Hydrocarbon Product Suppliers Serving Australia Business

Every hydrocarbon product supplied by Refinery Direct meets the very highest Australian and international standards. We source everything from the most reputable suppliers around the world, ensuring exceptional value and product performance for our loyal client base. Explore our product range then contact us to place your order today.

FUEL

We offer fuels and lubricants for all vehicle types from cars and motorcycles to industrial equipment such as trucks, boats and agricultural machinery.

Our range includes Diesel, Unleaded and Premium Unleaded.

Pioneer Petroleum and Solvents deliver the following fuel products:

DIESEL

Refinery Direct supply diesel with:
1.a sulfur content of less than 10ppm (typically 8ppm) to our clients. The low sulfur content ensures cleaner burning and reduces emissions.
2.High Cetane Index of 59 versus Australian standard of 48 which provides greater fuel economy and lower fuel use.

UNLEADED

ULP (Unleaded Petrol) is the most common form of unleaded fuel used by both commercial and domestic spark ignition vehicles. Refinery Direct supply unleaded fuel with Octane 91 (RON) rating.

PREMIUM UNLEADED

Premium Unleaded Octane 95 (PULP) provides greater protection from engine wear. Most modern vehicles are designed to use higher octane fuels and will experience reduced power and efficiency if regular unleaded fuel is used.

METHANOL

METHANOL USE

Methanol is used as a raw material in a wide variety of industrial production processes and as a more environmentally friendly fuel type. We supply high-quality methanol in any quantity you need.

Formaldehyde production for use in MDF and plywood industry
Melamine resin production for use in a range of utensils, inbuilt switches, and industrial glues.
Acetic acid production for use in VAM and cellulose acetate in the textile industry.
Methyl Methacrylate (PMAA) for use in laminates.
Methyl Tertiary Butyl Ether (MTBE) production as a gasoline enhancer.
Producing DME for substituting diesel fuel.
Mixing with petrol for car engine fuel usage.
Producing ethylene and propylene as raw materials.

METHANOL USAGEMETHANOL PRODUCT SPECIFICATION

Analytical Parameter	Method	Unit	Value
Appearance	IMPCA 003-98	-	CFSM
Purity on Dry Basis	IMPCA 001-14	wt%	Min 99.85
Acetone content	IMPCA 001-14	mg/kg	Max 30
Ethanol	IMPCA 001-14	mg/kg	Max 50
Color Pt-Co	ASTM D 1209-11	Pt-Co	Max 5
Water	ASTM E 1064-12	wt%	Max 0.1
Distillation Range at 760 mm Hg	ASTM D 1078-11	°C	Max 1.0
Initial Boiling Point (IBP)	ASTM D 1078-11	°C	Max 64.7
Dry point (DP)	ASTM D 1078-11	°C	Min 64.5
Specific Gravity@20°/20° °C	ASTM D 4052-11	-	0.791 – 0.793
PTT at 15°C	ASTM D 1363-11	Minutes	Min 60
Chloride as Cl-	IMPCA 002-98	mg/kg	Max 0.5
Sulphur	ASTM D 5453-12	mg/kg	Max 0.5
Hydrocarbons	ASTM D 1722-09	Visual	Pass test
Carbon sable Substances (Sulfuric Acid Wash)	ASTM E 346-08	Pt-Co	Max 30
Acidity as Acetic Acid	ASTM D 1613-12	mg/kg	Max 30
Total Iron	ASTM E 394-09	mg/kg	Max 0.1
Non Volatile Matter	ASTM D 1353-13	mg/1000ml	Max 8

ETHANOL

ETHANOL USE

Research into the possibilities of ethanol as an environmental and economic solution is currently ongoing and we can supply bulk quantities of ethanol for a wide range of applications.

Although ethanol could be a part of the environmental and economic solutions surrounding fossil fuels, debates about its efficiency are still being sorted out. Supporters of ethanol say that it adds energy to the economy while naysayers argue that producing ethanol results in a net loss of energy. A study by Argonne National Laboratory concluded that ethanol generated 35% more energy than what it took to produce the batch. Other studies, however, argue that ethanol production actually results in a net loss of energy, which means that it costs more energy to produce ethanol than what the ethanol can give back.

This would be the same thing as starting a business that loses money every quarter. Another problem with ethanol production that farmers are concerned about is the net loss of jobs that ethanol production could potentially create. This is because farmers, in pursuit of higher profits, could abandon livestock pursuits and switch to ethanol production, which requires far less manpower than the livestock sector. Some objectors even argue that ethanol production could decrease global food production.

FUEL GRADE ETHANOL SPECIFICATIONS

Standard Specification for Denatured Fuel Ethanol for Blending with Gasoline for Use as Automotive Spark-Ignition Engine Fuel

Parameter	Specification
Specification	92.1 min
Methanol, % v/v	0.5 max
Water content, % v/v	1.0 max
Denaturant content, % v/v	1.96 min 4.76 max
Solvent-washed gum, mg/100mL	5.0 max
Inorganic chloride content, mass ppm	40 max
Copper content, mg/kg	0.1 max
Acidity as acetic acid, mass % (mg/L)	0.0053 max (In presence of corrosion inhibitors and detergents)
pHe	6.5 to 9.0
Appearance	Visibly free of suspended or precipitated contaminants (clear and bright)

SPECIFICATION

PRODUCT: ETHYL ALCOHOL/ETHANOL-CAS [64-17-5] (HYDROUS)

CHARECTERISTICS	SPECIFICATION
Appearance, suspended matters.	Clear, colourless, volatile liquid, free from
Specific gravity at 20 o /20o C Max.	0.8126
Ethanol content, % v/v at 20o C Min.	95.00
Miscibility with water.	Miscible.
Alkalinity	Nil
Acidity (as Acetic acid), mg/L Max	100.00
Aldehyde content (as Acetaldehyde), mg/L Max	1000.00
Ester content (as Ethyl acetate), mg/L Max.	200.00
Methanol content, mg/L Max.	200.00
Fusel Oil /Higher Alcohol content, mg/L Max	400.00
Furfural content, mg/L Max.	ND
Residue on evaporation % by mass Max.	0.010
Copper (as Cu), mg/L Max.	4.000
Lead (as Pb), mg/L Max.	1.000

MTO

MINERAL TURPENTINE OIL USE

ABOUT REFINERY DIRECT

We supply all types of mineral turpentine oil for a variety of industrial and commercial uses.

Three different types and three different grades of white spirit exist. The type refers to whether the solvent has been subjected to hydrodesulfurization (removal of sulfur) alone (type 1), solvent extraction (type 2), or hydrogenation (type 3).
Each type comprises three grades: low flash grade, regular grade, and high flash grade (flash refers to flash point). The grade is determined by the crude oil used as the starting material and the conditions of distillation.
In addition, there is type 0, which is defined as a distillation fraction with no further treatment, consisting predominantly of saturated C9 to C12 hydrocarbons with a boiling range of 140–200 °C (284–392 °F).

Stoddard solvent is a specific mixture of hydrocarbons, typically over 65% C10 or higher hydrocarbons, developed in 1924 by Atlanta dry cleaner W. J. Stoddard and Lloyd E. Jackson of the Mellon Institute of Industrial Research as a less flammable petroleum-based dry cleaning solvent than the petroleum solvents then in use. Dry cleaners began using the result of their work in 1928, and it soon became the predominant dry cleaning solvent in the United States until the late 1950s.

Turpentine substitute is generally not made to a standard and can have a wider range of components than products marketed as white spirit, which is made to a standard (in the UK, British Standard BS 245, in Germany, DIN 51632). Turpentine substitute can be used for general cleaning but is not recommended for paint thinning as it may adversely affect drying times due to the less volatile components; while it may be used for brush cleaning, its heavier components may leave an oily residue.
In Australia, white spirit is normally sold under the generic name of Shellite (a trademark of Shell Australia), and is composed of C6 to C10 straight alkanes, classing it as light pure naphtha. It is used for fuel and cleaning.

White Spirit is a petroleum distillate used as a paint thinner and mild solvent. In the industry, mineral spirits are used for cleaning and degreasing machine tools and parts, and in conjunction with cutting oil as a thread cutting and reaming lubricant.

Mineral spirits are an inexpensive petroleum-based replacement for vegetable-based turpentine. It is commonly used as a paint thinner for oil-based paint and cleaning brushes, and as an organic solvent in other applications. Mineral turpentine is chemically very different from turpentine, which mainly consists of pinene, and it has inferior solvent properties. Artists use mineral spirits as an alternative to turpentine since it is less flammable and less toxic. Because of interactions with pigments in oil paints, artists require a higher grade of mineral spirits than many industrial users, including the complete absence of residual sulfur.

Mineral spirits were formerly an active ingredient in the laundry soap Fels Naptha, used to dissolve oils and grease in laundry stains, and as a popular remedy for eliminating the contagious oil urushiol in poison ivy. It was removed as a potential health risk.

Mineral spirits have a characteristic unpleasant kerosene-like odor. Chemical manufacturers have developed a low odor version of mineral turpentine which contains less of the highly volatile shorter hydrocarbons. Odorless mineral spirits are mineral spirits that have been further refined to remove the more toxic aromatic compounds and are recommended for applications such as oil painting, where humans have close contact with the solvent.

In screen printing (also referred to as silk-screening), mineral spirits are often used to clean and unclog screens after printing with oil-based textile and plastisol inks. They are also used to thin inks used in making monoprints.

Mineral spirits are often used inside liquid-filled compasses and gauges.

Mineral spirits are used for regripping golf clubs. After the old grip is removed, the mineral spirits are poured into the new grip and shaken. After the mineral spirits are poured on, the new underlying tape and the new grip are slid on. After an hour of drying out, the new grip and club are ready to use.

Although not normally marketed as a fuel, white spirit can be used as an alternative to kerosene in portable stoves, since it is merely a light grade of kerosene. It cannot be used as an alternative to white gas, which is a much more volatile gasoline-like fuel. White spirits are a major ingredient in some popular automotive fuel/oil additives, such as Marvel Mystery Oil, as they are capable of dissolving varnish and sludge buildup.

Mineral spirits are commonly used for cutting fluid in ultraprecision lathes (commonly referred to as diamond turning machines).

CERTIFICATE OF QUALITY

Description of Good : Low Aromatic White Spirit (LAWS) Packed in Flexi Bag
Reference No : Invoice No - AITS/INV/4918/1
Port of Loading : Jebel Ali, Dubai,U.A.E
Port of Discharge : Chennai, India.

We hereby conf irm that the quality of Low Aromatic White Spirit (LAW S) as per our lab repon is as quoted below:

Parameter	Specification
Specification	92.1 min
Methanol, % v/v	0.5 max
Water content, % v/v	1.0 max
Denaturant content, % v/v	1.96 min 4.76 max
Solvent-washed gum, mg/100mL	5.0 max
Inorganic chloride content, mass ppm	40 max
Copper content, mg/kg	0.1 max
Acidity as acetic acid, mass % (mg/L)	0.0053 max (In presence of corrosion inhibitors and detergents)
pHe	6.5 to 9.0
Appearance	Visibly free of suspended or precipitated contaminants (clear and bright)

XYLENE

XYLENE USE

You can order commercial or mixed xylene from us in any quantity and our team can provide expert advice and guidance to help you find the right product.

Commercial or mixed xylene usually contains about 40-65% m-xylene and up to 20% each of o-xylene and p-xylene and ethylbenzene. Xylenes are released into the atmosphere as fugitive emissions from industrial sources, from auto exhaust, and through volatilization from their use as solvents. Acute (short-term) inhalation exposure to mixed xylenes in humans results in irritation of the eyes, nose, and throat, gastrointestinal effects, eye irritation, and neurological effects. Chronic (long-term) inhalation exposure of humans to mixed xylenes results primarily in central nervous system (CNS) effects, such as headache, dizziness, fatigue, tremors, and incoordination; respiratory, cardiovascular, and kidney effects have also been reported. EPA has classified mixed xylenes as a Group D, not classifiable as to human carcinogenicity.

USES

Mixed xylenes are distributed throughout the environment; they have been detected in air, rainwater, soils, surface water, sediments, drinking water, and aquatic organisms. (1)

SOURCES AND POTENTIAL EXPOSURE

Xylenes are released into the atmosphere as fugitive emissions from industrial sources, from auto exhaust, and through volatilization from their use as solvents. (1)
Ambient air concentrations of mixed xylenes in urban areas of the United States range from 0.003 to 0.38 milligrams per cubic meter (mg/m³). (1)
Mixed xylenes have also been detected at low levels in indoor air; xylenes have been widely used in home use products such as synthetic fragrances and paints.
Levels of mixed xylenes in drinking water have been reported to range from 0.2 to 9.9 micrograms per liter (µg/L), with mean concentrations of less than 2 µg/L. (1)
Xylenes are released into the atmosphere as fugitive emissions from industrial sources, from auto exhaust, and through volatilization from their use as solvents. (1)
Occupational exposure to mixed xylenes may occur at workplaces where mixed xylenes are produced and used as industrial solvents. (1)
Xylene exposure may be to any of the three isomers or to mixtures of the isomers. (1)

ASSESSING PERSONAL EXPOSURE

Exposure to mixed xylenes may be determined by measuring the breakdown products of mixed xylenes in the urine or by measuring levels of xylene in blood or exhaled breath. (1)

PHYSICAL PROPERTIES

m-, o-, and p-Xylene are the three isomers of xylene; commercial or mixed xylene usually contains about 40-65% m-xylene and up to 20% each of o- and p-xylene and ethylbenzene. (1)
Mixed xylenes are colorless liquids that are practically insoluble in water and have a sweet odor. (1)
The odor threshold for m-xylene is 1.1 ppm. (4)
The chemical formula for mixed xylenes is C8H10, and the molecular weight is 106.16 g/mol. (1)
The vapor pressure for mixed xylenes is 6.728 mm Hg at 21 °C, and the log octanol/water partition coefficient (log Kow) is 3.12 – 3.20. (1)

SALES SPECIFICATION

The product is warranted to meet the values specified below. Actual values may deviate within the established reproducibility of the test method. In case of dispute, the test methods specified below, or their equivalent, will be used in conjunction with ASTM D 3244,

Standard Practice for Utilization of Test Data to Determine Conformance with Specifications.

Appearance, Visual	Pass
Nitration Grade Xylene, ASTM D 843-95	Complies
Aromatics Content, ASTM D 2306, Vol. %	99 Min.
Benzene Content, GCMS, (ppm)	300 Max.
Color	--
ASTM D 156, Saybolt Units	30 Min.
ASTM D 1209, Platinum-Cobalt Scale	10 Max
Distillation, ASTM D 850	--
IBP, ° C	137 Min
DP,° C	143 Max.
Range,° C	5 MAx.
Specific Gravity, ASTM D 4052	--
@15.6° /15.6° C	0.865 - 0.875

FERTILISERS

We supply a range of commonly used fertilisers, including diammonium phosphate and urea. Ask our team if you have any questions or want to place your order.

DIAMMONIUM PHOSPHATE (DAP)

Diammonium phosphate (DAP) is the world’s most widely used phosphorus fertilizer. It’s made from two common constituents in the fertilizer industry, and its relatively high nutrient content and excellent physical properties make it a popular choice in farming and other industries. Asbestos-filled Melamine resins possess very high dielectric strength and high heat resistance. Besides the best dimensional stability, Melamine Formaldehyde molding powder gives clear and bright colors, is easily moldable, and offers resistance to surface scratching.

PRODUCTION

Ammonium phosphate fertilizers first became available in the 1960s, and DAP rapidly became the most popular in this class of products. It’s formulated in a controlled reaction of phosphoric acid with ammonia, where the hot slurry is then cooled, granulated, and sieved. DAP handles and stores well. The standard nutrient grade of DAP is relatively high, at 18-46-0, so fertilizer products with lower nutrient content may not be labeled DAP.

The inputs required to produce one ton of DAP fertilizer are approximately 1.5 to 2 tons of phosphate rock, 0.4 tons of sulfur (S) to dissolve the rock, and 0.2 tons of ammonia. Changes in the supply or price of any of these inputs will impact DAP prices and availability. The high nutrient content of DAP helps reduce handling, freight, and application costs. DAP is produced in many locations in the world and is a widely traded fertilizer commodity .

CHEMICAL PROPERTIES

Chemica l formula: (NH₄)₂ HPO₄
Composition: 18% N, 46% P₂ 0₅ (20% P)
Water solu bi l ity (20 °C): 588 g/L
Solution pH: 7.5 to 8

AGRICULTURAL USE

DAP fertilizer is an excellent source of P and nitrogen (N) for plant nutrition. It’s highly soluble and thus dissolves quickly in soil to release plant-available phosphate and ammonium. A notable property of DAP is the alkaline pH that develops around the dissolving granule.

Once in the soil, the ammonium ion in DAP is rapidly converted to nitrate by soil bacteria, resulting in a subsequent drop in pH. Therefore, the rise in soil pH surrounding DAP granules is a temporary effect. This initial rise in soil pH neighboring DAP can influence the micro-site reactions of phosphate and soil organic matter.

As dissolving DAP granules release ammonium, the seedlings and plant roots nearest the volatile ammonia can be harmed. This potential damage more commonly occurs when the soil pH is greater than 7, a condition that often exists around the dissolving DAP granule. To prevent such damage, users should avoid placing high concentrations of DAP near germinating seeds.

MANAGEMENT PRACTICES

Differences in the initial chemical reaction between various commercial P fertilizers in soil become minor over time (within weeks or months) and are minimal as far as plant nutrition is concerned. Most field comparisons between DAP and monoammonium phosphate (MAP) show only minor or no differences in plant growth and yield due to P source with proper management.

NON-AGRICULTURAL USES

DAP also acts as a fire retardant. For example, a mixture of DAP and other ingredients can be spread in advance of a fire to prevent a forest from burning. It then becomes a nutrient source after the danger of fire has passed. DAP is used in various industrial processes, too, such as metal finishing. And, it’s commonly added to wine to sustain yeast fermentation and to milk to produce cheese cultures.

PACKING: IN BULK OR BAGS / 50 KG

SPECIFICATION DIAMMONIUM PHOSPHATE

Diammonium phosphate is the most popular phosphatic fertiliser because of its high analysis and good physical properties.

The composition of DAP is N-18% and P2O5-46%.

Moisture % by weight, maximum	2.5
Total N % by weight, minimum	18
Ammonical nitrogen % by weight, minimum	15.5
BIURET	1.0% maximum
Available Phosphorus (as P2O5)% by weight, minimum	46.0
Water Soluble Phosphorus (as P2O5)% by weight, minimum	39.5
Particle size: Minimum 90% of the material be retained on 1 mm and 4 mm IS sieve

UREA

Urea is a white crystalline substance with the chemical formula CO(NH2)2. It is highly soluble in water and contains 46.7% nitrogen. Urea, also known as carbamide, is an organic compound because it contains carbon. It was the first organic compound ever synthesized by chemists; this was accomplished by accident in 1828 by the German chemist Friedrich Wöhler. Urea is made by reacting carbon dioxide (CO2) with anhydrous ammonia (NH3) at pressures above 14,000 kPa (2000 psi) and temperatures above 180 °C in a two-step process: CO2 + 2NH3 → NH2COONH4 → CO(NH2)2 + H2O The water produced during the reaction must be removed by dehydration to maximize the yield. The resulting molten mixture is then further processed into either prills (solidified pellets) or granules. Urea also occurs naturally in urine (hence its name). We each excrete 20 to 30 grams of urea a day. As urea contains 46.7% nitrogen, each tonne supplies 467 kg of nitrogen. For comparison, a tonne of ammonium nitrate supplies only 350 kg of nitrogen, and a tonne of ammonium sulfate supplies only 212 kg of nitrogen. The high nitrogen content means lower transport and application costs per tonne of nitrogen. This depends on the environmental conditions. When soil conditions are favorable for microbial activity – in other words, warm and moist with an appropriate pH – the conversion is rapid and will begin within a few days. In a band application, it may continue for a month or more. Urea contains about one-third more nitrogen, is less corrosive, and is less prone to caking. Also, until nitrification occurs, the nitrogen is less subject to leaching or denitrification than the nitrate portion of the ammonium nitrate.

SPECIFICATION DIAMMONIUM PHOSPHATE

Product	UREA N46 agriculture grade
Nitrogen	46% minimum
Moisture	0.5 max
Free ammonia	160 PXT PPM maximum
BIURET	1.0% maximum
Harmful substances	100 % free from harmful substances
Melting point	132 degree Celsius
Granulation	1mm to 4mm 90% minimum
Color	White standard or white pure
Odor	Odorless
Boiling	Decomposes before boiling
Radiation	Non-radioactive
Physical state	Solid@20°C, 101 KPA white granules
Specific gravity	Solid@20° C-1.35 t/ms
Floatability in water	Sinks and mixes
Molecular weight	60.065
Fertilizer granular	94-96%min
Prill	96% max
Fisher	0.30%

TOULENE

TOLUENE USE

Toluene, also known as methylbenzene is widely used in industrial settings as a solvent and is also an ingredient in some consumer products such as paints, glues, and nail polish removers.
Toluene occurs naturally in crude oil and in the tolu tree. It is also produced during the manufacturing of gasoline and other fuels from crude oil, as well as in making coke, a type of fuel derived from coal used in steel production.

INDUSTRIAL USES

Toluene is typically used in the production of paints, rubber, lacquers, glues, and adhesives because it can help dry, dissolve, and thin other substances. It is used in the production process to make other chemicals, including benzene, nylon, plastics, polyurethane, and in the synthesis of trinitrotoluene (TNT), benzoic acid, benzoyl chloride, and toluene diisocyanate.

PERSONAL CARE PRODUCTS

Toluene has been used as an ingredient in nail polish removers due to its ability to help dissolve other substances, such as resins and plasticizers. It has also been used in the formulation of nail products to enable nail polishes, hardeners, and lacquers to be applied smoothly.

TRANSPORTATION

Toluene is produced in the manufacturing of gasoline, and it is also a gasoline additive that can be used to improve octane ratings for fuel used in race cars and other automobiles.

The higher the octane number or rating, the greater the fuel’s resistance to knocking or pinging during combustion. Toluene is used in these applications because it is dense and contains significant energy per unit of volume, which enhances power generation for vehicles.

Toluene is added to gasoline, used to produce benzene, and used as a solvent. Exposure to toluene may occur from breathing ambient or indoor air affected by such sources. The central nervous system (CNS) is the primary target organ for toluene toxicity in both humans and animals for acute (short-term) and chronic (long-term) exposures. CNS dysfunction and narcosis have been frequently observed in humans acutely exposed to elevated airborne levels of toluene; symptoms include fatigue, sleepiness, headaches, and nausea. CNS depression has been reported to occur in chronic abusers exposed to high levels of toluene. Chronic inhalation exposure of humans to toluene also causes irritation of the upper respiratory tract and eyes, sore throat, dizziness, and headache. Human studies have reported developmental effects, such as CNS dysfunction, attention deficits, and minor craniofacial and limb anomalies, in the children of pregnant women exposed to high levels of toluene or mixed solvents by inhalation. EPA has concluded that there is inadequate information to assess the carcinogenic potential of toluene.

SOURCES AND POTENTIAL EXPOSURE

Xylenes are released into the atmosphere as fugitive emissions from industrial sources, from auto exhaust, and through volatilization from their use as solvents. (1)
Ambient air concentrations of mixed xylenes in urban areas of the United States range from 0.003 to 0.38 milligrams per cubic meter (mg/m³). (1)
Mixed xylenes have also been detected at low levels in indoor air; xylenes have been widely used in home use products such as synthetic fragrances and paints.
Levels of mixed xylenes in drinking water have been reported to range from 0.2 to 9.9 micrograms per liter (µg/L), with mean concentrations of less than 2 µg/L. (1)
Xylenes are released into the atmosphere as fugitive emissions from industrial sources, from auto exhaust, and through volatilization from their use as solvents. (1)
Occupational exposure to mixed xylenes may occur at workplaces where mixed xylenes are produced and used as industrial solvents. (1)
Xylene exposure may be to any of the three isomers or to mixtures of the isomers. (1)

TECHNICAL SPECIFICATION

TEST	METHOD	SPECIFICATION
Colour	5 of IS : 82 -1973	Not darker than freshly prepared solution of 0.8 ml. of 0.1N Potassium Dichromate and 12 ml. of 0.1N of Cobalt Sulphate made up to 1000 ml with water.
At 15/15°C	---	0.8700 to 0.8740
At 27/27°C	---	0.8590 to 0.8630
Distillation range	IS : 5298(1969)	The difference between temperature (running pts) at which 1 & 96% of the volume taken have been collected shall not exceed 0.6°C when a treated sample is tested by standard method. This range shall include the temperature of 110.6°C.
Residue on evaporation, mg/100 ml.	9 of IS:82-1973
Total Sulphur %wt.	Appendix C of IS:537-1967	Max.0.1
Hydrogen Sulphide	Appendix D of IS:537-1967	To pass test
Mercaptan	P:19 of IS:1448	Shall give no positive reaction.
Conforms to specifications of IS:537-1967 Nitration grade of Toluene
In addition BPCL follows the following spec for better customer satisfaction
Acid Wash Colour	D - 848	Not darker than No. 2 Colour Standard.
Distillation	IS:5298-1969	Difference between IBP & DP shall be not more than 1°C

BITUMEN

DEFINITION OF BITUMEN PENETRATION GRADE 60/70

Bitumen Penetration Grade 60/70 is a standard penetration grade Bitumen usually used as a Paving Grade Bitumen suitable for road construction and for the production of asphalt pavements with superior properties. This grade of Bitumen is mainly used in the manufacture of hot mix asphalt for bases and wearing courses. Penetration Grade Bitumen supplied is petroleum grade bitumen, manufactured from fractional/vacuum distillation of crude oil. The Bitumen supplied is produced from the vacuum residue (short residue) feedstock. Penetration Grade bitumens are specified by the penetration and softening point test. The designation is by penetration range only. The penetration grade bitumens have a thermoplastic property which causes the material to soften at high temperatures and to harden at lower temperatures. This unique temperature/viscosity relationship is important when determining the performance parameters such as the adhesion, rheology, durability, and application temperatures of bitumen.

The Bitumen mode is dependent on temperature. The temperature-vs-stiffness relationship of bitumen is dependent on the type of crude oil and its refining method. Bitumen penetration grade 60/70 is semi-hard penetration grade bitumen used as a paving grade bitumen which is suitable for road construction and repair. It is also used for the production of asphalt pavements with the below technical specification. This grade of bitumen is mainly used in the manufacturing of hot mix asphalt for bases and wearing courses. Bitumen penetration grade 60/70 is one of the most used bitumen grades and it’s a basic material for all other bituminous products.
Penetration determines the hardness of bitumen by measuring the depth to which a standard loaded needle will vertically penetrate in 5 seconds, in a sample of bitumen maintained at a temperature of 25 degrees Celsius.

APPLICATION OF BITUMEN PENETRATION GRADE 60/70

Bitumen 60/70 is suitable for road construction and for asphalt pavements with superior properties. This type of bitumen is used in the manufacture of hot mix asphalt for bases and wearing courses.

SPECIFICATION OF BITUMEN PENETRATION 60/70

Bitumen 60/70	Test method	Unit	Specification
Specific gravity @ 25°C	ASTM D70	Kg/cm3	1.01/1.06
Penetration @ 25°C	ASTM D5	Mm/10	60/70
Softening point °C	ASTM D36	°C	42/50
Ductility @25 °C	ASTM D113	cm	100 min
Loss on heating(wt) %	ASTM D6	wt %	0.2 max
Drop in penetration after heating %	ASTM D5-D6	%	20 max
Flashpoint °C	ASTM D92	°C	250 min
Solubility is CS2(wt) %	ASTM D4	wt %	99.5 min
Spot test	A.A.S.H.O.T102	---	Negative

SPECIALTY CHEMICALS

PROPERTIES

Melamine powder is tasteless, odorless, and non-toxic. Melamine formaldehyde resins used for laminates offer good hardness, resistance to scratch, stain, water, and heat. Laminates used in some industrial electrical applications possess high mechanical strength, good heat resistance, and good electrical insulating properties.

Asbestos-filled melamine resins possess very high dielectric strength and high heat resistance. Besides the best dimensional stability, melamine formaldehyde molding powder gives clear and bright colors, is easily moldable, and offers resistance to surface scratching.

APPLICATIONS

Laminates
For table tops, kitchen shelves, platforms, wall cladding, bus bodies, interior of railway coaches, counters, deckings, instrument panels.

Consumer Moulded Goods
Bowls, trays, spatulas, mixer’s base, crockery, cutlery items, launderable buttons, lamp shades.

Industrial Moulded Goods
Circuit breakers, television tube support, automotive ignition components, washing machine, agitators, soda fountain parts, switch gears, switch housings, connector plus inserts, wattmeter terminal block, junction boxes, fuse carriers, plating tanks.

Treatment Resin for Paper
For currencies, toilet paper, facial tissues, shopping and shipping bags, map papers, food wrappers, photographic paper.

Resin for Lacquer Paints
For motorcars, refrigerator cabinets, washing machines, kitchen equipment, typewriters, water heaters.

Adhesives
Melamine adhesives from Melamine resins are extra strong, extra tough, highly water resistant, and colorless (veneered doors).

Melamine Resin for Textile Auxiliaries
For providing anti-crease treatment to cotton and other fabrics.

Leather Chemical
MF resins act as pre-tanning agents.

TECHNICAL SPECIFICATION

Test	Specification
Rapid Test	Clear to sight turbid
Shift during heating	0.8% Max.
Colour Alpha (after filtration)	20 Unit Max.
Moisture	0.1% Max.
Cold Water Insoluble	W:43:0.05% Max.
Bulk Density	800-1100 gm/Ltr.
Assay	99.8% Min.

CHEMICAL IDENTIFICATION

Name	Ferric Chloride Solution (40%+)
Synonyms:	Iron chloride, Iron III Chloride, Iron Tri Chloride
CAS #:	7705-08-0
Formula:	FeCl3
Molecular Wt.	162.2 (100% Basis)
Chemical Classification:	Inorganic Acidic Salt, Solution
ITC Number:	28273300
BIS No:	IS 711:1970
CAS No. :	7705-08-0
EINECS No. :	231-729-4

PHYSICAL AND CHEMICAL DATA

Form	Liquid Solution with 40 % Ferric Chloride in water
Specific Gravity	1.42
Appearance:	Dark Brown Liquid
Boiling Point:	106C (223
PH:	<2 (less than 2)
Solubility in Water:	Complete
Vapour Pressure:	40 mmHg @ 35° C
% Volatile	55-73% (Water)
Evaporation Ratio:	None Found
Odor:	Slightly Acidic

Algaecides are chemicals that kill algae and blue or green algae when they are added to water. Examples are copper sulfate, iron salts, rosin amine salts, and benzalkonium chloride. Algaecides are effective against algae but are not very usable for algal blooms for environmental reasons. The problem with most algaecides is that they kill all present algae, but they do not remove the toxins that are released by the algae prior to death.

ANTIFOAMS

Foam is a mass of bubbles created when certain types of gas are dispersed into a liquid. Strong films of liquid then surround the bubbles, forming large volumes of non-productive foam. The cause of foam is a complicated study in physical chemistry, but we already know that its existence presents serious problems in both the operation of industrial processes and the quality of finished products. When it is not held under control, foam can reduce the capacity of equipment and increase the duration and costs of processes. Antifoam blends contain oils combined with small amounts of silica. They break down foam thanks to two of silicone’s properties: incompatibility with aqueous systems and ease of spreading.
Antifoam compounds are available either as powder or as an emulsion of the pure product.

Powder

Antifoam powder covers a group of products based on modified polydimethylsiloxane. The products vary in their basic properties, but as a group they introduce excellent antifoaming in a wide range of applications and conditions. The antifoams are chemically inert and do not react with the medium that is defoamed. They are odorless, tasteless, non-volatile, non-toxic and they do not corrode materials. The only disadvantage of the powdery product is that it cannot be used in watery solutions.

Emulsions

BIOCIDES

In laboratory tests, a maximum tolerable microbial population limit in systems is determined. When these data are known, in many cases, the number of bacteria and other microorganisms needs serious reduction. This can be accomplished by the addition of biocides; chemical compounds that are toxic to the present microorganisms. Biocides are usually slug-fed to a system to bring about rapid, effective population reductions from which the microorganisms cannot easily recover. There are various different biocides, some of which have a wide range of effects on many different kinds of bacteria. They can be divided up into oxidizing agents and non-oxidizing agents.

Chlorine

Chlorine is the most widely used industrial biocide today. It has been used for disinfection of domestic water supplies and for the removal of tastes and odors from water for a long time. The amount of chlorine that needs to be added in a water system is determined by several factors, namely chlorine demand, contact time, pH, and temperature of the water, the volume of water, and the amount of chlorine that is lost through aeration. When chlorine gas enters a water supply it will hydrolyze to form hypochlorous and hydrochlorous acid. The latter determines the biocidal activity. This process takes place according to the following reaction:

Cl2 + H2O -> HOCl + HCl

Hydrochlorous acid is responsible for the oxidation reactions with the cytoplasm of microorganisms, after diffusion through the cell walls. Chlorine then disturbs the production of ATP (adenosine triphosphate), an essential compound for the respiration of microorganisms. The bacteria that are present in the water will die as a consequence of experienced breathing problems, caused by the activity of the chlorine.
The amount of chlorine that needs to be added for the control of bacterial growth is determined by the pH. The higher the pH, the more chlorine is needed to kill the unwanted bacteria in a water system. When the pH values are within a range of 8 to 9, 0.4 ppm of chlorine must be added. When the pH values are within a range of 9 to 10, 0.8 ppm of chlorine must be added.

Chlorine dioxide

Chlorine dioxide is an active oxidizing biocide that is applied more and more due to the fact that it has less damaging effects on the environment and human health than chlorine. It does not form hydrochlorous acids in water; it exists as dissolved chlorine dioxide, a compound that is a more reactive biocide at higher pH ranges. Chlorine dioxide is an explosive gas, and therefore it has to be produced or generated on-site, by means of the following reactions:
Cl2 + 2 NaClO2 -> 2 NaCl + 2 ClO2
2 HCl + 3 NaOCl + NaClO2 -> 2 ClO2 + 4 NaCl + H2O.

Chloroisocyanurates

Chloroisocyanurates are applied more and more due to the fact that they have less damaging effects on the environment and human health than chlorine. They do not form hydrochlorous acids in water; they exist as dissolved chlorine dioxide, a compound that is a more reactive biocide at higher pH ranges. Chlorine dioxide is an explosive gas, and therefore it has to be produced or generated on-site, by means of the following reactions:
Cl2 + 2 NaClO2 -> 2 NaCl + 2 ClO2
2 HCl + 3 NaOCl + NaClO2 -> 2 ClO2 + 4 NaCl + H2O.

Hypochlorite

Hypochlorite is a salt from hypochlorous acid. It is formulated in several different forms. Usually, hypochlorite is applied as sodium hypochlorite (NaOCl) and calcium hypochlorite (Ca(OCl)2). These compounds can be applied as biocides. They function in very much the same way as chlorine, although they are a bit less effective.

Ozone

Ozone is naturally unstable. It can be used as a powerful oxidizing agent when it is generated in a reactor. As a biocide, it acts in much the same way as chlorine; it disturbs the formation of ATP, so that the cell respiration of microorganisms will be made difficult. During oxidation with ozone, bacteria usually die from the loss of life-sustaining cytoplasm. While the oxidation process takes place, ozone splits into oxygen and an ozone atom, which is lost during the reaction with cell fluids of the bacteria:
O3 -> O2 + (O)
A number of factors determine the amount of ozone required during oxidation, these are pH, temperature, organics and solvents, and accumulated reaction products. Ozone is more environmentally friendly than chlorine because it does not add chlorine to the water system. Due to its decomposition to oxygen, it will not harm aquatic life. Usually, 0.5 ppm of ozone is added to a water system, either on a continuous or intermittent basis.

Non-oxidizing agents:

Acrolein

Acrolein is an extremely effective biocide that has an environmental advantage over oxidizing biocides because it can easily be deactivated by sodium sulfite before discharge to a receiving stream. Acrolein has the ability to attack and distort protein groups and enzyme synthesis reactions. It is usually fed to water systems as a gas in amounts of 0.1 to 0.2 ppm in neutral to slightly alkaline water. Acrolein is not used very frequently, as it is extremely flammable and also toxic.

Amines

Amines are effective surfactants that can act as biocides due to their ability to kill microorganisms. They can enhance the biocidal effect of chlorinated phenolics when they are applied in water.

Chlorinated phenolics

Chlorinated phenolics, unlike oxidizing biocides, have no effect on the respiration of microorganisms. However, they do induce growth. The chlorinated phenolics first adsorb to the cell wall of microorganisms by interaction with hydrogen bonds. After adsorption to the cell wall, they will diffuse into the cell where they go into suspension and precipitate proteins. Due to this mechanism, the growth of the microorganisms is inhibited.

Copper salts

Copper salts have been used as biocides for a long time, but their use has been limited in recent years due to concerns about heavy metal contamination. They are applied in amounts of 1 to 2 ppm. When the water that is treated is located in steel tanks, copper salts should not be applied because of their ability to corrode steel. Copper salts should not be used in water that will be applied as drinking water either because they are toxic to humans.

Organo-sulfur compounds

Organo-sulfur compounds act as biocides by inhibiting cell growth. There are a variety of different organo-sulfur compounds that function in different pH ranges. Normally, energy is transferred in bacterial cells when iron reacts from Fe3+ to Fe2+. Organo-sulfur compounds remove the Fe3+ by complexing as an iron salt. The transfer of energy through the cells is then stopped and immediate cell death will follow.

Quaternary ammonium salts

Quaternary ammonium salts are surface-active chemicals that generally consist of one nitrogen atom, surrounded by substitutes containing eight to twenty-five carbon atoms on four sides of the nitrogen atom. These compounds are generally most effective against bacteria in alkaline pH ranges. They are positively charged and will bond to the negatively charged sites on the bacterial cell wall. These electrostatic bonds will cause the bacteria to die from stresses in the cell wall. They also cause the normal flow of life-sustaining compounds through the cell wall to stop, by declining its permeability. Use of quaternary ammonium salts is limited due to their interaction with oil when this is present and the fact that they can cause foaming.

OXYGEN SCAVENGERS

Oxygen scavenging means preventing oxygen from introducing oxidation reactions. Most of the naturally occurring organics have a slightly negative charge. Due to that, they can absorb oxygen molecules, because these carry a slightly positive charge, to prevent oxidation reactions from taking place in water and other liquids. Oxygen scavengers include both volatile products, such as hydrazine (N2H4) or other organic products like carbohydrazine, hydroquinone, diethylhydroxyethanol, methylethylketoxime, but also non-volatile salts, such as sodium sulfite (Na2SO3) and other inorganic compounds, or derivatives thereof. The salts often contain catalyzing compounds to increase the rate of reaction with dissolved oxygen, for instance, cobalt chloride.

PH CONDITIONERS

Municipal water is often pH-adjusted to prevent corrosion from pipes and to prevent the dissolution of lead into water supplies. During water treatment, pH adjustments may also be required. The pH is brought up or down through the addition of basics or acids. An example of lowering the pH is the addition of hydrogen chloride, in case of a basic liquid. An example of bringing up the pH is the addition of sodium hydroxide, in case of an acidic liquid. The pH will be converted to approximately seven to seven and a half, after the addition of certain concentrations of acids or bases. The concentration of the substance and the kind of substance that is added depend on the necessary decrease or increase of the pH.

RESIN CLEANERS

Ion exchange resins need to be regenerated after application, after that, they can be reused. But every time the ion exchangers are used, serious fouling takes place. The contaminants that enter the resins will not be removed through regeneration; therefore, resins need cleaning with certain chemicals. Chemicals that are used are, for instance, sodium chloride, potassium chloride, citric acid, and chlorine dioxide. Chlorine dioxide cleansing serves the removal of organic contaminants on ion exchange resins. Prior to every cleaning treatment, resins should be regenerated. After that, in the case chlorine dioxide is used, 500 ppm of chlorine dioxide in a solution is passed through the resin bed and oxidizes the contaminants.

SCALE INHIBITORS

Scale is the precipitate that forms on surfaces in contact with water as a result of the precipitation of normally soluble solids that become insoluble as temperature increases. Some examples of scale are calcium carbonate, calcium sulfate, and calcium silicate. Scale inhibitors are surface-active negatively charged polymers. As minerals exceed their solubilities and begin to merge, the polymers become attached. The structure for crystallization is disrupted, and the formation of scale is prevented. The particles of scale combined with the inhibitor will then be dispersed and remain in suspension. Examples of scale inhibitors are phosphate esters, phosphoric acid, and solutions of low molecular weight polyacrylic acid.

CAUSTIC SODA USES

Due to the properties of caustic soda, it is used in many different industries. Here is a brief list of these industries:

Food Industry: milk industry, canning, olive sweetening, water treatment, chocolate production, cocoa and caramel production, vegetable and fruit washing, soft drinks, oil refining, sugar, and sugar production.
Metal and Electroplating Industries: metal, zinc, aluminum, galvanizing and electroplating, glass.

In the pharmaceutical industry
In the cosmetic industry
In the alcohol industry
In the battery industry and neutralizing the acid
In the ceramic tile industry
In the industries of detergents and soaps

In the paper and carton industry
In the oil and gas industry
In the textile and leather industries
In Rose Painting Industries
In oil and gas and petrochemical industries
In the chemical industry

In the silk industry
In laboratories to determine the concentration of acids in experiments
In the glue manufacturing industry
In industries as the disinfectant
Recovery of rubber

Caustic soda, known as Sodium Hydroxide, is a chemical substance used in various industries. It is an odorless, white crystalline, transparent, non-volatile, and highly corrosive compound that easily absorbs air humidity. When dissolved in water or neutralized with acid, it produces a considerable amount of heat.

FEATURES

Caustic soda has a variety of features, which make this highly consumable material in many industries very popular. Among these features are the following:

Strong fat and oil remover
Neutralize acidic environments
PH adjuster

TECHNICAL SPECIFICATIONS OF CAUSTIC SODA

Brand	Caustic Soda
Scientific name	Sodium Hydroxide
Chemical formula	Na-OH
Melting point	1390 ° C
Density	2.13
The molecular weight of caustic soda	01/40
The melting point of interest	12 ° C
Spot boiling point	140 ° C
Relative density of percolation	53.1% (50% solution), 2 at 5.5 ° C (solution 73% -70%)
Peroxide solubility in water	109 g / 100 ml at 20 ° C

INDUSTRIAL AND AUTOMOTIVE LUBRICANTS

REFINERY DIRECT SYNOL PLUS 10W40 4STROKE MOTORCYCLE OIL

SAE Viscosity grade	10W-40
Viscosity @ 100ºC, cSt (ASTM D445)	15.07
Viscosity, @ 40ºC, cSt (ASTM D445)	101.1
Apparent Viscosity by CCS @ -25ºC (cP) ASTM D5293	5270
Apparent Viscosity by MRV @ -30ºC (cP) ASTM D4684	18400
Viscosity Index ASTM D2270	156
Density @15.6 ºC, mg/l (ASTM D4052)	0.8613
Sulfated Ash (mass%) ASTM D874	0.9
Total Base Number(mg KOH/g) ASTM D2896	9.8
Flash Point, ºC (ASTM D92)	226

REFINERY DIRECT SYNOL POWER 5W30 CAR/LCV ENGINE OIL(PETROL/DIESEL)

SAE Viscosity grade	5W-30
Viscosity @ 100ºC, cSt (ASTM D445)	10.45
Viscosity, @ 40ºC, cSt (ASTM D445)	36.31
Apparent Viscosity by CCS @ -30ºC (cP) ASTM D5293	5940
Apparent Viscosity by MRV @ -35ºC (cP) ASTM D4684	29000
Viscosity Index ASTM D2270	154
Density @15.6 ºC, mg/l (ASTM D4052)	0.8554
Sulfated Ash (mass%) ASTM D874	0.9
Total Base Number(mg KOH/g) ASTM D2896	7.9
Flash Point, ºC (ASTM D92)	223

REFINERY DIRECT SYNOL MAGNET 15W50 4STROKE MOTORCYCLE

SAE Grade	15W-50
Viscosity, ASTM D 445
cSt @ 40º C	125
cSt @ 100º C	17.4
Viscosity Index, ASTM D 2270	153
Sulfated Ash, wt%, ASTM D 874	1.3
HTHS Viscosity, mPa·s @ 150º C, ASTM D 4683	5.11
Pour Point, ºC, ASTM D 97	-45
Flash Point, ºC, ASTM D 92	226
Density @15º C kg/l, ASTM D 4052	0.864

REFINERY DIRECT SYNOL CRISTAL 5W40 CAR/LCV ENGINE OIL(PETROL/DIESEL)

SAE Viscosity grade	5W-40
Viscosity @ 100ºC, cSt (ASTM D445)	13.33
Viscosity, @ 40ºC, cSt (ASTM D445)	82.21
Apparent Viscosity by CCS @ -30ºC (cP) ASTM D5293	5610
Apparent Viscosity by MRV @ -35ºC (cP) ASTM D4684	24700
Viscosity Index ASTM D2270	164
Density @15.6 ºC, mg/l (ASTM D4052)	0.8561
Sulfated Ash (mass%) ASTM D874	1.2
Total Base Number(mg KOH/g) ASTM D2896	9.9
Flash Point, ºC (ASTM D92)	222

REFINERY DIRECT SYNOL PROCARE 15W40 DIESEL ENGINE OIL(HEAVY VEHICLES)

Properties	-	-	Method	R4 15W-40
Viscosity Grade	-	-	-	15W-40
Kinematic Viscosity	@40°C	mm²/ s	ASTM D445	109
Kinematic Viscosity	@100°C	mm²/ s	ASTM D445	4.7
Dynamic Viscosity	@-20°C	mPa s	ASTM D5293	6700
Viscosity Index	-	-	ASTM D2270	139
Total Base Number	-	mg KOH/ g	ASTM D2896	10
Sulphated Ash	-	wt	ASTM D874	1.2
Density	@15°C	kg/ l	ASTM D4052	0.888
Flash Point (COC)	-	°C	ASTM D92	230
Pour Point	-	°C	ASTM D97	-36

REFINERY DIRECT SYNOL MAGNET 15W50 4STROKE MOTORCYCLE

SAE Grade	15W-50
Viscosity, ASTM D 445
cSt @ 40º C	125
cSt @ 100º C	17.4
Viscosity Index, ASTM D 2270	153
Sulfated Ash, wt%, ASTM D 874	1.3
HTHS Viscosity, mPa·s @ 150º C, ASTM D 4683	5.11
Pour Point, ºC, ASTM D 97	-45
Flash Point, ºC, ASTM D 92	226
Density @15º C kg/l, ASTM D 4052	0.864