CLUTCH
Power transmission:
The power developed by the engine in automobiles should be transmitted to the road wheel efficiently. The power transmission system basically needs a clutch to transmit the power from the engine to the remaining parts of the transmission. The power transmission system is different for different types of vehicles.
In case of two wheelers with gears the power is transmitted from the clutch to the gearbox and then transmitted to the wheels by means of chain drive or gear drive. In case of non geared two wheelers the power is transmitted from the clutch directly to the wheels through the chain drive / gear drive or sometimes through the variator mechanism.
In case of LMVs and HTVs the power transmission consists of clutch and gearbox as the common features. In the conventional (front engine rear wheel drive) the power is transmitted from gearbox to road wheels by means of universal joint, propeller shaft, sliding joint, differential and half shaft. In case of front engine front wheel drive transaxle is commonly used. In this case the gear box is arranged transversely and power transmission may not be provided with propeller shaft and bevel gear arrangement. This type of arrangement is compact and also contains less number of moving parts. In the case of four wheel drive, the arrangement is similar to conventional power transmission with transfer gear box or transfer case as the additional features. The transfer gear box transmits the power to both the axles uniformly.
Functions of a Clutch:
The torque developed b the engine at starting speed is very low. Therefore, it is not possible to start the engine under load. This requires that the transmission system should provide a means of connecting and disconnecting the engine from rest of the transmission system. Such an operation must be smooth and without shock to the occupants of the vehicle.
Thus the two main functions of a clutch are:
1. To engage and disengage the transmission from engine to the remaining parts of transmission. (To allow the engine to be separated from rest of the transmission system) This is required when:
(a) Starting and running the engine at a sufficiently high speed lo generate sufficient power necessary for moving the vehicle from rest.
(b) Shifting the gears so that damage to gear teeth can be avoided.
(c) Stopping the vehicle after applying brakes.
2. The second function of the clutch is to allow the engine to take up the driving load of the vehicle gradually and without shock.
Requirements of clutch:
The main requirements of a clutch are as follows:
- It should be able to transmit maximum torque of the engine.
- It should engage gradually to avoid sudden jerks.
- It should be able to dissipate large amount of heat generated during clutch operation.
- It should be dynamically balanced, particularly in the case of high speed engine clutches.
- It should have suitable mechanism to damp vibrations and to eliminate noise produced during power transmission.
- It should be as small as possible so that it will occupy minimum space.
- It should be easy to operate requiring as little exertion as possible on the part of the driver.
- It should be made as light as possible so that it will continue to rotate for any length of time after the clutch has been disengaged.
- It must be trouble free and have longer life.
10. It must be easy to inspect, adjust and repair.
Classification of clutches:
Principle of operation of clutches:
Clutch works on the principle of friction. When two friction surfaces are brought in contact with each other and pressed with certain force they are united due to friction between them. If one is rotated, other will also rotate during this condition. It can be separated or brought into contact whenever required. One surface is referred as driving member and other as driven member. The friction between two surfaces depends upon
- Area of contact surface.
- Force applied on them.
- Coefficient of friction of surface material.
When the driven member is brought in contact with driver, the clutch slips initially. As the pressure increases the driven member is brought to the speed of the driving member. When the speed of both members becomes equal then two members are in frictional contact without any slip and clutch is said to be fully engaged. The driving torque can be increased by increasing the effective radius of contact, coefficient of friction, clamping force, or the number of contact surfaces.
SINGLE PLATE CLUTCH
Construction: The main components of the single plate clutch are driving member, driven member and the actuating linkages.
Driving Members: Driving members of single plate clutch are input shaft (crank shaft) fixed to the flywheel, pressure plate, and the clutch cover which is bolted to the flywheel. These fly components rotate along with the crank shaft in both engaged and disengaged condition. Fly wheel is attached to the crank shaft and has threaded bolts or holes or grooves for bolting the clutch covers. Machined surface of the flywheel contacts the clutch facing. The pressure plate applies the required force on the clutch plate which contacts with fly wheel. To apply the required force pressure springs are attached between the pressure plate and clutch cover. Pressure plate can be withdrawn by releasing the spring with the help of release lever. Lugs are provided on the pressure plate for providing the release fingers. Pressure plate springs are provided inside, release finger, and anti-ratting springs are provided inside the clutch cover and the entire assembly is bolted to fly wheel.
Driven members: It is the clutch plate which is splined to the driven shaft (clutch shaft or input shaft of gear box) clutch plate is used with friction material on both the surfaces. It consists of a centre hub with internal splines which moves along the splined shaft during the transmission. The power is transmitted from the clutch to the shaft through these splines. It consists of torsional or cushioning springs which transmit the force applied to the facing to the central hub. The spring also reduces torsional vibrations and provides smooth engagement or disengagement of the clutch. The friction material is normally riveted to the projected portions of the clutch disc in CMVS and HMVS.
Actuating members: It consists of release fingers, withdrawal fork and release bearing. The outer end of the release finger is located on the pressure plate and inner end is projected towards the clutch shaft and are positioned with the help of anti-rattling springs. Withdrawal fork carrying the release bearing is pivoted in the clutch outer casing. The release bearing actuates the inner end of the release fingers.
Working / operation: In fully engaged condition the driven plate is firmly clamped between the flywheel and pressure plate due to the force applied by springs. This forms a non-slip connection between the driving and driven plates. Hence when the flywheel rotates the clutch plate also rotates and this cause the transmission of power to the input shaft of gear box through splines. When clutch pedal is depressed the pressure on the driven plate is released by compressing the pressure springs through the release fingers. In this condition there is no force acting on the clutch plate and is free between the flywheel and pressure plate. This disengaged condition ensures easier shifting of gears.
DIAPHRAGM CLUTCH
In this type of diagram type springs are used instead of coil / helical springs. This type of clutch does not require any release levers as the spring itself acts as the series of levers. This type of springs do not have constant rate characteristics as in the case of coil springs and the pressure on the diaphragm springs increases until it is in flat position, thereafter decreases after passing this position. Hence the driver does not have to exert heavy pedal pressure to hold the clutch out of engagement compared to coil spring type. In coil spring type the spring pressure increases when the pedal is depressed to disengage the clutch and high pressure is required to keep the clutch in disengaged position.
This clutch consists of conventional friction clutch, thrust plate, diaphragm type spring and release sleeve. The diaphragm is held between the inner end of the main bearing and its outer circumstance fits into the counter bore of the thrust plate. The central position of the diaphragm spring is divided into several segments by radial slots terminating into holes. These segments acts like spring providing the required thrust on the pressure plate. This simple arrangement eliminates the necessity for providing separate release levers.
Working: In the engaged position the spring pivots on the inner pivot rings as it is held on the clutch cover so that its outer rings contacts with the pressure plate. Again in this conical position the spring exerts through pressure to keep the pressure plate in firm contact with the clutch plate and flywheel. When the pedal is depressed the linkage moves release bearing toward the flywheel. When the pedal is depressed the linkage moves release bearing towards the flywheel to disengage the clutch. As the bearing contacts with inner position of the conical springs it moves that position forward which cause the link to move backward. This removes the pressure on the pressure plate and release the clutch plate from contact with other driving members.
Another type of conical spring used is the crown spring. This type differs from the tapered finger type with its surface corrugated instead of flat and the centre section is continuous without any spring. The clutch spring fits between the pressure plate and clutch cover. The entire assembly is held together by six spring retainer located on the pressure plate. The actuation of this type of spring is similar to integral / split type diaphragm spring.
MULTI PLATE CLUTCHES
The clutch having more than three discs is referred as multi disc clutch or multi plate clutch. It is similar to single plate clutch but has more number of frictional and metallic plates. Due to the increase in the numbers of plates (friction) the frictional surface in contact is also increased which increases the capacity of the clutch to transmit the some torque the diameter of the plate clutch. Hence the clutches are mostly commonly in two wheelers and three wheelers due to compact in size. It is used in heavy duty transmission system for transmitting higher torque. (For example torque transmission in heavy earth moving equipments) and power take off (P. T. O.) transmission in tractors.
SEMI-CENTRIFUGAL CLUTCHES:
The vacuum clutch is operated by the vacuum existing in the engine manifold. Fig shows the mechanism of a vacuum clutch. It consists of a vacuum cylinder with piston, solenoid operated valve, reservoir and a non-return valve. The reservoir is connected to the engine manifold through a non return valve. Vacuum cylinder is connected to the reservoir through solenoid operated valve. The solenoid is operated from the battery and the circuit incorporates a switch which is placed in the gear lever. The switch is operated when the driver holds the lever to change gears.
The hydraulic clutch is operated in the same way as the vacuum clutch. Only the difference is that it is operated by oil pressure whereas the vacuum clutch is operated by vacuum.
ONE WAY CLUTCHES / FREE WHEEL CLUTCHES:
SPRAG CLUTCH:
BALL AND ROLLER CLUTCH:
Construction: Construction of multi plate clutches is similar to single plate clutch except the arrangement of number of friction plates and metal plates. It consists of inner drum which is referred to clutch shaft and has a number of plates splined to the outer surface. Another drum is coupled to fly wheel and carries a number of plates splined to it inner surface. The plates are arranged in alternate manners. The plates can revolve with the drum as well as it can slide axially. A spring keeps the outer and inner plates pressed together, so that the driving members transmit the power to the driven member. The clutches can be disengaged by pulling the inner drum against the spring force.
Multi plate clutch can be dry type or wet type. The clutch is partially filled with oil. The coefficient of friction in oil varies from 0.07 to 0.17 of asbestos based fabrics.
- The oil acts as cushioning medium to provide smooth engagement and disengagement
- The oil also carries the heat dissipated by the clutch due to friction. This reduces operations temperature and increases the left of the clutch plates.
- The oil acts as lubricant and reduces axial thrust lost due to bending on splines.
- The major disadvantage is the reduction in coefficient of friction when immersed in oil. It can be compensated by using high operating pressure of different friction material. Generally cork inserted multi plate clutches are used in wet clutches. In wet clutches the fluid under pressure is fed along the shaft.
Cone clutch:
They are wedge clutch provides a positive drive when the external face of the male cone member engages with the internet face of recessed conical member. The facing is usually fitted to the female or recessed member in order to improve heat dissipation and durability. Normally cone clutch are used with epicyclic gear trains for a higher torque transmission. The energy which a cone clutch can absorb during on engagement is less compared to the energy absorbed by a multiple clutch. But it is compact, cheaper and requires low clamping load due to the wedging action. The cone clutches are loaded by spring or hydraulic cylinders. Wedge angle and accurate axial alignment are the two important factors for good cone clutch performance. If the wedge angle is very less, it results in excessive wedge action and fierce engagement. This in turn results in difficult operation for disengagement. If the wedge angle is too large it reduces torque transmission capacity of the clutch and make the clutches to skid. Semi-cone angle of 12-16 are commonly used for effective torque transmission.
The torque transmitted by a cone clutch is given by
T = μW (r1 + r2) / 2 sin α
Where, r1 and r2 are the radius of large and small cone (friction) in meters. α is the semi – cone angle.
During the engagement of clutch the driven member is forced towards the driving cone by the spring force. Hence the power is transmitted from the engine to the driving cone, driving cone to driven cone and driven to the gear box. When the clutch is to be disengaged the driven cone is to be pulled off by means of actuates cenkages and contact surfaces are separated hence no power is transmitted to the clutch shaft.
SEMI-CENTRIFUGAL CLUTCHES:
This type of clutch makes use of centrifugal force to assist the spring force at high speed. To reduce the effort of the driver operates the clutch the assistance is taken by the centrifugal force. To transmit small torque, spring with minimum stiffness is used which is sufficient for applying the required amount of force and also not so stiff to minimize the strain of the driver during disengagement. When high power is transmitted through the clutch then pressure of the springs is a considerable factor. In semi-centrifugal clutches help is taken by centrifugal force by keeping certain weights in eccentric position. The springs are designed to transmit the power at normal speeds and at high speed the assistance is taken by the weights, the weighted lever is hanged at three points at regular intervals. The lever is provided with fulcrum connected to the clutch cover at one end hinged to the pressure plate ate centre and the weight is connected at the outer end. The tail of the lever is provided with the adjusting screw by means of which centrifugal force on the pressure plate can be adjusted. During the increase in speed the weight moves about fulcrum due to the centrifugal force of the weight and hence the pressure plate moves towards the flywheel increasing the torque transmitting capacity.
Centrifugal Clutch:
This type of clutches operates automatically depending on engine speed of elements. The use of clutch pedal, pressure spring and also clutch making the operation very simple of makes use of centrifugal force to apply the force on the floating plate as well as on the pressure plate for keeping the clutch in engaged position. In this type, transmission of the power is controlled by the operation of the accelerator. It makes the driving operation very easy and convenient. Hence it is used in automatic transmission in two wheelers with variator mechanisms or two-wheeler without gear mechanism.
This system consists of flywheel as driving member and pressure plate as the driven member. The pressure plate is provided with friction lining on its outer surface. The pressure plate is actuated by means of floating spring which exerts pressure on the floating. The spring on the fly wheel keeps the clutch is disengaged position at low speeds. When the speed increases the weight flees off thereby operating bell crank lever and pressing the floating plate. The force acting on the floating plate is transmitted to the pressure plate through the helical spring placed between floating plate and pressure plated.
Due to this force the pressure plate is pressed on to flywheel providing the transmission through the friction lining and thereby resulting in engagement of clutch. The stop provided above the weight limits the amount of centrifugal force of the speed is increased over this limit the pressure on plate will be constant.
Other type of centrifugal clutches are used in automobiles (generally in mopeds) consists of spider as the driving member. The spider has four shoes having the frictional surfaces. These are kept in contact with the cylindrical clutch case by means of springs. As the speed increases, the shoes extend outwards due to centrifugal force and make contact with the cylindrical clutch to transmit the power. The transmission starts as soon as the spring force exceeds the spring force and shoes extends outwards. Hence the power transmission starts as soon as the engine starts rotating at a speed enough to develop the required centrifugal force. The transmission stops as soon as the engine speed drops below the desired value. Hence no power is transmitted to the road wheels when the engine is idle or running at lesser speed than the desired value.
Electromagnetic Clutch:
In this system the clutch is controlled by means electric current supplied to the field windings in the flywheel. The fly wheel is attached with the field winding, which is given electric current by means of battery, dynamo or alternator. The construction feature of main components is almost similar to the single plate clutch. When electric current is supplied to the windings the flywheel will attract the pressure plate and clutch plate is forced between pressure plate and flywheel resulting in engagement. When the supply to the winding is cut off the clutch is disengaged by releasing the pressure plate due to the force exerted by the helical springs or tension springs. Electromagnetic clutch consists of a clutch release switch. When then driver holds the gear lever to change the gear, the switch is operated cutting off the current to the winding which causes the clutch disengaged.
When the vehicle is stalling, the engine speed is lower & the dynamo output is low, the clutch is not firmly engaged. Therefore, three springs are also provided on the pressure plate which helps the clutch engaged firmly at low speed also.
The forces of the electromagnet can be regulated by means of an electrical resistance provided with acceleration system and controlled by the accelerator pedal. When the speed is increased, the accelerator pedal is pressed and the resistance is gradually cut off and thus in this way, force of electromagnet is increased and clutch transmission becomes more rigid.
FRICTION MATERIALS
The various types of friction materials are as given under—
(i) Mill board type: This material is in the form of sheets made of asbestos and treated with certain impregnates. From the standard sheet we can cut facing discs according to different size requirements. This is the cheapest material and gives satisfactory results.
(ii) Moulded type: When asbestos fibers are mixed with a suitable binder and heated to a definite temperature and then moulded in dies under pressure, this type of friction material is called “moulded type”. To improve the wearing qualities of the material (sometimes metallic wires are also inserted). This type of lining is stronger, dense and capable to transmit heavy loads through it. The disadvantage is only this that moulding for each size lining is very costly.
(iii) Woven type: This type of material is made by spinning threads from asbestos fibres, weaving this thread into a cloth and then impregnating it with a bonding material. This type of material is further divided into classes; (a) the solid woven variety is woven to the required thickness in one operation and has a greater mechanical strength; (h) the laminated variety consists of layers of cloth placed on top of each other and held together by the bonding material. Both types may incorporate brass wire.
CLUTCH LINING MATERIALS
Common materials used for clutch lining are:
(i) Asbestos: It can be used at high temperature also and linings of this material have coefficient of friction of about 0 2.
(ii) Reybestos and Ferodo: These materials are most suitable and generally used for clutch friction linings and have a co efficient of friction of about 0.35.
(iii) Leather: The co-efficient of friction between dry leather and iron is 0.27.
(iv) Cork: The co-efficient of friction between cork and steel or iron is 0.32.
(v) Fabric: This material has co-efficient of friction about 0.4, but it cannot be used a high temperature.
To put and hold the clutch in the disengaged position the clutch withdrawal mechanism is necessary. This mechanism including foot pedal and clutch actuating levers etc. are also seen some times from outside also.
A cross shaft type withdrawal mechanism is as shown in figure.
When the foot pedal is pressed by the driver the shaft having the two projections and supported at two bearings is turned, thereby moving the housing with the pressures of the pins. In this way this motion of the housing disengages the clutch. When the manual pressure from the foot pedal is removed, the housing comes in its original position thereby the clutch again engaged.
VACUUM CLUTCH
The vacuum clutch is operated by the vacuum existing in the engine manifold. Fig shows the mechanism of a vacuum clutch. It consists of a vacuum cylinder with piston, solenoid operated valve, reservoir and a non-return valve. The reservoir is connected to the engine manifold through a non return valve. Vacuum cylinder is connected to the reservoir through solenoid operated valve. The solenoid is operated from the battery and the circuit incorporates a switch which is placed in the gear lever. The switch is operated when the driver holds the lever to change gears.
When the throttle is wide opened, the pressure in the inlet manifold decreases due to which the non-return valve closes, isolating the reservoir from the manifold. Thus a vacuum exists in the reservoir all the time.
In the normal operation, the switch in the gear lever remains off, the solenoid operated valve remains in its bottom position. In this positions the atmospheric pressure acts on both the side of the vacuum cylinder, because the vacuum cylinder is open, so also atmosphere though a vent. When the driver holds the lever to change the gear, the switch is closed; energizing the solenoid which pulls the valve up. This connects one side of vacuum cylinder to the reservoir. Due to the difference of pressure on the vacuum cylinder piston, it moves. This movement of the piston is transmitted by a linkage to the clutch, causing it to disengage. When the driver is not operating the gear lever, the switch is open and the clutch remains engaged due to the force of springs.
Hydraulic Clutch
The hydraulic clutch is operated in the same way as the vacuum clutch. Only the difference is that it is operated by oil pressure whereas the vacuum clutch is operated by vacuum.
Fig. shows the mechanism of a hydraulic clutch. It consists of a cylinder with piston, control valve, pump, accumulator and oil reservoir. The piston is connected to the clutch by a linkage. The pump is operated by the engine itself. The oil from the reservoir is pumped into the accumulator tank. The accumulator tank is connected to the cylinder through the control valve. The control valve is electrically controlled by a switch in the gear lever.
When the driver holds the gear lever to change the gears, the switch is operated to open the control valve admitting the oil under pressure to the cylinder. Due to the oil pressure, the piston moves causing the clutch to be disengaged. As soon as the driver leaves the gear lever, the switch is open which closes the control valve and the clutch is engaged.
Dog and Splines clutch:
This type of clutch is used to lock two shafts together or to lock a gear to a shaft. It consists of a sleeve having two sets of internal splines. It slides on a splined shaft with smaller diameter splines. The bigger diameter splines match with the external dog clutch teeth on driving shaft. When the sleeve is made to slide on the splined shaft, its teeth match with the dog clutch teeth of the driving shaft. Thus the sleeve turns the splined shaft with the driving shaft. The clutch is said to be engaged. To disengage the clutch, the sleeve is moved back on the splined shaft to have no contact with the driving shaft.
This type of clutch is used to lock two shafts together or to lock a gear to a shaft. It consists of a sleeve having two sets of internal splines. It slides on a splined shaft with smaller diameter splines. The bigger diameter splines match with the external dog clutch teeth on driving shaft. When the sleeve is made to slide on the splined shaft, its teeth match with the dog clutch teeth of the driving shaft. Thus the sleeve turns the splined shaft with the driving shaft. The clutch is said to be engaged. To disengage the clutch, the sleeve is moved back on the splined shaft to have no contact with the driving shaft.
This type of clutch has no tendency to sup. The driven shaft revolves exactly at the same speed as that of the driving shaft, as soon as the clutch is engaged. Therefore it is also known as positive engagement clutch.
ONE WAY CLUTCHES / FREE WHEEL CLUTCHES:
These types of clutches are used to transmit the power in only one direction. The power is transmitted from the driver to driven and not vice-versa. When the drive rotates in the reverse direction the clutches slips or disengages. This type of clutch mainly consists of an inner race and outer race. The inner race is connected to the driver and the outer race is connected to the driven.
SPRAG CLUTCH:
In this type several sprags are equally spaced between the inner and outer races. The sprags can be installed in the direction as shown in the figure or can be tuned through 1800 to provide anti-clockwise rotation. Generally sprags are provided with energizing springs to hold the individual sprags against the two races.
When the inner race rotates in anticlockwise direction the sprag tilts in the same direction of rotation. Due to this action the sprag wedges between the inner and outer race. As a result the outer race rotates in the same direction as that of inner race and at the same speed. If the outer race rotates at more speed then the wedging action is removed and no power is transmitted. Similar action occurs if the inner race tries to rotate in the opposite direction. One way clutches are used to transmit the power in clockwise or anticlockwise direction by the proper positioning of springs.
BALL AND ROLLER CLUTCH:
In this the inner race and outer races has several ramp like grooves in which the clutch elements (roller or balls) are placed. A spring is positioned in front of these elements. Its purpose is to hold the element against the ramp and race surfaces. When the inner racer is rotated in clockwise direction, the friction between the inner race and rollers or balls moves them slightly in the same direction. This wedges the balls or rollers between the ramps and surface of the inner race or outer race, causing the outer race to be driven in the same speed as that of the inner race. If the outer race is rotated faster than the inner race, distance between the ramp and race increases, removing the wedging action of the clutch element and no power is transmitted between the inner and outer race. If the inner race is rotated in the opposite direction it will result in the similar way where no power is transmitted between the driving and driven member.
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