Icare Auto Relience
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airbag system : working principle and types
An airbag is an elastic bag or cushion like makeup which inflates and deflates quickly at some stage in certain types of car accidents.
It is a safety device aimed at preventing or minimizing injury to passengers when such an accident occurs.
Properties of Airbags:
1. High Tensile strength
2. Good heat stability
3. High Tear strength
4. Low Air permeability
5. Free of knots, splices, spots and broken ends.
6. Good Heat capacity
7. Good Folding behavior
8. Better Energy absorption
9. Good Coating adhesion
10. Functionality at extreme hot and cold conditions
11. Package ability
12. Reduced skin abrasion (softness)
What Occurs During Impact
So how does it work? The air bag system features four distinct steps, which happen in the blink of an eye.
1. Detection: Sophisticated sensors determine when a frontal or side collision occurs that’s serious enough to warrant deploying this essential technology.
2. Communication: The air bag system’s electronic control unit assesses information about where the impact occurred and how severe it is. It then immediately sends a signal to an inflator within the air bag module.
3. Ignition: The signal triggers an almost instantaneous reaction¬¬: the ignition of a chemical mix that produces a harmless gas, which inflates the bag at speeds of up to 200 mph.
4. Deflation: Tiny holes in the fabric of the bag allow the gas to escape. At this point the seat occupant comes into contact with the bag; the controlled deflation absorbs the person’s forward-moving energy.
How airbags work
1. When a car hits something, it starts to decelerate (lose speed) very rapidly.
2. An accelerometer (electronic chip that measures acceleration or force) detects the change of speed.
3. If the deceleration is great enough, the accelerometer triggers the airbag circuit. Normal braking doesn't generate enough force to do this.
4. The airbag circuit passes an electric current through a heating element(a bit like one of the wires in a toaster).
5. The heating element ignites a chemical explosive. Older airbags used sodium azide as their explosive; newer ones use different chemicals.
6. As the explosive burns, it generates a massive amount of harmless gas (typically either nitrogen or argon) that floods into a nylon bag packed behind the steering wheel.
7. As the bag expands, it blows the plastic cover off the steering wheel and inflates in front of the driver. The bag is coated with a chalky substance such as talcum powder to help it unwrap smoothly.
8. The driver (moving forward because of the impact) pushes against the bag. This makes the bag deflate as the gas it contains escapes through small holes around its edges. By the time the car stops, the bag should have completely deflated.
Reaction Sequence:
Inside the airbag is a gas generator containing a mixture of NaNO3, KNO3, and SiO2 . The signal from the deceleration sensor ignites the gas generator mixture by an electrical impulse when head-on collision, creating the high temperature conditions necessary for sodium asides to decompose at 300˚C . This causes a relatively slow kind of detonation (Deflagration) that liberates a pre-calculated volume of N2 gas through series of chemical reaction, which fills the air bag.
(1) 2 NaN3 → 2 Na + 3 N2 (g)
The first reaction is the decomposition of NaN3 under high temperature conditions using an electric impulse. This impulse generates to 300°C temperatures required for the decomposition of the NaN3 which produces Na metal and N2 gas. Since Na metal is highly reactive, the KNO3 and SiO2 react and remove it, in turn producing more N2 gas.
(2) 10 Na + 2 KNO3 → K2O + 5 Na2O + N2 (g)
The second reaction shows just that. The reason that KNO3 is used rather than something like NaNO3 is because it is less hygroscopic. It is very important that the materials used in this reaction are not hygroscopic because absorbed moisture can de-sensitize the system and cause the reaction to fail.
(3) K2O + Na2O + 2 SiO2 → K2O3Si + Na2O3Si (silicate glass)
The final reaction is used to eliminate the K2O and Na2O produced in the previous reactions because the first-period metal oxides are highly reactive. These products react with SiO2 to produce a silicate glass which is a harmless and stable compound
Types of Airbags
Most commonly airbags are thought to only be available to those seated in the front of the vehicle as front-side airbags will usually deploy from the dashboard and steering wheel of a vehicle. Since the 1980s though there have been a number of advancements in the airbag industries and modern cars are equipped with multiple airbags.
Some common types of airbags include:
1. Side
Side airbags include curtain and torso bags. Torso bags are usually situated in the seat and were placed there in order to reduce abdominal and pelvic injuries. Curtain airbags began being offered in the late 1990s and were the first door-mounted airbags. These types of airbags reduce the risk of head injuries during side-impact crashes and some even have rollover sensors that will detect if a vehicle begins to roll after a collision.
2. Knee
These airbags are usually situated underneath the steering wheel and glove compartment and can protect a driver or passenger from suffering knee injuries such as bruising or breaking a bone.
3. Rear
Includes rear-center and rear-window airbags which can prevent backseat passengers from colliding with one another and from the back window during a rear-end collision.
4. Motorcycle
Introduced in the mid-2000s, these types of airbags are only available in some types of motorcycles and are believed to lessen the energy of the cyclist moving forward and reduce the velocity they may be thrown at from the motorcycle.
5. Seatbelt
Available in only certain makes and models, seatbelt airbags could decrease the risk of seatbelt injuries during a car collision.
6. Pedestrian
Introduced in 2012, Volvo created airbags that would deploy when a driver hits a pedestrian. It is believed that these airbags could decrease the number of injuries a pedestrian may experience during an accident.
Airbag Injuries
Although more and more airbags have begun being implemented in vehicles in an effort to reduce the number of injuries people may suffer during a car collision, it could lead to more people suffering serious airbag injuries.
Some common types of airbag injuries include:
• Burns
• Skin Abrasions
• Rashes
• Bruising
• Facial Injuries
• Damage to the Eyes
Most airbag injuries are caused by the sudden inflation of the bag and the chemicals used to deploy the airbag. According to the National Highway Traffic Safety Administration, airbags have been the cause of more than 170 fatalities in the United States since 1990.
Injuries from airbags may be reduced by providing adequate room between yourself and the area of deployment.

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VALVE TRAIN: COMPONENTS, TYPES AND THEIR FUNCTION
The main function of the valve train, as indicated by its name, is to control the opening and closing of the valves and, for older models, the fuel output of the injectors. Most of the heavy-duty diesel engines we work with are 4 valve engines, meaning there are four valves in each cylinder: 2 intakes and 2 exhaust. The valve train uses different components based on the type, push on or lift up from the valves, allowing air into and out from the cylinder. In the middle of all the valves is the injector, which will be pushed down on to inject fuel into the cylinder. All of the timing for this process is incredibly precise. Newer engines use electrical signals to cue the injector, rather than the mechanical valve train, which makes that process even more precise.
Most new engines have overhead cam assemblies. Other designs locate the camshaft lower in the engine and use push rods to move valve assemblies. The camshaft is rotated by a timing belt, timing chain or direct gear.
VALVE TRAIN COMPONENTS
The valve train can have many components. The following are the most common components in the valve train. Depending on the type of engine, there may be varying quantities of the parts listed below or the engine may not contain all of the parts listed.
1. Camshaft
The camshaft is a long shaft that goes through the head or the block of the engine, depending on what type of engine it is. There are lobes along the length of the shaft positioned differently. The profile of the lobes has an egg-shape to them. The dimensions of these lobes are what determines the amount of lift. The more lift, the longer the valves stay open, which allows more air into the cylinder.
2. Camshaft Followers
A cam follower is a type of bearing that follows along the lobes of a camshaft as it rotates, providing a low-resistance surface for the lobe to push up against. A follower is also called a lifter, and sometimes a tappet. There are several types of cam followers, whose configurations generally depend on how they mount to their mating part. They will be used when the cam is in the block, rather than being overhead.
3. Push Rods
Pushrods are one of those parts that are not always used in a diesel engine. They will also only be used when the cam is in the block and not overhead. A push rod is a rod that pushes up on the rocker arm. It will move depending on the movement of the camshaft follower. Another job of the pushrod is to conduct oil up to the cylinder head.
4. Rocker Arms
A rocker arm is a pivoting lever that pushes on the valve stem. Rocker arms will sometimes be called rocker levers, or just rockers. Depending on the type of valve train, the rotating camshaft lobes will either push directly on the rocker arm, or on the pushrods, which will conduct the motion up to the rocker arm. In an overhead cam engine, the cam follower is built into the rocker arm in the form of a roller.
5. Rocker Shafts
Rocker shafts are simply the shafts that the rockers are on. It’s this shaft that is the pivot point for the rocker arms. The shaft also conducts oil to the various rocker arms.
6. Valve Bridges
Valve bridges are also sometimes called valve yokes. Bridges allow a single rocker to actuate multiple valves. It has a stem or bridge that sits on both valve stems, so that when the rocker is pressed down, the valve stems get pressed down as well.
7. Valves
A valve is composed of two major sections, the valve head, and the valve stem. The head of the valve is what allows air into and out of the cylinder. The stem is what gets pressed on by the rest of the valve train. At the end of the stem are grooves that keepers will fit into to hold the valve in place. Some engines have only two valves per cylinder, and some have four. The more common number in the heavy-duty diesel market is four. These are split evenly between the intake and exhaust valves.
8. Valve Springs
The camshaft creates an upward force that acts on the rocker arm, which in turn pushes the valve down. But as the cam rotates around, it does not pull the pushrod or rocker arm back with it. That’s why there is a valve spring to create force in the opposite direction and close the valve. The spring will hold the valve closed until the lobe of the camshaft comes around with a greater force and pushes it down.
9. Timing Belt:
A timing belt instead of a timing chain may be used to turn the camshafts. The inner side of the belt is designed with square (cogged) teeth which prevent the belt from slipping.
10. Belt Tensioner
The belt tensioner is a spring-loaded wheel which keeps the timing belt in tension and aligned with the cam sprocket. The smooth side of the timing belt rides over the tensioner. The tensioner applies a force on the backside of the belt. This keeps the belt in tension. Whenever the belt needs to be removed, the tensioner can be pulled away, freeing the belt.
TYPES OF VALVE TRAINS
1. OHV or Push-rod valve train
In case of OHV or push-rod systems, there are long rods which have to be pushed by the camshaft lobes to move the valve rockers, which in turn open the valves – thus the name ‘push-rod’. The long rods and the mechanical nature of the pushrod system make it heavy and it’s not compatible with engines which run at higher revolutions per minute. Now while OHV is an older design, it has its advantages in terms of simplicity of design, compact packaging and a simpler lubrication system requirement as compared to an OHC system.
The disadvantages, of a pushrod system, however, are many.
• To start with, the engines with an OHV system cannot run very high RPMs and such valve trains are suitable mostly for low engine speed applications such as heavy cruisers.
• Owing to the heavy components, the noise and friction on such systems are much more than an OHC system.
• Also, any issues with the camshaft require the entire engine to be opened up, as the camshaft sits inside the engine block, which increases the maintenance effort and cost in case of a breakdown.
• Finally, OHV engines lend their design well primarily to two-valves per cylinder layout. It’s not that there aren’t any three or four valves per cylinder engines with OHV, but that setup becomes way more complex, and OHC systems offer much more flexibility with multiple valves per cylinders.
2. OHC Valve trains
To overcome the shortcomings of the pushrod valve trains, OHC valve train was developed. As the name suggests, it’s a valve train configuration where the camshaft for the engine is placed over the head of the engine, above the pistons and valves. This design allows for very direct contact between the camshaft lobes and the valves or a lifter, thus reducing mass, reducing components and allowing better engine performance as well as more flexibility with the overall engine design.
A. Single Overhead Cam/SOHC
For this variety of valve trains, there is a single camshaft for each row of engine heads. So a single cylinder OHC engine will have one camshaft. However, if it’s an engine with multiple rows, say a V6, then it will have two camshafts – one for each row of heads, or each bank. For SOHC engines, the camshaft is connected directly to the crankshaft via a timing belt or chain to ensure that the opening and closing of the valves is perfectly in sync with the various strokes of the engine for each cylinder.
Now, with SOHC, there is an option to either open or close the valves directly with a shim between the cam lobe and the valve stem, or via a rocker arm. Valves have springs which return them back to their closed position once the pressure from the camshaft lobe is off. SOHC engines are also suited better for 2 or 3 valves per cylinder configuration. Not that a SOHC valve train cannot run on a 4 valve per cylinder layout, but the whole set-up then becomes too complex for the design of rocker arms and lobes and it’s generally considered better to employ a DOHC valve train is such scenarios.
B. Double Overhead Cam/DOHC
DOHC or dual overhead camshaft design includes two camshafts for every row of cylinder heads. Talking about the example we took for SOHC, a DOHC setup for a single-cylinder engine will have two camshafts. However, if it’s a V6, it will have 4 camshafts, two for each row of engine heads, or banks. The primary advantage of such a setup is that it allows manufacturers to have a well-engineered answer to handling a 4-valves per cylinder. Generally, one of the camshafts handles the intake valves, while the second one handles the exhaust valves. The 4-valve per cylinder setup allows for better breathing for the engine, and better performance in most cases, making DOHC a choice for engines that need to rev higher. A DOHC setup also allows for putting the spark plug bang in the middle of the cylinder head, which facilitates better combustion, and enhances performance, and fuel efficiency of the engine. With SOHC, such a setup is not possible for 4-valves per head, as it has to sit in the middle of the cylinder head so as to operate both intake and exhaust valves. As mentioned before, though, SOHC engines too can handle four valves per cylinder, and while the construction of such valve trains is complex, it’s desirable in some cases. DOHC brings along the extra weight of the additional cam, though by allowing the positioning of the spark plug in the middle of the cylinder head it also enhances optimum combustion of fuel. In a nutshell, DOHC is more suited for high-performance engines which need to rev higher and perform in the higher rev range. SOHC systems have somewhat better lower end torque though.
Finally, a DOHC system, with its more fine-grained control over valves is more suitable to implement variable valve timing for engines. Such systems utilize variable camshaft profiles for different engine speeds to enhance performance across the entire rev band. The control over the speed and position of valves opening and closing is better in case of DOHC, and in today's electronics driven world, great benefits can be extracted using that fact. DOHC valve train is more expensive than SOHV though and coupled with its suitability for 4 valves per cylinder, it makes it feasible to employ that setup only on automobiles above a certain price point. For applications where everyday usability, low and mid-range torque, simplicity of design, easy construction and cost are important factors, SOHC system works well.