Introduction to Gyroscopic 

Gyroscopic Couple Basic -‘Gyre’ is a Greek word, meaning ‘circular motion’ and Gyration means the whirling  motion. A gyroscope is a spatial mechanism which is generally employed for the study of precessional motion of a rotary body. Gyroscope finds applications in gyrocompass, used in aircraft, naval ship, control system of missiles and space shuttle.

gyroscope mechanism
gyroscope mechanism
A gyroscope consists of a rotor mounted in the inner gimbal. The inner gimbal is mounted in the outer gimbal which itself is mounted on a fixed frame as shown in Fig. When the rotor spins about X-axis with angular velocity ω rad/s and the inner gimbal precesses (rotates) about Y-axis, the spatial mechanism is forced to turn about Z-axis other than its own axis of rotation, and the gyroscopic effect is thus setup. The resistance to this motion is called gyroscopic effect.
 
GYROSCOPIC COUPLE
                         The turning moment which opposes any change of the inclination of the axis of rotation of a gyroscope.

Direction of Spin vector, Precession vector and Couple/Torque vector 

with forced precession
To determine the direction of spin, precession and torque/couple vector, right hand screw rule or right hand rule is used. The fingers represent the rotation of the disc and the thumb shows the direction of the spin, precession and torque vector
Direction of Spin vector, Precession vector and Couple/Torque vector
Direction of Spin vector, Precession vector and Couple/Torque vector

Case :

Consider a rotor rotating in anticlockwise direction when seen from the right, and to precess the spin axis about precession axis in clockwise and anticlockwise direction when seen from top. Then, to determine the active/reactive gyroscopic couple vector, the following procedure is used.
  • Turn the spin vector through 90 degree in the direction of  precession on the XOZ plane
  • The turned spin vector will then correspond to the direction of active  gyroscopic couple/torque vector
  • The reactive gyroscopic couple/torque vector is taken  opposite  to active gyro vector direction
Direction of active and reactive gyroscopic couple/torque vector 
Direction of active and reactive gyroscopic couple/torque vector 

Examples Of Gyroscopic Couples : 

GYROSCOPIC EFFECT ON SHIP 
Gyroscope is used for stabilization and directional control of a ship sailing in the  rough sea. A ship, while navigating in the rough sea, may experience the following three different types of motion:
(i) Steering—The turning of ship in a curve while moving forward
(ii) Pitching—The movement of the ship up and down  from horizontal position in a vertical plane about transverse axis
(iii)Rolling—Sideway motion of the ship about longitudinal axis.
For stabilization of a ship against any of the above motion, the major requirement is that the gyroscope shall be made to precess in such a way that reaction couple exerted by the rotor opposes the disturbing couple which may act on the frame.
Ship Terminology  
 (i) Bow – It is the fore end of  ship
(ii) Stern – It is the rear end of ship
(iii) Starboard – It is the right hand side of the ship looking in the direction of motion
(iv) Port – It is the left hand side of the ship looking in the direction of motion
ship terminology
ship terminology
Consider a gyro-rotor mounted on the ship along longitudinal axis (X-axis) as shown in above image and rotate in clockwise direction when viewed from rear end of the ship. The  angular speed of the rotor is rad/s. The direction of angular momentum vector, based on direction of rotation of rotor, is decided using right hand thumb rule.

Gyroscopic Effect on Aeroplane 

     Aeroplanes are subjected to gyroscopic effect when it taking off, landing and negotiating left or right turn in the air.
Let us analyze the effect of gyroscopic couple acting on the body of the aero plane for various conditions.
aeroplane front and rear
aeroplane front and rear

 

Case (i): PROPELLER rotates in CLOCKWISE direction when seen from rear end and Aeroplane turns towards LEFT
aeroplane taking turn to left
aeroplane taking turn to left
 
Case (ii): PROPELLER rotates in CLOCKWISE direction when seen from rear end and Aeroplane turns towards RIGHT
  Case (iii): PROPELLER rotates in ANTICLOCKWISE direction when seen from rear end and Aeroplane turns towards LEFT
Case (iv):  PROPELLER rotates in ANTICLOCKWISE direction when seen from rear end and Aeroplane turns towards RIGHT

Stability of Automotive

two wheeler taking turn
two wheeler taking turn
                      A vehicle running on the road is said to be stable when no wheel is supposed to leave the road surface. In other words, the resultant reactions by the road surface on wheels should  act in upward direction. For a moving vehicle, one of the reaction is due to gyroscopic couple  produced by the rotating wheels and rotating parts of the engine. Let us discuss stability of two and four wheeled vehicles when negotiating a curve/turn.
stability equation
stability of two wheeler vehicle
Stability of Four Wheeled Vehicle negotiating a turn.
                     When a vehicle moves on a curved path, a centrifugal force acts on the vehicle in  outward direction through  the centre of gravity of the vehicle. Total Gyroscopic Couple is Found out by making plus of Effect of Gyroscopic Couple due to Engine and Effect of Gyroscopic couple due to Wheel.
gyroscopic couple acting on four wheeler car body
gyroscopic couple acting on four wheeler car body
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