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Thursday, 15 February 2018
Wednesday, 14 February 2018
KNOW WHY GEARBOX IS NOT USED IN ELECTRIC VEHICLES !!
Internal combustion engines generate usable torque and power in a narrow band of engine speeds. To accelerate the vehicle, multispeed transmissions step that down, in varying gear ratios, to keep the engine in its power band. Keeping the engine in its power band also proves to be the most efficient and durable. An engine, in first gear, can easily accelerate a car to 30 mph, but would also shake itself to bits attempting to accelerate to highway speed. Likewise, that same engine would hardly be able to accelerate from a stop in 6th gear.So,we require gearbox in case of internal combustion engines because usable torque and power is generated in a narrow band of engine speeds.The variation of torque is very high at different engine speed range.
In case of electric vehicles, electric motor-generators (MG) generate 100% of their torque at very low speeds, DC MGs near stall (zero rpm), and AC MGs around 1,000 rpm, as a general rule. As rpms increase, torque falls off at a fairly linear rate, at the same time that power is increasing. Toyota Prius, for example, the MG generates up to 300 N•m of torque around 1,500 rpm, trailing off to about 50 N•m at 6,000 rpm. At its most-efficient, 93%, the MG is pushing only 100 N•m at 2,250 rpm, perfect for cruising. In any case, a multispeed electric vehicle transmission is unnecessary because even 100 N•m is plenty of torque at cruising speed.Torque is necessary for acceleration, the most of which is generated near stall. Power is necessary for cruising, the most of which is developed at high rpm.
In case of electric vehicles, electric motor-generators (MG) generate 100% of their torque at very low speeds, DC MGs near stall (zero rpm), and AC MGs around 1,000 rpm, as a general rule. As rpms increase, torque falls off at a fairly linear rate, at the same time that power is increasing. Toyota Prius, for example, the MG generates up to 300 N•m of torque around 1,500 rpm, trailing off to about 50 N•m at 6,000 rpm. At its most-efficient, 93%, the MG is pushing only 100 N•m at 2,250 rpm, perfect for cruising. In any case, a multispeed electric vehicle transmission is unnecessary because even 100 N•m is plenty of torque at cruising speed.Torque is necessary for acceleration, the most of which is generated near stall. Power is necessary for cruising, the most of which is developed at high rpm.
At lower speeds we need high torque which electric motor generates but in case of engines it is not so.This is shown in the graph above.The curve is almost linear in case of electric vehicle which shows that torque is almost same for wide range of operation.
Sunday, 11 February 2018
DIFFERENCE BETWEEN POLISHING AND BUFFING EXPLAINED !!
Buffing and polishing both are surface finishing process but there is a slight difference between two:
Polishing:
- Finishing processes that utilize abrasive belts are referred to as polishing.
- Polishing generates a brushed or lined finish.
Buffing:
- Processes that use cloth wheels with compound applied is called buffing.
- Buffing removes the lines and creates a bright luster finish. The process of buffing generally requires surface refinement polishing prior to buffing.
Polishing by abrasive belts or discs is required to level surfaces, remove scratches, pits, scale and polish the surface enough so the cut buff can remove the polishing lines. The first polishing step should be done with the finest abrasive possible that efficiently removes the welds, levels, or refines the surface imperfections. From that point on, the subsequent process works to remove the first polishing scratch lines.
Buffing is a rotating cloth wheel that is impregnated with fine abrasive compounds, and it produces a bright-luster finish on metal and composites. Buff wheels are impregnated with liquid rouge or a greaseless compound-based matrix of specialized fine abrasive called compound. The compound is sprayed or pressured into the rotating buffing wheel. The buff wheel acts as the carrier of the compound, which ultimately does the surface finishing.
Thursday, 8 February 2018
TOP 5 LAUNCHES OF AUTOEXPO 2018 !!
The Auto Expo 2018 is setting out to be an exciting event for two-wheeler aficionados in the country, with the promise of many new launches and unveils. Scroll down to find the top launches and unveils that took place at the 14th edition of the motor show.
1.Yamaha YZF-R15 3.0
India Yamaha Motor (IYM) launched the new version of its sports bike YZF-R15 (Version 3.0) priced at Rs 1.25 lakh (ex- showroom Delhi).The new bike’s engine appears to be different from that of the outgoing R15 in India; this means we could get the new 155cc, single-cylinder, liquid-cooled, fuel-injected engine from the international spec bike. However, this motor features Yamaha's Variable Valve Actuation (VVA) system which helps it make 19.3hp and 14.7Nm of torque.
2.BMW F 750 GS and F 850 GS
These new models feature sharper styling, new technology, a monocoque frame and a bigger 853cc engine – an upgrade to their 798cc predecessors, the F 700 GS and F 800 GS. The new 853cc parallel-twin engine is tuned to make different power figures in both bikes – 77hp and 83Nm of torque in the F750, and 85hp and 92Nm of torque in the F850. The'F 750 GS' and 'F 850 GS', priced at Rs 12.20 lakh and Rs 13.7 lakh (below), respectively.
3.BMW G 310 R
The G 310 R weighs 158kg and comes with a 313cc, single-cylinder engine with twin-overhead camshafts that puts down 33.6hp and 28Nm of torque. Like the TVS Apache RR 310, the G 310 R will come with a reversed-cylinder design that slopes towards the rear wheel, instead of the conventional engine layout.The G 310 R is expected to hit the market sometime in the fourth quarter of this year and is expected to be priced between Rs 2.25-2.4 lakh (ex-showroom).
4.Kawasaki Ninja 400
The 400 in the Ninja’s all-new 399cc parallel-twin engine that makes a claimed 45hp and 38Nm of torque. The motorcycle also comes with a larger 310mm disc up front with Nissin ABS.
5.HERO XPULSE 200
The new Hero XPulse will be drawing power from a 199.5 cc single-cylinder, fuel-injected engine.The unit is the same as the newly unveiled Hero Xtreme 200R and is tuned to produce 18.1 bhp at 8000 rpm and 17.1 Nm at 6000 rpm. The motor is paired to a 5-speed gearbox. Price-₹ 1 - 1.2 Lakh *(Expected)
DIFFERENCE BETWEEN CRANKSHAFT AND CAMSHAFT EXPLAINED !!
Crankshafts:
The crankshaft is an engine component that converts the linear (reciprocating) motion of the piston into rotary motion. The crankshaft is the main rotating component of an engine and is commonly made of ductile iron.
All major components of the engine like piston,connecting rod etc. are supported by this shaft.
Construction Of Crankshaft:
A crankshaft is simply the same as an eccentric, except the eccentric is a much smaller diameter than the shaft itself Crankshaft length mainly depends on number of cylinders are present in engine .Firing order also considered while designing the Crankshaft .
Location : Crankshaft is located in crank case . On Crankshaft, Connecting rods and pistons are mounted. The crankshaft rides on bearings which can wear down over time. The bearings support the crankshaft and also the rods which connect the pistons to the crankshaft.
Applications :It actually part of an engine where the power is available , and this power is transferred in the form of torque to clutch and thereby gearbox and wheels.The main function is to convert liner motion of the piston to useful rotary motion.
Camshafts:
Camshaft is a part of engine which is responsible for opening and closing of exhaust and inlet valves.As the engines work they need to breathe out exhaust gases and take in fresh air ( charge) for the next cycle to take place . All these processes need to take place at a designated time with respect to each other. These processes are timed through opening and closing of valves and actuation of fuel pumps through a actuating mechanism which is triggered by movement of the crankshaft. The camshaft comes into picture here. The Crankshaft drives through a belt or chain drive the camshaft on which the inlet,exhaust, fuel pump cams are fitted for each unit when the crankshaft rotates it in turn rotates the camshaft which precisely actuate the valve and fuel pumps.
Construction Of Camshafts:
A camshaft is a long bar with egg-shaped eccentric lobes, one lobe for each valve and fuel injector.
The relationship between the rotation of the camshaft and the rotation of the crankshaft is of critical importance. Since the valves control the flow of the air/fuel mixture intake and exhaust gases, they must be opened and closed at the appropriate time during the stroke of the piston. For this reason, the camshaft is connected to the crankshaft either directly, via a gear mechanism, or indirectly via a belt or chain called a timing belt or timing chain.
Location : Depending on the location of the camshaft, the cam operates the valves either directly or through a linkage of pushrods and rockers. Direct operation involves a simpler mechanism and leads to fewer failures, but requires the camshaft to be positioned at the top of the cylinders.
Applications :This shaft receives the power from crankshaft (1:2) and operates the engine valves through cam and follower mechanism(generally mushroom headed follower is used to reduce friction b/w cam and follower).
Tuesday, 6 February 2018
DIFFERENCE BETWEEN ROCKWELL,BRINELL & VICKERS HARDNESS TEST EXPLAINED !!
Hardness is the property of a material that enables it to resist plastic deformation, usually by penetration. However, the term hardness may also refer to resistance to bending, scratching, abrasion or cutting.
The usual method to achieve a hardness value is to measure the depth or area of an indentation left by an indenter of a specific shape, with a specific force applied for a specific time. There are three principal standard test methods for expressing the relationship between hardness and the size of the impression, these being Brinell, Vickers, and Rockwell. For practical and calibration reasons, each of these methods is divided into a range of scales, defined by a combination of applied load and indenter geometry.
The usual method to achieve a hardness value is to measure the depth or area of an indentation left by an indenter of a specific shape, with a specific force applied for a specific time. There are three principal standard test methods for expressing the relationship between hardness and the size of the impression, these being Brinell, Vickers, and Rockwell. For practical and calibration reasons, each of these methods is divided into a range of scales, defined by a combination of applied load and indenter geometry.
Comparison between Rockwell, Brinell, Vickers hardness test.
Friday, 2 February 2018
ELECTRON BEAM WELDING EXPLAINED !!
Electron Beam Welding (EBW) is a fusion welding in which coalescence is produced by heating the workpiece due to impingement of the concentrated electron beam of high kinetic energy on the workpiece. As the electron beam impinges the workpiece, kinetic energy of the electron beams converts into thermal energy resulting in melting and even evaporation of the work material.
2) High welding speed is obtained.
3) Material of high melting temperature can be welded.
4) Superior weld quality due to welding in vacuum.
5) High precision of the welding is obtained.
6) Distortion is less due to less heat affected zone.
7) Dissimilar materials can be welded.
8) Low operating cost.
9) Cleaning cost is negligible.
10) Reactive materials like beryllium, titanium etc. can be welded.
11) Materials of high melting point like columbium, tungsten etc. can be welded.
12) Inaccessible joints can be made.
13) Very wide range of sheet thickness can be joined (0.025 mm to 100 mm).
2) High vacuum is required.
3) High safety measures are required.
4) Large jobs are difficult to weld.
5) Skilled man power is required.
Principle:
In general, electron beam welding process is carried out in vacuum. In this process, electrons are emitted from the heated filament called electrode. These electrons are accelerated by applying high potential difference (30 kV to 175 kV) between cathode and anode. The higher the potential difference, the higher would be the acceleration of the electrons. The electrons get the speed in the range of 50,000 to 200,000 km/s. The electron beam is focused by means of electromagnetic lenses. When this high kinetic energy electron beam strikes on the workpiece, high heat is generated on the work piece resulting in melting of the work material. Molten metal fills into the gap between parts to be joined and subsequently it gets solidified and forms the weld joint.
Advantages of EBW:
1) High penetration to width can be obtained, which is difficult with other welding processes.2) High welding speed is obtained.
3) Material of high melting temperature can be welded.
4) Superior weld quality due to welding in vacuum.
5) High precision of the welding is obtained.
6) Distortion is less due to less heat affected zone.
7) Dissimilar materials can be welded.
8) Low operating cost.
9) Cleaning cost is negligible.
10) Reactive materials like beryllium, titanium etc. can be welded.
11) Materials of high melting point like columbium, tungsten etc. can be welded.
12) Inaccessible joints can be made.
13) Very wide range of sheet thickness can be joined (0.025 mm to 100 mm).
Disadvantages of EBW:
1) Very high equipment cost.2) High vacuum is required.
3) High safety measures are required.
4) Large jobs are difficult to weld.
5) Skilled man power is required.
Applications:
1. Electron beam welding process is mostly used in joining of refractive materials like columbium, tungsten, ceramic etc. which are used in missiles.
2. In space shuttle applications wherein reactive materials like beryllium, zirconium, titanium etc. are used.
3. In high precession welding for electronic components, nuclear fuel elements, special alloy jet engine components and pressure vessels for rocket plants.
4. Dissimilar material can be welded like invar with stainless steel.
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