The largest value of β in the ensuing motion.

Question

Want to see more full solutions like this?

Answer 1

Question

Chapter 18.3, Problem 18.141P

To determine

The largest value of β in the ensuing motion.

Expert Solution & Answer

Answer to Problem 18.141P

The largest value of βmax in the ensuing motion is 27.5°_.

Explanation of Solution

Given information:

The position of the sphere β is zero.

The rate of precession ϕ˙0=17g/11a.

Calculation:

Conservation of angular momentum about the Z and z axes:

The only external forces are acting in homogenous sphere is weight of the sphere and reaction at A. Hence, the angular momentum is conserved about the Z and z axes.

Choose the principal axes Axyz with taking y horizontal and pointing into the paper.

Write the expression for the angular velocity ω.

ω=−ϕ˙cosβi+β˙j+(ψ˙−ϕ˙sinβ)k

The principal moment of inertia are Ix=Iy=m(25a2+(2a)2) and Iz=25ma2.

Draw the Free body diagram of homogeneous sphere and the forces acting on it as in Figure (1).

VECTOR MECHANIC, Chapter 18.3, Problem 18.141P

Write the expression for the angular momentum about point A.

HA=Ixωxi+Iyωyj+Izωzk

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

HA=m(25a2+(2a)2)(−ϕ˙cosβ)i+m(25a2+(2a)2)β˙j+25ma2(ψ˙−ϕ˙sinβ)k=−225ma2ϕ˙cosβi+225ma2β˙j+25ma2(ψ˙−ϕ˙sinβ)k

Consider Hz=constant or HA⋅K=constant.

The scalar value of i⋅K=−cosβ, j⋅K=0, and k⋅K=−sinβ.

Determine the conservation of angular momentum about fixed Z axis HA⋅K.

HA⋅K=constant

Substitute −225ma2ϕ˙cosβi+225ma2βj+25ma2(ψ˙−ϕ˙sinβ)k for HA, −cosβ for (i⋅K), 0 for (j⋅K), and −cosβ for (k⋅K).

{−225ma2ϕ˙cosβ(i⋅K)+225ma2β˙(j⋅K)+25ma2(ψ˙−ϕ˙sinβ)(k⋅K)}=constant{−225ma2ϕ˙cosβ(−cosβ)+225ma2β˙(0)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant{−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant (1)

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (1).

{−225ma2ϕ˙0cos0(−cos0)+25ma2(0−ϕ˙0sin0)(−sin0)}=constantconstant=225ma2ϕ˙0

Substitute 225ma2ϕ˙0 for constant in Equation (1).

−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)=225ma2ϕ˙025ma2[11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ]=25×11ϕ˙011ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙0 (2)

Determine the constant value using the angular momentum along z–axis.

Hz=constantIzωz=constant

Substitute 25ma2 for Iz and (ψ˙−ϕ˙sinβ) for ωz.

25ma2(ψ˙−ϕ˙sinβ)=constant (3).

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (3).

25ma2(0−ϕ˙0sin(0))=constantconstant=0

Substitute 0 for constant in Equation (3).

25ma2(ψ˙−ϕ˙sinβ)=0ψ˙−ϕ˙sinβ=0

Substitute 0 for (ψ˙−ϕ˙sinβ) in Equation (2).

11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙011ϕ˙cos2β−0(sinβ)=11ϕ˙0ϕ˙=11ϕ˙011cos2βϕ˙=ϕ˙0sec2β

Conservation of energy:

Determine the value of kinetic energy T.

T=12(Ixωx2+Iyωy2+Izωz2)

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

T={12(m(25a2+(2a)2)(−ϕ˙cosβ)2+m(25a2+(2a)2)(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)}=12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)

Select the datum at β=0.

Determine the value of conservation of energy using the relation.

T+V=constant

Here, E is the constant and V is the potential energy.

Substitute 12(225ma2ϕ˙2cos2β+225ma2(β)2+25ma2(ψ˙−ϕ˙sinβ)2) for T and −2mgasinβ for V.

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=constant (4)

Substitute ϕ˙0 for ϕ˙, 0 for β, 0 for β˙, and 0 for ψ˙ in Equation (4).

{12(225ma2ϕ˙02cos20+225ma2(0)2+25ma2(0−ϕ˙0sin0)2)−2mgasin0}=constantconstant=115ma2ϕ˙02

Substitute 115ma2ϕ˙02 for constant in Equation (4).

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=115ma2ϕ˙0212×25ma2((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=115ma2ϕ˙02((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=11ϕ˙02 (5)

Consider β˙=0 for the maximum value of β.

Substitute ϕ˙0sec2β for ϕ˙, 0 for (ψ˙−ϕ˙sinβ), and 0 for β˙ in Equation (5).

11(ϕ˙0sec2β)2cos2β+11(0)2−10gasinβ=11ϕ˙0211ϕ˙02sec4β×1sec2β−10gasinβ=11ϕ˙0211ϕ˙02sec2β−11ϕ˙02=10gasinβ11ϕ˙02(1−cos2βcos2β)=10gasinβ

ϕ˙02(sin2βcos2β)=1011gasinβϕ˙02=1011gasinβ×cos2βsin2βϕ˙02=1011gacos2βsinβ (6)

Substitute 17g/11a for ϕ˙0 in Equation (6).

(17g/11a)2=1011gacos2βsinβ17g11a=1011ga(1−sin2β)sinβ17sinβ=10−10sin2β10sin2β+17sinβ−10=0 (7)

Solve the Equation (7).

The value of sinβ is 0.462 and –2.162.

Determine the largest value of βmax using the relation.

sinβmax=0.462βmax=sin−1(0.462)βmax=27.5°

Therefore, the largest value of βmax in the ensuing motion is 27.5°_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Students have asked these similar questions

A pump delivering 230 lps of water at 30C has a 300-mm diameter suction pipe and a 254-mm diameter discharge pipe as shown in the figure. The suction pipe is 3.5 m long and the discharge pipe is 23 m long, both pipe's materials are cast iron. The water is delivered 16m above the intake water level. Considering head losses in fittings, valves, and major head loss. a) Find the total dynamic head which the pump must supply. b)It the pump mechanical efficiency is 68%, and the motor efficiency is 90%, determine the power rating of the motor in hp.

The tensile 0.2 percent offset yield strength of AISI 1137 cold-drawn steel bars up to 1 inch in diameter from 2 mills and 25 heats is reported as follows: Sy 93 95 101 f 97 99 107 109 111 19 25 38 17 12 10 5 4 103 105 4 2 where Sy is the class midpoint in kpsi and fis the number in each class. Presuming the distribution is normal, determine the yield strength exceeded by 99.0% of the population. The yield strength exceeded by 99.0% of the population is kpsi.

Solve this problem and show all of the work

Answer 2

Question

Chapter 18.3, Problem 18.141P

To determine

The largest value of β in the ensuing motion.

Expert Solution & Answer

Answer to Problem 18.141P

The largest value of βmax in the ensuing motion is 27.5°_.

Explanation of Solution

Given information:

The position of the sphere β is zero.

The rate of precession ϕ˙0=17g/11a.

Calculation:

Conservation of angular momentum about the Z and z axes:

The only external forces are acting in homogenous sphere is weight of the sphere and reaction at A. Hence, the angular momentum is conserved about the Z and z axes.

Choose the principal axes Axyz with taking y horizontal and pointing into the paper.

Write the expression for the angular velocity ω.

ω=−ϕ˙cosβi+β˙j+(ψ˙−ϕ˙sinβ)k

The principal moment of inertia are Ix=Iy=m(25a2+(2a)2) and Iz=25ma2.

Draw the Free body diagram of homogeneous sphere and the forces acting on it as in Figure (1).

VECTOR MECHANIC, Chapter 18.3, Problem 18.141P

Write the expression for the angular momentum about point A.

HA=Ixωxi+Iyωyj+Izωzk

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

HA=m(25a2+(2a)2)(−ϕ˙cosβ)i+m(25a2+(2a)2)β˙j+25ma2(ψ˙−ϕ˙sinβ)k=−225ma2ϕ˙cosβi+225ma2β˙j+25ma2(ψ˙−ϕ˙sinβ)k

Consider Hz=constant or HA⋅K=constant.

The scalar value of i⋅K=−cosβ, j⋅K=0, and k⋅K=−sinβ.

Determine the conservation of angular momentum about fixed Z axis HA⋅K.

HA⋅K=constant

Substitute −225ma2ϕ˙cosβi+225ma2βj+25ma2(ψ˙−ϕ˙sinβ)k for HA, −cosβ for (i⋅K), 0 for (j⋅K), and −cosβ for (k⋅K).

{−225ma2ϕ˙cosβ(i⋅K)+225ma2β˙(j⋅K)+25ma2(ψ˙−ϕ˙sinβ)(k⋅K)}=constant{−225ma2ϕ˙cosβ(−cosβ)+225ma2β˙(0)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant{−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant (1)

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (1).

{−225ma2ϕ˙0cos0(−cos0)+25ma2(0−ϕ˙0sin0)(−sin0)}=constantconstant=225ma2ϕ˙0

Substitute 225ma2ϕ˙0 for constant in Equation (1).

−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)=225ma2ϕ˙025ma2[11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ]=25×11ϕ˙011ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙0 (2)

Determine the constant value using the angular momentum along z–axis.

Hz=constantIzωz=constant

Substitute 25ma2 for Iz and (ψ˙−ϕ˙sinβ) for ωz.

25ma2(ψ˙−ϕ˙sinβ)=constant (3).

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (3).

25ma2(0−ϕ˙0sin(0))=constantconstant=0

Substitute 0 for constant in Equation (3).

25ma2(ψ˙−ϕ˙sinβ)=0ψ˙−ϕ˙sinβ=0

Substitute 0 for (ψ˙−ϕ˙sinβ) in Equation (2).

11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙011ϕ˙cos2β−0(sinβ)=11ϕ˙0ϕ˙=11ϕ˙011cos2βϕ˙=ϕ˙0sec2β

Conservation of energy:

Determine the value of kinetic energy T.

T=12(Ixωx2+Iyωy2+Izωz2)

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

T={12(m(25a2+(2a)2)(−ϕ˙cosβ)2+m(25a2+(2a)2)(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)}=12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)

Select the datum at β=0.

Determine the value of conservation of energy using the relation.

T+V=constant

Here, E is the constant and V is the potential energy.

Substitute 12(225ma2ϕ˙2cos2β+225ma2(β)2+25ma2(ψ˙−ϕ˙sinβ)2) for T and −2mgasinβ for V.

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=constant (4)

Substitute ϕ˙0 for ϕ˙, 0 for β, 0 for β˙, and 0 for ψ˙ in Equation (4).

{12(225ma2ϕ˙02cos20+225ma2(0)2+25ma2(0−ϕ˙0sin0)2)−2mgasin0}=constantconstant=115ma2ϕ˙02

Substitute 115ma2ϕ˙02 for constant in Equation (4).

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=115ma2ϕ˙0212×25ma2((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=115ma2ϕ˙02((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=11ϕ˙02 (5)

Consider β˙=0 for the maximum value of β.

Substitute ϕ˙0sec2β for ϕ˙, 0 for (ψ˙−ϕ˙sinβ), and 0 for β˙ in Equation (5).

11(ϕ˙0sec2β)2cos2β+11(0)2−10gasinβ=11ϕ˙0211ϕ˙02sec4β×1sec2β−10gasinβ=11ϕ˙0211ϕ˙02sec2β−11ϕ˙02=10gasinβ11ϕ˙02(1−cos2βcos2β)=10gasinβ

ϕ˙02(sin2βcos2β)=1011gasinβϕ˙02=1011gasinβ×cos2βsin2βϕ˙02=1011gacos2βsinβ (6)

Substitute 17g/11a for ϕ˙0 in Equation (6).

(17g/11a)2=1011gacos2βsinβ17g11a=1011ga(1−sin2β)sinβ17sinβ=10−10sin2β10sin2β+17sinβ−10=0 (7)

Solve the Equation (7).

The value of sinβ is 0.462 and –2.162.

Determine the largest value of βmax using the relation.

sinβmax=0.462βmax=sin−1(0.462)βmax=27.5°

Therefore, the largest value of βmax in the ensuing motion is 27.5°_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Question

Chapter 18.3, Problem 18.141P

To determine

The largest value of β in the ensuing motion.

Expert Solution & Answer

Answer to Problem 18.141P

The largest value of βmax in the ensuing motion is 27.5°_.

Explanation of Solution

Given information:

The position of the sphere β is zero.

The rate of precession ϕ˙0=17g/11a.

Calculation:

Conservation of angular momentum about the Z and z axes:

The only external forces are acting in homogenous sphere is weight of the sphere and reaction at A. Hence, the angular momentum is conserved about the Z and z axes.

Choose the principal axes Axyz with taking y horizontal and pointing into the paper.

Write the expression for the angular velocity ω.

ω=−ϕ˙cosβi+β˙j+(ψ˙−ϕ˙sinβ)k

The principal moment of inertia are Ix=Iy=m(25a2+(2a)2) and Iz=25ma2.

Draw the Free body diagram of homogeneous sphere and the forces acting on it as in Figure (1).

VECTOR MECHANIC, Chapter 18.3, Problem 18.141P

Write the expression for the angular momentum about point A.

HA=Ixωxi+Iyωyj+Izωzk

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

HA=m(25a2+(2a)2)(−ϕ˙cosβ)i+m(25a2+(2a)2)β˙j+25ma2(ψ˙−ϕ˙sinβ)k=−225ma2ϕ˙cosβi+225ma2β˙j+25ma2(ψ˙−ϕ˙sinβ)k

Consider Hz=constant or HA⋅K=constant.

The scalar value of i⋅K=−cosβ, j⋅K=0, and k⋅K=−sinβ.

Determine the conservation of angular momentum about fixed Z axis HA⋅K.

HA⋅K=constant

Substitute −225ma2ϕ˙cosβi+225ma2βj+25ma2(ψ˙−ϕ˙sinβ)k for HA, −cosβ for (i⋅K), 0 for (j⋅K), and −cosβ for (k⋅K).

{−225ma2ϕ˙cosβ(i⋅K)+225ma2β˙(j⋅K)+25ma2(ψ˙−ϕ˙sinβ)(k⋅K)}=constant{−225ma2ϕ˙cosβ(−cosβ)+225ma2β˙(0)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant{−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant (1)

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (1).

{−225ma2ϕ˙0cos0(−cos0)+25ma2(0−ϕ˙0sin0)(−sin0)}=constantconstant=225ma2ϕ˙0

Substitute 225ma2ϕ˙0 for constant in Equation (1).

−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)=225ma2ϕ˙025ma2[11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ]=25×11ϕ˙011ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙0 (2)

Determine the constant value using the angular momentum along z–axis.

Hz=constantIzωz=constant

Substitute 25ma2 for Iz and (ψ˙−ϕ˙sinβ) for ωz.

25ma2(ψ˙−ϕ˙sinβ)=constant (3).

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (3).

25ma2(0−ϕ˙0sin(0))=constantconstant=0

Substitute 0 for constant in Equation (3).

25ma2(ψ˙−ϕ˙sinβ)=0ψ˙−ϕ˙sinβ=0

Substitute 0 for (ψ˙−ϕ˙sinβ) in Equation (2).

11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙011ϕ˙cos2β−0(sinβ)=11ϕ˙0ϕ˙=11ϕ˙011cos2βϕ˙=ϕ˙0sec2β

Conservation of energy:

Determine the value of kinetic energy T.

T=12(Ixωx2+Iyωy2+Izωz2)

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

T={12(m(25a2+(2a)2)(−ϕ˙cosβ)2+m(25a2+(2a)2)(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)}=12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)

Select the datum at β=0.

Determine the value of conservation of energy using the relation.

T+V=constant

Here, E is the constant and V is the potential energy.

Substitute 12(225ma2ϕ˙2cos2β+225ma2(β)2+25ma2(ψ˙−ϕ˙sinβ)2) for T and −2mgasinβ for V.

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=constant (4)

Substitute ϕ˙0 for ϕ˙, 0 for β, 0 for β˙, and 0 for ψ˙ in Equation (4).

{12(225ma2ϕ˙02cos20+225ma2(0)2+25ma2(0−ϕ˙0sin0)2)−2mgasin0}=constantconstant=115ma2ϕ˙02

Substitute 115ma2ϕ˙02 for constant in Equation (4).

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=115ma2ϕ˙0212×25ma2((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=115ma2ϕ˙02((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=11ϕ˙02 (5)

Consider β˙=0 for the maximum value of β.

Substitute ϕ˙0sec2β for ϕ˙, 0 for (ψ˙−ϕ˙sinβ), and 0 for β˙ in Equation (5).

11(ϕ˙0sec2β)2cos2β+11(0)2−10gasinβ=11ϕ˙0211ϕ˙02sec4β×1sec2β−10gasinβ=11ϕ˙0211ϕ˙02sec2β−11ϕ˙02=10gasinβ11ϕ˙02(1−cos2βcos2β)=10gasinβ

ϕ˙02(sin2βcos2β)=1011gasinβϕ˙02=1011gasinβ×cos2βsin2βϕ˙02=1011gacos2βsinβ (6)

Substitute 17g/11a for ϕ˙0 in Equation (6).

(17g/11a)2=1011gacos2βsinβ17g11a=1011ga(1−sin2β)sinβ17sinβ=10−10sin2β10sin2β+17sinβ−10=0 (7)

Solve the Equation (7).

The value of sinβ is 0.462 and –2.162.

Determine the largest value of βmax using the relation.

sinβmax=0.462βmax=sin−1(0.462)βmax=27.5°

Therefore, the largest value of βmax in the ensuing motion is 27.5°_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Question

Chapter 18.3, Problem 18.141P

To determine

The largest value of β in the ensuing motion.

Expert Solution & Answer

Answer to Problem 18.141P

The largest value of βmax in the ensuing motion is 27.5°_.

Explanation of Solution

Given information:

The position of the sphere β is zero.

The rate of precession ϕ˙0=17g/11a.

Calculation:

Conservation of angular momentum about the Z and z axes:

The only external forces are acting in homogenous sphere is weight of the sphere and reaction at A. Hence, the angular momentum is conserved about the Z and z axes.

Choose the principal axes Axyz with taking y horizontal and pointing into the paper.

Write the expression for the angular velocity ω.

ω=−ϕ˙cosβi+β˙j+(ψ˙−ϕ˙sinβ)k

The principal moment of inertia are Ix=Iy=m(25a2+(2a)2) and Iz=25ma2.

Draw the Free body diagram of homogeneous sphere and the forces acting on it as in Figure (1).

VECTOR MECHANIC, Chapter 18.3, Problem 18.141P

Write the expression for the angular momentum about point A.

HA=Ixωxi+Iyωyj+Izωzk

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

HA=m(25a2+(2a)2)(−ϕ˙cosβ)i+m(25a2+(2a)2)β˙j+25ma2(ψ˙−ϕ˙sinβ)k=−225ma2ϕ˙cosβi+225ma2β˙j+25ma2(ψ˙−ϕ˙sinβ)k

Consider Hz=constant or HA⋅K=constant.

The scalar value of i⋅K=−cosβ, j⋅K=0, and k⋅K=−sinβ.

Determine the conservation of angular momentum about fixed Z axis HA⋅K.

HA⋅K=constant

Substitute −225ma2ϕ˙cosβi+225ma2βj+25ma2(ψ˙−ϕ˙sinβ)k for HA, −cosβ for (i⋅K), 0 for (j⋅K), and −cosβ for (k⋅K).

{−225ma2ϕ˙cosβ(i⋅K)+225ma2β˙(j⋅K)+25ma2(ψ˙−ϕ˙sinβ)(k⋅K)}=constant{−225ma2ϕ˙cosβ(−cosβ)+225ma2β˙(0)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant{−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant (1)

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (1).

{−225ma2ϕ˙0cos0(−cos0)+25ma2(0−ϕ˙0sin0)(−sin0)}=constantconstant=225ma2ϕ˙0

Substitute 225ma2ϕ˙0 for constant in Equation (1).

−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)=225ma2ϕ˙025ma2[11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ]=25×11ϕ˙011ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙0 (2)

Determine the constant value using the angular momentum along z–axis.

Hz=constantIzωz=constant

Substitute 25ma2 for Iz and (ψ˙−ϕ˙sinβ) for ωz.

25ma2(ψ˙−ϕ˙sinβ)=constant (3).

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (3).

25ma2(0−ϕ˙0sin(0))=constantconstant=0

Substitute 0 for constant in Equation (3).

25ma2(ψ˙−ϕ˙sinβ)=0ψ˙−ϕ˙sinβ=0

Substitute 0 for (ψ˙−ϕ˙sinβ) in Equation (2).

11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙011ϕ˙cos2β−0(sinβ)=11ϕ˙0ϕ˙=11ϕ˙011cos2βϕ˙=ϕ˙0sec2β

Conservation of energy:

Determine the value of kinetic energy T.

T=12(Ixωx2+Iyωy2+Izωz2)

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

T={12(m(25a2+(2a)2)(−ϕ˙cosβ)2+m(25a2+(2a)2)(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)}=12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)

Select the datum at β=0.

Determine the value of conservation of energy using the relation.

T+V=constant

Here, E is the constant and V is the potential energy.

Substitute 12(225ma2ϕ˙2cos2β+225ma2(β)2+25ma2(ψ˙−ϕ˙sinβ)2) for T and −2mgasinβ for V.

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=constant (4)

Substitute ϕ˙0 for ϕ˙, 0 for β, 0 for β˙, and 0 for ψ˙ in Equation (4).

{12(225ma2ϕ˙02cos20+225ma2(0)2+25ma2(0−ϕ˙0sin0)2)−2mgasin0}=constantconstant=115ma2ϕ˙02

Substitute 115ma2ϕ˙02 for constant in Equation (4).

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=115ma2ϕ˙0212×25ma2((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=115ma2ϕ˙02((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=11ϕ˙02 (5)

Consider β˙=0 for the maximum value of β.

Substitute ϕ˙0sec2β for ϕ˙, 0 for (ψ˙−ϕ˙sinβ), and 0 for β˙ in Equation (5).

11(ϕ˙0sec2β)2cos2β+11(0)2−10gasinβ=11ϕ˙0211ϕ˙02sec4β×1sec2β−10gasinβ=11ϕ˙0211ϕ˙02sec2β−11ϕ˙02=10gasinβ11ϕ˙02(1−cos2βcos2β)=10gasinβ

ϕ˙02(sin2βcos2β)=1011gasinβϕ˙02=1011gasinβ×cos2βsin2βϕ˙02=1011gacos2βsinβ (6)

Substitute 17g/11a for ϕ˙0 in Equation (6).

(17g/11a)2=1011gacos2βsinβ17g11a=1011ga(1−sin2β)sinβ17sinβ=10−10sin2β10sin2β+17sinβ−10=0 (7)

Solve the Equation (7).

The value of sinβ is 0.462 and –2.162.

Determine the largest value of βmax using the relation.

sinβmax=0.462βmax=sin−1(0.462)βmax=27.5°

Therefore, the largest value of βmax in the ensuing motion is 27.5°_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Chapter 18.3, Problem 18.141P

To determine

The largest value of β in the ensuing motion.

Expert Solution & Answer

Answer to Problem 18.141P

The largest value of βmax in the ensuing motion is 27.5°_.

Explanation of Solution

Given information:

The position of the sphere β is zero.

The rate of precession ϕ˙0=17g/11a.

Calculation:

Conservation of angular momentum about the Z and z axes:

The only external forces are acting in homogenous sphere is weight of the sphere and reaction at A. Hence, the angular momentum is conserved about the Z and z axes.

Choose the principal axes Axyz with taking y horizontal and pointing into the paper.

Write the expression for the angular velocity ω.

ω=−ϕ˙cosβi+β˙j+(ψ˙−ϕ˙sinβ)k

The principal moment of inertia are Ix=Iy=m(25a2+(2a)2) and Iz=25ma2.

Draw the Free body diagram of homogeneous sphere and the forces acting on it as in Figure (1).

VECTOR MECHANIC, Chapter 18.3, Problem 18.141P

Write the expression for the angular momentum about point A.

HA=Ixωxi+Iyωyj+Izωzk

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

HA=m(25a2+(2a)2)(−ϕ˙cosβ)i+m(25a2+(2a)2)β˙j+25ma2(ψ˙−ϕ˙sinβ)k=−225ma2ϕ˙cosβi+225ma2β˙j+25ma2(ψ˙−ϕ˙sinβ)k

Consider Hz=constant or HA⋅K=constant.

The scalar value of i⋅K=−cosβ, j⋅K=0, and k⋅K=−sinβ.

Determine the conservation of angular momentum about fixed Z axis HA⋅K.

HA⋅K=constant

Substitute −225ma2ϕ˙cosβi+225ma2βj+25ma2(ψ˙−ϕ˙sinβ)k for HA, −cosβ for (i⋅K), 0 for (j⋅K), and −cosβ for (k⋅K).

{−225ma2ϕ˙cosβ(i⋅K)+225ma2β˙(j⋅K)+25ma2(ψ˙−ϕ˙sinβ)(k⋅K)}=constant{−225ma2ϕ˙cosβ(−cosβ)+225ma2β˙(0)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant{−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant (1)

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (1).

{−225ma2ϕ˙0cos0(−cos0)+25ma2(0−ϕ˙0sin0)(−sin0)}=constantconstant=225ma2ϕ˙0

Substitute 225ma2ϕ˙0 for constant in Equation (1).

−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)=225ma2ϕ˙025ma2[11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ]=25×11ϕ˙011ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙0 (2)

Determine the constant value using the angular momentum along z–axis.

Hz=constantIzωz=constant

Substitute 25ma2 for Iz and (ψ˙−ϕ˙sinβ) for ωz.

25ma2(ψ˙−ϕ˙sinβ)=constant (3).

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (3).

25ma2(0−ϕ˙0sin(0))=constantconstant=0

Substitute 0 for constant in Equation (3).

25ma2(ψ˙−ϕ˙sinβ)=0ψ˙−ϕ˙sinβ=0

Substitute 0 for (ψ˙−ϕ˙sinβ) in Equation (2).

11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙011ϕ˙cos2β−0(sinβ)=11ϕ˙0ϕ˙=11ϕ˙011cos2βϕ˙=ϕ˙0sec2β

Conservation of energy:

Determine the value of kinetic energy T.

T=12(Ixωx2+Iyωy2+Izωz2)

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

T={12(m(25a2+(2a)2)(−ϕ˙cosβ)2+m(25a2+(2a)2)(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)}=12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)

Select the datum at β=0.

Determine the value of conservation of energy using the relation.

T+V=constant

Here, E is the constant and V is the potential energy.

Substitute 12(225ma2ϕ˙2cos2β+225ma2(β)2+25ma2(ψ˙−ϕ˙sinβ)2) for T and −2mgasinβ for V.

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=constant (4)

Substitute ϕ˙0 for ϕ˙, 0 for β, 0 for β˙, and 0 for ψ˙ in Equation (4).

{12(225ma2ϕ˙02cos20+225ma2(0)2+25ma2(0−ϕ˙0sin0)2)−2mgasin0}=constantconstant=115ma2ϕ˙02

Substitute 115ma2ϕ˙02 for constant in Equation (4).

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=115ma2ϕ˙0212×25ma2((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=115ma2ϕ˙02((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=11ϕ˙02 (5)

Consider β˙=0 for the maximum value of β.

Substitute ϕ˙0sec2β for ϕ˙, 0 for (ψ˙−ϕ˙sinβ), and 0 for β˙ in Equation (5).

11(ϕ˙0sec2β)2cos2β+11(0)2−10gasinβ=11ϕ˙0211ϕ˙02sec4β×1sec2β−10gasinβ=11ϕ˙0211ϕ˙02sec2β−11ϕ˙02=10gasinβ11ϕ˙02(1−cos2βcos2β)=10gasinβ

ϕ˙02(sin2βcos2β)=1011gasinβϕ˙02=1011gasinβ×cos2βsin2βϕ˙02=1011gacos2βsinβ (6)

Substitute 17g/11a for ϕ˙0 in Equation (6).

(17g/11a)2=1011gacos2βsinβ17g11a=1011ga(1−sin2β)sinβ17sinβ=10−10sin2β10sin2β+17sinβ−10=0 (7)

Solve the Equation (7).

The value of sinβ is 0.462 and –2.162.

Determine the largest value of βmax using the relation.

sinβmax=0.462βmax=sin−1(0.462)βmax=27.5°

Therefore, the largest value of βmax in the ensuing motion is 27.5°_.

Answer 6

Chapter 18.3, Problem 18.141P

To determine

The largest value of β in the ensuing motion.

Expert Solution & Answer

Answer to Problem 18.141P

The largest value of βmax in the ensuing motion is 27.5°_.

Explanation of Solution

Given information:

The position of the sphere β is zero.

The rate of precession ϕ˙0=17g/11a.

Calculation:

Conservation of angular momentum about the Z and z axes:

The only external forces are acting in homogenous sphere is weight of the sphere and reaction at A. Hence, the angular momentum is conserved about the Z and z axes.

Choose the principal axes Axyz with taking y horizontal and pointing into the paper.

Write the expression for the angular velocity ω.

ω=−ϕ˙cosβi+β˙j+(ψ˙−ϕ˙sinβ)k

The principal moment of inertia are Ix=Iy=m(25a2+(2a)2) and Iz=25ma2.

Draw the Free body diagram of homogeneous sphere and the forces acting on it as in Figure (1).

VECTOR MECHANIC, Chapter 18.3, Problem 18.141P

Write the expression for the angular momentum about point A.

HA=Ixωxi+Iyωyj+Izωzk

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

HA=m(25a2+(2a)2)(−ϕ˙cosβ)i+m(25a2+(2a)2)β˙j+25ma2(ψ˙−ϕ˙sinβ)k=−225ma2ϕ˙cosβi+225ma2β˙j+25ma2(ψ˙−ϕ˙sinβ)k

Consider Hz=constant or HA⋅K=constant.

The scalar value of i⋅K=−cosβ, j⋅K=0, and k⋅K=−sinβ.

Determine the conservation of angular momentum about fixed Z axis HA⋅K.

HA⋅K=constant

Substitute −225ma2ϕ˙cosβi+225ma2βj+25ma2(ψ˙−ϕ˙sinβ)k for HA, −cosβ for (i⋅K), 0 for (j⋅K), and −cosβ for (k⋅K).

{−225ma2ϕ˙cosβ(i⋅K)+225ma2β˙(j⋅K)+25ma2(ψ˙−ϕ˙sinβ)(k⋅K)}=constant{−225ma2ϕ˙cosβ(−cosβ)+225ma2β˙(0)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant{−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant (1)

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (1).

{−225ma2ϕ˙0cos0(−cos0)+25ma2(0−ϕ˙0sin0)(−sin0)}=constantconstant=225ma2ϕ˙0

Substitute 225ma2ϕ˙0 for constant in Equation (1).

−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)=225ma2ϕ˙025ma2[11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ]=25×11ϕ˙011ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙0 (2)

Determine the constant value using the angular momentum along z–axis.

Hz=constantIzωz=constant

Substitute 25ma2 for Iz and (ψ˙−ϕ˙sinβ) for ωz.

25ma2(ψ˙−ϕ˙sinβ)=constant (3).

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (3).

25ma2(0−ϕ˙0sin(0))=constantconstant=0

Substitute 0 for constant in Equation (3).

25ma2(ψ˙−ϕ˙sinβ)=0ψ˙−ϕ˙sinβ=0

Substitute 0 for (ψ˙−ϕ˙sinβ) in Equation (2).

11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙011ϕ˙cos2β−0(sinβ)=11ϕ˙0ϕ˙=11ϕ˙011cos2βϕ˙=ϕ˙0sec2β

Conservation of energy:

Determine the value of kinetic energy T.

T=12(Ixωx2+Iyωy2+Izωz2)

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

T={12(m(25a2+(2a)2)(−ϕ˙cosβ)2+m(25a2+(2a)2)(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)}=12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)

Select the datum at β=0.

Determine the value of conservation of energy using the relation.

T+V=constant

Here, E is the constant and V is the potential energy.

Substitute 12(225ma2ϕ˙2cos2β+225ma2(β)2+25ma2(ψ˙−ϕ˙sinβ)2) for T and −2mgasinβ for V.

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=constant (4)

Substitute ϕ˙0 for ϕ˙, 0 for β, 0 for β˙, and 0 for ψ˙ in Equation (4).

{12(225ma2ϕ˙02cos20+225ma2(0)2+25ma2(0−ϕ˙0sin0)2)−2mgasin0}=constantconstant=115ma2ϕ˙02

Substitute 115ma2ϕ˙02 for constant in Equation (4).

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=115ma2ϕ˙0212×25ma2((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=115ma2ϕ˙02((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=11ϕ˙02 (5)

Consider β˙=0 for the maximum value of β.

Substitute ϕ˙0sec2β for ϕ˙, 0 for (ψ˙−ϕ˙sinβ), and 0 for β˙ in Equation (5).

11(ϕ˙0sec2β)2cos2β+11(0)2−10gasinβ=11ϕ˙0211ϕ˙02sec4β×1sec2β−10gasinβ=11ϕ˙0211ϕ˙02sec2β−11ϕ˙02=10gasinβ11ϕ˙02(1−cos2βcos2β)=10gasinβ

ϕ˙02(sin2βcos2β)=1011gasinβϕ˙02=1011gasinβ×cos2βsin2βϕ˙02=1011gacos2βsinβ (6)

Substitute 17g/11a for ϕ˙0 in Equation (6).

(17g/11a)2=1011gacos2βsinβ17g11a=1011ga(1−sin2β)sinβ17sinβ=10−10sin2β10sin2β+17sinβ−10=0 (7)

Solve the Equation (7).

The value of sinβ is 0.462 and –2.162.

Determine the largest value of βmax using the relation.

sinβmax=0.462βmax=sin−1(0.462)βmax=27.5°

Therefore, the largest value of βmax in the ensuing motion is 27.5°_.

Answer 7

Chapter 18.3, Problem 18.141P

To determine

The largest value of β in the ensuing motion.

Answer 8

Expert Solution & Answer

Answer to Problem 18.141P

The largest value of βmax in the ensuing motion is 27.5°_.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given information:

The position of the sphere β is zero.

The rate of precession ϕ˙0=17g/11a.

Calculation:

Conservation of angular momentum about the Z and z axes:

The only external forces are acting in homogenous sphere is weight of the sphere and reaction at A. Hence, the angular momentum is conserved about the Z and z axes.

Choose the principal axes Axyz with taking y horizontal and pointing into the paper.

Write the expression for the angular velocity ω.

ω=−ϕ˙cosβi+β˙j+(ψ˙−ϕ˙sinβ)k

The principal moment of inertia are Ix=Iy=m(25a2+(2a)2) and Iz=25ma2.

Draw the Free body diagram of homogeneous sphere and the forces acting on it as in Figure (1).

VECTOR MECHANIC, Chapter 18.3, Problem 18.141P

Write the expression for the angular momentum about point A.

HA=Ixωxi+Iyωyj+Izωzk

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

HA=m(25a2+(2a)2)(−ϕ˙cosβ)i+m(25a2+(2a)2)β˙j+25ma2(ψ˙−ϕ˙sinβ)k=−225ma2ϕ˙cosβi+225ma2β˙j+25ma2(ψ˙−ϕ˙sinβ)k

Consider Hz=constant or HA⋅K=constant.

The scalar value of i⋅K=−cosβ, j⋅K=0, and k⋅K=−sinβ.

Determine the conservation of angular momentum about fixed Z axis HA⋅K.

HA⋅K=constant

Substitute −225ma2ϕ˙cosβi+225ma2βj+25ma2(ψ˙−ϕ˙sinβ)k for HA, −cosβ for (i⋅K), 0 for (j⋅K), and −cosβ for (k⋅K).

{−225ma2ϕ˙cosβ(i⋅K)+225ma2β˙(j⋅K)+25ma2(ψ˙−ϕ˙sinβ)(k⋅K)}=constant{−225ma2ϕ˙cosβ(−cosβ)+225ma2β˙(0)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant{−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)}=constant (1)

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (1).

{−225ma2ϕ˙0cos0(−cos0)+25ma2(0−ϕ˙0sin0)(−sin0)}=constantconstant=225ma2ϕ˙0

Substitute 225ma2ϕ˙0 for constant in Equation (1).

−225ma2ϕ˙cosβ(−cosβ)+25ma2(ψ˙−ϕ˙sinβ)(−sinβ)=225ma2ϕ˙025ma2[11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ]=25×11ϕ˙011ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙0 (2)

Determine the constant value using the angular momentum along z–axis.

Hz=constantIzωz=constant

Substitute 25ma2 for Iz and (ψ˙−ϕ˙sinβ) for ωz.

25ma2(ψ˙−ϕ˙sinβ)=constant (3).

Substitute ϕ˙0 for ϕ˙, 0 for ψ˙, and 0 for β in Equation (3).

25ma2(0−ϕ˙0sin(0))=constantconstant=0

Substitute 0 for constant in Equation (3).

25ma2(ψ˙−ϕ˙sinβ)=0ψ˙−ϕ˙sinβ=0

Substitute 0 for (ψ˙−ϕ˙sinβ) in Equation (2).

11ϕ˙cos2β−(ψ˙−ϕ˙sinβ)sinβ=11ϕ˙011ϕ˙cos2β−0(sinβ)=11ϕ˙0ϕ˙=11ϕ˙011cos2βϕ˙=ϕ˙0sec2β

Conservation of energy:

Determine the value of kinetic energy T.

T=12(Ixωx2+Iyωy2+Izωz2)

Substitute m(25a2+(2a)2) for Ix, −ϕ˙cosβ for ωx, m(25a2+(2a)2) for Iy, β˙ for ωy, , 25ma2 for Iz, and (ψ˙−ϕ˙sinβ) for ωz.

T={12(m(25a2+(2a)2)(−ϕ˙cosβ)2+m(25a2+(2a)2)(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)}=12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)

Select the datum at β=0.

Determine the value of conservation of energy using the relation.

T+V=constant

Here, E is the constant and V is the potential energy.

Substitute 12(225ma2ϕ˙2cos2β+225ma2(β)2+25ma2(ψ˙−ϕ˙sinβ)2) for T and −2mgasinβ for V.

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=constant (4)

Substitute ϕ˙0 for ϕ˙, 0 for β, 0 for β˙, and 0 for ψ˙ in Equation (4).

{12(225ma2ϕ˙02cos20+225ma2(0)2+25ma2(0−ϕ˙0sin0)2)−2mgasin0}=constantconstant=115ma2ϕ˙02

Substitute 115ma2ϕ˙02 for constant in Equation (4).

{12(225ma2ϕ˙2cos2β+225ma2(β˙)2+25ma2(ψ˙−ϕ˙sinβ)2)−2mgasinβ}=115ma2ϕ˙0212×25ma2((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=115ma2ϕ˙02((11ϕ˙2cos2β+11(β˙)2+(ψ˙−ϕ˙sinβ)2)−10gasinβ)=11ϕ˙02 (5)