Boyle's and Charles's Law

 

   cONTENTS PAGE

Introduction.................................................................................................................. Page 2

Boyle’s Law................................................................................................................. Page 2

Charles’s Law............................................................................................................. Page 3

Internal Combustion Engine.................................................................................... Page 5

Conclusion.................................................................................................................. Page 7

Reference.................................................................................................................... Page 9

The following research paper is based on my understanding of the Boyle and Charles laws. It will identify my understanding of the laws in my own words, whilst showing how each law relates to the internal combustion engine.

Boyle’s Law

Boyle’s law, which is also known as the Boyle-Mariotte law, was first identified in 1662 by Robert Boyle. The Boyle’s law, one of numerous gas laws, is defined as the ‘inversely bond between the complete pressure and volume of a gas’. In my understanding this means, that as long as the gas is at a constant temperature, the volume of the gas will vary inversely with its pressure. Shown in the graph below:

When the pressure is low, the volume is at its highest and vice versa, when its pressure is high, the volume is low, assuming that the temperature of the gas remains the same throughout. Using a capped syringe or a closed engine piston as an example, when the volume changes the amount of space which is required for the molecules to move will change. For that reason when the space is smaller, it will require more pressure to be exerted to adapt to the change.

Another example which uses Boyle’s law is spray cans; the forceful pressure within the can thrusts outward the liquid that is within the can. The pressure, that is attempting to escape, pushes the fluid out of the cap when it is opened. Boyle’s law also can be applied to the human race breathing, balloons and a car engine.

Boyle created a formula which reads as a mathematical equation:

P represents the pressure, V is the volume and k stands for the constant pressure and volume in which is used however this will only work as long as the temperature is kept stable and unchanged.

Diagram above shows how temperature when kept stable and unchanged at 300ºf, the volume will decrease as pressure builds up. As this is Boyle’s Law, it will only work because the temperature is constant to ensure that there is a relationship between pressure and volume.

Charles’s Law

Charles’s law, also known as the law of volumes, was found by Jacques Charles in 1802. Charles’s law is dealt in a different situation however is similar to the Boyle’s law which deals with the same variables. My understanding of this gas law is that it reviews the temperature and volume that is directly proportionate to each other at a constant pressure. This means that the volume of an object will increase if the temperature increases however this is only if the pressure is kept stable and constant throughout.

According to Benson (2011), an example used was the car tyres, during the months of summer months the tyres increase whilst winter months it will decrease in volume. Another example that I believe uses Charles’s Law is a bottle of fizzy drink. When the fizzy drink is cold, there is not that much pressure released when the bottle is opened however if it was warm, there is a build-up of pressure to spurt out of the bottle. Yet if it was placed into direct sunlight, image the explosion that could be caused.

Equation that was found to be used by Charles’ to describe their findings is a shown below:

V represents the volume, T is the temperature and the constant variable used is the pressure.

The diagram above shows that when pressure is kept at 1.50kPa, the volume of a given mass of an ideal gas will either increase or decrease together. As the temperature increases, the volume increases too and also the other way, when temperature decreases, volume will do the same. This can be written as:

Internal Combustion Engine

Both Boyle’s and Charles's laws assume that one of the variables is controlled. Using Boyle’s law, a car engine works when there is a sudden increase of pressure from the combustion of the fuel to ensure it expands in the cylinder and thrusts out into the piston, causing the crankshaft to work. The following examples used below to demonstrate Boyle’s and Charles’s Law being used within the internal combustion engine is based on the assumption that there is a constant variable however in reality there isn’t really a chance that you will find it suitable as things change. 

Boyle’s Law:

Assuming that the combustion chamber is filled with gas, the piston will be moving in an upwards movement. This causing the volume of the gas to decrease and increase pressure from the gas. May and Simpson (2007), states that at the “peak compression, one should expect the air to be compressed to about ¹/₈ of its original volume” (p. 135).

The diagram above shows that during the compression stroke (assuming that temperature is constant), gas particles commence to decrease if the fuel particle increases. However as shown once the volume of the fuel decreases, an increase of pressure occurs causing Boyle’s law to take place.

Charles’s Law:

The example below uses the absolute pressure of the gases or the amount of gas found in the internal combustion engine. During the  power stroke, the constant variable may change (Real life applications. n.d.).

Spark ignition:

The gases that are created from the combustion process are done in very high temperatures. As there is a high exposure to temperature, the gases result in an increase in volume. The spark plug when sparked will burn a mixture of heat and other gases. In this process, you will be able to witness the beauty of Charles’s law as the volume will increase due to the temperature. In reality you will see this likely when the fuel and air combustion are exposed to high temperature and expands in volume. This causes the cylinder wall and piston to be forced outwards and pushes the piston head downwards. This continues till it is passed to the conrod, crankshaft and allowing the crankshaft to move in a circular motion.

Compression ignition:

Before entering the power stroke, air is compressed into small molecules (Clark, 2002). The temperature of the air is increase during the stroke of power and fuel is injected into the cylinder to cause a mixture of hot air and fuel particles. As Charles’s law illustrates the importance of temperature and volume with the constant amount of pressure, the gases within that is exposed to high temperature will increase in volume to push the piston downwards to ensure the transfer of movement to the crankshaft to turn over (May & Simpson, 2011).

Conclusion

Boyle’s Law reviews the volume and pressure and its relationship with each other whilst Charles’s Law identified the relationship between the volume and temperature. Two different gases however very similar ideas of both requiring a constant variable to ensure that their experiment works. Boyle’s Law requires the stable temperature to ensure it continues to work whereas Charles’s Law required the pressure to remain constant.

Boyle’s Law has been identified and has been discussed to be used within an internal combustion engine however theoretical this is not shown. There is an aim within the strokes of the compression to decrease the volume and to continue to increase the pressure found in the combustion chamber. The likelihood of collision to occur between atomized fuel and air particles are increased as the concentration of air particles increases too.

Charles’s Law reviews the volume and temperature of a gas that are proportionate to each other. The concept used within this theory can be found to be used in the spark ignition and compression ignition within the internal combustion engine. The cylinder walls are likely to enlarge due to the air fuel gases. The expansion of the cylinder wall ensures the pressure of the gas to move the piston head therefore allowing movement and force into the crankshaft.

   Reference

Anonymous. (n.d). Gases - Real Life Applications. (n.d). Retrieved April 05 2012 from http://www.scienceclarified.com/everyday/Real-Life-Chemistry-Vol-1/Gases-Real-life-applications.html

Anonymous. (n.d). How Does Boyle's law & Charles's Law Apply To Internal Combustion Engine?. Retrieved April 13 2012 from http://www.experts123.com/q/how-does-boyles-law-and-charles-law-apply-to-internal-combustion-engine.html

Benson, T. (2011). Boyle's Law. Retrieved April 12, 2012, from http://www.grc.nasa.gov/WWW/k-12/airplane/boyle.html

Clark, J. (2002). The Effect Of Pressure On Reaction Rates. Retrieved April 12 2012 from http://www.chemguide.co.uk/physical/basicrates/pressure.html

May, E. & Simpson, L. (2007). Engine Fundamentals. In A. Evans et al., Automotive Mechanics. 1(8). 133 – 148.

May, E., & Simpson, L. (2011). Automotive Mechanics – Volume 1. (8^th ed.). Australia: McGraw Hill Australia Ltd.

May, E., & Simpson, L. (2011). Automotive Mechanics – Volume 2. (8^th ed.). Australia: McGraw Hill Australia Ltd.

West, J. B. (1999). The original presentation of Boyle's Law. Journal of applied Physiology, 1(98), 31 – 39.

Continuously Variable Transmission

Continuously Variable Transmission

Continuously Variable Transmission (Transaxle), also known as CVT, is a type of automatic transmission that gives improved performance within its power and allows smoother driving and supports a better fuel economy. The following paper is based on my understanding of a CVT. There are several types of CVT engines; Variable-diameter pulley (VDP) or Reeves drive, Magnetic CVT (MCVT), Toroidal or Roller-based CVT (extroid CVT), Hydrostatic CVT and a Ratcheting CVT. In this essay we will refer to the VDP which is commonly used in our vehicles today. I will research the history, full operations and internal components to understand its advantages and disadvantages over other transmissions.

The History of CVT

Well improved and enhanced continuously variable transmissions were introduced in the late 1990s and early 2000s. Now recognised in our everyday vehicles, the CVT is found in a Honda, Ford, Nissan and much more. In the early stages of the CVT, there were complications due to limitations of technology and was then considered inappropriate to use with engines whose engine speed power was greater than 100. The CVT, in 1490, was first sketched by Leonardo DaVinci and was then used in the late 1950 by a Dutch automaker.

Leonardo DaVinci

What is a CVT?

As defined above in the introduction, a CVT is well enhanced than a “traditional” automatic. The CVT is a transmission that will change gear ratio without a person hearing or feeling it shift. The gear ratios will move from the lowest to the highest to determine the engine and car speed. This is an advantage when working with a CVT as it enables outstanding acceleration and breaking.

While using a CVT, the driving shaft will retain a consistent velocity to enable a variety of velocity outputs. This will support the engine to work to its highest quality of RPMs (revolutions per minute); to allow speed changes to occur. In the view of a driver, it is an advantage as the CVT does not require a clutch pedal however Simpson & May (2010) included that a few vehicles include a clutch to offer neutral stances on a motorcycle… which is useful when idling.

Internal Components and Full Operations

One of the components found in the CVT is called a final drive and reduction gears. Now this reduction gears system has two reduction gears which is called a driver and driven. This is also used to calculate the ratio of the moving gears. There is also a final drive gear inside the CVT and also the speedometer which is located on the differential case. All the gears are helical except for the reverse idler, which is made of cast harden medal. You will notice when you reverse in a manual transmission, you will hear the spur gears.

Another component inside the CVT is called the steel belt and pulley system. Now the pulley system consists of the input and output pulley otherwise known as the primary or secondary. The belt is slightly on an angle of 11 degrees which fits in the groove of the pulley. The pulley both input and output has a fixed half and sliding half. As the gears are widening and expanding in a narrow direction, the CVT enables for a smooth change in the gears. The pulley and belt system supports a successful outcome which allows CVT users to not feel the shifting or changes of the gears.

The belt consists of approximately 280 steel blocks which are held together by two laminated steel bands. Basically when pressure is put onto the output pulley (secondary), the steel blocks tighten together creating a tight grip and therefore forcing the pulley upwards.  Once the pull is created, the steel blocks will clam together and force the power into the bands, yet the bands will retain the friction needed to continue driving. Inside the internal components, as stated above in the final drive, there are common gears called helical and spurs. These are the most common gears used in a transmission. The helical enables good grip and works well whereas spurs causes friction against the shaft. A great example of the spur is when you hear the reversal in manual transmission.

The steel belt and pulley system is controlled by the ECU (electronic control unit) which is found inside the CVT. This will take into account the engine speed, engine torque also the position of the accelerator or where the brake pedal is at the moment. For example, a magnetic clutch will give drive between the engine and the transmission.

The electronic power clutch, in my understanding, has a small gap between the driver and driven gears which receives iron powder. This powder plays an important part as it enables magnetism within the drive to give power. This will be connected to the engine or the drive to enable power to be transmitted within it. Therefore more powder equal more power which gives more solidification nevertheless too much solidification will or can cause the clutch to lock up.

Most cars will be using the VDP. The pulleys within the VDP will be in reverse opposites of each other with a metal belt running between the pulleys. One pulley will be connected to drive and the other to engine (input and output shaft). Each half is capable of moving to allow a ratio of the gears to move upwards to offer further power.

Advantages and Disadvantages

The following advantages and disadvantages were found in our textbook “Automotive Mechanics” by Ed May & Les Simpson (Volume 1 and 2). Resources were also found in the textbook “Continuously Variable Transmission (CVT)” by Bruce D Anderson and John R Maten.

The advantages are as follows:

·         CVT changes the engine speed when required to ensure it is working at a high performance level

·         The torque also works at the highest level

·         Great fuel economy

·         Does not require a clutch pedal

·         Ensures smoother driving allowing the engine to increase to its fullest power

·         Quicker acceleration which is faster than a ‘normal’ automatic or manual transmission

According to research, the one disadvantage found is acceptance by the customers. As many customers will usually purchase a transmission which was either manual or automatic; they were not familiar to the unusual noises that arose from the engine when increasing the power. The noise coming from the hood when a CVT is in place, is a noise which sounds of a clutch that may have slipped off or a transmission which had slided therefore allowing the user to believe there was something incorrect occurring inside the hood of the car and problems may happen thereafter. The noise occurring is not what the customer believes is happening however is what is considered normal for a CVT transmission.

                                    

As shown above, the advantages of using a CVT are better than those of other transmissions. In this research, I’ve learnt that a traditional automatic or manual car when flooring will cause an impulsive force of power which causes the vehicle to stagger and stumble whereas the CVT enables efficient and swift boosts to the engine to work smoothly. According to Harris (2007), a few drivers have the impression that the car is running at a slower pace however Harris mentions that a CVT will normally out-accelerate an automatic or manual.

Conclusion

The history of Continuously Variable Transmission did not begin in such a great note; with it having limited technology and therefore restricting vehicles with less than 100 horsepower to use it. There were anxieties in regards to the noise that was generated by the CVT transmission and concerns over the reliability to whether or not it will endure long-term. Nevertheless advanced technology was later introduced enabling a robust CVT to be used in today’s vehicles. The VDP (Variable-Diameter Pulley) is the most common used CVT today and as it does not require a “given road speed directly to a given engine speed”, the CVT can differ within its engine speed to retrieve the highest power in addition  to increasing effective fuel economy. When choosing a car, both a CVT and a DSG transmission have a range of advantages and disadvantages, therefore when choosing a car it depends solely on the users’ personality and needs. In my opinion, I would choose a CVT as I prefer the quietness and the ability to drive smoothly.

Beginning of new beginnings

This week it has been very interesting and compelling in different levels. I have been accepted into CAT6 at Unitec 2012. This semester we as students have been asked to begin a blog of our daily experiences and to reflect upon a variety of things.




As I am beginning up this new blogger and familiarizing myself with this page, I thought it would be a great idea if I blogged about my first day at Unitec.




One word to describe my first day - CONFUSING....




I was in the wrong class at first and was taken out half way through the day. I must say, better late then never right! However I'm glad as I was hoping to do what I'm now classed in.




I hope for a great development in my understanding of automotive technology and be able to build the beginning of my future in working in the automobile industries and much more...




As time is limited and an assignment awaits, I shall be off and commence my first assignment...




Wish me luck!