PPT: Gyroscopic Motion | Theory of Machines (TOM) - Mechanical Engineering PDF Download

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• Gyroscope is a mechanical system or arrangement having a
rotor(usually heavy) spinning at high speed about its axis and being
free to turn in any direction.
Page 2


• Gyroscope is a mechanical system or arrangement having a
rotor(usually heavy) spinning at high speed about its axis and being
free to turn in any direction.
Principle of Gyroscope :
Whenever a body is rotating in a plane(plane YZ) about an axis(axis
Ox) and a couple is applied on the rotating body across the axis of
rotation or spin in an another perpendicular plane(plane XY), the
rotating or spinning body starts processing in a third mutually
perpendicular plane(plane XZ).
Page 3


• Gyroscope is a mechanical system or arrangement having a
rotor(usually heavy) spinning at high speed about its axis and being
free to turn in any direction.
Principle of Gyroscope :
Whenever a body is rotating in a plane(plane YZ) about an axis(axis
Ox) and a couple is applied on the rotating body across the axis of
rotation or spin in an another perpendicular plane(plane XY), the
rotating or spinning body starts processing in a third mutually
perpendicular plane(plane XZ).
Applications of Gyroscope
? Computer Pointing Devices
? Gyroscopic behaviour is used in the racing car industry.
This is because car engines act just like big gyroscopes.
? Wheels on motorbikes act as gyroscopes and make the
bike easier to balance (stay up right) when moving.
? Ship stabilisers
Page 4


• Gyroscope is a mechanical system or arrangement having a
rotor(usually heavy) spinning at high speed about its axis and being
free to turn in any direction.
Principle of Gyroscope :
Whenever a body is rotating in a plane(plane YZ) about an axis(axis
Ox) and a couple is applied on the rotating body across the axis of
rotation or spin in an another perpendicular plane(plane XY), the
rotating or spinning body starts processing in a third mutually
perpendicular plane(plane XZ).
Applications of Gyroscope
? Computer Pointing Devices
? Gyroscopic behaviour is used in the racing car industry.
This is because car engines act just like big gyroscopes.
? Wheels on motorbikes act as gyroscopes and make the
bike easier to balance (stay up right) when moving.
? Ship stabilisers
Precessional Angular Motion
(Vectorial representation of angular motion)
• We know that the angular acceleration is the rate of change of
angular velocity with respect to time.
• It is a vector quantity and may be represented by drawing a vector
diagram with the help of right hand screw rule.
• Consider a disc, as shown in Fig. (a), revolving or spinning about the
axis OX (known as axis of spin) in anticlockwise when seen from the
front, with an angular velocity in a plane at right angles to the paper .
Page 5


• Gyroscope is a mechanical system or arrangement having a
rotor(usually heavy) spinning at high speed about its axis and being
free to turn in any direction.
Principle of Gyroscope :
Whenever a body is rotating in a plane(plane YZ) about an axis(axis
Ox) and a couple is applied on the rotating body across the axis of
rotation or spin in an another perpendicular plane(plane XY), the
rotating or spinning body starts processing in a third mutually
perpendicular plane(plane XZ).
Applications of Gyroscope
? Computer Pointing Devices
? Gyroscopic behaviour is used in the racing car industry.
This is because car engines act just like big gyroscopes.
? Wheels on motorbikes act as gyroscopes and make the
bike easier to balance (stay up right) when moving.
? Ship stabilisers
Precessional Angular Motion
(Vectorial representation of angular motion)
• We know that the angular acceleration is the rate of change of
angular velocity with respect to time.
• It is a vector quantity and may be represented by drawing a vector
diagram with the help of right hand screw rule.
• Consider a disc, as shown in Fig. (a), revolving or spinning about the
axis OX (known as axis of spin) in anticlockwise when seen from the
front, with an angular velocity in a plane at right angles to the paper .
• After a short interval of time t, let the disc be spinning about the new axis of spin
OX ’ (at an angle d? ) with an angular velocity ( ? + d ?).
• Using the right hand screw rule, initial angular velocity of the disc ? is represented
by vector ox; and the final angular velocity of the disc ( ? +d? ) is represented by
vector ox ’ as shown in Fig. (b).
• The vector xx ’ represents the change of angular velocity in time dt i.e. the angular
acceleration of the disc. This may be resolved into two components, one parallel
to ox and the other perpendicular to ox.
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FAQs on PPT: Gyroscopic Motion - Theory of Machines (TOM) - Mechanical Engineering

1. What is gyroscopic motion in mechanical engineering?
Ans. Gyroscopic motion in mechanical engineering refers to the behavior of rotating objects, known as gyroscopes, which exhibit unique properties due to their angular momentum. These properties include precession, nutation, and gyroscopic stability, which are crucial in various applications such as navigation systems, gyrocompasses, and stabilization systems.
2. How does gyroscopic motion affect the stability of vehicles?
Ans. Gyroscopic motion plays a significant role in the stability of vehicles. For example, in motorcycles, the rotating wheels act as gyroscopes, providing stability and preventing the vehicle from tipping over while in motion. Similarly, gyroscopic effects in ships and aircraft contribute to their stability and maneuverability.
3. What are the applications of gyroscopic motion in mechanical engineering?
Ans. Gyroscopic motion finds applications in various fields of mechanical engineering. Some common applications include gyroscopic sensors in navigation systems, gyrocompasses for accurate direction determination, gyroscopic stabilization systems for cameras and drones, and gyroscopic control systems in spacecraft and satellites.
4. How does gyroscopic motion affect the behavior of rotating machinery?
Ans. Gyroscopic motion can significantly impact the behavior of rotating machinery. For instance, when gyroscopic forces are not properly accounted for, they can cause vibrations, misalignments, and instability in rotating equipment, leading to potential damage and reduced performance. Hence, engineers must consider gyroscopic effects during the design and analysis of such machinery.
5. Is there any relationship between gyroscopic motion and angular momentum?
Ans. Yes, there is a direct relationship between gyroscopic motion and angular momentum. Gyroscopic motion arises due to the conservation of angular momentum, where the rotational motion of an object tends to maintain its axis of rotation. This property allows gyroscopes to exhibit unique behaviors, such as resisting changes in their orientation and maintaining stability in various applications.
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