The largest value of β in the ensuing motion.

Question

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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 MECH...,STAT.+DYNA.(LL)-W/ACCESS, 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°_.

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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 MECH...,STAT.+DYNA.(LL)-W/ACCESS, 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°_.

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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 MECH...,STAT.+DYNA.(LL)-W/ACCESS, 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°_.

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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 MECH...,STAT.+DYNA.(LL)-W/ACCESS, 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°_.

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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 MECH...,STAT.+DYNA.(LL)-W/ACCESS, 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 MECH...,STAT.+DYNA.(LL)-W/ACCESS, 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 MECH...,STAT.+DYNA.(LL)-W/ACCESS, 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)