Archives November 2020

The main use of hexane is as a solvent to extract edible oils from seed and vegetable crops (e.g., soybeans, peanuts, corn). (6) Commercial grades of hexane are used as solvents for glues (rubber cement, adhesives), varnishes, and inks. (3,6) Hexane is also used as a cleaning agent (degreaser) in the printing industry.

Hexane is used as the liquid in low temperature thermometers. Rubber cement is an adhesive made from elastic polymers (typically latex) mixed in a solvent such as acetone, hexane, heptane or toluene to keep them fluid enough to be used. Water-based formulas, often stabilised by ammonia, are also available. There are even paper specific rubber cements, used by paper crafters and scrapbookers worldwide!Rubber cement is an opaque liquid that contains pulverized natural or synthetic rubber and a solvent based on hexane or heptane. Grades of rubber cement may contain 70-90% heptane or hexane and 1-15% isopropyl alcohol (isopropanol) or ethyl alcohol . The rubber is received in the form of large blocks or slabs, typically 100 lb (45 kg) in size. Different grades of rubber cement may contain pulverized natural or synthetic rubber in combination with 70 percent to 90 percent heptane or hexane and 1 percent to 15 percent isopropanol or ethanol. Solvent percentage and resultant strength may or may not produce a rubber cement that can dissolve vinyl.

What is the solvent in rubber cement?
Silicone is a typical example. Rubber cement is an opaque liquid that contains pulverized natural or synthetic rubber and a solvent based on hexane or heptane. Grades of rubber cement may contain 70-90% heptane or hexane and 1-15% isopropyl alcohol (isopropanol) or ethyl alcohol (ethanol).

What is rubber adhesive?
Keeping the rubber in a solvent solution allows the rubber to remain fluid enough to be spread and used as an adhesive. These cements are considered drying adhesives, meaning that as the solvents evaporate, the “rubber” portion remains behind, ready to form a strong and flexible bonds.

What is solvent based contact adhesive?
Solvent-based contact adhesive formulations typically consist of a solvent or solvent blend, in which rubber, resin, and additives such as anti-oxidants, fillers etc. are dissolved. 

Can you use toluene solvent to remove cement?
If you are needing to remove cement that is still stuck to your surface with a solvent, you should use the same solvent that your contact cement is suspended in. Like with like. This means if you have a toluene based glue, you could apply toluene solvent to a rag and soak your dried cement to see if you can work it up that way.

The high adhesion properties of SB thermoplastic rubber-based adhesives mean that they often only have to be applied to one of the two substrates to be bonded (single spread).They generally have a high solid content that reduces the amount of adhesive required per unit of bonded surface area and the quantity of solvent emissions.
Chloroprene rubber adhesive is a solution type adhesive among widely-used rubber adhesives. It is made up of neoprene, magnesium oxide, anti-aging agent, antioxidant and filler etc., mixed and then resolved in solvent. Such adhesive has good resistance to water, oil, weak-acid, weak-alkali, aliphatic hydrocarbon and alcohols

What is chloroprene rubber adhesive?
Chloroprene rubber adhesive is a solution type adhesive among widely-used rubber adhesives. It is made up of neoprene, magnesium oxide, anti-aging agent, antioxidant and filler etc., mixed and then resolved in solvent.

Is acetone a good solvent for rubber?
Acetone is a good one on rubber, the other solvents make rubber swell. We clean the rubber gaskets on our dry time wheel with acetone, it is also easier on paint as it is a very fast evaporating solvent. I would not pur it in a bath but use a rag or paper towell.

What is rubber adhesive?
Chloroprene Rubber Adhesive (CR) Chloroprene rubber adhesive is a solution type adhesive among widely-used rubber adhesives. It is made up of neoprene, magnesium oxide, anti-aging agent, antioxidant and filler etc., mixed and then resolved in solvent.

What is rubber adhesive?
Chloroprene Rubber Adhesive (CR) Chloroprene rubber adhesive is a solution type adhesive among widely-used rubber adhesives. It is made up of neoprene, magnesium oxide, anti-aging agent, antioxidant and filler etc., mixed and then resolved in solvent.

What is rubber chemical resistance?
Use this rubber chemical resistance chart to make sure that the elastomer or O-ring seal you choose will be compatible with the particular environment. The chemical compatibility of rubber is extremely important as the rubber can degrade rapidly if the rubber material is not compatible with the environment or media that it comes into contact with.

This week, the overall price of hydrocarbon structured products (n-Pentane, n-Hexane and n-Heptane) rose, sporadically stable, mainly due to the price rise of raw materials, the price of pentane blends (foaming agents) products fell slightly.

The price of n-Octane products decreased slightly this week.

“Pentane product market weekly analysis report” is a weekly summary report which provides analysis and forecast of pentane product short-term price and influencing factors. This information is based on the domestic market, through the analysis of pentane market short-term market changes, for enterprises to research the market, decision-making operation and to provide support.

• Biden’s victory is expected to warm up, the scale of the new fiscal stimulus may shrink, and the policy toward Iran may ease or improve its supply recovery, and international oil prices will fall. In terms of gasoline, the rise of gasoline price was relatively small, and the enthusiasm of the middle and lower reaches of the market was fair, but most of them were small and just needed to be purchased. In terms of mixed C5, the shipment was generally good yesterday, with refinery inventory falling to a medium low level, but crude oil closed down. It is expected that the market will maintain stability today.
• The market prices of high purity n-Pentane, n-Heptane and n-Hexane remain firm. The price of n-Pentane with a purity of 95% varies greatly.
  After several days of continuous price decline, the current market price is relatively stable, there is no price change on pentane blends today.
• For customers who need to pack n-pentane in drums, please note that the drums suitable for international transportation belong to class I packaging, and the drums used for domestic delivery are usually class II packaging, and the product performance of the two is also different. At present, there is a difference of 300 yuan per ton between the first class and the second class, which is 45.30 US dollars at today’s real-time foreign exchange rate.

• The price of pentane blends is stable at present.
• The Chinese market for n-Pentane, Isopentane, Pentane Blends/pentane blowing/foaming agent, n-Heptane market inquiries are active.
• The price of n-Heptane in the Chinese market rose slightly, which supported the market. The supply of n-Heptane is in short supply, and the market is slightly firm.
• The Solvent Oil/D Series fluid market in China is still weak, and the price may continue to move downward. At present, the inventory of solvent oil raw materials is relatively sufficient, the intention of large-scale purchase is not high, and the export is also reduced. The domestic inventory is facing the risk of recovery, in the near future, the market price will decrease slightly.
• At present, the transaction price of high purity n-Hexane is on the high side in the Chinese market, and the orders of various manufacturers are still relatively concentrated. Moreover, all factories need to carry out annual maintenance, and the stock shortage situation is persistent. Moreover, the market price of n-Hexane raw materials is too high, which leads to the shortage situation in the short term, and the price keeps rising steadily.
• At present, the volume of n-Octane in the Chinese market is scarce, the market price is falling, and the orders are scarce.

Price Information Bulletin – Real-time price updates – n-Heptane price adjustment – n-Octane price today – n-Octane price update (November 4, 2020) price information
According to the news just released by the market information center, the price of n-Octane has come down just now. Compared with the previous day’s public ex-Factory price, the price has decreased by 500 yuan, and the price has decreased by 74.3 US dollars according to the real-time exchange rate between us dollar and RMB at 12:34 p.m. today, November 4, 2020. The price fell by 6.25% on a daily basis.

Octane
Chemical Compound
Octane is a hydrocarbon and an alkane with the chemical formula C₈H₁₈, and the condensed structural formula CH₆CH₃. Octane has many structural isomers that differ by the amount and location of branching in the carbon chain. One of these isomers, 2,2,4-trimethylpentane is used as one of the standard values in the octane rating scale.
Density: 0.70 g/cm³
Boiling point: 257°F (125°C)
Chemical formula: C8H18
Average Molar mass: 114.23 g/mol
Melting point: -70.60°F (-57°C)
IUPAC ID: Octane

n-Octane for synthesis; CAS Number: 111-65-9; Synonym: n-Octane; Linear Formula: C8H18; Manufacturer: Junyuan Petroleum Group

According to the price information just released by the marketing department, the factory price of pentane blend (pentane foaming agent) has dropped by 7.49 US dollars / ton today. The price is 1.35 percentage points lower than yesterday. The prices of n-pentane, n-hexane and n-heptane remained relatively stable this week after rising at the end of October last month.

n-Hexane (normal hexane) is a colourless, volatile liquid. 
Commercial hexane is mainly a mixture of hexane isomers and related 
6-carbon compounds, and has an  n-hexane content varying between 20 
and 80%.  Gas chromatography coupled with flame ionization 
detection or mass spectroscopy is a suitable technique for the 
measurement of  n-hexane.  Occupational exposure limits range from 
100 - 1800 mg/m3 (time-weighted average, TWA) and 400 - 1500 mg/m3 
(ceiling value, CLV) in various countries. 

     n-Hexane can be isolated from natural gas and crude oil.  It is 
used in food processing, including the extraction of vegetable oil, 
and as a solvent in various products and processes. 

    Once emitted into the environment,  n-hexane exists 
predominantly in the vapour phase.  In the atmosphere its half-life 
is estimated to be approximately 2 days, based on its reactivity 
with the OH radical alone.  Reported LC50 values for aquatic 
organisms are few and variable and have been conducted under 
inappropriate conditions; an assessment of the toxic effects of 
 n-hexane in this environment is, therefore, not possible.  Low 
water solubility and high volatility make exposure of aquatic 
organisms unlikely except from uncontrolled discharge into surface 
waters. 

    In mammals,  n-hexane is absorbed rapidly through the lungs and 
is distributed widely in the adult body, as well as to fetal 
tissue.  Dermal absorption is limited.   n-Hexane is metabolized 
oxidatively to a number of compounds, including 2,5-hexanedione, 
which is thought to be the ultimate neurotoxic agent.  Particularly 
high levels of  n-hexane and 2,5-hexanedione can occur in the 
sciatic nerve of rats.  Most  n-hexane is excreted unchanged in 
exhaled air; some is excreted as metabolites in exhaled air and 
urine. 

     n-Hexane is of low acute toxicity for adult rats by oral 
administration or inhalation.  Oral LD50 values of 15 - 30 g/kg 
have been recorded, and an inhalation LC50 value of 271 040 mg/m3 
(77 000 ppm) has been reported for a 1-h exposure.  At high vapour 
concentrations, animals show ataxia, seizures, and signs of central 
nervous system depression. 

    Testicular lesions and neurotoxicity appear to be the principal 
effects of repeated  n-hexane exposure in rats.  Severe testicular 
lesions have resulted from inhalation exposure to  n-hexane and oral 
exposure to 2,5-hexanedione.  Effects have been attributed to 
disruption of the cytoskeleton of Sertoli cells.  There are 
secondary effects on post-spermatogonial germ cells, which 
disappear from affected tubules.  Testicular effects were 
reversible after a single exposure for 24 h to 17 600 mg/m3 (5000 
ppm) but irreversible after a 2-week exposure to the same 
concentration for 16 h/day, 6 days/week.  2,5-Hexanedione at 1% in 
drinking-water produced similar reversible testicular lesions after 
2 to 3 weeks of dosing and irreversible effects (within 17 weeks) 
after 5 weeks of dosing. 

    The neurotoxic effect is characterized clinically by hindlimb 
weakness, which can progress to paralysis.  Axonal swellings 
develop in the central and peripheral nervous systems; more severe 
lesions (axonal degeneration and loss) can occur, particularly in 
the longest, largest-diameter nerves.  In essentially continuous 
6-month inhalation studies, peripheral and central nervous system 
lesions were present at doses of 1760 mg/m3 (500 ppm) or more, but 
no clinical or pathological effects were noted at 440 mg/m3 (125 
ppm).  Only limited recovery of amplitude of the fifth brainstem 
auditory-evoked response (believed to reflect central nervous 
system activity) and tail nerve action potential was recorded 15 - 
22 weeks after cessation of continuous exposure to a vapour 
concentration of 3520 mg/m3 (1000 ppm), 5 days/week, for 11 weeks. 
Discontinuous exposure of rats to 3168 mg/m3 (900 ppm) for 72 weeks 
did not cause any apparent peripheral or central nervous system 
lesions, but there was some evidence of electrophysiological 
effects on peripheral nerves. 

     n-Hexane-induced neurotoxicity can be enhanced by combined 
exposure to methyl ethyl ketone, methyl isobutyl ketone, and lead 
acetate, and decreased by co-exposure to toluene.  Toluene and 
 n-hexane also have a synergistic effect in the disturbance of 
dopamine levels. 

    Severe microscopic lesions were noted in skin when  n-hexane 
was applied dermally under occlusive conditions for short periods. 
Prolonged exposure to an  n-hexane vapour concentration of 10 560 
mg/m3 (3000 ppm) can cause conjunctival irritation in rats and 
marked ocular irritation in rabbits.  No skin sensitization data 
are available from animal studies. 

    Chromosomal damage (polyploidy in one study, structural 
aberrations in a second study) has been reported in both  in vitro
and  in vivo studies.  No increase in point mutation frequency or 
effects in tests for DNA damage has been noted. 

    There has been one carcinogenicity study with  n-hexane (skin 
painting on mice), which provided no evidence of carcinogenicity. 

    The reproductive toxicity of  n-hexane has not been studied 
adequately.  There was no substantial evidence of embryotoxicity or 
teratogenicity in rats following inhalation, though concentrations 
were relatively low, or in mice after oral dosing.  Postnatal 
development of rats was transiently delayed when dams were exposed 
to an  n-hexane vapour concentration of 3520 mg/m3 (1000 ppm). 

    Very little information is available on the acute toxicity of 
 n-hexane to humans.  Most studies have involved occupational 
exposure to solvent mixtures.  The available data suggest that 
 n-hexane has low acute toxicity.  Signs of central nervous system 
depression, such as drowsiness, vertigo, and giddiness, have been 
reported after exposure to a commercial hexane level of 3520 to 
17 600 mg/m3 (1000 - 5000 ppm) for 10 - 60 min. 

     n-Hexane is a mild irritant causing transient erythema when in 
contact with human skin for short periods.  More severe effects 
(erythema and blistering) were documented after occlusive skin 
contact for 5 h with commercial grade hexane.  There have been no 
case reports of sensitization of skin in exposed workers, and no 
skin sensitization was noted in a maximization test with  n-hexane. 

    On repeated exposure,  n-hexane is neurotoxic, inducing a type 
of sensorimotor peripheral neuropathy.  Many studies on the 
prevalence of  n-hexane-induced neurotoxicity have been published; 
however, adequate exposure data are often lacking.  Exposure to 
 n-hexane concentrations in air varying from 106 - 8800 mg/m3 
(30 - 2500 ppm) has been associated with neuropathy.  Cases of 
marked peripheral neuropathy were reported among Japanese sandal 
workers and Taiwanese press proofers exposed to  n-hexane levels of 
approximately 176 and 352 mg/m3 (50 and 100 ppm), respectively, for 
periods exceeding 8 h per day.  In many cases exposure measurements 
were recent and probably did not accurately reflect previous 
exposures causing neuropathy. 

    Several cross-sectional studies have independently reported 
mild subclinical effects (for example, electrophysiological 
changes in peripheral nerves) in workers exposed to 70 - 352 mg/m3 
(20 - 100 ppm).  However, no clear cases of clinically overt 
peripheral neuropathy were identified in any of these studies at 
exposure levels of less than 352 mg/m3 (100 ppm). 

    The effects of  n-hexane on the central nervous system have been 
investigated only in a few studies.  Changes in somatosensory 
evoked potentials recorded from workers exposed to  n-hexane were 
suggested to result from a central nerve conduction block.  Altered 
visual evoked potentials and EEG traces have also been noted. 
These results suggest that  n-hexane may produce central nervous 
system dysfunction, but the available data provide no information 
on related exposure levels. 
Identity 
Common synonyms: Hexyl hydride, hexane, Skellysolve 
B Chemical structure:
     H H H H H H
    | | | | | |
    | | | | | |
H---C---C---C---C---C---C---H
    | | | | | |
    | | | | | |
     H H H H H H
Chemical formula: C6H14
CAS registry number: 110-54-3
Relative molecular mass: 86.177
Physical and chemical properties
Some physical and chemical properties of various grades of
n-hexane are given in Table 1.
Table 1. Physical and chemical properties of n-hexanea
Boiling point (°C) 68.74b
Melting point (°C) -95.35b
Relative density (20 °C/4 °C) 0.66
Vapour pressure (25 °C) 20 kPa (150 mmHg)
Vapour density 2.97
Autoignition temperature (°C) 225
Explosive limit in air (% by volume) 1.1-7.5
Flash point (°C) -21.7
Closed-cup flash point (°C)c -30.56
Solubility in water (mg/litre at 25 °C) 9.5
Log n-octanol/water partition coefficient
(log Pow at 25 °C) 3.6
Refractive index (20 °C) 1.37
Colour, Saybolt +39
a From: Mellan (1977)and IRPTC (1990).
b From: Clayton & Clayton (1981).
c From: ACGIH (1986).
n-Hexane is colourless, highly volatile (NIOSH, 1977a), and
flammable (Dale & Drehman, 1980; ACGIH, 1986). It is poorly
soluble in water but is soluble in most organic solvents including
ethanol and ether (McAuliffe, 1963; NIOSH, 1977a; ACGIH, 1986).
Purified n-hexane contains 95 - 99.5% n-hexane, together with
small amounts of other hexane isomers as impurities (Mellan, 1977;
Baker & Rickert, 1981; Sandmeyer, 1981). Traces of benzene (0.05%)
have been detected (Baker & Rickert, 1981). Commercial hexane is a
mixture of hexane isomers ( n-hexane, 2-methylpentane,
3-methylpentane, 2,3-dimethylbutane), cyclohexane, methyl
cyclopentane and small amounts of pentane and heptane isomers,
acetone, methyl ethyl ketone, dichloromethane, and
trichloroethylene (Perbellini et al., 1981a,b,c; ACGIH, 1986). The
n-hexane content of commercial hexane (Table 2) can vary between
20% and 80% (ACGIH, 1986).
Table 2. Composition (% by weight) of different
grades of n-hexanea
Research Pure Technical
grade grade grade
n-Hexane 99.98 99.5 95-97.7
2-Methylpentane trace trace trace
3-Methylpentane 0.02 0.1 0.2
Methylcyclopentane trace 0.4 2.1
a From: Mellan (1977).
Pure n-hexane contains approximately 0.0005% of non-volatile
material (Mellan, 1977), whereas commercial hexane may contain up
to 0.04% (Patty & Yant, 1929; Vicedo et al., 1985). In commercial
hexane, a number of phthalate esters (including dimethyl, diethyl,
di- n-butyl, di-isobutyl, dihexyl, and diethylhexyl), adipate
esters (dibutyl and dioctyl), and organophosphorus compounds (e.g.,
triphenyl phosphate) have been identified and total about 0.3% of
the distillation residue (Vicedo et al., 1985).
Commercial hexane (containing about 30% n-hexane) has a
slightly disagreeable odour, perceptible at 282 mg/m3 (80 ppm)
(intermittent exposure) or 528 mg/m3 (150 ppm) (continuous
exposure) (Patty & Yant, 1929). An odour threshold of 211 mg/m3
(60 ppm) for hexane (purity not stated) has also been reported
(Laffort & Dravnieks, 1973).

Normal hexane (n-hexane) is both an anthropogenic and naturally occurring chemical. n-Hexane is a minor constituent of crude oil and natural gas. Its inclusion in a variety of petroleum products is a consequence of refining operations that separate hydrocarbons within specific ranges of boiling points for such uses as heating oils or automotive fuels. It may also be a metabolic byproduct from certain types of fungi (Ahearn et al.1996). Such sources of natural releases are discussed in Chapter 5. In commercial products prepared from the distillation of petroleum, n-hexane has many uses as a special-purpose solvent
and oil extractant. In a highly purified form, n-hexane is used in chemical laboratories as an extractant for a wide range of hydrocarbons and nonpolar organic compounds.
Virtually all n-hexane is obtained from petroleum mixtures through controlled fractional distillation and other refinery-based processes (Speight 1991). n-Hexane can also be synthesized from sugar cane wastes
using special catalysts (SUCRON 1996). This type of synthesis is relatively new and the volume produced is still very limited. The presence of many types of hydrocarbon impurities in many commercial grades of n-hexane, combined with the intentional denaturing of n-hexane preparations to discourage substance abuse, make it difficult to establish odor thresholds for many products containing n-hexane.

Hexane in Solvent extraction method. Hexane in its pure form is a colorless liquid , and its boiling point is between 50℃ – 70℃ all of which work in favor for oil extraction. To begin the process of solvent extraction, oil seeds (soybean, rapeseed etc.) are removed of impurities and dried to reduce moisture content.
Hexane is the solvent that is widely utilized in the process of herbal medicine and bioactive components production and oil industry. Hexane is one of the most commonly used solvents not only in the edible oil industry but also in the process of herbal medicine and bioactive components production.
Edible oils and fats can be produced either by solvent or mechanical extraction of oilseeds. Hexane is one of the most commonly used solvents in the edible oil industry.
Is soybean oil hexane free?
Whole soybeans (edamame) are always a hexane-free and healthy option. Expeller-pressing and cold-pressing are physical methods to extract oils that do not involve solvents, so soy and other vegetable oils produced in this manner are also hexane-free.
Is hexane toxic to humans?
Hexane has a long record of use without as much irritation of human skin or the immediate or severe toxicity of many competitive solvents. It does not mix with water, allowing fairly simple processes to keep it in the system while water passes through the extraction process as moisture in the seed, meal, oil or air.

USE
n-Hexane is used mainly as an edible-oil extractant for a variety of seed crops such as soybeans, cottonseed, rape seed (canola), flax (linseed), mustard seed, peanuts, safflower seed, and corn germ, which are then processed into foods for humans or livestock. While other petroleum-derived solvents (e.g., pentane) or other organic solvents (e.g.,
chloroform, methanol, ethanol, or ammonia-alcohol mixtures) are currently being studied or are used for certain processes, n-hexane has been widely used since the early part of this century, especially with
soybeans, cottonseed, and linseed (Conkerton et al.1995). Part of n-hexane’s appeal relates to aesthetic properties such as preserving the colors of the original plant materials. Different extractant mixtures can also have significant effects on the levels of materials that can cause bitter tastes (e.g., tannins) and on the degree to which certain flatulence-causing sugars are removed. While other solvents could be used in the initial oil extraction phases, several decades of experience in combining the oil-extraction steps with other procedures to preserve desirable colors and eliminate unwanted tastes or other undesirable food properties have worked to maintain a heavy reliance on n-hexane for edible-oil extraction (Lawson 1995). In the
1970s it was estimated that soybean oil extraction alone accounted for approximately 30% of all uses of n-hexane in the United States (HSDB 1996).

n-Hexane has other major uses as a special-purpose solvent and cleaning agent (degreaser) in such industries as textile manufacture, shoe and leather making, and furniture manufacturing (Jorgensen and Chor 1981). It is used in the printing industry as a cleaner and as a component of some inks (EPA 1996c; Wadden et al.1995). Facilities that use rotogravure printers (facilities that produce catalogues, magazines, “glossy” newspaper inserts, or telephone directories) or similar rotogravure or flexographic technologies (for labels, gift wrap, metal foils, flexible packaging materials, and some floor coverings) also use n-hexane (EPA 1996c). While not used in most glues or epoxy cements (Rastogi 1993), n-hexane is the solvent used
in “rubber” cement (also known as gum adhesive) widely used in schools and libraries and by artists (McCann 1992). Various glues, adhesives, and leather-dressing preparations, especially those used in assembling shoes, may contain n-hexane (Cardona et al.1993; Periago et al.1993; Takeuchi et al.1993).
In bookbinding and leather working, n-hexane, often mixed with other hydrocarbon solvents, is used as a carrier for cedar oil, beeswax, or lanolin dressings (Jorgensen and Chor 1981; Roberts and Etherington 1996). n-Hexane is used in some typeover correction (“white-out”) fluids (Ong et al.1993). It has been used in many types of non-mercury thermometers, especially for thermometers used in low temperature ranges (EPA 19948). It has been used as a denaturing agent in some alcohol preparations (HSDB 1996).
New roofing materials using rubber or plastic films and membranes held together by adhesives, sealants, or hardening agents may contain n-hexane (Herbert et al.1995). It may be used as a carrier or aerosol (propellant) agent in some perfumes (Bouhamra 1995; Jorgensen and Chor 1981). It is used in the pharmaceutical industry to help shape pills and tablets, which are then dried to vent off the n-hexane before packaging (Jorgensen and Chor 1981). In the petrochemical industry, lighter alkane fractions including n-hexane may be used as feedstocks in the manufacture of polyethylene or polypropylene (Jorgensen and Chor 1981). In canning operations, the ends of tin cans are held in place with adhesives that commonly contain n-hexane (Bachmann et al.1993). The balls used in several sports (e.g., baseball) have cores wrapped with strings or yarns, which are often held in place with adhesives containing n-hexane (Huang et al.1991). In the manufacture of truck and automobile tires, n-hexane is a solvent in mixtures (called “thinners”) used to adjust the viscosity of the rubber while it is being polymerized and formed into tires (Jorgensen and Chor 1981; Van Ert et al.1980). n-Hexane is apparently in the adhesives for certain types
of tapes, bandages, and dressings used in hospitals (Jorgensen and Chor 198I). Adhesives, cleaners, or lacquers containing n-hexane are also used to prepare the veneers used in making many types of furniture or ornamental boxes (Graham et al.1995).
Pure n-hexane is widely used in laboratories as an extractant for nonpolar compounds and in calibrating instruments for analyses of volatile organic compounds (VOC) or total petroleum hydrocarbons (TPH) (Kanatharana et al.1993). Since such analyses may require very high levels of purity, laboratories sometimes carry out their own fractional distillation or other pretreatment-purification procedures to remove petroleum hydrocarbon impurities found in commercially available grades of n-hexane
(Kanatharana et al.1993). Request a quote or for more information about testing for n-hexane, please email us at: info@junyuanpetroleumgroup.com.
Finally, n-hexane may be a component of many types of commercial preparations or in mixtures produced in small batches on-site such as paint thinners, general-purpose solvents, degreasing agents, or cleaners.
For instance, until the 1970s naphtha, a mixture with a high n-hexane content, was widely used as a dry cleaning agent. Since the early 1900s construction workers, metal workers, janitors, furniture workers, motor-vehicle mechanics, and print-shop workers have used these general-purpose mixtures. Such mixtures have also been used extensively for home repair and hobby projects. These mixtures have wide variations in their compositions but often contain up to 20% n-hexane even when the main components are other petroleum alkane fractions (e.g., kerosene), aromatic hydrocarbons (e.g., toluene), chlorinated hydrocarbon solvents, or other organic liquids (Farmer 1996; Veulemans et al.1987).

This Table shows the output power and efficiency for the selected four working fluids calculated at geothermal temperature of 92˚C, reinjection temperature of 70˚C and geothermal flow rate of 20 kg/s. It was found from the Table that, Pentane meets our customers’ demand, giving the highest output power of approximately 213 kW and the highest thermal efficiency of 11.5%. On the other hand, R245fa yielded the lowest power output and the lowest efficiency.

#Heptane is a component of natural gas and crude oil (0.1-1.9%). All isomers of heptane are used as #solvents for glues, lacquers and inks, as #industrial #solvent for extracting natural gas, in #organic #synthesis, as an anesthetic, and are ingredients of gasoline and #petroleum #solvents. 

Pure #heptane has two main uses. The first use is as the standard zero point for the octane rating scale for gasoline. As a driver, you may have noticed that higher #octane fuel is more expensive because it is better for your engine. You can correctly conclude that a fuel rated zero #octane would be terrible for your car. Indeed, pure heptane with its zero #octane rating is a terrible fuel choice. The reason is that #heptane burns very explosively, which is the source of engine knocking.