![]() Simply supported beam with uniform distributed load (UDL) In the following table, the formulas describing the static response of the simple beam under a uniform distributed load w are presented. Either the total force W or the distributed force per length w may be given, depending on the circumstances. The total amount of force applied to the beam is W=w L, where L the span length. The load w is distributed throughout the beam span, having constant magnitude and direction. Simply supported beam with uniform distributed load I : the moment of inertia of the cross-section around the elastic neutral axis of bending.E : the material modulus of elasticity (Young's modulus).A different set of rules, if followed consistently would also produce the same physical results. These rules, though not mandatory, are rather universal. The bending moment is positive when it causes tension to the lower fiber of the beam and compression to the top fiber.The shear force is positive when it causes a clock-wise rotation of the part. ![]() ![]() The axial force is considered positive when it causes tension to the part.Sign conventionįor the calculation of the internal forces and moments, at any section cut of the beam, a sign convention is necessary. The last two assumptions satisfy the kinematic requirements for the Euler Bernoulli beam theory that is adopted here too. This is the case when the cross-section height is quite smaller than the beam length (10 times or more) and also the cross-section is not multi layered (not a sandwich type section). Every cross-section that initially is plane and also normal to the longitudinal axis, remains plane and and normal to the deflected axis too.The cross section is the same throughout the beam length.The loads are applied in a static manner (they do not change with time).The material is homogeneous and isotropic (in other words its characteristics are the same in ever point and towards any direction). ![]() The calculated results in the page are based on the following assumptions: For a simply supported beam that carries only transverse loads, the axial force is always zero, therefore it is often neglected. Typically, for a plane structure, with in plane loading, the internal actions of interest are the axial force N, the transverse shear force V and the bending moment M. The static analysis of any load carrying structure involves the estimation of its internal forces and moments, as well as its deflections. To the contrary, a structure that features more supports than required to restrict its free movements is called redundant or indeterminate structure. These type of structures, that offer no redundancy, are called critical or determinant structures. If a local failure occurs the whole structure would collapse. Therefore, the simply supported beam offers no redundancy in terms of supports. Obviously this is unwanted for a load carrying structure. Removing any of the supports or inserting an internal hinge, would render the simply supported beam to a mechanism, that is body the moves without restriction in one or more directions. The roller support also permits the beam to expand or contract axially, though free horizontal movement is prevented by the other support. Both of them inhibit any vertical movement, allowing on the other hand, free rotations around them. It features only two supports, one at each end. The sum and product of three distinct positive integers are 15 and 45, respectively.The simply supported beam is one of the most simple structures. Value of t for a germ population to double its original value Ratio of force of water to force of oil acting on submerged plateįind the approximate height of a mountain by using mercury barometerĮquivalent head, in meters of water, of 150 kPa pressureĬompute for the discharge on the sewer pipeĬoefficient of discharge of circular orifice in a wall tank under constant headĪbsolute pressure of oil tank at 760 mm of mercury barometerĪbsolute pressure at 2.5 m below the oil surfaceįind $x$ from $xy = 12$, $yz = 20$, and $zx = 15$ Which curve has a constant first derivative?ĭepth and vertex angle of triangular channel for minimum perimeterĬalculation for the location of support of vertical circular gate
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