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Theory of Machines and Vibrations – Short Notes 
Instantaneous Centre of Velocity (I-centre) 
• The instantaneous centre of velocity can be defined as a point which has no velocity 
with respect to the fixed link. 
Centro 
• Instantaneous centre is also called centro 
• Primary Centro One which can be easily located by a mere observation of the 
mechanism. 
• Secondary Centro Centros that cannot be easily located 
Aronhold-Kennedy Theorem of Three Centre 
• It state that if three bodies are in relative motion with respect to one another, the 
three relative instantaneous centers of velocity ar collinear. 
 
Number of Centros in a Mechanism 
• For a mechanism of n links, the number of centros (Instantaneous centre) N is 
 
Linkages are the basic building blocks of all mechanisms 
• Links: rigid member having nodes. 
• Node: attachment points. 
• Binary link: 2 nodes 
• Ternary link: 3 nodes 
• Quaternary link: 4 nodes 
• Joint: connection between two or more links (at their nodes) which allows motion; 
(Joints also called kinematic pairs) 
D’Alembert’s Principle and Inertia Forces 
Page 2


Theory of Machines and Vibrations – Short Notes 
Instantaneous Centre of Velocity (I-centre) 
• The instantaneous centre of velocity can be defined as a point which has no velocity 
with respect to the fixed link. 
Centro 
• Instantaneous centre is also called centro 
• Primary Centro One which can be easily located by a mere observation of the 
mechanism. 
• Secondary Centro Centros that cannot be easily located 
Aronhold-Kennedy Theorem of Three Centre 
• It state that if three bodies are in relative motion with respect to one another, the 
three relative instantaneous centers of velocity ar collinear. 
 
Number of Centros in a Mechanism 
• For a mechanism of n links, the number of centros (Instantaneous centre) N is 
 
Linkages are the basic building blocks of all mechanisms 
• Links: rigid member having nodes. 
• Node: attachment points. 
• Binary link: 2 nodes 
• Ternary link: 3 nodes 
• Quaternary link: 4 nodes 
• Joint: connection between two or more links (at their nodes) which allows motion; 
(Joints also called kinematic pairs) 
D’Alembert’s Principle and Inertia Forces 
• D’Alembert’s principle states that the reverse-effective forces and torques and the 
external forces and torques on a body together give statical equilibrium 
 
Gear Terminology 
 
Circular Pitch (p):  
• It is a distance measured along the circumference of the pitch circle from a point on 
one tooth to the corresponding point on the adjacent tooth. 
 
Diametrical Pitch (P) 
• It is the number of teeth per unit length of the pitch circle diameter in inches. 
 
Module (m) 
• It is the ratio of pitch diameter in mm to the number of teeth. The term is used SI 
units in place of diametrical pitch. 
 
Gear Ratio (G) 
• It is the ratio of the number of teeth on the gear to that on the pinion. 
Page 3


Theory of Machines and Vibrations – Short Notes 
Instantaneous Centre of Velocity (I-centre) 
• The instantaneous centre of velocity can be defined as a point which has no velocity 
with respect to the fixed link. 
Centro 
• Instantaneous centre is also called centro 
• Primary Centro One which can be easily located by a mere observation of the 
mechanism. 
• Secondary Centro Centros that cannot be easily located 
Aronhold-Kennedy Theorem of Three Centre 
• It state that if three bodies are in relative motion with respect to one another, the 
three relative instantaneous centers of velocity ar collinear. 
 
Number of Centros in a Mechanism 
• For a mechanism of n links, the number of centros (Instantaneous centre) N is 
 
Linkages are the basic building blocks of all mechanisms 
• Links: rigid member having nodes. 
• Node: attachment points. 
• Binary link: 2 nodes 
• Ternary link: 3 nodes 
• Quaternary link: 4 nodes 
• Joint: connection between two or more links (at their nodes) which allows motion; 
(Joints also called kinematic pairs) 
D’Alembert’s Principle and Inertia Forces 
• D’Alembert’s principle states that the reverse-effective forces and torques and the 
external forces and torques on a body together give statical equilibrium 
 
Gear Terminology 
 
Circular Pitch (p):  
• It is a distance measured along the circumference of the pitch circle from a point on 
one tooth to the corresponding point on the adjacent tooth. 
 
Diametrical Pitch (P) 
• It is the number of teeth per unit length of the pitch circle diameter in inches. 
 
Module (m) 
• It is the ratio of pitch diameter in mm to the number of teeth. The term is used SI 
units in place of diametrical pitch. 
 
Gear Ratio (G) 
• It is the ratio of the number of teeth on the gear to that on the pinion. 
 
 
where, T = number of teeth on the gear 
t = number of teeth on the pinion 
Velocity Ratio 
• The velocity ratio is defined as the ratio of the angular velocity of the follower to the 
angular velocity of the driver gear 
 
Gear Train 
• A gear train is a combination of gears used to transmit motion from one shaft to 
another. Gear trains are used to speed up or stepped down the speed of driven 
shaft. The following are main types of gear trains. 
Simple Gear Train 
• Series of gears, capable of receiving and transmitting motion from one gear to 
another is called a simple gear train. 
Train value 
 
Speed ratio  
 
Gears-and-gear-trains  
• The intermediate gears have no effect on the speed ratio and therefore they are 
known as idlers. 
Compound Gear Train 
Page 4


Theory of Machines and Vibrations – Short Notes 
Instantaneous Centre of Velocity (I-centre) 
• The instantaneous centre of velocity can be defined as a point which has no velocity 
with respect to the fixed link. 
Centro 
• Instantaneous centre is also called centro 
• Primary Centro One which can be easily located by a mere observation of the 
mechanism. 
• Secondary Centro Centros that cannot be easily located 
Aronhold-Kennedy Theorem of Three Centre 
• It state that if three bodies are in relative motion with respect to one another, the 
three relative instantaneous centers of velocity ar collinear. 
 
Number of Centros in a Mechanism 
• For a mechanism of n links, the number of centros (Instantaneous centre) N is 
 
Linkages are the basic building blocks of all mechanisms 
• Links: rigid member having nodes. 
• Node: attachment points. 
• Binary link: 2 nodes 
• Ternary link: 3 nodes 
• Quaternary link: 4 nodes 
• Joint: connection between two or more links (at their nodes) which allows motion; 
(Joints also called kinematic pairs) 
D’Alembert’s Principle and Inertia Forces 
• D’Alembert’s principle states that the reverse-effective forces and torques and the 
external forces and torques on a body together give statical equilibrium 
 
Gear Terminology 
 
Circular Pitch (p):  
• It is a distance measured along the circumference of the pitch circle from a point on 
one tooth to the corresponding point on the adjacent tooth. 
 
Diametrical Pitch (P) 
• It is the number of teeth per unit length of the pitch circle diameter in inches. 
 
Module (m) 
• It is the ratio of pitch diameter in mm to the number of teeth. The term is used SI 
units in place of diametrical pitch. 
 
Gear Ratio (G) 
• It is the ratio of the number of teeth on the gear to that on the pinion. 
 
 
where, T = number of teeth on the gear 
t = number of teeth on the pinion 
Velocity Ratio 
• The velocity ratio is defined as the ratio of the angular velocity of the follower to the 
angular velocity of the driver gear 
 
Gear Train 
• A gear train is a combination of gears used to transmit motion from one shaft to 
another. Gear trains are used to speed up or stepped down the speed of driven 
shaft. The following are main types of gear trains. 
Simple Gear Train 
• Series of gears, capable of receiving and transmitting motion from one gear to 
another is called a simple gear train. 
Train value 
 
Speed ratio  
 
Gears-and-gear-trains  
• The intermediate gears have no effect on the speed ratio and therefore they are 
known as idlers. 
Compound Gear Train 
• When a series of gears are connected in such a way that two or more gears rotate 
about an axis with the same angular velocity. 
 
Train value 
 
Planetary or Epicyclic Gear Train 
• A gear train having a relative motion of axes is called a planetary or an epicyclic gear 
train. In an epicyclic train, the axis of at least one of the gears also moves relative to 
the frame. 
• If the arm a is fixed the wheels S and P constitute a simple train. However if the 
wheel S is fixed so that arm a can rotate about the axis of S. The P would be moved 
around S therefore it is an epicyclic train 
Flywheel 
• A flywheel is used to control the variations in speed during each cycle of an 
operation. A flywheel acts as a reservoir of energy which stores energy during the 
period when the supply of energy is more than the requirement and releases the 
energy during the period when the supply energy is less than the requirement. 
Maximum fluctuation of energy (e), 
 
where, 
?max and ?min are the maximum and minimum angular speed respectively. 
Page 5


Theory of Machines and Vibrations – Short Notes 
Instantaneous Centre of Velocity (I-centre) 
• The instantaneous centre of velocity can be defined as a point which has no velocity 
with respect to the fixed link. 
Centro 
• Instantaneous centre is also called centro 
• Primary Centro One which can be easily located by a mere observation of the 
mechanism. 
• Secondary Centro Centros that cannot be easily located 
Aronhold-Kennedy Theorem of Three Centre 
• It state that if three bodies are in relative motion with respect to one another, the 
three relative instantaneous centers of velocity ar collinear. 
 
Number of Centros in a Mechanism 
• For a mechanism of n links, the number of centros (Instantaneous centre) N is 
 
Linkages are the basic building blocks of all mechanisms 
• Links: rigid member having nodes. 
• Node: attachment points. 
• Binary link: 2 nodes 
• Ternary link: 3 nodes 
• Quaternary link: 4 nodes 
• Joint: connection between two or more links (at their nodes) which allows motion; 
(Joints also called kinematic pairs) 
D’Alembert’s Principle and Inertia Forces 
• D’Alembert’s principle states that the reverse-effective forces and torques and the 
external forces and torques on a body together give statical equilibrium 
 
Gear Terminology 
 
Circular Pitch (p):  
• It is a distance measured along the circumference of the pitch circle from a point on 
one tooth to the corresponding point on the adjacent tooth. 
 
Diametrical Pitch (P) 
• It is the number of teeth per unit length of the pitch circle diameter in inches. 
 
Module (m) 
• It is the ratio of pitch diameter in mm to the number of teeth. The term is used SI 
units in place of diametrical pitch. 
 
Gear Ratio (G) 
• It is the ratio of the number of teeth on the gear to that on the pinion. 
 
 
where, T = number of teeth on the gear 
t = number of teeth on the pinion 
Velocity Ratio 
• The velocity ratio is defined as the ratio of the angular velocity of the follower to the 
angular velocity of the driver gear 
 
Gear Train 
• A gear train is a combination of gears used to transmit motion from one shaft to 
another. Gear trains are used to speed up or stepped down the speed of driven 
shaft. The following are main types of gear trains. 
Simple Gear Train 
• Series of gears, capable of receiving and transmitting motion from one gear to 
another is called a simple gear train. 
Train value 
 
Speed ratio  
 
Gears-and-gear-trains  
• The intermediate gears have no effect on the speed ratio and therefore they are 
known as idlers. 
Compound Gear Train 
• When a series of gears are connected in such a way that two or more gears rotate 
about an axis with the same angular velocity. 
 
Train value 
 
Planetary or Epicyclic Gear Train 
• A gear train having a relative motion of axes is called a planetary or an epicyclic gear 
train. In an epicyclic train, the axis of at least one of the gears also moves relative to 
the frame. 
• If the arm a is fixed the wheels S and P constitute a simple train. However if the 
wheel S is fixed so that arm a can rotate about the axis of S. The P would be moved 
around S therefore it is an epicyclic train 
Flywheel 
• A flywheel is used to control the variations in speed during each cycle of an 
operation. A flywheel acts as a reservoir of energy which stores energy during the 
period when the supply of energy is more than the requirement and releases the 
energy during the period when the supply energy is less than the requirement. 
Maximum fluctuation of energy (e), 
 
where, 
?max and ?min are the maximum and minimum angular speed respectively. 
E = kinematic energy of the flywheel at mean speed. 
Flywheel in Punching Press 
• Generally, flywheel is used to reduce fluctuation of speed where the load on the 
crank shaft constant while the applied torque varies. 
• However, the flywheel can also be used to reduce fluctuation of speed when the 
torque is constant but load varies during the cycle e.g., in punching press in riveting 
machine. 
• Let E be energy required for one punch energy supplied to crank shaft from the 
motor during punching 
 
Governors 
The function of a governor is to maintain or regulate the speed of an engine within specified 
limits whenever there is variation of load. 
Types of Governors 
The broadly classification of the governors are given below. 
Centrifugal Governor 
• In this type of governor, the action of governor depends upon the centrifugal effects 
produced by the masses of two balls. 
Inertia Governor 
• In this type of governor, positions of the balls are effected by the forces set up by an 
angular acceleration or deceleration of the given spindle in addition to centrifugal 
forces on the balls. 
Pendulum Type Watt Governor 
 
height of each bal 
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FAQs on Theory of Machines Formulas for GATE ME Exam - Theory of Machines (TOM) - Mechanical Engineering

1. What are the important formulas to remember for the Theory of Machines section in the GATE ME exam?
Ans. Some of the important formulas for the Theory of Machines section in the GATE ME exam include: - Velocity Ratio (VR) = (angular velocity of driver/ angular velocity of follower) - Mechanical Advantage (MA) = (load/effort) - Efficiency (η) = (MA/VR) x 100% - Power Output = (Load x Velocity)/1000 - Centrifugal Tension (Tc) = (m x v^2)/r - Gyroscopic Couple (C) = I x ω x ω
2. How can I prepare for the Theory of Machines section in the GATE ME exam?
Ans. To prepare for the Theory of Machines section in the GATE ME exam, you can follow these steps: 1. Understand the syllabus and exam pattern: Familiarize yourself with the topics and weightage of the Theory of Machines section in the exam. 2. Study from recommended textbooks: Refer to standard textbooks on Theory of Machines to gain a comprehensive understanding of the concepts and formulas. 3. Solve previous year question papers: Practice solving previous year GATE ME exam papers to get an idea of the types of questions asked and improve your time management skills. 4. Take online mock tests: Mock tests will help you evaluate your preparation level and identify areas that need improvement. 5. Revise and practice: Regularly revise the concepts and formulas, and solve practice questions to strengthen your understanding.
3. Can you provide some tips to solve numerical problems in the Theory of Machines section of the GATE ME exam?
Ans. Here are some tips to solve numerical problems in the Theory of Machines section of the GATE ME exam: 1. Understand the problem statement: Read the problem statement carefully and identify the given data and what needs to be calculated. 2. Draw clear diagrams: Draw clear and labeled diagrams to visualize the problem and identify the relevant parameters. 3. Apply the appropriate formula: Use the relevant formula from the Theory of Machines section to solve the problem. Make sure to substitute the correct values and units. 4. Simplify calculations: Break down complex calculations into smaller steps to avoid mistakes. Use a systematic approach and double-check your calculations. 5. Practice numerical problems: Regularly practice solving numerical problems from previous year question papers and mock tests to improve your problem-solving skills.
4. Are there any specific topics in the Theory of Machines section that are frequently asked in the GATE ME exam?
Ans. While the entire syllabus of the Theory of Machines section is important for the GATE ME exam, some topics are frequently asked. These include: - Gear trains and their analysis - Cam mechanisms and their analysis - Balancing of rotating masses - Flywheels and governors - Vibrations and critical speed analysis It is advisable to thoroughly study and practice numerical problems from these topics to be well-prepared for the exam.
5. How can I improve my conceptual understanding of the Theory of Machines section for the GATE ME exam?
Ans. To improve your conceptual understanding of the Theory of Machines section for the GATE ME exam, you can follow these strategies: 1. Study from reliable sources: Refer to standard textbooks, online lectures, and educational websites to gain a clear understanding of the concepts. 2. Take notes and make diagrams: While studying, take concise notes and draw diagrams to visualize the concepts and their applications. 3. Solve conceptual questions: Practice solving conceptual questions that require a deep understanding of the principles and theories of Theory of Machines. 4. Discuss with peers or mentors: Engage in discussions with fellow students or mentors to clarify doubts and exchange different perspectives on the topics. 5. Teach others: Explaining concepts to others can enhance your own understanding. Teach your peers or colleagues about the Theory of Machines topics to reinforce your knowledge.
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