55:59","date_gmt":"2020-04-18T11:55:59","guid":{"rendered":"https:\/\/blogs.ua.es\/jjrr2011\/?p=953"},"modified":"2020-04-18T12:57:51","modified_gmt":"2020-04-18T11:57:51","slug":"chapter6-ii-stability","status":"publish","type":"post","link":"https:\/\/blogs.ua.es\/jjrr2011\/2020\/04\/18\/chapter6-ii-stability\/","title":{"rendered":"Chapter 6: Equilibrium of rigid bodies (II). Stability"},"content":{"rendered":"

Any system of forces may be replaced by a resultant force R<\/strong> and a resultant moment (couple of a force) M<\/strong> at any point of the space. We call this couple vectors (R<\/strong>, M<\/strong>) as system “torsor”. Figure (from Meriam & Kraige 7th edition) shows a system of forces acting on a rigid body.<\/p>\n

\"\"<\/a>The point O selected as the point of concurrency for the forces is arbitrary, and the magnitude and direction of M<\/strong> depend on the particular point O selected. The magnitude and direction of R<\/strong>, however, are invariant, i.e. are the same no matter which point is selected.<\/p>\n

If a system of forces acting on a body are such that the resultant force and resultant moment at point O are mutually perpendicular, the whole system can be replaced by a single force acting along a new line of action such that it causes the same moment with respect to O. We now examine the resultants for several special system of forces:<\/p>\n