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[[PEH:Mathematics_of_Vibrating_Systems]]
[[PEH:Mathematics_of_Vibrating_Systems]]
== Categories ==
[[Category:1.10 Drilling equipment]] [[Category:NR]]
[[Category:1.10 Drilling equipment]] [[Category:NR]]

Revision as of 18:35, 9 July 2015

Analyzing the effects of vibration get more complex as more sources of motion are added. Sources of motion are modeled as degrees of freedom (DOFs). Systems with one degree of freedom and two or more degrees of freedom are discussed elsewhere. If one continues to add DOFs, the limit at an infinite DOF defines a continuous system. The result becomes a partial differential equation (PDE). The following is a brief description of the separation of variables method for solving a PDE. (See this refresher on differential calculus if needed.)

Calculating motion in a continuous system

Fig. 1 shows a freebody diagram for axial and torsional systems. The axial system equations will be used to determine the solution of the equations of motion. Eq. 1 is the axial equation of motion:

RTENOTITLE....................(1)

where RTENOTITLE = the inertial force, RTENOTITLE = the rate of strain change, mgc = the static weight of the element, and RTENOTITLE = the force from viscous damping. This PDE, Eq. 1, can be solved using the separation of variables method. This is shown as:

RTENOTITLE....................(2)

The following solution assumption is made concerning the time function:

RTENOTITLE....................(3)

This equation is substituted back into the assumed solution, which then is appropriately differentiated and substituted back into the equation of motion. The equation becomes

RTENOTITLE....................(4)

which is of the form

RTENOTITLE....................(5)

The standard solution of this equation is:

RTENOTITLE....................(6)

The constants of integration, C1 and C2, are determined by the initial and boundary conditions, and φ is a collection of the constants and is given by:

RTENOTITLE....................(7)

Therefore, the total solution is:

RTENOTITLE....................(8)

The solution to the torsional equation of motion is derived similarly to the axial equation, with the substitution of the appropriate variables and noting that there is no initial strain from gravity. The variables u, m, Ac, E, c, ω, vs, and φ are replaced by θ, I, J, G, cθ, ωθ, vθ, and η, respectively. The torsional equation of motion is:

RTENOTITLE....................(9)

This gives the solution as:

RTENOTITLE....................(10)

Constants C1 and C2 are based on the initial and boundary conditions, and η is a collection of the constants and is given by:

RTENOTITLE....................(11)

where

RTENOTITLE....................(12)

and

RTENOTITLE....................(13)

Nomenclature

Ac = cross-sectional area, L2, in.2
c = axial damping coefficient, mL/t, lbf-ft/sec
cθ = torsional damping coefficient, mL/t, lbf-sec/rad
C = constant of integration, various
di = inner diameter, L, in.
do = outer diameter, L, in.
E = modulus of elasticity, m/Lt2, psia
gc = gravitational constant, L/t2, 32.174 ft/sec2
G = shear modulus, m/Lt2, psia
i = imaginary operator
I = second moment of inertia, L4, in.4
J = polar moment, L3, in.3
m = mass, m, lbm
mθ = mass polar moment of inertia, mL, lbf-sec2
t = time, seconds
T(t) = displacement function in terms of time, t
u = displacement, L, in.
U(x,t) = continuous displacement function, L, in.
vθ = torsional sonic velocity, L/t, ft/sec
x = displacement, L, in.
X(x) = displacement function in terms of location x
y = dependent variable, various
η = convenient coefficient, 1/L, 1/ft
θ = twist, rad
ρ = density, m/L3, lbm/in.3
ω = frequency, 1/t, Hz
ωθ = twist natural frequency, 1/t, Hz
φ = convenient coefficient, 1/L, 1/ft

Noteworthy papers in OnePetro

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External links

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See also

Vibration theory

Basic vibration analysis

Vibrating systems with multiple sources of motion

Differential calculus refresher

PEH:Mathematics_of_Vibrating_Systems

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