HADEY Automobile

04/09/2023

To save fuel while driving, consider the following tips:

1. Maintain a steady speed: Avoid frequent acceleration and braking. Smooth, consistent driving helps reduce fuel consumption.

2. Proper tire maintenance: Keep your tires properly inflated, as under-inflated tires can increase rolling resistance and reduce fuel efficiency.

3. Lighten the load: Remove unnecessary items from your vehicle, as extra weight can decrease fuel efficiency.

4. Use air conditioning sparingly: Air conditioning can increase fuel consumption. Use it wisely, and consider opening windows for ventilation at lower speeds.

5. Plan your trips: Combine errands to reduce the number of trips you make, and plan routes to avoid traffic and congestion.

6. Drive at a moderate speed: High speeds consume more fuel. Driving within the speed limit can significantly improve fuel efficiency.

7. Avoid idling: Turn off your engine if you anticipate a long stop, such as waiting for a train or at a drive-thru.

8. Maintain your vehicle: Regular maintenance, such as changing the oil, replacing air filters, and ensuring the engine is in good condition, can improve fuel efficiency.

9. Use cruise control: On highways, cruise control can help maintain a consistent speed and save fuel.

By following these tips, you can reduce your fuel consumption and save money while driving.

21/07/2022

FIVE THINGS THAT CAN CAUSE A CAR BATTERY NOT TO CHARGE

⭕Computer Error
Most people are driving cars made within the last 20 years. These newer cars all have a central computer system or engine control unit (ECU) which manages and operates the vehicle’s components and parts.
This computer manages the alternator as well. Therefore, all it would take is a computer error and the result would be a malfunctioning alternator, preventing it from charging.

⭕ – Broken Belt or Pulley
The belt and pulley produce the mechanical power which gets converted into electrical energy by the alternator. Your serpentine belt can easily break if it gets stretched out too much, causing it to snap apart.
The pulley can also get damaged after a while. In either case, the alternator will no longer be able to produce a charge for the battery.

⭕ – Blown Fuse
There are certain models of car which have alternators dependent on a particular fuse to operate. However, these fuses can blow due to a power surge or simply from old age. Once that happens, the alternator will no longer charge the battery.
Not all vehicles have these fuses, so you will have to check your owner’s manual to see if your car has them. If so, this is well worth investigating in the event your car battery is not charging properly.

⭕ – Wiring Issues
There are numerous wiring components in a vehicle that help produce power for the alternator. All it would take is for one wire to be disconnected or cut for power to stop being generated. As a result, the alternator won’t be able to charge the battery until the wire is repaired or replaced.

⭕– Bad Alternator or Battery
Alternators and batteries do not last forever, and each have their own lifespans. A car battery will last from 2 to 5 years, depending on how often you drive and the climate where you live. Batteries generally last longer in colder environments and shorter in hotter environments.
Alternators will on average last about 7 years or every 80,000 miles.

17/07/2022

06/07/2022

Type of Breaking system

23/04/2022

Main Components or Parts
1. Shafts–
There are usually 3 shafts used in a manual transmission that are-

(i) Main-Shaft-
It is the shaft that is also called the output shaft and is placed in front of the clutch shaft and in parallel to the lay-shaft. gears, gear lever along with the meshing devices such as dog clutches and synchromesh devices are mounted over this shaft.

(ii) Lay-shaft or Counter Shaft-
It is the shaft used as an intermediate shaft between the clutch shaft and the main shaft, it is usually mounted below and parallel to the main shaft, and act as an engine output carrier from the clutch shaft to the main shaft.
(iii) Clutch-Shaft-
It is the shaft that carries the rotational output from the engine’s flywheel to the transmission with the help of a clutch that engages and disengages the output from the engine.

2. Gears –
There are mainly 4 types of gears used in manual gearbox that are-

(i) Spur Gear: Used in old sliding mesh gearbox these types of gears have straight cut teethes.

(ii) Helical Gear: They are the modified version of the latter as they have angular cut teethes.

(iii) Bevel: They are best of all above gears having a conical cross-sectional area with angular cut teethes.

(iv) Idler-gear: It is the small gear used as a reverse gear usually mounted over the lay shaft.

3. Meshing Devices:
There are usually 2 types of meshing devices used in manual transmission-

(i) Dog Clutches: They are the devices used for meshing of gears in constant mesh gearbox.

(ii) Synchromesh Devices: They are the devices which are used in synchromesh gearbox for the meshing, these devices provide smooth shifting of gears.

4. Gear lever-
It is the lever used by the driver to shift a gear.

23/04/2022

Just in case some of you aren't sure how two-stroke engines work, here is some review. In a four-stroke engine, each of the four essential steps of the power-producing cycle is given its own piston stroke:

1) Compression

2) Power

3) Exhaust

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4) Intake

A two-stroke engine performs all the same steps, but in just two piston strokes. The simplest two-stroke engines do this by using the crankcase and the underside of the moving piston as a fresh charge pump. Such engines carry the official name "crankcase-scavenged two-strokes."

As the two-stroke’s piston rises on compression, its underside pulls a partial vacuum in the crankcase. An intake port of some kind (cylinder wall port, reed valve or rotary disc valve) opens, allowing air to rush into the crankcase through a carburetor.

As the piston nears Top Dead Center, a spark fires the compressed mixture. As in a four-stroke, the mixture burns and its chemical energy becomes heat energy, raising the pressure of the burned mixture to hundreds of psi. This pressure drives the piston down the bore, rotating the crankshaft.

As the piston continues down the bore, it begins to expose an exhaust port in the cylinder wall. As spent combustion gas rushes out through this port, the descending piston is simultaneously compressing the fuel-air mixture trapped beneath it in the crankcase.

As the piston descends more, it begins to expose two or more fresh-charge ports, which are connected to the crankcase by short ducts. As pressure in the cylinder is now low and pressure in the crankcase higher, fresh charge from the crankcase rushes into the cylinder through the fresh-charge (or “transfer”) ports. These ports are shaped and aimed to minimize direct loss of fresh charge to the exhaust port. Even in the best designs, there is some loss, but simplicity has its price! This process of filling the cylinder while also pushing leftover exhaust gas out the exhaust port is called “scavenging.”

While the piston is near Bottom Dead Center, mixture continues to move from the crankcase, up through the transfer ports, and into the cylinder.

As the piston rises, it first covers the transfer ports, leaving only the exhaust port still open. If there were no way to stop it, much of the fresh charge would now be pumped out the exhaust.

But there is a simple way to stop it—using exhaust pressure waves in the exhaust. If we shape and dimension the exhaust pipe right, a reflection of the original pressure pulse, generated as the exhaust port opened, will bounce back to the port just as fresh charge is being pumped out of it. This pressure wave stuffs the fresh charge back into the cylinder just as the rising piston covers the exhaust port.

Because fuel-air mixture is constantly being pumped by the crankcase, it is not practical to lubricate piston and crank by pumped circulating oil—it would be swept away by the mixture rushing in and out. Therefore, we must either mix a little oil with the fuel (2 to 4 percent) or inject it very sparingly into the bearings with a tiny metering pump. The fact that there is so little oil dictates that such simple two-stroke engines must employ rolling bearings, whose need for oil is very small.

More complicated two-stroke engines exist. Instead of using the crankcase and underside of the piston as a fresh-charge pump, we can use a separate rotary blower, directly connected to the transfer ports in the cylinders. We don't have to place the exhaust port in the cylinder wall—it can take the form of four overhead poppet exhaust valves, as it does in two-stroke marine, rail, and truck diesels. Because such engines do not use their crankcases as fresh charge pumps, they can employ long-lasting plain bearings, lubricated conventionally by pumped recirculating oil.

Two-stroke diesels are scavenged with pure air, not a fuel-air mixture. Their fuel is injected only after all ports have closed, preventing any loss. Certain crankcase scavenged two-strokes do the same, and are called “DI,” or Direct Injection two-strokes. They can be made as fuel-efficient and low in exhaust emissions as four-strokes.

The world’s most efficient piston engines are in fact the giant, slow-turning marine diesels that carry the world’s international shipping trade—they are twice as efficient as the usual four-stroke spark-ignition engines found in cars and motorcycles.

23/04/2022

Steering System

23/04/2022

23/04/2022

DIESEL vs PETROL ENGINE
Compression Ignition Vs Spark Ignition.