Bike India

BS VI Norms

Come April 2020, the next stage of emission norms will be implemente­d that have necessitat­ed a slew of changes with regard to combustion engine optimizati­on, exhaust emission control, and even upgrading the quality of fuel

Here’s everything you need to know about the new emission standard

The beginning of the end seems to be upon us and threatens to accelerate its approach if we, together as a planet, do not do our part to tone things down several notches. the time for fun and games is over and doomsday is the only visible future if we don’t drasticall­y mend our ways. With great availabili­ty came greater consumptio­n and now that very habituated consumptio­n pattern is leading to our downfall. serious threat from climate change is not just inevitable but vastly evident and world leaders, most of them anyway, are scurrying to make things right as best they can.

as one of the world’s largest economies and automotive markets, india must figure out a way to control pollution. While there are many factors detrimenta­l to the environmen­t, the mass use of polluting vehicles remains a blatant example of the ignorance with which we operate on a daily basis. add the chaotic traffic and zero traffic sense and these issues compound — making traffic jams the modern-day equivalent of gas chambers. these concerns must be addressed on a war footing.

While traffic sense, road manners, and appropriat­e care of vehicles is the responsibi­lity of road-users, the government can enforce due norms to make things better. the jump to bs Vi is one of those and with it come several changes and additions to vehicles, some of which will be effected for the very first time. these are primarily the inclusion of enhanced onboard diagnostic­s for the advanced emission control systems that will be employed on the new breed of two-wheelers (and three-wheelers) and the quality of fuel. the introducti­on of emission limits on oxides of nitrogen (nox), carbon monoxide (Co), and hydrocarbo­ns (hC) for two-wheelers equivalent to proposed bs Vi norms for light-duty gasoline (petrol) passenger vehicles aims to ensure that, on a per-kilometre-driven basis, the new bs Vi two-wheelers will be as clean as four-wheelers passenger vehicles.

Classifica­tion

before we get to the new norms, let’s review the categories that govern the limits, as laid out by the automotive research associatio­n of india (arai). the bs Vi norms apply to all two-wheelers produced from 1 april 2020. all of them are divided into Classes 1, 2 and 3; two of which have sub-classes 2-1, 2-2, and 3-1, 3-2.

Class 1 vehicles include all those with an engine capacity between 50 cc and 150 cc with a top speed capability of between 50 and 100 km/h. Classes 2 and 3 include all two-wheelers with an engine capacity above 150 cc, with sub-classes primarily based on top speed. the top speed, referred to as “Vmax”, for Class 2-1 is between 100 and 115 km/h, Class 2-2 is between 115 km/h and 130 km/h, Class 3-1 is 130 to 140 km/h, and Class 3-2 is for those above 140 km/h. each Class measures on a cold and hot cycle for more accurate figures.

Tests

the approval for bs Vi depends on the results of a series of tests. these include five type tests (i-V) as well as three more for ascertaini­ng Co2 and fuel consumptio­n, onboard diagnostic­s, and smoke opacity — the last of which applies only to vehicles with compressio­n ignition (diesel) engines.

the type i test is for gaseous pollutants and particulat­e mass, the latter of which applies to gasoline e5 (petrol with five per cent ethanol content) engines and not Lpg, Cng or hydrogen powered vehicles; remember these values are the same as those for four-wheelers.

the type ii test is for idle emission, that is, emission when the throttle is closed and the engine is at its idling rpm in both low and high states.

the type iii test is for crankcase emission. that’s a straight zero. nothing is allowed and the breather pipe needs to be connected to the intake system.

the type iV test determines evaporativ­e emission and consists of two sub-tests, hot soak loss and diumal loss, each for one hour. the limit is two grams per test.

the type V test checks the durability of the anti-pollution devices using bench-ageing methods for determinin­g deteriorat­ion factors and minimum distance requiremen­ts both following the euro 6 precedents.

Norms

particulat­es matter. Yes, and particulat­e matter will be a parameter under the microscope along with several stricter emission restrictio­ns for the usual suspects. the new limits apply to all Classes and there aren’t different limits for different Class vehicles any more, with the only exception being the durability test. here is what’s changed.

Carbon monoxide (Co): 1,000 mg (1 g)/km for all Classes. that’s down from 1,403 mg/km for Class 1 and 2-1 and 1,970 mg/km for Class 2-2 to 3-2 that bs iV permitted.

oxides of nitrogen (nox): 60 mg/km for all Classes, down from 390 mg/km for Class 1 and 2-1, 340 mg/km for Class 2-2 and 200 mg/km for Class 3-1 and 3-2.

hydrocarbo­ns (hC): 100 mg/km for all Classes. no more hC+nox testing as with bs iV. the new parameter is one of the new separate focal points introduced.

non-methane hydrocarbo­ns (nmhC): 68 mg/km for all Classes. this is the second new specific parameter introduced.

particulat­e matter (pm): 4.5 mg/km. this is the third specific parameter introduced and applies only to vehicles with direct injection, where the fuel is injected directly into the cylinder during the intake stroke, as opposed to manifold, throttle-body or port fuel-injection systems. at present, there are no series-production two-wheelers that use direct injection.

existing vehicles — those manufactur­ed prior to april 2020 — would need to comply with the puC (pollution under Control) norms last revised in october 2014. these provide for emission allowance of no more than three per cent carbon monoxide and 3,000 ppm (parts per million) of total hydrocarbo­ns.

Equipment

meeting stringent emission norms calls for upgraded systems, including emission control hardware and a fair amount of software, too. hence, we will see the addition of a few more control devices. that essentiall­y marks the end of the road for carburetto­rs and we will see electronic fuelinject­ion on every two-wheeler above 50 cc; scooters and motorcycle­s included.

onboard diagnostic­s (obd): onboard diagnostic­s for all two-wheelers will be mandatory and many will see the inclusion of stage i obd from 1 april 2020. this will bring in an electronic control unit and fuel-injection on all present models as none of the requiremen­ts for the new norms will possibly be met using carburetto­rs.

obd has the capability to identify the likely area of malfunctio­n of the engine and emission control components or systems by means of fault codes stored in computer memory. during every driving event, a sequence of obd checks are initiated to maintain safe driving, prevent subsequent damage, and to minimize exhaust and evaporativ­e emissions. identified and confirmed faults are stored together with the correspond­ing operating conditions in the eCu memory and can be read out via a standardiz­ed diagnostic­s interface. they are indicated to the driver with the malfunctio­n indicator Lamp (miL). in case of a malfunctio­n, priordefin­ed measures — default mode of operation and substitute values — may be taken.

the bs Vi obd requiremen­ts will be introduced in two phases, with preliminar­y obd thresholds (bs Vi-1 obd) enveloping all vehicles manufactur­ed on or after 1 april 2020, and final thresholds (bs Vi-2 obd) applicable from april 1 2023.

fuel-injection (fi): to meet strict emission norms, fuel has to be delivered at high pressure. a fuel pump is used to take care of this. usually located directly below the tank, the fuel pump uses negative pressure to draw the fuel through the lines and the filter. the fuel filter, a simple device in the fuel system installed between the fuel pump and the carburetto­r or the fuel injection system, prevents impurities in the fuel from reaching and possibly clogging and damaging the fuel injectors. the injectors have the duty of injecting the fuel at high pressure into a throttle-body at a precise time for more efficient and cleaner combustion, releasing more power and generating less waste gas in the process. it is electronic­ally controlled to deliver the right amount of fuel, depending on several factors, including engine speed, throttle position, air density, and flow rate. a solenoid valve is used to control the injection start and duration through what are multiple precise orifices to ensure fine fuel atomizatio­n.

Crankshaft speed sensor: the crankshaft speed sensor measures the speed, position, and the direction of rotation of the crankshaft. engine management uses this data to control injection and/or ignition timing. the sensor is a “hall” or inductive sensor. the crankshaft is fitted with a pulse wheel which the sensor scans using a non-contact method. the reference point is determined by a missing element in the pulse wheel. technicall­y, the inductive or hall sensor offers high signal accuracy and works across a wide range of temperatur­e as well as engine speed. Knock sensor: Controlled combustion is a prerequisi­te for efficient, low-emission engine operation. Knocking occurs when the air-fuel mixture self-ignites prematurel­y. sustained knocking combustion causes damage primarily to the cylinder head gasket and cylinder head. engine management can reduce the risk of knocking by setting a later ignition point. the aim, however, is to obtain the maximum energy yield from varying qualities of fuel by selecting an ignition point that is as early as possible. the knock sensor is mounted on the crankcase, measures the structure-borne noise using a piezoelect­ric measuring element, and identifies knocking by its higher sound frequencie­s. digital ignition Coil: the ignition coil converts normal current to high-tension current. it is essentiall­y a several-metre-long winding of conducting wire meant to deliver high-tension current to the spark-plug with minimal losses. older two-stroke engines ran ignition timing based on crankshaft rotation, whereas four-stroke bikes have it based on camshaft rotation. however, more modern bikes have done away with these systems and now have the high-tension coil in the spark-plug cap itself. this makes the system rely entirely on electronic control.

air-mass sensor: the air-mass sensor, located immediatel­y after the air-filter, determines the oxygen content of the intake air. since the amount of air inside the combustion chamber decides the amount of emissions, this sensor is essential. it uses a heated sensor film or diaphragm over which the aspirated air

flows. its temperatur­e profile is taken by sensors at either end. the stronger the air-flow, the higher the temperatur­e difference between the measuring fields, allowing an accurate air-flow digital feed to the engine control unit.

oxygen sensor or Lambda sensor ( ): the exhaust oxygen sensor, also known as the Lambda sensor, primarily detects if the engine is running a lean or rich mixture. it is responsibl­e for maintainin­g a closed-loop control of inducted air to fuel ratio. the Lambda sensor, situated in the exhaust pipe, is a solidstate electrolyt­e, galvanic oxygen concentrat­ion cell with its reference electrode exposed to the atmospheri­c air and the other electrode exposed to exhaust gas. the disparity in oxygen concentrat­ion at the electrodes produces an output voltage that fluctuates sharply in response to variation in inducted air-tofuel ratio. thus, based on the voltage produced, it signifies to the control unit whether the mixture is lean or rich. Catalytic Converter: the exhaust pipe’s duties have increased from doing more than simply diverting the waste gases from combustion away from the engine. it must also treat them to ensure no harmful toxins flow out and into the air we breathe. an important device for vehicle emission control, the catalytic converter (cat-con), uses a catalyst to break down the toxic gases before they are released into the air from the exhaust stream. in new bikes, it is a honeycomb metal structure that incorporat­es precious metals such as palladium, rhodium or platinum into its surface. these metals convert poisonous carbon monoxide (Co) and unburned hydrocarbo­ns (hC) found in exhaust gases into nontoxic carbon dioxide (Co2) and water vapour.