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Chapter 5: Axial Force, Shear, and Bending Moment

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Monark Sutariya
Monark Sutariya

Engineering Mechanics of Solids by Popov Chapter 5: Axial Force, Shear, and Bending Moment

Engineering
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Chapter 5 Axial Force, Shear, and Bending Moment Mechanics of Solids
β€’ Even for a beam with all forces on the same plane, i.e., a planar beam problem, a system of three internal force components can develop at a section: the axial force, the shear and the bending moment β€’ For members in 3-D systems, there are six possible internal force components: an axial force, two shear components, two bending moment components, and a torque. Part A - Calculation of Reaction β€’ 3 types of supports for planar structures, identified by the kind of resistance they offer to the forces. β€’ One type of support is physically realized by a roller or a link. It is capable of resisting a force in only one specific line of action.
Fig. 1: link and roller types of supports (the only possible lines of action of the reactions are shown by the dashed lines) β€’ The link shown in Fig. 1(a) can resist a force only in the direction of line 𝐴𝐡. The roller in Fig. 1(b) can resist only a vertical force, whereas the rollers in Fig. 1(c) can resist only a force that acts perpendicular to the plane 𝐢𝐷. β€’ A reaction of these types corresponds to a single unknown when equation of statics is applied.
β€’ Another type of support that may be used is a pin. In construction, such a support is realized by using a detail shown in Fig. 2(a). While, Fig. 2(b) is diagrammatical representation. Fig. 2: Pinned support: (a) actual, (b) diagrammatic β€’ A pinned support is capable of resisting a force acting in any direction of the plane. In general, the reaction at such a support may have two components in horizontal and vertical directions. β€’ The third type of support is able to resist a force in any direction and is also capable of resisting a moment or a couple. A system of three forces can exist at such a support, two components of force and a moment. Such a support is called a fixed support.
β€’ In which, the built-in end is fixed or prevented from rotating as Fig. 3 Fig. 3: Fixed support β€’ The roller and pin supports are termed as simple supports. Fig. 4: three basic types of idealized supports for planar structural systems. Simple supports: (a) a pinned support resists two force components, and (b) a roller or a link resists only one directed force Fixed support: (c) it resists two force components and a moment
Diagrammatic Conventions for Loading β€’ Frequently a force is applied to a beam through a post, a hanger, or a bolted detail, as shown in Fig. 5(a). Such arrangements apply the force over a very limited portion of the beam and are idealized as concentrated forces. Fig. 5: Concentrated loading on a beam, (a) actual, (b) idealized β€’ In a warehouse, goods may be piled up along the length of a beam. Such distributed loads are defined by their load intensity at any point in force per unit length.
β€’ Two kinds of distributed loads are particularly important: the uniformly distributed loads and the uniformly varying loads Fig. 6: Distributed loading on a beam, (a) actual, (b) idealized β€’ Uniformly varying loads act on the vertical and inclined walls of a vessel containing liquid. Fig. 7, where it is assumed that the vertical beam is one meter wide and 𝛾 (𝑁/π‘š3 ) is the unit weight of the liquid. β€’ The maximum intensity of the load of π‘ž0(𝑁/π‘š) is applicable only to an infinitesimal length of the beam. It is twice as large as the average intensity of pressure.
Fig. 7: Hydrostatic loading on a vertical wall β€’ The total force exerted by such a loading on a beam is π‘ž0β„Ž 2 N, and its resultant acts at a distance h/3 above the vessel’s bottom. Horizontal bottoms of vessels containing liquid are loaded uniformly. various aerodynamic loadings are of distributed types. β€’ It is conceivable to load a beam with a concentrated moment applied to the beam essentially at a point. Consider, Fig. 8(a) and its diagrammatic representation shown in Fig. 8(c).
Fig. 8: A method for applying a concentrated moment to a beam β€’ In Fig. 9, to maintain the applied force 𝑃 in the equilibrium at joint 𝐢, a shear 𝑃 and a moment 𝑃𝑑 must be developed at the support, Fig. 9(c). These forces apply a concentrated moment and an axial force, as shown in Fig. 9(b)
Classification of Beams Fig. 9: loaded horizontal member applies an applied force and a concentrated moment to the vertical member β€’ If the supports at the ends of a beam are either pins or rollers, the beams are simply supported, or simple beams, Figs. 10(a) and (b) β€’ Fixed beam, if the ends have fixed supports, Fig. 10(c)
Fig. 10: Types of Beams β€’ Restrained beams, one end is fixed and other is simply supported, Fig. 10(d). This beam is restrained from rotation. β€’ Cantilever beam, fixed at one end and completely free at the other end, Fig. 10(e)
β€’ If the beam projects beyond a support, Overhanging beam, Fig. 10(f) β€’ If intermediate supports are provided for a physically continuous member acting as a beam, Fig. 10(g), Continuous beam. β€’ The distance 𝐿, between supports is called a span. In a continuous beam, there are several spans that may be of varying lengths. β€’ The beam shown in Fig. 10(a) is a simple beam with a concentrated load, whereas the beam in Fig. 10(b) is a simple beam with a uniformly distributed load. β€’ If for a planar beam or a frame, the number of unknown reaction components, including a bending moment, does not exceed three, such a system is externally statically determinate. β€’ These unknowns can be found from the equations of static equilibrium.
Calculation of Beam Reactions β€’ When all the forces are applied in one plane, three equations of static equilibrium are available for the analysis. 𝐹π‘₯ = 0 , 𝐹𝑦 = 0 , 𝑀𝑧 = 0 β€’ From straight beams in the horizontal position, the x-axis will be taken in an horizontal direction, the y-axis in the upward vertical direction, and the z-axis normal to the plane of the paper. β€’ The deformation of beams, being small, is neglected when the equations of statics are applied.
Part B - Direct Approach for Axial Force, Shear and Bending Moment Application of the method of sections β€’ The analysis of any beam or frame for determining the internal forces begins with the preparation of a free-body diagram showing both the applied and the reactive forces. β€’ If a whole body is in equilibrium, any part of it is likewise in equilibrium. β€’ Consider a beam shown in Fig. 11, with certain concentrated and distributed forces acting on it. The reactions can be computed using equations of static equilibrium. At a section of such a member, a vertical force, a horizontal force, and a moment are necessary to maintain the isolated part in equilibrium.
Axial Force in Beams Fig. 11: An application of the method of sections to a statistically determinate beam
β€’ A horizontal force such as 𝑃, shown in Fig. 11(b) and (c) may be necessary at section of a beam to satisfy the conditions of equilibrium. The magnitude and sense of this force follows from a particular solution of the equation, 𝐹π‘₯ = 0. β€’ If the horizontal force 𝑃 acts towards the section, it is called a β€˜thrust’; if away, it is called β€˜axial tension’. β€’ It is imperative to apply this force through the centroid of the cross- sectional area of the member to avoid bending. β€’ The line of action of the axial force will always be directed through the centroid of the beam’s cross-sectional area. β€’ The tensile force at a section is customarily taken positive. β€’ The axial force (thrust) at section 𝑋 βˆ’ 𝑋 in Figs. 11(b) and (c) is equal to the horizontal force 𝑃2.
Shear in Beams β€’ To maintain a segment of a beam, as shown in Fig. 11(b), in equilibrium, there must be an internal vertical force 𝑉, acting at right angles to the axis of the beam, is called the shear force. β€’ The shear is numerically equal to the algebraic sum of all the vertical components of the external forces acting on the isolated segment, but it is opposite in direction. β€’ Given the qualitative data shown in Fig. 11(b), 𝑉 is opposite in the direction to the downward load to the left of the section. This shear may also be computed by considering the right hand segment shown in Fig. 11(c). β€’ The same shear shown in Figs. 11(b) and (c) at the section 𝑋 βˆ’ 𝑋 is opposite in direction in the two diagrams.
β€’ For the part of the downward load π‘Š1 to the left of section 𝑋 βˆ’ 𝑋, the beam at the section provides an upward support to maintain vertical forces in equilibrium. Conversely, the loaded portion of the beam exerts a downward force on the beam, as shown in Fig. 11(c) β€’ A reversal in the direction of shear takes place at one section or another along a beam. β€’ A downward internal force 𝑉 acting at a section on an isolated left section of the beam, as in Fig. 12(a), or an upward force 𝑉 acting at the same section on the right segment of the beam, as in Fig. 12(b),corresponds to positive shear. β€’ Positive shears are shown in Fig. 12(c) for an element isolated from a beam by two sections, and again in Fig. 12(d). β€’ The shear at section 𝑋 βˆ’ 𝑋 of Fig. 11(a) is a negative shear. It is essential to associate the direction with a particular side of a section.
Fig. 13: Positive sense of shear and bending Fig. 12: Definition of positive shear moment defined in (a) is used in this text with coordinates shown in (b) β€’ The selected sign convention for shear appears to be based on directing the coordinate axis as shown in Fig. 13(a). β€’ A few books reverse the direction of positive shear to be consistent with the direction of axes in Fig. 13(b)
Bending Moment in Beams β€’ The internal shear and axial forces at a section of a beam satisfy only two equations of equilibrium: 𝐹π‘₯ = 0 and 𝐹𝑦 = 0 β€’ The remaining condition of a static equilibrium for a planar problem is 𝑀𝑧 = 0. This can be satisfied only by developing a couple or an internal resisting moment within the cross-sectional area of the cut to counteract the moment caused by the external forces. β€’ These moments tend to bend a beam in the plane of the loads and are usually referred as β€˜bending moments’. β€’ To determine an internal bending moment maintaining a beam segment in equilibrium, either the left- or the right-hand part of a beam free-body can be used, as shown in Figs. 11(b) and (c).
β€’ The magnitude of the bending moment is found by summation of the moments caused by all forces multiplied by their respective arms. β€’ The internal forces 𝑉 and 𝑃, as well as the applied couples, must be included in the sum. β€’ In order to exclude the moments caused by 𝑉 and 𝑃, it is advantageous to select the point of intersection of these two internal forces as the point around which the moments are summed. This points lies on the centroidal axis of the beam cross-section. β€’ In Figs. 14(b) and (c), the internal bending moments shown cause tension in the upper part of the beam and compression in the lower. β€’ A continuous occurrence of such moments along the beam makes the beam deform convex upwards, i.e., β€˜shed water’. Such bending moments are assigned a negative sign, Fig. 14(c)
Fig. 14: definition of bending moment signs β€’ A positive moment is defined as one that produces compression in the top part and tension in the lower part of a beam’s cross-section. The beam assumes a shape that β€˜retains water’, Fig. 14(b) β€’ As for shears 𝑉, in addition to the sense of 𝑀, it is also essential to associate the moment for a particular side of a section.
Axial-Force, Shear, and Bending-Moment Diagrams β€’ Using the obtained magnitude and the sign conventions adopted for these quantities, a plot of their values may be made on separate diagrams. β€’ On such diagrams, ordinates may be laid off equal to the computed quantities from a base line representing the length of a beam. β€’ It is convenient to make these plots directly below the free-body diagram of the beam, using the same horizontal scale for the length of the beam. β€’ The procedure of sectioning a beam or a frame and finding the system of forces at the section is the most fundamental approach.
Part C- Shear and Bending Moments by Integration Differential Equations of Equilibrium for a Beam Element β€’ Consider a beam element βˆ†π‘₯ long, isolated by two adjoining sections taken perpendicular to its axis, Fig. 15(b). Such an element is shown as a free-body in Fig. 15(c). β€’ All the forces shown acting on this element have positive sense. As the shear and the moment may each change from one section to the next, on the right side of the element, these quantities are, respectively, 𝑉 + βˆ†π‘‰ and 𝑀 + βˆ†π‘€.
Fig. 15: Beam and beam-elements between adjoining sections β€’ From the condition for equilibrium of vertical forces, 𝐹𝑦 = 0 ↑ + 𝑉 + π‘ž βˆ†π‘₯ βˆ’ 𝑉 + βˆ†π‘‰ = 0 or βˆ†π‘‰ βˆ†π‘₯ = π‘ž
β€’ For equilibrium, the summation of moments around 𝐴 must be zero. β€’ From point 𝐴 the arm of the distributed forces is βˆ†π‘₯/2, one has 𝑀𝐴 = 0 β†Ί + 𝑀 + βˆ†π‘€ βˆ’ π‘‰βˆ†π‘₯ βˆ’ 𝑀 βˆ’ π‘ž βˆ†π‘₯ βˆ†π‘₯ 2 = 0 or βˆ†π‘€ βˆ†π‘₯ = 𝑉 + π‘ž βˆ†π‘₯ 2 β€’ In above equations, in the limit as βˆ†π‘₯ β†’ 0 yield the following two basic differential equations: 𝑑𝑉 𝑑π‘₯ = π‘ž and 𝑑𝑀 𝑑π‘₯ = 𝑉 ⟹ 𝑑2 𝑀 𝑑π‘₯2 = 𝑑𝑉 𝑑π‘₯ = π‘ž β€’ These differential equations can be used for determining reactions of statically determinate beams from boundary conditions.
Shear Diagrams by Integration of the Load 𝑉 = 0 π‘₯ π‘ž 𝑑π‘₯ + 𝐢1 β€’ It is seen that the shear at a section is simply an integral (i.e., a sum) of the vertical forces along the beam from the left end of the beam to the section plus a constant of integration 𝐢1. This constant is equal to the shear on the left-hand end. β€’ If no force occurs between any two sections, no change in the amount of shear takes place. If a concentrated force comes into the summation, a discontinuity, or a β€˜jump’ in the value of shear occurs. β€’ The shear at a section is simply equal to the sum of all vertical forces to the left of the section.
Fig. 16: Shear diagrams for (a) a uniformly distributed load intensity, and (b) a uniformly increasing load intensity β€’ If the applied load acts upward, the slope of the shear diagram is positive, and vice versa. The slope is equal to the corresponding applied load intensity.
β€’ Consider a segment of a beam with a uniformly distributed downward load 𝑀0 and known shears at both ends, as shown in Fig. 16(a). Since here the applied load intensity 𝑀0 is negative and uniformly distributed, i.e., π‘ž = βˆ’π‘€0 = π‘π‘œπ‘›π‘ π‘‘π‘Žπ‘›π‘‘, the slope of the shear diagram exhibits the same characteristics. β€’ The linearly varying load intensity acting upward on a beam segment with known shears at the ends has a diagram as shown in Fig. 16 β€’ The locally applied upward load π‘ž1 is smaller than the corresponding one π‘ž2 near the right end. Therefore, the positive slope of the shear diagram on the left is smaller than it is on the right, and the shear diagram is concave upward. β€’ When the consecutive summation process is used, the diagram must end up with the previously calculated shear (reaction) at the right end of a beam.
Moment Diagrams by Integration of the Shear 𝑀 = 0 π‘₯ 𝑉 𝑑π‘₯ + 𝐢2 β€’ Where 𝐢2 is a constant of integration corresponding to boundary conditions at π‘₯ = 0. β€’ The meaning of the term 𝑉 𝑑π‘₯ is shown graphically by the hatched areas of the shear diagrams in Fig. 17. The summation of these areas between definite sections through a beam corresponds to an evaluation of the definite integral. β€’ If the ends of a beam are on rollers, pin-ended, or free, the starting and the terminal moments are zero. β€’ If the end is built-in (fixed against rotation), in statically determinate beams, the end moment is known from the reaction calculations.
β€’ If the fixed end of the beam is on the left, this moment with the proper sign is the initial constant of integration 𝐢2. Fig. 17: Shear and moment diagrams for (a) a uniformly distributed load intensity, and (b) a uniformly increasing load intensity
β€’ By proceeding continuously along the beam from the left-hand end and summing up the areas of the shear diagram with due regard to their sign, the moment is obtained. β€’ The change in moment in a given segment of a beam is equal to the area of the corresponding shear diagram. β€’ The slopes of the diagram have the same sign and magnitude as the corresponding shears on the shear diagram, since 𝑑𝑀 𝑑π‘₯ = 𝑉. β€’ If no shear occurs along a certain portion of a beam, no change in moment takes place. β€’ The maximum or minimum moment occurs where the shear is zero. β€’ In a bending-moment diagram obtained by summation, at the right- hand end of the beam, the terminal conditions for the moment must be satisfied.
β€’ If the end is free or pinned, the computed sum must equal to zero. β€’ If the end is built-in, the end moment computed by summation equals the one calculated initially for the reaction. Effect of Concentrated Moments on Moment Diagrams β€’ If there is external concentrated moment acting on the infinitesimal element, the derived summation process applies only up to the point of application of an external moment. β€’ At a section just beyond an externally applied moment, a different bending moment is required to maintain the segment of a beam in equilibrium.
Fig. 18: An external concentrated moment acting on an element of a beam β€’ In above Fig. 18, an external clockwise moment 𝑀𝐴 is acting on the element of a beam at 𝐴. Then, if the internal clockwise moment in the left is 𝑀 𝑂, for equilibrium of the element, the resisting counter- clockwise moment on the right must be 𝑀 𝑂 + 𝑀𝐴. β€’ At the point of the externally applied moment, a discontinuity, or a β€˜jump’, equal to the concentrated moment appears in the moment diagram. β€’ After the discontinuity in the moment-diagram is passed, the summation process of the shear-diagram areas may be continued over the remainder of the beam.
Moment Diagram and the Elastic Curve β€’ The shape of the deflected axis of a beam can be established from the sign of the moment diagram. β€’ The trace of the axis of a loaded elastic beam in a deflected position is known as the elastic curve. Fig. 19: (b) Shear and (c) bending-moment diagrams for (a) the symmetrically loaded beam β€’ An inspection of Fig. 19(c) shows that the bending moment throughout the length of the beam is positive. Accordingly, the elastic curve shown in Fig. 19(d) is concave up at every point.
Fig. 20: (b) Axial-force, (c) Shear and (d) bending-moment diagrams for (a) the loaded beam
β€’ In a more complex diagram, Fig. 20(d), zones of positive and negative moment occur. β€’ Corresponding to the zones of negative moment, a definite curvature of the elastic curve that is concave down takes place, Fig. 20(e). β€’ on the other hand, for the zone 𝐻𝐽, where the positive moment occurs, the concavity of the elastic curve is upward. β€’ Where curves join, as at 𝐻 and 𝐽, there are lines that are tangent to the two joining curves since the beam is physically continuous. β€’ The free end 𝐹𝐺 of the beam is tangent to the elastic curve at 𝐹. There is no curvature in 𝐹𝐺, since the moment is zero in that segment of the beam. β€’ The point of transition on the elastic curve into reverse curvature is called the β€˜point of inflection’ or β€˜contraflexure’. At this point, the moment changes its sign, and the beam is not called upon to resist any moment.
Singularity Functions β€’ If the loading π‘ž π‘₯ is a continuous function between the supports, solution of the differential equation 𝑑2 𝑀 𝑑π‘₯2 = 𝑑𝑉 𝑑π‘₯ = π‘ž π‘₯ is a convenient approach for determining 𝑉 π‘₯ and 𝑀 π‘₯ . β€’ If the loading function is discontinuous, the notation of operational calculus can be used. The function π‘ž π‘₯ considered here are polynomials with integral powers of π‘₯. Fig. 21: A loaded beam
β€’ Consider a loaded beam as in Fig. 21. Since the applied loads are point (concentrated) forces, four distinct regions exist to which different bending moment expressions apply. These are 𝑀 = 𝑅1 π‘₯ when 0 ≀ π‘₯ ≀ 𝑑 𝑀 = 𝑅1 π‘₯ βˆ’ 𝑃1 π‘₯ βˆ’ 𝑑 when d ≀ π‘₯ ≀ 𝑏 𝑀 = 𝑅1 π‘₯ βˆ’ 𝑃1 π‘₯ βˆ’ 𝑑 + 𝑀 𝑏 when b ≀ π‘₯ ≀ 𝑐 𝑀 = 𝑅1 π‘₯ βˆ’ 𝑃1 π‘₯ βˆ’ 𝑑 + 𝑀 𝑏 + 𝑃2 π‘₯ βˆ’ 𝑐 when c ≀ π‘₯ ≀ 𝐿 β€’ All four equations can be written as one using the following symbolic function: π‘₯ βˆ’ π‘Ž 𝑛 = 0 π‘₯ βˆ’ π‘Ž 𝑛 for 0 ≀ π‘₯ ≀ π‘Ž for π‘Ž ≀ π‘₯ ≀ ∞ where 𝑛 β‰₯ 0 𝑛 = 0, 1, 2, . . . .
β€’ The expression enclosed by the pointed brackets does not exist until π‘₯ reaches π‘Ž. For π‘₯ beyond π‘Ž, the expression becomes an ordinary binomial. For 𝑛 = 0 and for π‘₯ > π‘Ž, the function is unity. β€’ On this basis, the four separate functions for 𝑀 π‘₯ given for the beam of Fig. 21 can be combined into one expression that is applicable across the whole span: 𝑀 = 𝑅1 π‘₯ βˆ’ 0 1 βˆ’ 𝑃1 π‘₯ βˆ’ 𝑑 1 + 𝑀 𝑏 π‘₯ βˆ’ 𝑏 0 + 𝑃2 π‘₯ βˆ’ 𝑐 1 Here the values of π‘Ž are 0, 𝑑, 𝑏, and 𝑐, respectively. β€’ To work with this function further, it is convenient to introduce two additional symbolic functions. One is for the concentrated force, treating it as a degenerate case of a distributed. The other is for the concentrated moment, treating it similarly.
Fig. 22: Concentrated force 𝑃 and moment 𝑀 π‘Ž: (a) and (b) considered as distributed load, and (c) Symbolic notation for 𝑃 and 𝑀 at π‘Ž β€’ A concentrated (point) force may be considered as an enormously strong distributed load acting over a small interval πœ€, Fig. 22 (a). By treating πœ€ as a constant, lim πœ€β†’0 π‘Žβˆ’ πœ€ 2 π‘Ž+πœ€/2 𝑃 πœ€ 𝑑π‘₯ = 𝑃
β€’ 𝑃 πœ€ has the dimensions of force per unit distance such as lb/in, and corresponds to the distributed load π‘ž π‘₯ in the earlier treatment. β€’ As π‘₯ βˆ’ π‘Ž 1 β†’ 0, by an analogy of π‘₯ βˆ’ π‘Ž 1 to πœ€, for a concentrated force at π‘₯ = π‘Ž, π‘ž = 𝑃 π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 β€’ For π‘ž, this expression is dimensionally correct, although π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 at π‘₯ = π‘Ž becomes infinite and by definition is zero everywhere else. Thus, it is a singular function. β€’ The asterisk subscript of the bracket is a remainder that, the integral of this expression extending over the range πœ€ remains bounded and upon integration, yields the point force itself. β€’ Therefore, a special symbolic rule of integration must be adopted: 0 π‘₯ 𝑃 π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 = 𝑃 π‘₯ βˆ’ π‘Ž 0
β€’ The coefficient 𝑃 is known as the strength of singularity. β€’ For 𝑃 equal to unity, the unit point load function π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 is also called the Dirac delta or unit impulse function. β€’ By analogous reasoning, Fig. 22(b), the loading function π‘ž for concentrated moment at π‘₯ = π‘Ž is π‘ž = 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— βˆ’2 β€’ This function in being integrated twice defines two symbolic rules of integration. 0 π‘₯ 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— βˆ’2 𝑑π‘₯ = 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 0 π‘₯ 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 𝑑π‘₯ = 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— 0
β€’ The expression of π‘ž is correct dimensionally since π‘ž has the units of lb/in. β€’ For 𝑀 π‘Ž equal to unity, one obtains the unit point moment function, π‘₯ βˆ’ π‘Ž βˆ— βˆ’2, which is also called the doublet or dipole. This function is also singular being infinite at π‘₯ = π‘Ž and zero elsewhere. However after integrating twice, a bounded result is obtained. β€’ The integral of binomial functions in pointed brackets for 𝑛 β‰₯ 0 is given by: 0 π‘₯ π‘₯ βˆ’ π‘Ž 𝑛 𝑑π‘₯ = π‘₯ βˆ’ π‘Ž 𝑛 + 1 𝑛 + 1 for 𝑛 β‰₯ 0 β€’ This integration process is shown in Fig. 23. if the distance π‘Ž is set equal to zero, one obtains conventional integrals.
Fig. 23: Typical integrations

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Chapter 5: Axial Force, Shear, and Bending Moment

  • 1. Chapter 5 Axial Force, Shear, and Bending Moment Mechanics of Solids
  • 2. β€’ Even for a beam with all forces on the same plane, i.e., a planar beam problem, a system of three internal force components can develop at a section: the axial force, the shear and the bending moment β€’ For members in 3-D systems, there are six possible internal force components: an axial force, two shear components, two bending moment components, and a torque. Part A - Calculation of Reaction β€’ 3 types of supports for planar structures, identified by the kind of resistance they offer to the forces. β€’ One type of support is physically realized by a roller or a link. It is capable of resisting a force in only one specific line of action.
  • 3. Fig. 1: link and roller types of supports (the only possible lines of action of the reactions are shown by the dashed lines) β€’ The link shown in Fig. 1(a) can resist a force only in the direction of line 𝐴𝐡. The roller in Fig. 1(b) can resist only a vertical force, whereas the rollers in Fig. 1(c) can resist only a force that acts perpendicular to the plane 𝐢𝐷. β€’ A reaction of these types corresponds to a single unknown when equation of statics is applied.
  • 4. β€’ Another type of support that may be used is a pin. In construction, such a support is realized by using a detail shown in Fig. 2(a). While, Fig. 2(b) is diagrammatical representation. Fig. 2: Pinned support: (a) actual, (b) diagrammatic β€’ A pinned support is capable of resisting a force acting in any direction of the plane. In general, the reaction at such a support may have two components in horizontal and vertical directions. β€’ The third type of support is able to resist a force in any direction and is also capable of resisting a moment or a couple. A system of three forces can exist at such a support, two components of force and a moment. Such a support is called a fixed support.
  • 5. β€’ In which, the built-in end is fixed or prevented from rotating as Fig. 3 Fig. 3: Fixed support β€’ The roller and pin supports are termed as simple supports. Fig. 4: three basic types of idealized supports for planar structural systems. Simple supports: (a) a pinned support resists two force components, and (b) a roller or a link resists only one directed force Fixed support: (c) it resists two force components and a moment
  • 6. Diagrammatic Conventions for Loading β€’ Frequently a force is applied to a beam through a post, a hanger, or a bolted detail, as shown in Fig. 5(a). Such arrangements apply the force over a very limited portion of the beam and are idealized as concentrated forces. Fig. 5: Concentrated loading on a beam, (a) actual, (b) idealized β€’ In a warehouse, goods may be piled up along the length of a beam. Such distributed loads are defined by their load intensity at any point in force per unit length.
  • 7. β€’ Two kinds of distributed loads are particularly important: the uniformly distributed loads and the uniformly varying loads Fig. 6: Distributed loading on a beam, (a) actual, (b) idealized β€’ Uniformly varying loads act on the vertical and inclined walls of a vessel containing liquid. Fig. 7, where it is assumed that the vertical beam is one meter wide and 𝛾 (𝑁/π‘š3 ) is the unit weight of the liquid. β€’ The maximum intensity of the load of π‘ž0(𝑁/π‘š) is applicable only to an infinitesimal length of the beam. It is twice as large as the average intensity of pressure.
  • 8. Fig. 7: Hydrostatic loading on a vertical wall β€’ The total force exerted by such a loading on a beam is π‘ž0β„Ž 2 N, and its resultant acts at a distance h/3 above the vessel’s bottom. Horizontal bottoms of vessels containing liquid are loaded uniformly. various aerodynamic loadings are of distributed types. β€’ It is conceivable to load a beam with a concentrated moment applied to the beam essentially at a point. Consider, Fig. 8(a) and its diagrammatic representation shown in Fig. 8(c).
  • 9. Fig. 8: A method for applying a concentrated moment to a beam β€’ In Fig. 9, to maintain the applied force 𝑃 in the equilibrium at joint 𝐢, a shear 𝑃 and a moment 𝑃𝑑 must be developed at the support, Fig. 9(c). These forces apply a concentrated moment and an axial force, as shown in Fig. 9(b)
  • 10. Classification of Beams Fig. 9: loaded horizontal member applies an applied force and a concentrated moment to the vertical member β€’ If the supports at the ends of a beam are either pins or rollers, the beams are simply supported, or simple beams, Figs. 10(a) and (b) β€’ Fixed beam, if the ends have fixed supports, Fig. 10(c)
  • 11. Fig. 10: Types of Beams β€’ Restrained beams, one end is fixed and other is simply supported, Fig. 10(d). This beam is restrained from rotation. β€’ Cantilever beam, fixed at one end and completely free at the other end, Fig. 10(e)
  • 12. β€’ If the beam projects beyond a support, Overhanging beam, Fig. 10(f) β€’ If intermediate supports are provided for a physically continuous member acting as a beam, Fig. 10(g), Continuous beam. β€’ The distance 𝐿, between supports is called a span. In a continuous beam, there are several spans that may be of varying lengths. β€’ The beam shown in Fig. 10(a) is a simple beam with a concentrated load, whereas the beam in Fig. 10(b) is a simple beam with a uniformly distributed load. β€’ If for a planar beam or a frame, the number of unknown reaction components, including a bending moment, does not exceed three, such a system is externally statically determinate. β€’ These unknowns can be found from the equations of static equilibrium.
  • 13. Calculation of Beam Reactions β€’ When all the forces are applied in one plane, three equations of static equilibrium are available for the analysis. 𝐹π‘₯ = 0 , 𝐹𝑦 = 0 , 𝑀𝑧 = 0 β€’ From straight beams in the horizontal position, the x-axis will be taken in an horizontal direction, the y-axis in the upward vertical direction, and the z-axis normal to the plane of the paper. β€’ The deformation of beams, being small, is neglected when the equations of statics are applied.
  • 14. Part B - Direct Approach for Axial Force, Shear and Bending Moment Application of the method of sections β€’ The analysis of any beam or frame for determining the internal forces begins with the preparation of a free-body diagram showing both the applied and the reactive forces. β€’ If a whole body is in equilibrium, any part of it is likewise in equilibrium. β€’ Consider a beam shown in Fig. 11, with certain concentrated and distributed forces acting on it. The reactions can be computed using equations of static equilibrium. At a section of such a member, a vertical force, a horizontal force, and a moment are necessary to maintain the isolated part in equilibrium.
  • 15. Axial Force in Beams Fig. 11: An application of the method of sections to a statistically determinate beam
  • 16. β€’ A horizontal force such as 𝑃, shown in Fig. 11(b) and (c) may be necessary at section of a beam to satisfy the conditions of equilibrium. The magnitude and sense of this force follows from a particular solution of the equation, 𝐹π‘₯ = 0. β€’ If the horizontal force 𝑃 acts towards the section, it is called a β€˜thrust’; if away, it is called β€˜axial tension’. β€’ It is imperative to apply this force through the centroid of the cross- sectional area of the member to avoid bending. β€’ The line of action of the axial force will always be directed through the centroid of the beam’s cross-sectional area. β€’ The tensile force at a section is customarily taken positive. β€’ The axial force (thrust) at section 𝑋 βˆ’ 𝑋 in Figs. 11(b) and (c) is equal to the horizontal force 𝑃2.
  • 17. Shear in Beams β€’ To maintain a segment of a beam, as shown in Fig. 11(b), in equilibrium, there must be an internal vertical force 𝑉, acting at right angles to the axis of the beam, is called the shear force. β€’ The shear is numerically equal to the algebraic sum of all the vertical components of the external forces acting on the isolated segment, but it is opposite in direction. β€’ Given the qualitative data shown in Fig. 11(b), 𝑉 is opposite in the direction to the downward load to the left of the section. This shear may also be computed by considering the right hand segment shown in Fig. 11(c). β€’ The same shear shown in Figs. 11(b) and (c) at the section 𝑋 βˆ’ 𝑋 is opposite in direction in the two diagrams.
  • 18. β€’ For the part of the downward load π‘Š1 to the left of section 𝑋 βˆ’ 𝑋, the beam at the section provides an upward support to maintain vertical forces in equilibrium. Conversely, the loaded portion of the beam exerts a downward force on the beam, as shown in Fig. 11(c) β€’ A reversal in the direction of shear takes place at one section or another along a beam. β€’ A downward internal force 𝑉 acting at a section on an isolated left section of the beam, as in Fig. 12(a), or an upward force 𝑉 acting at the same section on the right segment of the beam, as in Fig. 12(b),corresponds to positive shear. β€’ Positive shears are shown in Fig. 12(c) for an element isolated from a beam by two sections, and again in Fig. 12(d). β€’ The shear at section 𝑋 βˆ’ 𝑋 of Fig. 11(a) is a negative shear. It is essential to associate the direction with a particular side of a section.
  • 19. Fig. 13: Positive sense of shear and bending Fig. 12: Definition of positive shear moment defined in (a) is used in this text with coordinates shown in (b) β€’ The selected sign convention for shear appears to be based on directing the coordinate axis as shown in Fig. 13(a). β€’ A few books reverse the direction of positive shear to be consistent with the direction of axes in Fig. 13(b)
  • 20. Bending Moment in Beams β€’ The internal shear and axial forces at a section of a beam satisfy only two equations of equilibrium: 𝐹π‘₯ = 0 and 𝐹𝑦 = 0 β€’ The remaining condition of a static equilibrium for a planar problem is 𝑀𝑧 = 0. This can be satisfied only by developing a couple or an internal resisting moment within the cross-sectional area of the cut to counteract the moment caused by the external forces. β€’ These moments tend to bend a beam in the plane of the loads and are usually referred as β€˜bending moments’. β€’ To determine an internal bending moment maintaining a beam segment in equilibrium, either the left- or the right-hand part of a beam free-body can be used, as shown in Figs. 11(b) and (c).
  • 21. β€’ The magnitude of the bending moment is found by summation of the moments caused by all forces multiplied by their respective arms. β€’ The internal forces 𝑉 and 𝑃, as well as the applied couples, must be included in the sum. β€’ In order to exclude the moments caused by 𝑉 and 𝑃, it is advantageous to select the point of intersection of these two internal forces as the point around which the moments are summed. This points lies on the centroidal axis of the beam cross-section. β€’ In Figs. 14(b) and (c), the internal bending moments shown cause tension in the upper part of the beam and compression in the lower. β€’ A continuous occurrence of such moments along the beam makes the beam deform convex upwards, i.e., β€˜shed water’. Such bending moments are assigned a negative sign, Fig. 14(c)
  • 22. Fig. 14: definition of bending moment signs β€’ A positive moment is defined as one that produces compression in the top part and tension in the lower part of a beam’s cross-section. The beam assumes a shape that β€˜retains water’, Fig. 14(b) β€’ As for shears 𝑉, in addition to the sense of 𝑀, it is also essential to associate the moment for a particular side of a section.
  • 23. Axial-Force, Shear, and Bending-Moment Diagrams β€’ Using the obtained magnitude and the sign conventions adopted for these quantities, a plot of their values may be made on separate diagrams. β€’ On such diagrams, ordinates may be laid off equal to the computed quantities from a base line representing the length of a beam. β€’ It is convenient to make these plots directly below the free-body diagram of the beam, using the same horizontal scale for the length of the beam. β€’ The procedure of sectioning a beam or a frame and finding the system of forces at the section is the most fundamental approach.
  • 24. Part C- Shear and Bending Moments by Integration Differential Equations of Equilibrium for a Beam Element β€’ Consider a beam element βˆ†π‘₯ long, isolated by two adjoining sections taken perpendicular to its axis, Fig. 15(b). Such an element is shown as a free-body in Fig. 15(c). β€’ All the forces shown acting on this element have positive sense. As the shear and the moment may each change from one section to the next, on the right side of the element, these quantities are, respectively, 𝑉 + βˆ†π‘‰ and 𝑀 + βˆ†π‘€.
  • 25. Fig. 15: Beam and beam-elements between adjoining sections β€’ From the condition for equilibrium of vertical forces, 𝐹𝑦 = 0 ↑ + 𝑉 + π‘ž βˆ†π‘₯ βˆ’ 𝑉 + βˆ†π‘‰ = 0 or βˆ†π‘‰ βˆ†π‘₯ = π‘ž
  • 26. β€’ For equilibrium, the summation of moments around 𝐴 must be zero. β€’ From point 𝐴 the arm of the distributed forces is βˆ†π‘₯/2, one has 𝑀𝐴 = 0 β†Ί + 𝑀 + βˆ†π‘€ βˆ’ π‘‰βˆ†π‘₯ βˆ’ 𝑀 βˆ’ π‘ž βˆ†π‘₯ βˆ†π‘₯ 2 = 0 or βˆ†π‘€ βˆ†π‘₯ = 𝑉 + π‘ž βˆ†π‘₯ 2 β€’ In above equations, in the limit as βˆ†π‘₯ β†’ 0 yield the following two basic differential equations: 𝑑𝑉 𝑑π‘₯ = π‘ž and 𝑑𝑀 𝑑π‘₯ = 𝑉 ⟹ 𝑑2 𝑀 𝑑π‘₯2 = 𝑑𝑉 𝑑π‘₯ = π‘ž β€’ These differential equations can be used for determining reactions of statically determinate beams from boundary conditions.
  • 27. Shear Diagrams by Integration of the Load 𝑉 = 0 π‘₯ π‘ž 𝑑π‘₯ + 𝐢1 β€’ It is seen that the shear at a section is simply an integral (i.e., a sum) of the vertical forces along the beam from the left end of the beam to the section plus a constant of integration 𝐢1. This constant is equal to the shear on the left-hand end. β€’ If no force occurs between any two sections, no change in the amount of shear takes place. If a concentrated force comes into the summation, a discontinuity, or a β€˜jump’ in the value of shear occurs. β€’ The shear at a section is simply equal to the sum of all vertical forces to the left of the section.
  • 28. Fig. 16: Shear diagrams for (a) a uniformly distributed load intensity, and (b) a uniformly increasing load intensity β€’ If the applied load acts upward, the slope of the shear diagram is positive, and vice versa. The slope is equal to the corresponding applied load intensity.
  • 29. β€’ Consider a segment of a beam with a uniformly distributed downward load 𝑀0 and known shears at both ends, as shown in Fig. 16(a). Since here the applied load intensity 𝑀0 is negative and uniformly distributed, i.e., π‘ž = βˆ’π‘€0 = π‘π‘œπ‘›π‘ π‘‘π‘Žπ‘›π‘‘, the slope of the shear diagram exhibits the same characteristics. β€’ The linearly varying load intensity acting upward on a beam segment with known shears at the ends has a diagram as shown in Fig. 16 β€’ The locally applied upward load π‘ž1 is smaller than the corresponding one π‘ž2 near the right end. Therefore, the positive slope of the shear diagram on the left is smaller than it is on the right, and the shear diagram is concave upward. β€’ When the consecutive summation process is used, the diagram must end up with the previously calculated shear (reaction) at the right end of a beam.
  • 30. Moment Diagrams by Integration of the Shear 𝑀 = 0 π‘₯ 𝑉 𝑑π‘₯ + 𝐢2 β€’ Where 𝐢2 is a constant of integration corresponding to boundary conditions at π‘₯ = 0. β€’ The meaning of the term 𝑉 𝑑π‘₯ is shown graphically by the hatched areas of the shear diagrams in Fig. 17. The summation of these areas between definite sections through a beam corresponds to an evaluation of the definite integral. β€’ If the ends of a beam are on rollers, pin-ended, or free, the starting and the terminal moments are zero. β€’ If the end is built-in (fixed against rotation), in statically determinate beams, the end moment is known from the reaction calculations.
  • 31. β€’ If the fixed end of the beam is on the left, this moment with the proper sign is the initial constant of integration 𝐢2. Fig. 17: Shear and moment diagrams for (a) a uniformly distributed load intensity, and (b) a uniformly increasing load intensity
  • 32. β€’ By proceeding continuously along the beam from the left-hand end and summing up the areas of the shear diagram with due regard to their sign, the moment is obtained. β€’ The change in moment in a given segment of a beam is equal to the area of the corresponding shear diagram. β€’ The slopes of the diagram have the same sign and magnitude as the corresponding shears on the shear diagram, since 𝑑𝑀 𝑑π‘₯ = 𝑉. β€’ If no shear occurs along a certain portion of a beam, no change in moment takes place. β€’ The maximum or minimum moment occurs where the shear is zero. β€’ In a bending-moment diagram obtained by summation, at the right- hand end of the beam, the terminal conditions for the moment must be satisfied.
  • 33. β€’ If the end is free or pinned, the computed sum must equal to zero. β€’ If the end is built-in, the end moment computed by summation equals the one calculated initially for the reaction. Effect of Concentrated Moments on Moment Diagrams β€’ If there is external concentrated moment acting on the infinitesimal element, the derived summation process applies only up to the point of application of an external moment. β€’ At a section just beyond an externally applied moment, a different bending moment is required to maintain the segment of a beam in equilibrium.
  • 34. Fig. 18: An external concentrated moment acting on an element of a beam β€’ In above Fig. 18, an external clockwise moment 𝑀𝐴 is acting on the element of a beam at 𝐴. Then, if the internal clockwise moment in the left is 𝑀 𝑂, for equilibrium of the element, the resisting counter- clockwise moment on the right must be 𝑀 𝑂 + 𝑀𝐴. β€’ At the point of the externally applied moment, a discontinuity, or a β€˜jump’, equal to the concentrated moment appears in the moment diagram. β€’ After the discontinuity in the moment-diagram is passed, the summation process of the shear-diagram areas may be continued over the remainder of the beam.
  • 35. Moment Diagram and the Elastic Curve β€’ The shape of the deflected axis of a beam can be established from the sign of the moment diagram. β€’ The trace of the axis of a loaded elastic beam in a deflected position is known as the elastic curve. Fig. 19: (b) Shear and (c) bending-moment diagrams for (a) the symmetrically loaded beam β€’ An inspection of Fig. 19(c) shows that the bending moment throughout the length of the beam is positive. Accordingly, the elastic curve shown in Fig. 19(d) is concave up at every point.
  • 36. Fig. 20: (b) Axial-force, (c) Shear and (d) bending-moment diagrams for (a) the loaded beam
  • 37. β€’ In a more complex diagram, Fig. 20(d), zones of positive and negative moment occur. β€’ Corresponding to the zones of negative moment, a definite curvature of the elastic curve that is concave down takes place, Fig. 20(e). β€’ on the other hand, for the zone 𝐻𝐽, where the positive moment occurs, the concavity of the elastic curve is upward. β€’ Where curves join, as at 𝐻 and 𝐽, there are lines that are tangent to the two joining curves since the beam is physically continuous. β€’ The free end 𝐹𝐺 of the beam is tangent to the elastic curve at 𝐹. There is no curvature in 𝐹𝐺, since the moment is zero in that segment of the beam. β€’ The point of transition on the elastic curve into reverse curvature is called the β€˜point of inflection’ or β€˜contraflexure’. At this point, the moment changes its sign, and the beam is not called upon to resist any moment.
  • 38. Singularity Functions β€’ If the loading π‘ž π‘₯ is a continuous function between the supports, solution of the differential equation 𝑑2 𝑀 𝑑π‘₯2 = 𝑑𝑉 𝑑π‘₯ = π‘ž π‘₯ is a convenient approach for determining 𝑉 π‘₯ and 𝑀 π‘₯ . β€’ If the loading function is discontinuous, the notation of operational calculus can be used. The function π‘ž π‘₯ considered here are polynomials with integral powers of π‘₯. Fig. 21: A loaded beam
  • 39. β€’ Consider a loaded beam as in Fig. 21. Since the applied loads are point (concentrated) forces, four distinct regions exist to which different bending moment expressions apply. These are 𝑀 = 𝑅1 π‘₯ when 0 ≀ π‘₯ ≀ 𝑑 𝑀 = 𝑅1 π‘₯ βˆ’ 𝑃1 π‘₯ βˆ’ 𝑑 when d ≀ π‘₯ ≀ 𝑏 𝑀 = 𝑅1 π‘₯ βˆ’ 𝑃1 π‘₯ βˆ’ 𝑑 + 𝑀 𝑏 when b ≀ π‘₯ ≀ 𝑐 𝑀 = 𝑅1 π‘₯ βˆ’ 𝑃1 π‘₯ βˆ’ 𝑑 + 𝑀 𝑏 + 𝑃2 π‘₯ βˆ’ 𝑐 when c ≀ π‘₯ ≀ 𝐿 β€’ All four equations can be written as one using the following symbolic function: π‘₯ βˆ’ π‘Ž 𝑛 = 0 π‘₯ βˆ’ π‘Ž 𝑛 for 0 ≀ π‘₯ ≀ π‘Ž for π‘Ž ≀ π‘₯ ≀ ∞ where 𝑛 β‰₯ 0 𝑛 = 0, 1, 2, . . . .
  • 40. β€’ The expression enclosed by the pointed brackets does not exist until π‘₯ reaches π‘Ž. For π‘₯ beyond π‘Ž, the expression becomes an ordinary binomial. For 𝑛 = 0 and for π‘₯ > π‘Ž, the function is unity. β€’ On this basis, the four separate functions for 𝑀 π‘₯ given for the beam of Fig. 21 can be combined into one expression that is applicable across the whole span: 𝑀 = 𝑅1 π‘₯ βˆ’ 0 1 βˆ’ 𝑃1 π‘₯ βˆ’ 𝑑 1 + 𝑀 𝑏 π‘₯ βˆ’ 𝑏 0 + 𝑃2 π‘₯ βˆ’ 𝑐 1 Here the values of π‘Ž are 0, 𝑑, 𝑏, and 𝑐, respectively. β€’ To work with this function further, it is convenient to introduce two additional symbolic functions. One is for the concentrated force, treating it as a degenerate case of a distributed. The other is for the concentrated moment, treating it similarly.
  • 41. Fig. 22: Concentrated force 𝑃 and moment 𝑀 π‘Ž: (a) and (b) considered as distributed load, and (c) Symbolic notation for 𝑃 and 𝑀 at π‘Ž β€’ A concentrated (point) force may be considered as an enormously strong distributed load acting over a small interval πœ€, Fig. 22 (a). By treating πœ€ as a constant, lim πœ€β†’0 π‘Žβˆ’ πœ€ 2 π‘Ž+πœ€/2 𝑃 πœ€ 𝑑π‘₯ = 𝑃
  • 42. β€’ 𝑃 πœ€ has the dimensions of force per unit distance such as lb/in, and corresponds to the distributed load π‘ž π‘₯ in the earlier treatment. β€’ As π‘₯ βˆ’ π‘Ž 1 β†’ 0, by an analogy of π‘₯ βˆ’ π‘Ž 1 to πœ€, for a concentrated force at π‘₯ = π‘Ž, π‘ž = 𝑃 π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 β€’ For π‘ž, this expression is dimensionally correct, although π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 at π‘₯ = π‘Ž becomes infinite and by definition is zero everywhere else. Thus, it is a singular function. β€’ The asterisk subscript of the bracket is a remainder that, the integral of this expression extending over the range πœ€ remains bounded and upon integration, yields the point force itself. β€’ Therefore, a special symbolic rule of integration must be adopted: 0 π‘₯ 𝑃 π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 = 𝑃 π‘₯ βˆ’ π‘Ž 0
  • 43. β€’ The coefficient 𝑃 is known as the strength of singularity. β€’ For 𝑃 equal to unity, the unit point load function π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 is also called the Dirac delta or unit impulse function. β€’ By analogous reasoning, Fig. 22(b), the loading function π‘ž for concentrated moment at π‘₯ = π‘Ž is π‘ž = 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— βˆ’2 β€’ This function in being integrated twice defines two symbolic rules of integration. 0 π‘₯ 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— βˆ’2 𝑑π‘₯ = 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 0 π‘₯ 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— βˆ’1 𝑑π‘₯ = 𝑀 π‘Ž π‘₯ βˆ’ π‘Ž βˆ— 0
  • 44. β€’ The expression of π‘ž is correct dimensionally since π‘ž has the units of lb/in. β€’ For 𝑀 π‘Ž equal to unity, one obtains the unit point moment function, π‘₯ βˆ’ π‘Ž βˆ— βˆ’2, which is also called the doublet or dipole. This function is also singular being infinite at π‘₯ = π‘Ž and zero elsewhere. However after integrating twice, a bounded result is obtained. β€’ The integral of binomial functions in pointed brackets for 𝑛 β‰₯ 0 is given by: 0 π‘₯ π‘₯ βˆ’ π‘Ž 𝑛 𝑑π‘₯ = π‘₯ βˆ’ π‘Ž 𝑛 + 1 𝑛 + 1 for 𝑛 β‰₯ 0 β€’ This integration process is shown in Fig. 23. if the distance π‘Ž is set equal to zero, one obtains conventional integrals.
  • 45. Fig. 23: Typical integrations