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Introduction

  • If the components of a machine accelerate, inertia forces are produced due to their masses. However, if the magnitudes of these forces are small compared to the externally applied loads, they can be neglected while analysing the mechanism. Such an analysis is known as static-force analysis.
  • For example, in lifting cranes, the bucker load and the static weight loads may be quite high relative to any dynamic loads due to accelerating masses, and thus static-force analysis is justified.
  • When the inertia effect due to the mass of the components is also considered, it is called dynamic-force analysis.

Kinematic Analysis of Single-Slider Crank Mechanism

  • Figure below shows a slider-crank mechanism in which the crank OA rotates in the clockwise direction. ℓ and r are the lengths of the connecting rod and the crank respectively.
  • In kinematic analysis, inertia of connecting rod is not considered in this analysis
     Schematic of single-slider crank mechanism
     Schematic of single-slider crank mechanism
    ω = dθ/dt
    sinβ = 1/n sinθ
    Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering
  1. Displacement Analysis (x) of piston
    Let x = displacement of piston from inner-dead centre at the moment when the crank has turned through angle θ from the inner-dead centre
    Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering
  2. Velocity Analysis (V) of piston
    Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering
  3. Acceleration Analysis (f) of piston

    Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering ← 

    Acceleration of Reciprocating mass
  4. Angular Velocity of Connecting rod
    Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering
  5. Angular Acceleration of Connecting rod
    Let ∝CR = angular acceleration of the connecting Rod
    Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering

Dynamic-Analysis of Single-Slider Crank Mechanism

An engine is acted upon by various forces such as weight of reciprocating masses and connecting rod, gas forces, forces due to friction and inertia due to acceleration and retardation of engine elements, the last being dynamic in nature.
Fig.2: Dynamics of single-slider crank mechanismFig.2: Dynamics of single-slider crank mechanism

Total Piston Effort (F)
Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering (mg is used for vertical engines)
Force/thrust along connecting Rod (Fc)
Let Fc = Force In the connecting rod (Fig. 2)
Then equating the horizontal components of forces,
Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering
Normal thrust to cylinder walls (Fn)
It Is the normal reaction on the cylinder walls.

Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering
Radial thrust on crank shaft Bearings (Fr
The component of FC along the crank (In the radial direction) produces a thrust on the crankshaft bearings.
Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering

Crank Effort (Ft)
Force Is exerted on the crankpln as a result of the force on the piston. Crank effort Is the net effort (force) applied at the crankpln perpendicular to the crank which gives the required turning moment on the crankshaft. It Is the force needed to drive crank.
Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering
Turning moment on crank-Shaft:
Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering

Flywheel

  • A flywheel acts as an energy reservoir, which stores energy during the period when the supply of energy is more than the requirement and releases energy during the period when the requirement is more than the supply.
  • In case a variable torque is supplied where demand is a constant torque or demand is variable torque whereas constant torque is supplied. In both these cases there is mismatch between the supply and demand. This results in speed variation.
  1. Fluctuation of Energy
    (i) The fluctuation of energy may be determined by the turning moment diagram for one complete cycle of operation. The variations of energy above and below the mean resisting torque line are called fluctuations of energy.
    (ii) The difference between the greatest speed and the least speed is known as the maximum fluctuation of speed and the ratio of the maximum fluctuation of speed to mean speed is define as the coefficient of fluctuation of speed.
    Maximum fluctuation of speed = Nmax -Nmin
    Coefficent of fluctuation of Speed, Cs = (Nmax -Nmin)/(Nmean)  
    (Nmean = mean speed of engine)
    (iii) The difference between the maximum and minimum kinetic engines of the flywheel is known as the maximum fluctuation of energy.
    ΔE = Iω2Cs
  2. Requirement of Flywheel in Power Presses
    (i) When the load on the crankshaft is constant or varies and the input torque varies continuously during a cycle, a flywheel is used to reduce the fluctuations of speed.
    (ii) A flywheel can perform the same purpose in a punching press or a riveting machine in which the torque available is constant but the load varies during the cycle.
  3. Designing of Flywheel Rim
    Below we are studying Rim (Ring shaped) type flywheel, which is practical not usable.
    Let, A → cross section area of the rim
    Fig.3: Rim type FlywheelFig.4: Cross-section of flywheelFig.3: Rim type Flywheel
    Fig.4: Cross-section of flywheel
    For safe designing, σ ≤ σb (bearing strength)
    Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering
The document Study Notes for Flywheel | Theory of Machines (TOM) - Mechanical Engineering is a part of the Mechanical Engineering Course Theory of Machines (TOM).
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FAQs on Study Notes for Flywheel - Theory of Machines (TOM) - Mechanical Engineering

1. What is a flywheel in mechanical engineering?
Ans. A flywheel in mechanical engineering is a rotating mechanical device that is used to store rotational energy. It is typically a heavy disc or wheel with a high moment of inertia, designed to resist changes in rotational speed. It is commonly used in machines such as engines and turbines to smooth out the fluctuations in power output and provide a more consistent and steady rotation.
2. How does a flywheel work in mechanical engineering?
Ans. In mechanical engineering, a flywheel works by storing kinetic energy in its rotating mass. When a machine delivers excess power, the flywheel absorbs and stores the energy, and when the machine requires additional power, the flywheel releases the stored energy to provide a boost. This helps to maintain a constant rotational speed and reduces the impact of sudden changes in load or power demand.
3. What are the applications of flywheels in mechanical engineering?
Ans. Flywheels find various applications in mechanical engineering. They are commonly used in internal combustion engines, where they help to smooth out the power delivery and reduce vibration. Flywheels are also used in energy storage systems, such as in hybrid vehicles and grid-scale energy storage, where they store excess energy and release it when needed. Additionally, flywheels are utilized in heavy machinery, such as presses and punches, to provide a constant rotational speed and improve efficiency.
4. How is the size of a flywheel determined in mechanical engineering?
Ans. The size of a flywheel in mechanical engineering is determined based on various factors, including the desired inertia, the power requirements of the system, and the space limitations. The moment of inertia, which depends on the mass and distribution of the flywheel's mass, is a crucial parameter in determining its size. Engineers consider the rotational speed, torque, and power fluctuations of the system to calculate the appropriate size of the flywheel to ensure smooth operation and stability.
5. Can a flywheel fail in mechanical engineering applications?
Ans. Yes, a flywheel can fail in mechanical engineering applications. Common failure modes include fatigue failure, material fracture, and excessive wear. Fatigue failure can occur due to cyclic loading, causing cracks to develop and propagate over time. Material fracture can happen under extreme operating conditions or when the flywheel is subjected to excessive stress. Excessive wear can occur due to inadequate lubrication or the presence of contaminants. Proper maintenance, inspections, and adherence to design specifications can help minimize the risk of flywheel failure.
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