Monday, March 3, 2014

Petrol Prices In Malaysia updated 9th January 2014

Budget 2014: More petrol price adjustments seen next year Updated:October 26, 2013

ECONOMISTS and analysts expect more adjustments in petrol prices next year, in line with the Government’s subsidy rationalisation plan, which aims to lighten the burden on the country’s fiscal deficit.
“The hint in that the petrol subsidy is going to be the focus in terms of subsidy rationalisation. I expect more frequent price adjustments in the future,” said Malaysian Rating Corp Bhd chief economist Nor Zahidi Alias.
He believes that adjustments will be made after the first quarter of 2014, when concerns over the budget battle in the US economy and the lower targeted gross domestic product growth of below 8% in China are more settled.
It is anticipated that a new subsidy reduction will generate at least RM3.3bil in savings. “At current global oil prices, assuming a revision of fuel subsidies at 20 sen, it will generate an additional RM3.3bil in savings,” said Alliance Research economist Manokaran Mottain.
The recent hike in RON95 and diesel by 20 sen to RM2.10 and RM2 per litre respectively is expected to bring savings of RM1.1bil from September to December, and RM3.3bil per year.


For 2014, the Government will reduce subsidies to RM39.4bil, primarily from lower provision of fuel subsidies. This year, almost RM47bil was allocated for various subsidies, incentives and assistance, including subsidies for petroleum products, food, health, agriculture and fisheries, utilities, toll as well as welfare and education.
In his speech, Prime Minister Datuk Seri Najib Tun Razak said some RM24.8bil or 53% of the total subsidies was used to subsidise petroleum products.
“A portion of the savings from the restructuring of the subsidy system will be distributed in the form of direct cash assistance, while the other half will be used to finance development projects,” he said.
Besides subsidy rationalisation for petrol, the Government also proposed to abolish the sugar subsidy of 34 sen, effective today. The abolishment of the sugar subsidy is expected to bring RM1.1bil in savings.
The Government will also allocate RM2.4bil for subsidies and incentives, including those for fertilisers, seeds, price of paddy and rice as well as incentives for higher production of paddy and fish landing.
Due to the implementation of the goods and services tax, as well as subsidy reductions, he expects inflation to come in at around 2.8% in 2014. He added that inflation could rise to between 3% and 4% in 2015.
“However, the Government has taken steps to ensure that the needy will be somewhat compensated. In the long-term, the subsidy rationalisation programme makes sense, as it reduces the burden on the Government’s coffers,” he said.

Ahmad Maslan: No increase in RON 95 petrol prices Updated: January 9, 2014 

KUALA LUMPUR: There will not be an increase in RON 95 petrol prices Thursday night, and rumours of a supposed hike are untrue.
"There will not be a 20 sen reduction in RON 95 subsidies tonight (Thursday), contrary to rumours," Deputy Finance Minister Datuk Ahmad Maslan tweeted.
The subsidised price of RON95 petrol is currently RM2.10 per litre.
Up to date prices for gasoline (unleaded) are available at>> http://www.mytravelcost.com/petrol-prices/





Our Global Consumption On Petrol

Motor Gasoline Definition: 
A complex mixture of relatively volatile hydrocarbons with or without small quantities of additives, blended to form a fuel suitable for use in spark-ignition engines. Motor gasoline, as defined in ASTM Specification D 4814 or Federal Specification VV-G-1690C, is characterized as having a boiling range of 122 to 158 degrees Fahrenheit at the 10 percent recovery point to 365 to 374 degrees Fahrenheit at the 90 percent recovery point. 
Motor Gasoline includes conventional gasoline; all types of oxygenated gasoline, including gasohol; and reformulated gasoline, but excludes aviation gasoline. 
Note: Volumetric data on blending components, such as oxygenates, are not counted in data on finished motor gasoline until the blending components are blended into the gasoline.

What is Petroleum?
Petroleum (L. petroleum, from Greekπέτρα (rock) + Latinoleum (oil) is a naturally occurring, yellow-to-black liquid found in geologic formations beneath the Earth's surface, which is commonly refined into various types of fuels. It consists of hydrocarbons of various molecular weights and other liquid organic compounds.The name petroleum covers both naturally occurring unprocessed crude oil and petroleum products that are made up of refined crude oil. A fossil fuel, petroleum is formed when large quantities of dead organisms, usually zooplankton and algae, are buried underneath sedimentary rock and subjected to intense heat and pressure.
Petroleum is recovered mostly through oil drilling. This comes after the studies of structural geology (at the reservoir scale), sedimentary basin analysis, reservoir characterization (mainly in terms of the porosity and permeability of geologic reservoir structures). It is refined and separated, most easily by boiling point, into a large number of consumer products, from gasoline (petrol) and kerosene to asphalt and chemical reagents used to make plastics and pharmaceuticals. Petroleum is used in manufacturing a wide variety of materials, and it is estimated that the world consumes about 90 million barrels each day.
The use of fossil fuels such as petroleum has a negative impact on Earth's biosphere, releasing pollutants and greenhouse gases into the air and damaging ecosystems through events such as oil spills. Concern over the depletion of the earth's finite reserves of oil, and the effect this would have on a society dependent on it, is a concept known as peak oil.

Composition
In its strictest sense, petroleum includes only crude oil, but in common usage it includes all liquid, gaseous, and solid hydrocarbons. Under surface pressure and temperature conditions, lighter hydrocarbons methaneethanepropane and butane occur as gases, while pentane and heavier ones are in the form of liquids or solids. However, in an underground oil reservoir the proportions of gas, liquid, and solid depend on subsurface conditions and on the phase diagram of the petroleum mixture.
An oil well produces predominantly crude oil, with some natural gas dissolved in it. Because the pressure is lower at the surface than underground, some of the gas will come out of solution and be recovered (or burned) as associated gas or solution gas. A gas well produces predominantly natural gas. However, because the underground temperature and pressure are higher than at the surface, the gas may contain heavier hydrocarbons such as pentane, hexane, and heptane in the gaseous state. At surface conditions these will condense out of the gas to form natural gas condensate, often shortened to condensate. Condensate resembles petrol in appearance and is similar in composition to some volatile light crude oils.
The proportion of light hydrocarbons in the petroleum mixture varies greatly among different oil fields, ranging from as much as 97 percent by weight in the lighter oils to as little as 50 percent in the heavier oils and bitumens.
The hydrocarbons in crude oil are mostly alkanescycloalkanes and various aromatic hydrocarbons while the other organic compounds contain nitrogenoxygen and sulfur, and trace amounts of metals such as iron, nickel, copper and vanadium. The exact molecular composition varies widely from formation to formation but the proportion of chemical elements vary over fairly narrow limits as follows.
Composition by weight
ElementPercent range
Carbon83 to 85%
Hydrogen10 to 14%
Nitrogen0.1 to 2%
Oxygen0.05 to 1.5%
Sulfur0.05 to 6.0%
Metals< 0.1%
Four different types of hydrocarbon molecules appear in crude oil. The relative percentage of each varies from oil to oil, determining the properties of each oil.
Composition by weight
HydrocarbonAverageRange
Alkanes (paraffins)30%15 to 60%
Naphthenes49%30 to 60%
Aromatics15%3 to 30%
Asphaltics6%remainder

Crude oil varies greatly in appearance depending on its composition. It is usually black or dark brown (although it may be yellowish, reddish, or even greenish). In the reservoir it is usually found in association with natural gas, which being lighter forms a gas cap over the petroleum, and saline water which, being heavier than most forms of crude oil, generally sinks beneath it. Crude oil may also be found in semi-solid form mixed with sand and water, as in the Athabasca oil sands in Canada, where it is usually referred to as crude bitumen. In Canada, bitumen is considered a sticky, black, tar-like form of crude oil which is so thick and heavy that it must be heated or diluted before it will flow. Venezuela also has large amounts of oil in the Orinoco oil sands, although the hydrocarbons trapped in them are more fluid than in Canada and are usually called extra heavy oil. These oil sands resources are called unconventional oil to distinguish them from oil which can be extracted using traditional oil well methods. Between them, Canada and Venezuela contain an estimated 3.6 trillion barrels (570×109 m3) of bitumen and extra-heavy oil, about twice the volume of the world's reserves of conventional oil.
Petroleum is used mostly, by volume, for producing fuel oil and petrol, both important "primary energy" sources. 84 percent by volume of the hydrocarbons present in petroleum is converted into energy-rich fuels (petroleum-based fuels), including petrol, diesel, jet, heating, and other fuel oils, and liquefied petroleum gas.The lighter grades of crude oil produce the best yields of these products, but as the world's reserves of light and medium oil are depleted, oil refineries are increasingly having to process heavy oil and bitumen, and use more complex and expensive methods to produce the products required. Because heavier crude oils have too much carbon and not enough hydrogen, these processes generally involve removing carbon from or adding hydrogen to the molecules, and using fluid catalytic cracking to convert the longer, more complex molecules in the oil to the shorter, simpler ones in the fuels.
Due to its high energy density, easy transportability and relative abundance, oil has become the world's most important source of energy since the mid-1950s. Petroleum is also the raw material for many chemical products, including pharmaceuticalssolventsfertilizerspesticides, and plastics; the 16 percent not used for energy production is converted into these other materials. Petroleum is found in porous rock formations in the upper strata of some areas of the Earth's crust. There is also petroleum in oil sands (tar sands). Known oil reserves are typically estimated at around 190 km3 (1.2 trillion (short scale) barrels) without oil sands, or 595 km3 (3.74 trillion barrels) with oil sands. Consumption is currently around 84 million barrels (13.4×106 m3) per day, or 4.9 km3 per year. Which in turn yields a remaining oil supply of only about 120 years , if current demand remain static.

Chemistry
Petroleum is a mixture of a very large number of different hydrocarbons; the most commonly found molecules are alkanes (paraffins),cycloalkanes (naphthenes), aromatic hydrocarbons, or more complicated chemicals like asphaltenes. Each petroleum variety has a unique mix of molecules, which define its physical and chemical properties, like color and viscosity.
The alkanes, also known as paraffins, are saturated hydrocarbons with straight or branched chains which contain only carbon andhydrogen and have the general formula CnH2n+2. They generally have from 5 to 40 carbon atoms per molecule, although trace amounts of shorter or longer molecules may be present in the mixture.
The alkanes, also known as paraffins, are saturated hydrocarbons with straight or branched chains which contain only carbon andhydrogen and have the general formula CnH2n+2. They generally have from 5 to 40 carbon atoms per molecule, although trace amounts of shorter or longer molecules may be present in the mixture.
The alkanes from pentane (C5H12) to octane (C8H18) are refined into petrol, the ones from nonane (C9H20) to hexadecane (C16H34) intodiesel fuelkerosene and jet fuel. Alkanes with more than 16 carbon atoms can be refined into fuel oil and lubricating oil. At the heavier end of the range, paraffin wax is an alkane with approximately 25 carbon atoms, while asphalt has 35 and up, although these are usually cracked by modern refineries into more valuable products. The shortest molecules, those with four or fewer carbon atoms, are in a gaseous state at room temperature. They are the petroleum gases. Depending on demand and the cost of recovery, these gases are either flared off, sold as liquified petroleum gas under pressure, or used to power the refinery's own burners. During the winter, butane (C4H10), is blended into the petrol pool at high rates, because its high vapor pressure assists with cold starts. Liquified under pressure slightly above atmospheric, it is best known for powering cigarette lighters, but it is also a main fuel source for many developing countries. Propane can be liquified under modest pressure, and is consumed for just about every application relying on petroleum for energy, from cooking to heating to transportation.
The cycloalkanes, also known as naphthenes, are saturated hydrocarbons which have one or more carbon rings to which hydrogen atoms are attached according to the formula CnH2n. Cycloalkanes have similar properties to alkanes but have higher boiling points.
The aromatic hydrocarbons are unsaturated hydrocarbons which have one or more planar six-carbon rings called benzene rings, to which hydrogen atoms are attached with the formula CnHn. They tend to burn with a sooty flame, and many have a sweet aroma. Some are carcinogenic.
These different molecules are separated by fractional distillation at an oil refinery to produce petrol, jet fuel, kerosene, and other hydrocarbons. For example, 2,2,4-trimethylpentane(isooctane), widely used in petrol, has a chemical formula of C8H18 and it reacts with oxygen exothermically:
C
8
H
18
(l) + 25 O
2
(g) → 16 CO
2
(g) + 18 H
2
O
(g) (ΔH = −5.51 MJ/mol of octane)
The number of various molecules in an oil sample can be determined in laboratory. The molecules are typically extracted in a solvent, then separated in a gas chromatograph, and finally determined with a suitable detector, such as a flame ionization detector or a mass spectrometer. Due to the large number of co-eluted hydrocarbons within oil, many cannot be resolved by traditional gas chromatography and typically appear as a hump in the chromatogram. This unresolved complex mixture (UCM) of hydrocarbons is particularly apparent when analysing weathered oils and extracts from tissues of organisms exposed to oil.
Incomplete combustion of petroleum or petrol results in production of toxic byproducts. Too little oxygen results in carbon monoxide. Due to the high temperatures and high pressures involved, exhaust gases from petrol combustion in car engines usually include nitrogen oxides which are responsible for creation of photochemical smog.

Rate of world energy usage per day, from 1970 to 2010. 1000TWh=1PWh



Global fossil carbon emissions, an indicator of consumption, for 1800–2007. Total is black, Oil is in blue.



Daily oil consumption from 1980 to 2006


Oil consumption per day by region
Oil consumption by percentage of total per region from 1980 to 2006: red=USA, blue=Europe, yellow=Asia+Oceania

Source provided by >> http://en.wikipedia.org/wiki/Petroleum

Nanomite and Replicating The Lotus Effect



NANOMITE and  Replicating The Lotus Effect:
Lotus plants have superhydrophobic surfaces: water droplets falling onto them bead up and, if the surface slopes slightly, will roll off. As a result, the surfaces stay dry even during a heavy shower. What’s more, the droplets pick up small particles of dirt as they roll, so that the lotus leaves are self-cleaning.
The effect arises because lotus leaves have a very fine surface structure and are coated with hydrophobic wax crystals of around 1 nm in diameter. Surfaces that are rough on a nanoscale tend to be more hydrophobic than smooth surfaces because of the reduced contact area between the water and solid. In the lotus plant, the actual contact area is only 2-3% of the droplet-covered surface.
Nanomite has perfected silicate and carbon base nano particles and every particle contains a positive charge that can create a uniform nano layer for up to 3 months of protection of any surface.

Developed in Switzerland, NANOMITE™ uses Positively Charged Organic Carbon & Silicate Nano Particles (10 -9) that Deliver Major Benefits:
ORDER HERE
  • Cleans: thoroughly & protects against build-up of dirt
  • Protects: against oxidation and corrosion
  • Temperature Resistant: from – 40° C to + 300° C (- 40° F to + 572° F)
  • Disinfects: all surfaces to a high degree
  • Seals: for extended periods
  • Safe: is non-toxic & environmentally safe
  • Shines: enhances the shine and luster of any smooth surface up to 100%
  • UV resistance: for months & pH 7 Neutral





1st Of Its Kind In The Nanotechnology World

Clearer Visibility , Better Sensitivity , Anti-Static 

NANOMITE™ SCREENBRITE is a revolutionary new Swiss nanotechnology formula laboratory manufactured specifically for use on all types of today’s electronic screens, panels, and monitors – the first of its kind in the world!

NANOMITE™ SCREENBRITE thoroughly cleans, protects and shines all types of electronic displays such as ipads, iphones, smart phones, tablets, laptops,LED & LCD flat panel screens. 

An invisible layer of positively charged nano particles attaches to the surface of your screen lifting away dirt,  skin oil, and grime at the nanoscopic level. 
Shine is increased up to 100%, and the layer of nano particles applied provides ongoing protection – including anti-static protection – to the surface of your TV screen, computer screen, and photocopier or scanner glass. 
Simply spray it on and wipe it off with a clean, dry, soft cloth. Repeat when necessary.

NANOMITE™ SCREEN BRITE is biodegradable, non-toxic, non-flammable, hypoallergenic, contains no CFC’s (chlorofluorocarbon), is not enzyme or petrochemical based, and is environmentally safe.
  • Cleans, Shines & Protects all LED & LCD Screens

  • Cleans, Shines & Protects all Laptop Screens

  • Cleans, Shines & Protects all iphones, ipads & smartphones & touch screens.


Besides the above, I uses it to clean all types of glass , mirrors and glass/ceramic decor. 
Most of the glass cleaner products contain ammonium hydroxite and alcohol which is harmful to use in long run especially to young children and sensitive skin.

For Your Order >>
 http://impian_gallery.tripleclicks.com/14001421


Height   : 13 cm 
Width    : 4.5 cm
Depth    : 3 cm
Weight  : 110 g approximately
Content : 100 ml

RM 15.99 per bottle (excluding delivery & handling fee)


A chlorofluorocarbon (CFC) is an organic compound that contains only carbon, chlorine, and fluorine, produced as a volatile derivative of methane, ethane, and propane. They are also commonly known by the DuPont brand name Freon. The most common representative is dichlorodifluoromethane (R-12 or Freon-12). Many CFCs have been widely used as refrigerants, propellants (in aerosol applications), and solvents. The manufacture of such compounds has been phased out under the Montreal Protocol, and are being replaced with products such as HFCs (e.g., R-410A), hydrocarbons, and CO2, because CFCs contribute to ozone depletion in the upper atmosphere







Nanotechnology Products

Many common products on the market today already make use of nanotechnology:
  • Sun screen -- By using nanoparticles of zinc oxide instead of bulk particles, the cream becomes more transparent.
  • Self-cleaning glass -- A product called Pilkington Activ glass incorporates nanoparticles to keep the glass clear of debris. Upon contact with the sun's rays, the nanoparticles break down unwanted organic particles that have accumulated on the glass. Rain then washes the remains away.
  • Clothing -- By coating fabrics with nanoparticles of zinc oxide, clothing can offer protection from UV radiation or stains.
  • Scratch-resistant coating -- By adding aluminum silicate nanoparticles to the coating, scratch-resistant surfaces become even more effective.
  • Antimicrobial bandages -- By using nanoparticles of silver in bandages, harmful cells are destroyed.
  • Swimming pool disinfectants -- By using nano-sized drops of oil along with bactericide to disinfect pools, the cleaning is more effective.



Fabric Coating Takes the Ouch Out of Speeding Bullets

When a heavy bullet slams into soft body armor, it can cause a lot of damage even without penetrating the fabric. If that armor is coated with Nanorepel, the force will spread out over a much wider area, in effect cushioning the blow. At the moment of impact, a thin layer of organic molecules on the surface of each fiber freezes up, locking the sturdy strands in place. A company called First Choice Armor is using that technology in its N-Force line of vests, which hit the market in the summer of '08.



Nanoparticles Give Power Tools More Juice

As an everyday rechargeable battery releases energy, lithium ions wiggle out from a cobalt oxide cathode and race through a membrane to a carbon anode. Those devices are low in power, wear out quickly, and run the risk of catching fire or exploding.
MIT researcher Yet-Ming Chiang solved all of those problems by replacing the positive electrode with nanoparticles of a new material, lithium iron phosphate, which allows the ions to swiftly slip out and return just as quickly during a recharge cycle. Black and Decker and DeWalt have started using the batteries in high-end power tools, and appear in the Chevy Volt electric car.



Bits of Palm-Tree Wax Hide the Streaks on Your Ride

If you coat your car in an ordinary polish, it will be covered with swirl marks and possibly an unsightly gloss or haze. By formulating their product with bits of carnauba (palm-tree wax) that are only nanometers wide, automotive cosmetics maker Eagle One says it's able to make a coating that always goes on clear.
Since the carnauba wax particles are tremendously small, they appear transparent. Their minuscule size also lets them fill the tiniest flaws and adhere strongly to paint. Sunblock manufacturers accomplish the same trick using zinc oxide.





Semiconductor Nanoparticles Make Printing Solar Cells Affordable

Solar cells are expensive in part because they are hard to make. Most of them are produced in vacuum chambers that use tons of energy to deposit thin layers of semiconductor materials onto a flawless wafer. Nanosolar churns them out at a fraction of the cost by printing nanoparticles on spools of cheap metal foil. The start-up company is currently building larger factories to ramp up production.




Gold Nanoparticles Make Pregnancy Tests Easy to Read

Gold nanoparticles can make the pink "get ready to be a parent" mark on home pregnancy tests much easier to read. When a woman gets pregnant, her body immediately starts making the hormone human chorionic gonadotropin (hCG). As the potential mother urinates into a sample-collection area and the pee migrates to a test strip, some of the antibody-coated gold nanoparticles on the strip latch onto the hCG, migrate up the paper, and collect at an indicator line. If the chemical is not present in her urine, all of the pink nanoparticles will drift up the strip, past the pregnancy-indicator line to a second marker.



Clay Coating Keeps the Air in Tennis Balls

For several years, Wilson Sporting Goods lined its high-end Double Core tennis balls with a composite made from butyl rubber and vermiculite and developed by nanotech company InMat. The clay nanoparticles would spread out like sheets of paper scattered across a floor and keep air molecules from escaping, which kept the balls firm for an unusually long time. But American tennis players didn't want to pay more for a ball that lasted longer, so Wilson discontinued it

.


Aluminosilicate Nanoparticles Stop Bleeding in a Hurry

Nosebleeds can last for hours, but a bandage that has been infused with aluminosilicate nanoparticles--just roll it up and jam it in your nose--can stop them almost immediately. The inorganic specks, which are derived from kaolin clay, trigger the body's natural clotting process. For years doctors have used the same substance to test their patients' blood-clotting ability.
Two chemists at the University of California at Santa Barbara, Sarah Baker and April Sawvel, realized that the material could be used to halt severe bleeding. Their mentor, Galen Stucky, filed a patent and worked with Z-Medica to develop a product that can save wounded soldiers. The technology just hit the civilian market.