Behavioral Study of Finite Beam Resting on Elastic Foundation and Subjected to Travelling Distributed Masses

Omolofe, B.; Adeloye, T. O.

doi:10.1590/1679-78253071

Cited by 3 publications

(5 citation statements)

References 15 publications

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“…= ( * * ) + 0 (2e) (17) The Q = Flow rate of the eroded soil. We adapted it and the formula from the study [20], as shown in Eq.…”

Section: Parameterization Of Pothole Model Equationmentioning

confidence: 99%

“…Investigations have shown that potholes, warping, rutting, raveling, edge-break, cracks, and shear failures are common types of road deformation [1,2,4,13]. During road deformation (pothole) modeling, most research focused on the phenomena that affect the top layers of the road [7,2,[14][15][16][17]. It is because modeling the road's subsurface activities is tricky since it requires roadway subsurface data and different principles.…”

Section: Introductionmentioning

confidence: 99%

“…It is because modeling the road's subsurface activities is tricky since it requires roadway subsurface data and different principles. Studies assumed the roadway surface (asphalt layers) to be plates, beams, or slabs resting on foundations [2,7,[14][15][16][17]. Using those assumptions may not describe what happens below the surface layers.…”

Section: Introductionmentioning

confidence: 99%

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Mechanistic Mathematical Modelling of Pothole Development from Loss of Roadway Subsurface-Materials

Ezekwesili¹,

Agunwamba²

2021

MMEP

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In this paper, we developed a mechanistic mathematical model. It implies the engineering problem of pothole development on roadways. The issue involves internal erosion, a decline of subsurface materials, voids creation, depression, materials damage, and potholes’ appearance on the road’s surface. Our study aims to predict why, how, and when pothole develops from the loss of roadway subsurface materials. We reviewed many sources as our first method. It involved using and adapting the guiding principles for migrating particles upwards. We then changed specific parameters, formulated our model equation, solved it using the separation of variables, and then verified it. Observations from our review show that high traffic load pressure and water must be present on the road for particle migration to occur. They generate excess pore-water pressure that enables the movement of particles upwards. Particle relocation causes voids and dislocation of materials. Results show that an increase in time, cracks, soil erosion coefficient, and a decrease in the roadway’s height led to a rise in the number of materials lost from the pavement. Our study is relevant because it will better inform road managers and modelers on potholes, and they can-do preventive measures to avert total road failure.

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“…= ( * * ) + 0 (2e) (17) The Q = Flow rate of the eroded soil. We adapted it and the formula from the study [20], as shown in Eq.…”

Section: Parameterization Of Pothole Model Equationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Mechanistic Mathematical Modelling of Pothole Development from Loss of Roadway Subsurface-Materials

Ezekwesili¹,

Agunwamba²

2021

MMEP

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“…In the latter, under tensile loads and in the former, under compressive axial loads. Later, [3] investigated the forced vibration of an elastic uniform Bernoulli-Euler beam having simple supports with a constant axial force resting on variable elastic foundation and traversed by uniformly distributed loads. [4] studied the transverse vibration of a Rayleigh cantilever beam with arbitrarily distributed axial loading and carrying a concentrated mass at the free end.…”

Section: Introductionmentioning

confidence: 99%

"On the Moving Distributed Force Problem of a Non-Uniform Prestressed Simply Supported Rayleigh Beam"

Andi

2020

NRS

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This paper presents a mini review on the moving distributed force problem of a non-uniform prestressed simply supported Rayleigh beam resting on an elastic foundation. The problem, which is reduced to a nonhomogeneous second order ordinary differential equation, is tackled by means of Laplace transforms and Convolution theory. Analytical solutions are presented for the boundary condition under consideration. Conditions under which resonance occur are established. The theoretical considerations find application in calculations relating to dynamic stresses in railways, bridges and foundation for all types of highways.

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“…The theoretical and experimental studies of the moving load problems have shown that moving loads may be divided into three categories namely: moving oscillator, moving mass, and moving force. Vibrations of beams due to moving oscillators are studied in [14,17,23,33,39], vibrations of beams due to a moving mass are investigated in [3,4,13,16,25,36,41], and vibration of beams due to moving force have been considered in [1,8,15,18,27,40]. Moving load problem with or without elastic foundation has been extensively studied and so many other aspects of the moving load problem have also been considerably explored [7,11,12,21,26,30,34].…”

Section: Introductionmentioning

confidence: 99%

Damping influence on the critical velocity and response characteristics of structurally pre-stressed beam subjected to traveling harmonic load

Omolofe¹,

Awodola²,

Adeloye³

2019

Math. Nat. Sci.

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In this present study, the response characteristics of a flexible member carrying harmonic moving load are investigated. The beam is assumed to be of uniform cross section and has simple support at both ends. The moving concentrated force is assumed to move with constant velocity type of motion. A versatile mathematical approximation technique often used in structural mechanics called assumed mode method is in first instance used to treat the fourth order partial differential equation governing the motion of the slender member to obtain a sequence of second order ordinary differential equations. Integral transform method is further used to treat this sequence of differential equations describing the motion of the beam-load system. Various results in plotted curves show that, the presence of the vital structural parameters such as the axial force N, rotatory inertia correction factor r 0 , the foundation modulus F 0 , and the shear modulus G 0 , significantly enhances the stability of the beam when under the action of moving load. Dynamic effects of these parameters on the critical speed of the dynamical system are carefully studied. It is found that as the values of these parameters increase, the critical speed also increases. Thereby reducing the risk of resonance and thus the safety of the occupant of this structural member is guaranteed.

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Behavioral Study of Finite Beam Resting on Elastic Foundation and Subjected to Travelling Distributed Masses

Cited by 3 publications

References 15 publications

Mechanistic Mathematical Modelling of Pothole Development from Loss of Roadway Subsurface-Materials

Mechanistic Mathematical Modelling of Pothole Development from Loss of Roadway Subsurface-Materials

"On the Moving Distributed Force Problem of a Non-Uniform Prestressed Simply Supported Rayleigh Beam"

Damping influence on the critical velocity and response characteristics of structurally pre-stressed beam subjected to traveling harmonic load

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