Quickest-descent curve in the problem of rolling of a homogeneous cylinder

Legeza, V. P.

doi:10.1007/s10778-009-0149-z

Cited by 11 publications

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“…In this connection, it is necessary to find the shape of the directrix of a cylindrical surface over which a heavy homogeneous cylinder rolls without slipping (pure rolling) in the least time. The requirement of no slipping is standard for vibration-protection problems.The present study continues the research reported in [4,5] where the following differential equation of brachistochrone along which a cylinder rolls without slipping (Fig. 1) was for the first time derived by setting up and minimizing a functional T z x [ ( )]: ( )[ ( ) ] ( ) z C z r z C + + ¢ -+ ¢ = 1 1 2 2 1 , z zx z L L ( ) , ( ) 0 0 = = .…”

supporting

confidence: 91%

“…The present study continues the research reported in [4,5] where the following differential equation of brachistochrone along which a cylinder rolls without slipping (Fig. 1) was for the first time derived by setting up and minimizing a functional T z x [ ( )]: ( )[ ( ) ] ( ) z C z r z C + + ¢ -+ ¢ = 1 1 2 2 1 , z zx z L L ( ) , ( ) 0 0 = = .…”

supporting

confidence: 91%

“…We have established that a special parametrization ( ¢ = z x ( ) cot( ) j / 2 ) allows quadratures to be used to solve the differential equation (1) derived in [4,5]. We have derived a system of algebraic parametric equations describing the brachistochrone for a cylinder.…”

Section: Determining the Minimum Timementioning

confidence: 99%

“…(1), we will use a special parametrization of the curve z z x = ( ) different from that in [5]. The parametrization is done as follows ( / ) a j = 2 : …”

mentioning

confidence: 99%

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Conditions for pure rolling of a heavy cylinder along a brachistochrone

Legeza

2010

Int Appl Mech

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Algebraic equations for the line of steepest descent of a cylinder are derived in parametric form. Conditions for rolling without slipping and separation of the cylinder along a brachistochrone are established based on the equations of motion with constraint reaction. The important conclusion is drawn that the center of mass of a cylinder moving along a brachistochrone describes a cycloid Introduction. Brief Review of Relevant Studies. In 1696, Bernoulli posed the following brachistochrone problem: find the shape of the curve down which a bead slipping from rest and accelerated by gravity will slip from one point to another in the least time. It is assumed that the bead (material point) moves in a vertical plane and in a uniform gravity field.Newton, Leibniz, l'Hopital, and two Bernoullis showed that the solution of this problem is a cycloid [14]. Analytic solutions of the brachistochrone problem obtained using geometrical optics and the calculus of variations can be found in [15,16]. Brachistochrone with Coulomb friction was studied in detail by Ashby et al. [10], Hayen [18], Heijden and Diepstraten [25]. The problem of a brachistochrone on a cylindrical surface with Coulomb friction was generalized by Covic and Veskovic in [12]. The problem of a brachistochrone in nonconservative force fields was addressed in [27]. The problem of a brachistochrone on a cylinder in uniform force fields was solved in [28]. Brachistochrones on cylinders and spheres were considered by Palmieri [20]. The same problem was generalized to nonuniform force fields by Aravind [9], Denman [13], and Venezian [26]. Venezian solved the problem of brachistochronein linear radial force fields. Denman [13], Parnovsky [21], and Tee [24] solved the same problem for radial force fields inversely proportional to the squared distance between the interacting points. The generalizations of the brachistochrone problem involving relativistic effects were outlined by Goldstein and Bender [17], Scarpello and Ritelli [23].The next natural step in the generalization of the brachistochrone problem is to derive the brachistochrone equation for rolling finite-size bodies (balls, cylinders, disks, wheels, etc.). Various formulations of the brachistochrone problem for arbitrary rolling bodies were given in [22,19].The brahistohrone problem for a heavy cylinder is of theoretical importance due to the following applied problem.There is a variety of antivibration devices for which the minimum time they take to reduce the amplitude of forced vibrations to a standard level is the performance criterion [6,7,11]. This criterion is applied to rolling antivibration devices [2,3]. In this connection, it is necessary to find the shape of the directrix of a cylindrical surface over which a heavy homogeneous cylinder rolls without slipping (pure rolling) in the least time. The requirement of no slipping is standard for vibration-protection problems.The present study continues the research reported in [4,5] where the following differential equation of brachistochrone along whi...

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supporting

confidence: 91%

supporting

confidence: 91%

Section: Determining the Minimum Timementioning

confidence: 99%

“…(1), we will use a special parametrization of the curve z z x = ( ) different from that in [5]. The parametrization is done as follows ( / ) a j = 2 : …”

mentioning

confidence: 99%

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Conditions for pure rolling of a heavy cylinder along a brachistochrone

Legeza

2010

Int Appl Mech

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“…This is because over time, these structures wear out and may require urgent restoration for (i) reduction of the dynamic loads on these structures and (ii) strengthening of their load-carrying components. Here we address only case (i) and propose a new engineering solution based on a roller shock absorber with working surface in the form of a brachistochrone [10,16,32].The dynamic analysis of high-rise structures for wind forces deals with forced vibrations excited by pulsating wind pressure and self-excited vibrations such as wind resonance [1,3,4]. The principal natural frequencies of such structures are low, and the displacements of the upper parts of high-rise structures are great (1 to 3 m).…”

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Dynamics of vibration isolation system with a quasi-isochronous roller shock absorber

Legeza

2011

Int Appl Mech

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The low-frequency vibrations of a vibration isolation system of rigid bodies (roller shock absorber and carrying body) under external harmonic loading are considered. The working surface of the absorber has the form of a brachistochrone. The equations describing the slip-free motion of the absorber over the hinged roller and the motion of the carrying body are derived. A graphical method for optimizing the parameters of the roller absorber as a component of the vibration isolation system is proposed Keywords: vibration isolation system, kinematic constraints, roller shock absorber, carrying body, brachistochrone, rolling without slipping, amplitude-frequency characteristicsIntroduction. The vibration protection of flexible high-rise structures (such as TV towers, radio masts, metal vent stacks, wind turbine towers, etc.) has recently become important. This is because over time, these structures wear out and may require urgent restoration for (i) reduction of the dynamic loads on these structures and (ii) strengthening of their load-carrying components. Here we address only case (i) and propose a new engineering solution based on a roller shock absorber with working surface in the form of a brachistochrone [10,16,32].The dynamic analysis of high-rise structures for wind forces deals with forced vibrations excited by pulsating wind pressure and self-excited vibrations such as wind resonance [1,3,4]. The principal natural frequencies of such structures are low, and the displacements of the upper parts of high-rise structures are great (1 to 3 m).So far, suspended pendulum-type dynamic shock absorbers have been used [1,[3][4][5]14]. However, they have a number of disadvantages, including failure to normally operate in the low-frequency range (w = 0.2-2.0 rad/sec).The most promising new method of vibration protection of high-rise structures employs rolling-type shock absorbers that include heavy balls, cylinders, or rollers rolling without slipping over the curvilinear working surfaces of the carrying bodies [5-9, 17, 30]. They were successfully tested [5] on TV towers, vent stacks, and radio masts in the range of low natural frequencies (lower than 2.0 rad/sec). Compared with the conventional pendulum-type shock absorbers, they are compact, do not require a separate room for maintenance, and can reliably and safely operate in various climates.A cantilever rod of variable cross-section is a model standardized on to design flexible structures [3,4]. The spectrum of natural frequencies is sparse, which makes it possible, in most cases, to expand the solutions of dynamic problems into trigonometric series of natural modes that converge relatively rapidly. However, the full-scale test and measurement data [1,[3][4][5]14] demonstrate that the first vibration mode makes the major contribution to the dynamic load on such flexible structures. Therefore, use is made of one-mass absorbers tuned to a frequency close to the principal natural frequency of the structure. As a rule, the effectiveness of dynamic shock absorbers is as...

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On the solutions and stability for an auto-parametric dynamical system

2022

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The main goal of this study is to look at the motion of a damped two degrees-of-freedom (DOF) auto-parametric dynamical system. Lagrange’s equations are used to derive the governing equations of motion (EOM). Up to a good desired order, the approximate solutions are achieved utilizing the method of multiple scales (MMS). Two cases of resonance, namely; internal and primary external one are examined simultaneously to explore the solvability conditions of the motion and the corresponding modulation equations (ME). These equations are reduced to two algebraic equations, through the elimination of the modified phases, in terms of the detuning parameters and the amplitudes. The kind of stable or unstable fixed point is estimated. In certain plots, the time histories graphs of the achieved solutions, as well as the adjusted phases and amplitudes are used to depict the motion of the system at any instant. The conditions of Routh–Hurwitz are used to study the various stability zones and their analysis. The achieved outcomes are considered to be novel and original, in which the used strategy is applied on a particular dynamical system. The significance of the studied system can be observed in its applications in a number of disciplines, such as swaying structures and rotor dynamics.

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Quickest-descent curve in the problem of rolling of a homogeneous cylinder

Cited by 11 publications

References 11 publications

Conditions for pure rolling of a heavy cylinder along a brachistochrone

Conditions for pure rolling of a heavy cylinder along a brachistochrone

Dynamics of vibration isolation system with a quasi-isochronous roller shock absorber

On the solutions and stability for an auto-parametric dynamical system

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