Transmission System in Automotive Engineering

Questions and Answers

What was the primary motivation behind the development of independent front suspension in the 1930s?

To reduce the cost of production

To increase the speed of the vehicle

To improve vehicle ride control and riding comfort (correct)

To reduce the weight of the vehicle

Which type of spring is commonly used in independent front suspension systems?

Leaf spring

Coil spring (correct)

Torsion bar

All of the above

What is the effect of a wider spacing of the front springs on the steering system?

It increases the weight of the vehicle

It deteriorates the steering conditions and qualities

It has no effect on the steering system

It improves the steering conditions and qualities (correct)

Which of the following is NOT a type of independent front suspension?

Rigid axle front suspension

What is the advantage of independent front suspension in terms of wheel movement?

It allows for a greater wheel movement

What is the effect of independent front suspension on wheel wobble?

It completely prevents wheel wobble

How many types of independent front suspensions are mentioned in the content?

7

Which type of suspension system is widely used in modern vehicles?

Independent front suspension

What is the advantage of independent front suspension in terms of road conditions?

It responds to road conditions individually

What is the primary component that supports each front wheel in an independent front suspension system?

Coil spring or torsion bar or leaf spring

What is the primary benefit of independent front suspension in terms of ride control and comfort?

Increased wheel movement without affecting steering system

Which of the following is a characteristic of longitudinal leaf spring rear suspension?

Mounted on a longitudinal axle

What is the primary difference between independent front suspension and rigid axle front suspension?

Number of axles used

Which type of independent front suspension uses a combination of a strut and a link?

Mac Pherson Strut and link type suspension

What is the effect of independent front suspension on the vehicle's response to road conditions?

Wheels respond individually to road conditions

Which type of suspension system is characterized by a sliding movement of the wheel?

Sliding suspension

What is the primary advantage of a wider spacing of the front springs in independent front suspension?

Enhanced steering quality

Which type of independent front suspension is also known as Wishbone type suspension?

Parallelogram type suspension

What is the primary component that supports each front wheel in a rigid axle front suspension?

Rigid axle

Which of the following is NOT a type of rear end suspension?

Sliding suspension

What is the primary benefit of using a coil spring in independent front suspension systems?

Enhanced ride control and comfort

Which type of independent front suspension is characterized by a longitudinal movement of the wheel?

Longitudinal suspension

What is the primary difference between independent front suspension and longitudinal leaf spring rear suspension?

Location of the suspension system

Which type of rear end suspension is similar to independent front suspension in terms of wheel movement?

Coil spring rear end suspension

What is the primary advantage of using a torsion bar in independent front suspension systems?

Improved ride control and comfort

Which type of independent front suspension is characterized by a vertical movement of the wheel?

Vertical guide suspension

What is the primary benefit of using a leaf spring in independent front suspension systems?

Improved ride control and comfort

Which type of independent front suspension is characterized by a parallelogram movement of the wheel?

Parallelogram type suspension

What is the primary difference between independent front suspension and transverse leaf spring rear suspension?

Location of the suspension system

Which type of independent front suspension is characterized by a trailing link movement of the wheel?

Trailing link type suspension

Which suspension system is characterized by the presence of a rigid axle connecting the two front wheels?

Rigid axle front suspension

What is the primary advantage of using a coil spring in independent front suspension systems over a leaf spring?

It provides a smoother ride

Which type of independent front suspension is characterized by a combination of a strut and a link?

Mac Pherson Strut and link type suspension

What is the primary difference between independent front suspension and longitudinal leaf spring rear suspension?

The direction of wheel movement

Which type of rear end suspension is similar to independent front suspension in terms of wheel movement?

Coil spring rear end suspension

What is the primary advantage of using a torsion bar in independent front suspension systems?

It allows for greater wheel movement

Which type of independent front suspension is characterized by a vertical movement of the wheel?

Vertical guide suspension

What is the primary benefit of using a leaf spring in independent front suspension systems?

It is more durable

Which type of independent front suspension is characterized by a parallelogram movement of the wheel?

Parallelogram type suspension

What is the primary difference between independent front suspension and transverse leaf spring rear suspension?

The direction of wheel movement

Study Notes

Transmission System

• The transmission system plays a crucial role in transferring power from the engine to the wheels, enabling the vehicle to move efficiently across different speeds and conditions.
• Components of a transmission system:
  • Transmission (manual or automatic)
  • Clutch (for manual transmission)
  • Gearbox
  • Differential
  • Driveshaft (propeller shaft)
  • Torque converter (for automatic transmission)

Functions of a Transmission System

• Gear ratio selection
• Torque multiplication
• Smooth power delivery
• Adaptability to driving conditions
• Efficiency improvement (modern transmission systems aim to optimize fuel efficiency and reduce emissions)

Clutches and Power Transmission

• The purpose of the clutch is to allow the driver to couple or decouple the engine and transmission.
• Requirements of a clutch:
  • Pick up its load smoothly without grab or clatter
  • Have a driven disc of low moment of inertia to permit easy shifting
  • Damp out any vibration of the crankshaft to prevent gear clatter
  • Require little pedal pressure to operate
  • Be easy to adjust and service
  • Be cheap to manufacture

Types of Clutches

• Positive clutches
  • Merits: simple, no slip, no heat generated, compact, and low cost
• Friction clutches
  • Merits: smooth engagement, can slip during engagement, high torque capacity
  • Types:
    • Single plate clutch
    • Multi-plate clutch
    • Centrifugal clutch
    • Semi-centrifugal clutch
    • Diaphragm spring single plate clutch
    • Electro-magnetic clutch
    • Overrunning clutch or free-wheel unit

Diaphragm Spring Single Plate Clutch

• Advantages:
  • Compact design
  • Easier to balance rotationally
  • Uniformly distributed pressure on pressure plate
  • No release levers required
  • Minimum effort required to disengage the clutch
  • Minimum internal friction

Multi-Plate Clutch

• Used in heavy transport vehicles, epicyclic gearboxes, and racing cars
• Advantages:
  • Higher torque transmission capacity
  • Compact design

Automatic Clutch

• Centrifugal clutch: automatically disengages when speed falls below a certain value and re-engages when speed rises above it
• Fluid coupling or fluid torque converter: used to transmit power between two rotating shafts without Interrupting the flow of power

Gear Box in an Automobile

• Necessity of gear box: to maintain engine speed at the most economical value under all conditions of vehicle movement
• Functions of a gear box:
  • Torque ratio variation between engine and wheels
  • Means of reversal of vehicle motion
  • Transmission can be disconnected from engine by neutral position of gear box

Types of Gear Box

• Progressive type gear box
• Epicyclic (or) planetary type gear box
• Selective type gear box (e.g., constant mesh gear box with positive dog clutch, constant mesh gear box with synchromesh device, sliding mesh gear box)### Gearbox
• A gearbox is a mechanical device that uses gears to transmit and change the speed of rotation of a mechanical shaft
• Types of gearboxes:
  • Constant mesh gearbox
  • Synchromesh gearbox
  • Automatic gearbox

Constant Mesh Gearbox

• All gears on the main shaft are in constant mesh with the corresponding gears on the lay shaft
• Gears on the lay shaft are fixed, while those on the main shaft are free to rotate
• Dog clutches are used to engage and disengage gears

Synchromesh Gearbox

• Similar to constant mesh gearbox, but with synchronizers instead of dog clutches
• Synchronizers allow for smooth gear changes by equalizing the speed of the gears before engagement
• Used in modern cars to reduce the cost of production

Automatic Gearbox

• Also known as automatic transmission
• Uses a complex system of gears, clutches, and hydraulic pumps to change gear ratios automatically
• Components:
  • Torque converter
  • Planetary gear sets
  • Hydraulic system
  • Control unit (TCU or TCM)
• Working:
  • The TCU receives inputs from sensors and determines the appropriate gear ratio
  • Hydraulic pressure is used to engage and disengage clutches and brake bands
  • Shift points are determined by factors such as vehicle speed, engine load, and driver demand

Differential

• A mechanical device that allows each of the driving wheels to rotate at different speeds
• Purpose:
  • To drive a pair of wheels with equal torque while allowing them to rotate at different speeds
  • To prevent wheel spinning and road damage when turning
• Components:
  • Pinion drive gear
  • Crown wheel/ring gear
  • Spider/planet gear
  • Cross-pin
  • Side/sun gear
  • Differential case assembly
• Construction:
  • The differential is an arrangement of gears that work together to allow the vehicle to take a turn smoothly
  • The pinion gear is fixed to the propeller shaft and rotates the crown wheel

Suspension System

• The chassis of the vehicle is connected to the front and rear wheels through the medium of springs, shock absorbers, and axles
• Components:
  • Springs
  • Dampers (shock absorbers)
  • Stabilizer (sway bar or anti-roll bar)
  • Linkage system
• Functions:
  • To eliminate road shocks from transmission to vehicle components
  • To obtain good road holding while driving, cornering, and braking
  • To keep the proper steering geometry
  • To obtain a particular height to body structure
  • To resist the torque and braking reactions
  • To maintain the stability of the vehicle while traveling over rough roads
  • To safeguard the occupants against road shocks and provide a riding comfort

Sprung Weight and Unsprung Weight

• Sprung weight: The weight of the vehicle body that is supported by springs
• Unsprung weight: The weight of the wheels, axles, and other parts of the vehicle that are not supported by springs
• Effects of unsprung weight:
  • Controls the trade-off between wheel bump and vibration isolation
  • Affects the ride quality and road noise
  • Exacerbates wheel control issues under hard acceleration or braking### Types of Springs
• There are five types of springs: compression, compression-shear, steel reinforced, progressive, and face shear springs.
• Air springs are also used in air suspension systems, which can be adjusted up or down by supplying air pressure.

Leaf Spring Suspension

• Leaf spring suspension consists of a number of leaves of increasing lengths made of steel plates.
• The spring eye is mounted to the frame by a pin called shackle pin.
• The centre portion of the spring is attached to the front axle by a V-bolt.
• The stiffness or spring rate of the leaf spring is determined by its length, width, and thickness.
• Greater the number of leaves, higher the stiffness.

Air Suspension System

• Air springs are flexible bellows made of textile-reinforced rubber, containing compressed air.
• They are used to carry load on vehicles and provide elasticity or "springiness" when compressed.
• Air springs have three characteristics: they are soft when unloaded, they increase stiffness when loaded, and they maintain constant vehicle height.
• They provide optimum riding comfort in both lightly loaded and fully loaded conditions.

Shock Absorber

• Shock absorbers are used to control vibrations on springs, provide comfortable ride, and act flexible and rigid.
• They are used as a part of the suspension system and provide more resistance to the motion of the spring and road wheel.
• Types of shock absorbers include mechanical, hydraulic, and telescopic shock absorbers.

Telescopic Shock Absorber

• Construction consists of an upper eye attached to the axle, a lower eye attached to the chassis frame, and two-way valves.
• Working involves fluid flowing between the valves to produce a damping force.
• The damping force varies with the speed of the piston.

Types of Suspension System

• There are two basic types of suspension systems: front end suspension and rear end suspension.
• Front end suspension types include independent front suspension and rigid axle front suspension.
• Rear end suspension types include longitudinal leaf spring, transverse leaf spring, and coil spring rear end suspension.

Independent Front Suspension

• Developed in the 1930s to improve vehicle ride control and riding comfort.
• Each front wheel is mounted on its own axle and independently supported by a coil or torsion bar or leaf spring.
• Types of independent front suspensions include longitudinal, transverse, sliding, MacPherson Strut, parallelogram, trailing link, and vertical guide suspensions.

Transmission System

• The transmission system plays a crucial role in transferring power from the engine to the wheels, enabling the vehicle to move efficiently across different speeds and conditions.
• Components of a transmission system:
  • Transmission (manual or automatic)
  • Clutch (for manual transmission)
  • Gearbox
  • Differential
  • Driveshaft (propeller shaft)
  • Torque converter (for automatic transmission)

Functions of a Transmission System

• Gear ratio selection
• Torque multiplication
• Smooth power delivery
• Adaptability to driving conditions
• Efficiency improvement (modern transmission systems aim to optimize fuel efficiency and reduce emissions)

Clutches and Power Transmission

• The purpose of the clutch is to allow the driver to couple or decouple the engine and transmission.
• Requirements of a clutch:
  • Pick up its load smoothly without grab or clatter
  • Have a driven disc of low moment of inertia to permit easy shifting
  • Damp out any vibration of the crankshaft to prevent gear clatter
  • Require little pedal pressure to operate
  • Be easy to adjust and service
  • Be cheap to manufacture

Types of Clutches

• Positive clutches
  • Merits: simple, no slip, no heat generated, compact, and low cost
• Friction clutches
  • Merits: smooth engagement, can slip during engagement, high torque capacity
  • Types:
    • Single plate clutch
    • Multi-plate clutch
    • Centrifugal clutch
    • Semi-centrifugal clutch
    • Diaphragm spring single plate clutch
    • Electro-magnetic clutch
    • Overrunning clutch or free-wheel unit

Diaphragm Spring Single Plate Clutch

• Advantages:
  • Compact design
  • Easier to balance rotationally
  • Uniformly distributed pressure on pressure plate
  • No release levers required
  • Minimum effort required to disengage the clutch
  • Minimum internal friction

Multi-Plate Clutch

• Used in heavy transport vehicles, epicyclic gearboxes, and racing cars
• Advantages:
  • Higher torque transmission capacity
  • Compact design

Automatic Clutch

• Centrifugal clutch: automatically disengages when speed falls below a certain value and re-engages when speed rises above it
• Fluid coupling or fluid torque converter: used to transmit power between two rotating shafts without Interrupting the flow of power

Gear Box in an Automobile

• Necessity of gear box: to maintain engine speed at the most economical value under all conditions of vehicle movement
• Functions of a gear box:
  • Torque ratio variation between engine and wheels
  • Means of reversal of vehicle motion
  • Transmission can be disconnected from engine by neutral position of gear box

Types of Gear Box

• Progressive type gear box
• Epicyclic (or) planetary type gear box
• Selective type gear box (e.g., constant mesh gear box with positive dog clutch, constant mesh gear box with synchromesh device, sliding mesh gear box)### Gearbox
• A gearbox is a mechanical device that uses gears to transmit and change the speed of rotation of a mechanical shaft
• Types of gearboxes:
  • Constant mesh gearbox
  • Synchromesh gearbox
  • Automatic gearbox

Constant Mesh Gearbox

• All gears on the main shaft are in constant mesh with the corresponding gears on the lay shaft
• Gears on the lay shaft are fixed, while those on the main shaft are free to rotate
• Dog clutches are used to engage and disengage gears

Synchromesh Gearbox

• Similar to constant mesh gearbox, but with synchronizers instead of dog clutches
• Synchronizers allow for smooth gear changes by equalizing the speed of the gears before engagement
• Used in modern cars to reduce the cost of production

Automatic Gearbox

• Also known as automatic transmission
• Uses a complex system of gears, clutches, and hydraulic pumps to change gear ratios automatically
• Components:
  • Torque converter
  • Planetary gear sets
  • Hydraulic system
  • Control unit (TCU or TCM)
• Working:
  • The TCU receives inputs from sensors and determines the appropriate gear ratio
  • Hydraulic pressure is used to engage and disengage clutches and brake bands
  • Shift points are determined by factors such as vehicle speed, engine load, and driver demand

Differential

• A mechanical device that allows each of the driving wheels to rotate at different speeds
• Purpose:
  • To drive a pair of wheels with equal torque while allowing them to rotate at different speeds
  • To prevent wheel spinning and road damage when turning
• Components:
  • Pinion drive gear
  • Crown wheel/ring gear
  • Spider/planet gear
  • Cross-pin
  • Side/sun gear
  • Differential case assembly
• Construction:
  • The differential is an arrangement of gears that work together to allow the vehicle to take a turn smoothly
  • The pinion gear is fixed to the propeller shaft and rotates the crown wheel

Suspension System

• The chassis of the vehicle is connected to the front and rear wheels through the medium of springs, shock absorbers, and axles
• Components:
  • Springs
  • Dampers (shock absorbers)
  • Stabilizer (sway bar or anti-roll bar)
  • Linkage system
• Functions:
  • To eliminate road shocks from transmission to vehicle components
  • To obtain good road holding while driving, cornering, and braking
  • To keep the proper steering geometry
  • To obtain a particular height to body structure
  • To resist the torque and braking reactions
  • To maintain the stability of the vehicle while traveling over rough roads
  • To safeguard the occupants against road shocks and provide a riding comfort

Sprung Weight and Unsprung Weight

• Sprung weight: The weight of the vehicle body that is supported by springs
• Unsprung weight: The weight of the wheels, axles, and other parts of the vehicle that are not supported by springs
• Effects of unsprung weight:
  • Controls the trade-off between wheel bump and vibration isolation
  • Affects the ride quality and road noise
  • Exacerbates wheel control issues under hard acceleration or braking### Types of Springs
• There are five types of springs: compression, compression-shear, steel reinforced, progressive, and face shear springs.
• Air springs are also used in air suspension systems, which can be adjusted up or down by supplying air pressure.

Leaf Spring Suspension

• Leaf spring suspension consists of a number of leaves of increasing lengths made of steel plates.
• The spring eye is mounted to the frame by a pin called shackle pin.
• The centre portion of the spring is attached to the front axle by a V-bolt.
• The stiffness or spring rate of the leaf spring is determined by its length, width, and thickness.
• Greater the number of leaves, higher the stiffness.

Air Suspension System

• Air springs are flexible bellows made of textile-reinforced rubber, containing compressed air.
• They are used to carry load on vehicles and provide elasticity or "springiness" when compressed.
• Air springs have three characteristics: they are soft when unloaded, they increase stiffness when loaded, and they maintain constant vehicle height.
• They provide optimum riding comfort in both lightly loaded and fully loaded conditions.

Shock Absorber

• Shock absorbers are used to control vibrations on springs, provide comfortable ride, and act flexible and rigid.
• They are used as a part of the suspension system and provide more resistance to the motion of the spring and road wheel.
• Types of shock absorbers include mechanical, hydraulic, and telescopic shock absorbers.

Telescopic Shock Absorber

• Construction consists of an upper eye attached to the axle, a lower eye attached to the chassis frame, and two-way valves.
• Working involves fluid flowing between the valves to produce a damping force.
• The damping force varies with the speed of the piston.

Types of Suspension System

• There are two basic types of suspension systems: front end suspension and rear end suspension.
• Front end suspension types include independent front suspension and rigid axle front suspension.
• Rear end suspension types include longitudinal leaf spring, transverse leaf spring, and coil spring rear end suspension.

Independent Front Suspension

• Developed in the 1930s to improve vehicle ride control and riding comfort.
• Each front wheel is mounted on its own axle and independently supported by a coil or torsion bar or leaf spring.
• Types of independent front suspensions include longitudinal, transverse, sliding, MacPherson Strut, parallelogram, trailing link, and vertical guide suspensions.

Transmission System

• The transmission system plays a crucial role in transferring power from the engine to the wheels, enabling the vehicle to move efficiently across different speeds and conditions.
• Components of a transmission system:
  • Transmission (manual or automatic)
  • Clutch (for manual transmission)
  • Gearbox
  • Differential
  • Driveshaft (propeller shaft)
  • Torque converter (for automatic transmission)

Functions of a Transmission System

• Gear ratio selection
• Torque multiplication
• Smooth power delivery
• Adaptability to driving conditions
• Efficiency improvement (modern transmission systems aim to optimize fuel efficiency and reduce emissions)

Clutches and Power Transmission

• The purpose of the clutch is to allow the driver to couple or decouple the engine and transmission.
• Requirements of a clutch:
  • Pick up its load smoothly without grab or clatter
  • Have a driven disc of low moment of inertia to permit easy shifting
  • Damp out any vibration of the crankshaft to prevent gear clatter
  • Require little pedal pressure to operate
  • Be easy to adjust and service
  • Be cheap to manufacture

Types of Clutches

• Positive clutches
  • Merits: simple, no slip, no heat generated, compact, and low cost
• Friction clutches
  • Merits: smooth engagement, can slip during engagement, high torque capacity
  • Types:
    • Single plate clutch
    • Multi-plate clutch
    • Centrifugal clutch
    • Semi-centrifugal clutch
    • Diaphragm spring single plate clutch
    • Electro-magnetic clutch
    • Overrunning clutch or free-wheel unit

Diaphragm Spring Single Plate Clutch

• Advantages:
  • Compact design
  • Easier to balance rotationally
  • Uniformly distributed pressure on pressure plate
  • No release levers required
  • Minimum effort required to disengage the clutch
  • Minimum internal friction

Multi-Plate Clutch

• Used in heavy transport vehicles, epicyclic gearboxes, and racing cars
• Advantages:
  • Higher torque transmission capacity
  • Compact design

Automatic Clutch

• Centrifugal clutch: automatically disengages when speed falls below a certain value and re-engages when speed rises above it
• Fluid coupling or fluid torque converter: used to transmit power between two rotating shafts without Interrupting the flow of power

Gear Box in an Automobile

• Necessity of gear box: to maintain engine speed at the most economical value under all conditions of vehicle movement
• Functions of a gear box:
  • Torque ratio variation between engine and wheels
  • Means of reversal of vehicle motion
  • Transmission can be disconnected from engine by neutral position of gear box

Types of Gear Box

• Progressive type gear box
• Epicyclic (or) planetary type gear box
• Selective type gear box (e.g., constant mesh gear box with positive dog clutch, constant mesh gear box with synchromesh device, sliding mesh gear box)### Gearbox
• A gearbox is a mechanical device that uses gears to transmit and change the speed of rotation of a mechanical shaft
• Types of gearboxes:
  • Constant mesh gearbox
  • Synchromesh gearbox
  • Automatic gearbox

Constant Mesh Gearbox

• All gears on the main shaft are in constant mesh with the corresponding gears on the lay shaft
• Gears on the lay shaft are fixed, while those on the main shaft are free to rotate
• Dog clutches are used to engage and disengage gears

Synchromesh Gearbox

• Similar to constant mesh gearbox, but with synchronizers instead of dog clutches
• Synchronizers allow for smooth gear changes by equalizing the speed of the gears before engagement
• Used in modern cars to reduce the cost of production

Automatic Gearbox

• Also known as automatic transmission
• Uses a complex system of gears, clutches, and hydraulic pumps to change gear ratios automatically
• Components:
  • Torque converter
  • Planetary gear sets
  • Hydraulic system
  • Control unit (TCU or TCM)
• Working:
  • The TCU receives inputs from sensors and determines the appropriate gear ratio
  • Hydraulic pressure is used to engage and disengage clutches and brake bands
  • Shift points are determined by factors such as vehicle speed, engine load, and driver demand

Differential

• A mechanical device that allows each of the driving wheels to rotate at different speeds
• Purpose:
  • To drive a pair of wheels with equal torque while allowing them to rotate at different speeds
  • To prevent wheel spinning and road damage when turning
• Components:
  • Pinion drive gear
  • Crown wheel/ring gear
  • Spider/planet gear
  • Cross-pin
  • Side/sun gear
  • Differential case assembly
• Construction:
  • The differential is an arrangement of gears that work together to allow the vehicle to take a turn smoothly
  • The pinion gear is fixed to the propeller shaft and rotates the crown wheel

Suspension System

• The chassis of the vehicle is connected to the front and rear wheels through the medium of springs, shock absorbers, and axles
• Components:
  • Springs
  • Dampers (shock absorbers)
  • Stabilizer (sway bar or anti-roll bar)
  • Linkage system
• Functions:
  • To eliminate road shocks from transmission to vehicle components
  • To obtain good road holding while driving, cornering, and braking
  • To keep the proper steering geometry
  • To obtain a particular height to body structure
  • To resist the torque and braking reactions
  • To maintain the stability of the vehicle while traveling over rough roads
  • To safeguard the occupants against road shocks and provide a riding comfort

Sprung Weight and Unsprung Weight

• Sprung weight: The weight of the vehicle body that is supported by springs
• Unsprung weight: The weight of the wheels, axles, and other parts of the vehicle that are not supported by springs
• Effects of unsprung weight:
  • Controls the trade-off between wheel bump and vibration isolation
  • Affects the ride quality and road noise
  • Exacerbates wheel control issues under hard acceleration or braking### Types of Springs
• There are five types of springs: compression, compression-shear, steel reinforced, progressive, and face shear springs.
• Air springs are also used in air suspension systems, which can be adjusted up or down by supplying air pressure.

Leaf Spring Suspension

• Leaf spring suspension consists of a number of leaves of increasing lengths made of steel plates.
• The spring eye is mounted to the frame by a pin called shackle pin.
• The centre portion of the spring is attached to the front axle by a V-bolt.
• The stiffness or spring rate of the leaf spring is determined by its length, width, and thickness.
• Greater the number of leaves, higher the stiffness.

Air Suspension System

• Air springs are flexible bellows made of textile-reinforced rubber, containing compressed air.
• They are used to carry load on vehicles and provide elasticity or "springiness" when compressed.
• Air springs have three characteristics: they are soft when unloaded, they increase stiffness when loaded, and they maintain constant vehicle height.
• They provide optimum riding comfort in both lightly loaded and fully loaded conditions.

Shock Absorber

• Shock absorbers are used to control vibrations on springs, provide comfortable ride, and act flexible and rigid.
• They are used as a part of the suspension system and provide more resistance to the motion of the spring and road wheel.
• Types of shock absorbers include mechanical, hydraulic, and telescopic shock absorbers.

Telescopic Shock Absorber

• Construction consists of an upper eye attached to the axle, a lower eye attached to the chassis frame, and two-way valves.
• Working involves fluid flowing between the valves to produce a damping force.
• The damping force varies with the speed of the piston.

Types of Suspension System

• There are two basic types of suspension systems: front end suspension and rear end suspension.
• Front end suspension types include independent front suspension and rigid axle front suspension.
• Rear end suspension types include longitudinal leaf spring, transverse leaf spring, and coil spring rear end suspension.

Independent Front Suspension

• Developed in the 1930s to improve vehicle ride control and riding comfort.
• Each front wheel is mounted on its own axle and independently supported by a coil or torsion bar or leaf spring.
• Types of independent front suspensions include longitudinal, transverse, sliding, MacPherson Strut, parallelogram, trailing link, and vertical guide suspensions.

Transmission System

• The transmission system plays a crucial role in transferring power from the engine to the wheels, enabling the vehicle to move efficiently across different speeds and conditions.
• Components of a transmission system:
  • Transmission (manual or automatic)
  • Clutch (for manual transmission)
  • Gearbox
  • Differential
  • Driveshaft (propeller shaft)
  • Torque converter (for automatic transmission)

Functions of a Transmission System

• Gear ratio selection
• Torque multiplication
• Smooth power delivery
• Adaptability to driving conditions
• Efficiency improvement (modern transmission systems aim to optimize fuel efficiency and reduce emissions)

Clutches and Power Transmission

• The purpose of the clutch is to allow the driver to couple or decouple the engine and transmission.
• Requirements of a clutch:
  • Pick up its load smoothly without grab or clatter
  • Have a driven disc of low moment of inertia to permit easy shifting
  • Damp out any vibration of the crankshaft to prevent gear clatter
  • Require little pedal pressure to operate
  • Be easy to adjust and service
  • Be cheap to manufacture

Types of Clutches

• Positive clutches
  • Merits: simple, no slip, no heat generated, compact, and low cost
• Friction clutches
  • Merits: smooth engagement, can slip during engagement, high torque capacity
  • Types:
    • Single plate clutch
    • Multi-plate clutch
    • Centrifugal clutch
    • Semi-centrifugal clutch
    • Diaphragm spring single plate clutch
    • Electro-magnetic clutch
    • Overrunning clutch or free-wheel unit

Diaphragm Spring Single Plate Clutch

• Advantages:
  • Compact design
  • Easier to balance rotationally
  • Uniformly distributed pressure on pressure plate
  • No release levers required
  • Minimum effort required to disengage the clutch
  • Minimum internal friction

Multi-Plate Clutch

• Used in heavy transport vehicles, epicyclic gearboxes, and racing cars
• Advantages:
  • Higher torque transmission capacity
  • Compact design

Automatic Clutch

• Centrifugal clutch: automatically disengages when speed falls below a certain value and re-engages when speed rises above it
• Fluid coupling or fluid torque converter: used to transmit power between two rotating shafts without Interrupting the flow of power

Gear Box in an Automobile

• Necessity of gear box: to maintain engine speed at the most economical value under all conditions of vehicle movement
• Functions of a gear box:
  • Torque ratio variation between engine and wheels
  • Means of reversal of vehicle motion
  • Transmission can be disconnected from engine by neutral position of gear box

Types of Gear Box

• Progressive type gear box
• Epicyclic (or) planetary type gear box
• Selective type gear box (e.g., constant mesh gear box with positive dog clutch, constant mesh gear box with synchromesh device, sliding mesh gear box)### Gearbox
• A gearbox is a mechanical device that uses gears to transmit and change the speed of rotation of a mechanical shaft
• Types of gearboxes:
  • Constant mesh gearbox
  • Synchromesh gearbox
  • Automatic gearbox

Constant Mesh Gearbox

• All gears on the main shaft are in constant mesh with the corresponding gears on the lay shaft
• Gears on the lay shaft are fixed, while those on the main shaft are free to rotate
• Dog clutches are used to engage and disengage gears

Synchromesh Gearbox

• Similar to constant mesh gearbox, but with synchronizers instead of dog clutches
• Synchronizers allow for smooth gear changes by equalizing the speed of the gears before engagement
• Used in modern cars to reduce the cost of production

Automatic Gearbox

• Also known as automatic transmission
• Uses a complex system of gears, clutches, and hydraulic pumps to change gear ratios automatically
• Components:
  • Torque converter
  • Planetary gear sets
  • Hydraulic system
  • Control unit (TCU or TCM)
• Working:
  • The TCU receives inputs from sensors and determines the appropriate gear ratio
  • Hydraulic pressure is used to engage and disengage clutches and brake bands
  • Shift points are determined by factors such as vehicle speed, engine load, and driver demand

Differential

• A mechanical device that allows each of the driving wheels to rotate at different speeds
• Purpose:
  • To drive a pair of wheels with equal torque while allowing them to rotate at different speeds
  • To prevent wheel spinning and road damage when turning
• Components:
  • Pinion drive gear
  • Crown wheel/ring gear
  • Spider/planet gear
  • Cross-pin
  • Side/sun gear
  • Differential case assembly
• Construction:
  • The differential is an arrangement of gears that work together to allow the vehicle to take a turn smoothly
  • The pinion gear is fixed to the propeller shaft and rotates the crown wheel

Suspension System

• The chassis of the vehicle is connected to the front and rear wheels through the medium of springs, shock absorbers, and axles
• Components:
  • Springs
  • Dampers (shock absorbers)
  • Stabilizer (sway bar or anti-roll bar)
  • Linkage system
• Functions:
  • To eliminate road shocks from transmission to vehicle components
  • To obtain good road holding while driving, cornering, and braking
  • To keep the proper steering geometry
  • To obtain a particular height to body structure
  • To resist the torque and braking reactions
  • To maintain the stability of the vehicle while traveling over rough roads
  • To safeguard the occupants against road shocks and provide a riding comfort

Sprung Weight and Unsprung Weight

• Sprung weight: The weight of the vehicle body that is supported by springs
• Unsprung weight: The weight of the wheels, axles, and other parts of the vehicle that are not supported by springs
• Effects of unsprung weight:
  • Controls the trade-off between wheel bump and vibration isolation
  • Affects the ride quality and road noise
  • Exacerbates wheel control issues under hard acceleration or braking### Types of Springs
• There are five types of springs: compression, compression-shear, steel reinforced, progressive, and face shear springs.
• Air springs are also used in air suspension systems, which can be adjusted up or down by supplying air pressure.

Leaf Spring Suspension

• Leaf spring suspension consists of a number of leaves of increasing lengths made of steel plates.
• The spring eye is mounted to the frame by a pin called shackle pin.
• The centre portion of the spring is attached to the front axle by a V-bolt.
• The stiffness or spring rate of the leaf spring is determined by its length, width, and thickness.
• Greater the number of leaves, higher the stiffness.

Air Suspension System

• Air springs are flexible bellows made of textile-reinforced rubber, containing compressed air.
• They are used to carry load on vehicles and provide elasticity or "springiness" when compressed.
• Air springs have three characteristics: they are soft when unloaded, they increase stiffness when loaded, and they maintain constant vehicle height.
• They provide optimum riding comfort in both lightly loaded and fully loaded conditions.

Shock Absorber

• Shock absorbers are used to control vibrations on springs, provide comfortable ride, and act flexible and rigid.
• They are used as a part of the suspension system and provide more resistance to the motion of the spring and road wheel.
• Types of shock absorbers include mechanical, hydraulic, and telescopic shock absorbers.

Telescopic Shock Absorber

• Construction consists of an upper eye attached to the axle, a lower eye attached to the chassis frame, and two-way valves.
• Working involves fluid flowing between the valves to produce a damping force.
• The damping force varies with the speed of the piston.

Types of Suspension System

• There are two basic types of suspension systems: front end suspension and rear end suspension.
• Front end suspension types include independent front suspension and rigid axle front suspension.
• Rear end suspension types include longitudinal leaf spring, transverse leaf spring, and coil spring rear end suspension.

Independent Front Suspension

• Developed in the 1930s to improve vehicle ride control and riding comfort.
• Each front wheel is mounted on its own axle and independently supported by a coil or torsion bar or leaf spring.
• Types of independent front suspensions include longitudinal, transverse, sliding, MacPherson Strut, parallelogram, trailing link, and vertical guide suspensions.

Description

Learn about the transmission system in automotive engineering, its components, and functions that enable efficient power transfer from the engine to the wheels. Understand the key components and their roles in the transmission system.