As a kind of solvent oil, D series solvent oil (CAS No.: 64742-94-5) has been keeping a quiet attitude in the environment of other products fluctuating with the market price for a long time due to the low consumption of the market, few attention groups and no obvious price fluctuation. Dearomatic solvents, also known as dearomatic hydrocarbon solvents or dearomatic solvents, are a class of hydrocarbon solvents characterized by the presence of paraffins, isoparaffins and naphthenes with a very low aromatic content (The global concentration of dearomatic hydrocarbon solvent industry is quite high. Today, I’ll take you to know about this calm product.
D series solvent oil (CAS No.: 64742-94-5), also known as dearomatic solvent oil, is a kind of environmentally friendly solvent oil. In China, the D series brand of Junyuan Petroleum Group is widely used in China. D refers to dearomatic, and the number represents the flash point. The main grades of D Solvents (CAS No.: 64742-94-5) are D20, D30, D40, D60, D70, D80, D100, D120 etc.
The upstream of D series solvent oil is mainly aviation kerosene and straight run kerosene, while the downstream is mainly paint, medicine and aluminum industry.
The number of domestic production enterprises of D series solvent oil is small, mainly concentrated in North China and East China market. Representative enterprises include Junyuan Petroleum Group, Qinjiang Petrocompany, Canian Specialty Oil, etc., with an average annual output of about 70,000 tons.
D series solvent oils have different brands and uses. Among them, solvent oils with flash point below 60 are used as perfume processing, pharmaceutical intermediate oil, cleaning agent, dry cleaning agent, printing and dyeing auxiliaries, adhesive solvent and paint thinner. The solvent oil with flash point of 80-100 is mainly used as insecticide, aerosol insecticide, herbicide solvent, glass glue solvent, wool degreasing agent and circuit board cleaning agent, base oil for aluminum foil and aluminum plate, and oil for EDM. The solvent oil with flash point above 110 is mainly used as ink solvent, mineral extraction assistant, liquid mosquito repellent incense, leather auxiliary agent, cigarette glue solvent, etc.
From the perspective of influencing factors, D series solvent oil is mainly affected by the price of refined oil. However, since this year, due to the frequent grounding of product oil price adjustment and the weak performance of downstream demand side, D series solvent oil enterprises are cautious in price adjustment and stable operation has become the main pattern of the industry.
Source: ChinaPetro News

On October 16, Miao Guangfa, Chairman of Junyuan Petroleum Group, organized a site scheduling meeting for the commissioning of technical transformation projects at a construction site. General manager Qi Chunxiao, Deputy General Manager and Factory Director Wei Yu, Deputy Factory Director Zhang Laibao, Safety (Environmental Protection) Director Qiao Huijie, Director of Production and Operation Center Wei Fuchang, Deputy Director Yue xinbing and Deputy Director Zhu Xiaoliang attended the meeting. At the meeting, everyone discussed and analyzed the operation of the project.

Oil Extraction The chemical oil extraction takes place in the extractor. In this equipment a solid bed is formed which is continuously immersed in miscella (oil mixed with hexane). The solvent passing through the material bed carries the oil from solids to the miscella.

• File Size: 405KB
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• Analysis of the Hexane Loss in a Vegetable Oil Extraction Unit

Hexane
CAS No.: 110-54-3
Hazard Summary
Hexane is used to extract edible oils from seeds and vegetables, as a special-use solvent, and as a cleaning agent. Acute (short-term) inhalation exposure of humans to high levels of hexane causes mild central nervous system (CNS) effects, including dizziness, giddiness, slight nausea, and headache. Chronic (longterm) exposure to hexane in air is associated with polyneuropathy in humans, with numbness in the extremities, muscular weakness, blurred vision, headache, and fatigue observed. Neurotoxic effects have also been exhibited in rats. No information is available on the carcinogenic effects of hexane in humans or animals. EPA has classified hexane as a Group D, not classifiable as to human carcinogenicity.

n-Hexane, CAS Number: 110-54-3

Heptane
Heptane anhydrous, 99% CAS Number 142-82-5. Linear Formula CH 3 (CH 2) 5 CH 3. Molecular Weight 100.20 . Beilstein/REAXYS Number 1730763 . EC Number 205-563-8. MDL number MFCD00009544. PubChem Substance ID 57648092
N-Heptane, is used as a non-polar solvent typically during the plant extraction or crystallization process. N-heptane or normal heptane is a pure single molecule product, which functions better for crystallization due to the tighter control of the chemical properties.
n-Heptane is the straight-chain alkane with the chemical formula H3C(CH2)5CH3 or C7H16. When used as a test fuel component in anti-knock test engines, a 100% heptane fuel is the zero point of the octane rating scale (the 100 point is a 100% iso-octane).
Number of Transactions>200
Total Quantity: (kg)14,177,933 kg
Total Value:(USD)$27,346,608

API Imports and Exports for n-Heptane from India

Hexane
N-hexane CAS Number: 110-54-3 Molecular formula: C6H14 IUPAC Name: hexane. Hydrocarbons, C6, isoalkanes, 5% n-hexane . Type: legal entity composition of the substance. Constituent 1. Reference substance name: 2,3-dimethylbutane EC Number: 201-193-6 EC Name: 2,3-dimethylbutane CAS Number: 79-29-8 Molecular formula: C6H14
Hexane is a liquid solvent used in industrial, professional and consumer products such as adhesives and coatings. It can also be used in food contact applications such as a solvent for oil seed extraction. One of the most common applications for hexane is its use as a solvent, specifically as an industrial grade degreaser and cleaner.

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. The next step is to crack the seeds for size reduction, they are then flattened to form flakes which increases the surface area to facilitate easier extraction. In the succeeding step food grade hexane is fed as counter current and the solvent extracts oil from the flakes. Then the solvent is evaporated from the oil solvent mixture and from the defatted flakes by exposing them to steam by direct or indirect method. The solvent is condensed to recover back hexane. The oil which is devoid of the solvent undergoes further processing to achieve commercial quality.

The oil content in the flakes after removes by solvent extraction method is only 1/2% which is far less when compared to other methods of extraction which may range anywhere between 30- 45%.

Extraction of oil from seeds is carried out by three method

• Hydraulic press
• Expeller pressing
• Solvent extraction

The Solvent extraction process scores over the other two methods by the following advantages

• Maximum oil recovery
• Lesser working cost
• Cheaper price tags for end users
• Production meets demand
• The extracted oil is low in sedimentation
• Solvent loss is low

Why hexane for oil extraction and not other solvents?

• Hexane has greater ability to extract oil when compared to other solvent like petroleum ether and ethyl acetate.
• With a boiling point of 69℃ it is able to retain its liquid state at all atmospheric conditions other than for extreme climates.
• Its reasonable volatility aids easy removal from solids and oil, using low energy.
• When compared to other solvents hexane records the lowest skin irritation.
• It aggressively mixes with the vegetable oil and washes it out with out disturbing fiber, protein, sugar and undesired gums.
• It is low in odor and does not cause discomfort during exposures.

Hexane considerably scores over all other solvents and is the universally accepted chemical for solvent extraction. The method by itself uses lesser hp and maintenance is also minimal. The process flow is quiet similar with slight variation depending on the seed that’s involved in extraction. Seeds that are subjected solvent extraction process are rape seed, canola, sunflower, safflower, Soybean etc. Pure Chemicals Co. has 36 years of experience in chemical industry and is one of the largest supplier of hexane for all the big names in edible oil extraction industry that follow solvent extraction process.

Number of Transactions>200
Total Quantity: (kg)357,295,003 kg
Total Value: (USD)$418,591,307

API Imports and Exports for n-Hexane from India

n-Heptane
CAS No.:142-82-5
Article No.:00157
Grade:Extra Pure
Purity: 99%
Molecular Formula: C7H16
H.S. Code:2901.2990
Shelf Life: 60 Months
Packings:1) in 137kg drums, 160 drums/40″GP, 80 drums/20″ GP 2) in Isotank, 16MT/Isotank
Manufacturer: Junyuan Petroleum Group
TDS: TDS for n-Heptane
Phone:+86 178 1030 0898
Email: info@junyuanpetroleumgroup.com
Web: www.junyuanpetroleumgroup.com

Junyuan Petroleum Group is an ISO certified and established manufacturer of Isohexane.
The company has a modern manufacturing facility with a well-equipped laboratory to maintain the highest global quality standards of Isohexane production.
Isohexane C6H14 – 2-Methylpentane – UN1208 – 107-83-5.
A clear, colourless liquid commonly used as a constituent of gasoline and glues used for shoes, leather products and roofing. Additionally, it is used in solvents to extract oils for cooking and as a cleansing agent for shoe, furniture and textile manufacturing. In laboratories, Isohexane is used to extract oil and grease from water and soil before determination by gravimetric analysis or gas chromatography. Junyuan Isohexane can also help control drying properties of adhesive formulations.
Features:
Alternative to n-Hexane.
Can be used in brake cleaners, adhesives and as a polymerisation solvent.
Packaging:
Isohexane is available in drums and ISO Tanks.
Safety:
Please consult the SDS on Isohexane before use.

Isohexane, a clear, colourless liquid commonly used as a constituent of gasoline and glues used for shoes, leather products and roofing. Additionally, it is used in solvents to extract oils for cooking and as a cleansing agent for shoe, furniture and textile manufacturing.
Common Name: Isohexane
CAS Number: 107-83-5
Density: 0.7±0.1 g/cm3
Molecular Formula: C6H14
Flash Point: -23.3±0.0 °C
Symbol: GHS02 GHS07 GHS08 GHS09
GHS02, GHS07, GHS08, GHS09
Molecular Weight: 86.175
Boiling Point: 59.6±3.0 °C at 760 mmHg
Melting Point: -154 °C

Pentane is a straight chain alkane consisting of 5 carbon atoms. It has a role as a non-polar solvent and a refrigerant. It is a volatile organic compound and an alkane.
Pentane is an organic compound with the formula C 5 H 12 — that is, an alkane with five carbon atoms. The term may refer to any of three structural isomers, or to a mixture of them: in the IUPAC nomenclature, however, pentane means exclusively the n -pentane isomer; the other two being called “methylbutane” and “dimethylpropane“.
CID 8003
Pentane
PENTANE
DEPOSITOR-SUPPLIED SYNONYMS
Depositor-Supplied Synonyms
PENTANE
n-Pentane
109-66-0
Pentan
Skellysolve A
Pentanen
Pentani
Amyl hydride
Tetrafume
Tetrakil
Tetraspot
Hydrocarbons, C5-rich
Pentan [Polish]
Pentanen [Dutch]
Pentani [Italian]
Caswell No. 642AA
Hydrocarbons, C4-6, C5-rich
n-Pentan
NSC 72415
UNII-4FEX897A91
HSDB 109
EINECS 203-692-4
UN1265
EPA Pesticide Chemical Code 098001
AI3-28785
CHEBI:37830
4FEX897A91
MFCD00009498
68476-43-7
68476-55-1
Hydrocarbons, C>4
NCGC00091116-01
n-Pentane, for analysis
DSSTox_CID_5846
Pentane, analytical standard
DSSTox_RID_77944
DSSTox_GSID_25846
102056-77-9
n-Pentane, 99+%, extra pure
n-Pentane, 99+%, for HPLC
n-Pentane, 95%, technical grade
Pentanes
n-Pentane, 99+%, for spectroscopy
Butane, methyl-
CAS-109-66-0
n-Pentane, 99+%, extra pure, anhydrous
Pentanes (petroleum)
n-Pentane, 99+%, Extra Dry, AcroSeal(R)
Pentane, pentene fraction
npentane
n-Pentane, 99+%, Extra Dry over Molecular Sieve, AcroSeal(R)
syn-pentane
Normal Pentane
1-ethylpropane
n-Pentane, 99+%, for residue analysis, ECD tested for pesticide analysis
High purity Pentane
Pentane, p.a.
EINECS 270-684-5
EINECS 270-695-5
EINECS 271-960-8
95% N-pentane
99% N-pentane
High purity N-pentane
blowing agent N-pentane
foaming agent N-pentane
Pentane Fraction, purum
Butane, methyl- (9CI)
ACMC-209t5d
EC 203-692-4
EC 270-695-5
Pentane 109-66-0
Pentane, p.a., 99%
Pentane, purification grade
Pentane, AR, >=99%
Pentane, LR, >=99%
WLN: 5H
68647-60-9
KSC175E1B
UN 1265 (Salt/Mix)
CHEMBL16102
Pentane, anhydrous, >=99%
n-C5H12
Pentane, >=99% (GC)
Pentane, p.a., 99.5%
Pentane, reagent grade, 98%
DTXSID2025846
CTK0H5210
Pentane, >=99%, HPLC grade
KS-00000V5R
NSC72415
Pentane, for HPLC, >=99.0%
ZINC1698513
EINECS 270-654-1
Tox21_111085
Tox21_200248
ANW-42047
LMFA11000583
LS-483
NSC-72415
STL301896
Pentane, purum, >=95.0% (GC)
AKOS009158849
MCULE-4643148765
Pentane, UV HPLC spectroscopic, 99%
n-Pentane 1000 microg/mL in Methanol
Pentane, SAJ first grade, >=96.0%
NCGC00091116-02
NCGC00257802-01
Pentane, SAJ special grade, >=99.0%
Pentanes [UN1265] [Flammable liquid]
Pentanes [UN1265] [Flammable liquid]
Pentane, spectrophotometric grade, >=99%
9,11,13-Octadecatriyoic acid methyl ester
NS00008602
P0048
P2621
Pentane, puriss. p.a., >=99.0% (GC)
R-601
S0277
EC 270-654-1
Pentane, Laboratory Reagent, >=95.0% (GC)
10047-EP2269986A1
10047-EP2269993A1
10047-EP2270000A1
10047-EP2270006A1
10047-EP2270014A1
10047-EP2270113A1
10047-EP2272509A1
10047-EP2272813A2
10047-EP2272826A1
10047-EP2272839A1
10047-EP2272840A1
10047-EP2272935A1
10047-EP2275395A2
10047-EP2275410A1
10047-EP2275411A2
10047-EP2275414A1
10047-EP2277877A1
10047-EP2280000A1
10047-EP2281813A1
10047-EP2281821A1
10047-EP2281822A1
10047-EP2287147A2
10047-EP2287165A2
10047-EP2287166A2
10047-EP2289509A2
10047-EP2289879A1
10047-EP2289893A1
10047-EP2289965A1
10047-EP2292576A2
10047-EP2292589A1
10047-EP2292592A1
10047-EP2292596A2
10047-EP2292606A1
10047-EP2292615A1
10047-EP2292620A2
10047-EP2295433A2
10047-EP2295437A1
10047-EP2295438A1
10047-EP2295439A1
10047-EP2298734A2
10047-EP2298763A1
10047-EP2298775A1
10047-EP2298828A1
10047-EP2301544A1
10047-EP2301627A1
10047-EP2301918A1
10047-EP2305625A1
10047-EP2305642A2
10047-EP2305649A1
10047-EP2305667A2
10047-EP2305668A1
10047-EP2305672A1
10047-EP2305677A1
10047-EP2305769A2
10047-EP2305808A1
10047-EP2308838A1
10047-EP2308857A1
10047-EP2308861A1
10047-EP2308867A2
10047-EP2308870A2
10047-EP2308876A1
10047-EP2311801A1
10047-EP2311802A1
10047-EP2311803A1
10047-EP2311837A1
10047-EP2314576A1
10047-EP2314577A1
10047-EP2315502A1
10047-EP2316832A1
10047-EP2316833A1
10047-EP2316835A1
10047-EP2316836A1
10047-EP2371795A1
10047-EP2371811A2
10047-EP2371814A1
10047-EP2374780A1
10047-EP2374781A1
10047-EP2380568A1
10047-EP2380871A1
15414-EP2275469A1
15414-EP2280007A1
15414-EP2281559A1
15414-EP2281820A2
15414-EP2284174A1
15414-EP2287940A1
15414-EP2289897A1
15414-EP2289965A1
15414-EP2298754A1
15414-EP2298828A1
15414-EP2301983A1
15414-EP2305683A1
15414-EP2305825A1
15414-EP2308926A1
15414-EP2309564A1
15414-EP2309584A1
15414-EP2311839A1
15414-EP2314576A1
15414-EP2314577A1
15414-EP2314589A1
15414-EP2316837A1
15414-EP2371814A1
15414-EP2380871A1
25661-EP2292616A1
25661-EP2298749A1
25661-EP2314580A1
125901-EP2272846A1
125901-EP2277868A1
125901-EP2277869A1
125901-EP2277870A1
125901-EP2295422A2
A802071
Q150429
EB93985D-C6D5-4EC7-A089-73B41F8B4583
Pentane, United States Pharmacopeia (USP) Reference Standard
Pentane, capillary GC grade, >=98% n-pentane basis, 99.9+% C5 isomers.
Pentane, puriss., absolute, over molecular sieve (H2O <=0.005%), >=99.0% (GC)
AKS

Pentane is widely used as a foaming agent for expandable polystyrene and polyurethane foam systems. It is used in the fields of fluorine free refrigerators, freezers, cold storage and pipeline insulation. It can be used as a solvent for linear low density polyethylene catalyst, an industrial solvent for deasphalting, an extractant for dewaxing of molecular sieve, and also a chemical raw material, such as isopentane and isoprene, which can be dehydrogenated from isopentane. Through chlorination, rectification and catalytic hydrolysis of pentane mixture, crude amyl alcohol can be produced. After multistage separation and distillation, l-amyl alcohol can be obtained. At the same time, research on the oxidation of n-pentane to phthalic anhydride and maleic anhydride has also made some progress. At present, there are 36 high-purity isopentane, n-pentane, cyclopentane and mixed pentane foaming agents in China, with a production capacity of about 190 kt / A. Among them, there are 5 manufacturers with stable raw material supply, advanced technology, good product quality and large production scale. The total production capacity is 156 kt / A, accounting for 71% of the national production capacity. These five enterprises are mainly concentrated in the relatively developed southeast coastal areas. The main domestic pentane manufacturers, product types and production capacity are shown in Table 1.

With the gradual improvement of domestic pentane unit operating rate, the output has increased significantly. Some enterprises have exported in batch. In 2020, the export volume reached 86 KT, but there is still a gap in domestic high-quality pentane foaming agent. In the same period, domestic imports of high-quality pentane foaming agent were nearly 86 kt. There are also many manufacturers of pentane products. There are great differences in production scale, process level and product quality. At present, there is no unified national standard for related products, but each enterprise has its own enterprise standard. As for the quality index of pentane foaming agent at home and abroad, the sulfur content of foreign index is low, and there are clear requirements for the proportion of n-pentane and isopentane.

The production status of a domestic plant index and a foreign company index density (20 ℃) / kg · M-3 615-630 620-640 sulfur content, 10-6 ≤ 50 ≤ 30 pentane total content (mol),% ≥ 98 – ω (n-pentane),% – 80-82 ω (isopentane),% – 20-18 C6 heavy components (mol),% ≤ 1 ≤ 2 1.2 production status At present, domestic pentane production technology mainly comes from Tianjin University and Beijing Institute of chemical industry. The main raw materials are light hydrocarbon of oil field, topping oil of crude oil pretreatment unit, light naphtha of hydrogenation unit, mixed hydrocarbon after reforming and hydrogenation, C5 of refinery gas separation unit and C5 fraction of cracking by-product of ethylene unit, which can also be obtained by separation and purification of mixed C5 after C5 etherification, or by hydrogenation of cyclopentadiene. The C5 fraction obtained by fractionation from straight run gasoline, natural gas condensate, hydrocracking tail oil and reforming gasoline is separated by high-efficiency distillation with pentane separator and isopentane column, and the products of n-pentane and isopentane are dominant. The main process flow is as follows (taking natural gas condensate as an example): it is heated to 55 ℃ in the preheater before entering into the debutanizer. The operating pressure of the debutanizer is 0.34 MPa. Propane and butane fractions are taken out from the top of the tower (the tower top temperature is 48 ℃), part of the overhead condensate is used as the reflux, and the surplus condensate is heated to 76 ℃ by the heat exchanger before entering the depropanizer. The operating pressure of depropanizer is 2 MPa. Propane is removed from the top of the depropanizer (top temperature is 50 ℃) and butane is removed from the bottom of the column. The gasoline from the bottom of debutanizer enters the depentanizer. The number of trays in the depentanizer is 30, the operating pressure is 2.2 MPa, and the reflux ratio is 1.5. Plate number of isopentane separator
The operating pressure of the separation column is 0.2 MPa. The purity of the distillate from the top of the column is 95% isopentane, and the fraction from the bottom of the tower contains 90% n-pentane. Pentane and other products can be separated from mixed C5 separated from FCC LPG separation unit and ethylene unit. The main process is hydrogenation under the condition of new Ziegler type catalyst. The reaction temperature is 60-80 ℃, and the pressure is 0.8-1.0 MPa. After hydrogenation, isopentane, n-pentane and cyclopentane can be separated from C5 by distillation.

At present, there is no unified national standard for pentane products, but the manufacturers have their own enterprise standards, which are equivalent to the standards of foreign similar products.

Market analysis: the growth of pentane consumption is directly related to the prohibition of Freon. According to the Montreal protocol adopted by all countries in 1992, countries are required to stop using CFC in 2000. Pentane as the final alternative product has great development potential in the next few years. In 2017, the annual consumption of pentane in China was nearly 116kt, of which, the consumption of EPS (expanded polystyrene) pentane foaming agent was about 60 kt / A, accounting for 45% of the total consumption; the consumption of pentane for polyurethane foaming agent was 65 kt / A, accounting for 50% of the total consumption; the consumption of pentane carrier solvent of linear low density polyethylene accounted for about 5% of the total consumption.

Pentane Blends, CAS:109-66-0, in Isotank,15MT/Isotank

pentaneblend #pentaneblends #mixture_of_Isopentane_and Normal_Pentane #CAS1096

n-Pentane, CAS:109-66-0, in 130kg drums and Isotank,160 drums/40″GP, 80 drums/20″ GP, 15MT/Isotank

pentane #normal_pentane #normalpentane #CAS109660 #pentaneblends #pentanes #C5H12 #nPentane Please contact us to request a quote

Why Use Pentane, a Hydrocarbon?

Polyisocyanurate foams were traditionally produced using CFC-11 (a chloro-fluorocarbon) as the blowing agent. When evidence became irrefutable that CFCs destroyed stratospheric ozone, most of the world adopted the ground-breaking Montreal Protocol, which mandated the phaseout of CFCs for non-essential uses by 1996. Many polyiso producers gradually transitioned to HCFC-141b (a hydro-chlorofluorocarbon), which has only 10% to 12% the ozone-depletion potential of CFC-11. But since HCFC-141b was recognized as the most damaging of the HCFCs, HCFC-141b would be only a temporary solution. (Modifications to the Montreal Protocol later mandated the phaseout of this chemical by 2003.)

As polyiso manufacturers studied possible substitutes for HCFC-141b, two different hydrofluorocarbons emerged as possible substitutes: HFC-245FA and HFC-365. HFCs have the advantage of being non-ozone-depleting (since they don’t contain chlorine or bromine), but they are significant greenhouse gases. Most HFCs are also expensive to manufacture.

Another alternative was a hydrocarbon blowing agent – – pentane. Hydrocarbon blowing agents have the advantage of being less expensive, but their flammability requires special safety measures at manufacturing plants. Yet the cured foam is no more flammable than HCFC-blown foam.

As for energy performance, leading industry experts report there is no appreciable change in R-value with the hydrocarbon-blown foams. The finer cell structure of pentane-blown foams, for instance, tends to offset the pentane’s higher thermal conductivity. Pentane-blown foams have another advantage: better dimensional stability due to the fact that pentane does not condense as much as HCFC-141b at temperatures normally experienced by the foam in use. The condensation of HCFC-141b causes the cells to shrink and expand on a cyclical basis, reducing dimensional stability.”

Rigid Foam Insulation and the Environment

Ozone depletion and global warming are two of our most serious environmental problems—and foam insulation materials containing CFCs (chlorofluorocarbons) contribute significantly to both of these problems. The environmentally concerned builder or designer should make it a highest priority to avoid them. Even many of the non-CFC alternatives that manufacturers are now switching to are still damaging to the environment—though less so than CFCs. This article takes a detailed look at various types of foam insulation materials—how the materials are produced, what their environmental impacts are, and what the alternatives available to you are.

Rigid foam has played an important role in the energy-efficient construction revolution we have witnessed since the mid-’70s, permitting wall and roof R-values to be boosted dramatically with only minimal increases in wall thickness. The foam has such a significant effect in part because it covers the framing members, thus reducing the thermal bridging that occurs through framing members when only cavity-fill insulation is used. The increasing popularity of foam-core stress-skin panels—some of which are produced with CFC-based foams—for use in both timber frame and structural panel (frameless) buildings is further increasing use of environmentally damaging foams.

Types of Rigid Foam Insulation

There are several major types of rigid foam insulation, including polyiso­cyanurate (which is a type of polyurethane), extruded polystyrene, phenolic foam, and expanded polystyrene (EPS). The first three are described below, with information on their general properties and how they are produced. EPS, which does not cause ozone depletion, is discussed later.

Polyisocyanurate

Polyisocyanurate insulation (iso) is widely used in the construction industry, with some 2.5 billion board feet produced in North America in 1989, according to the Society of the Plastics Industry. Iso insulation is typically foil-faced, and it is widely available in thicknesses from

¹/₂” to 4″. Common trade names for iso insulation include R-max, Thermax, Tuff-R, Energy Shield, ACFoam, and ENRGy 1. It is also used in certain Exterior Insulation and Finish Systems (EIFS), and in foam-core stress-skin panels made by Winter Panel Corp., Atlas Industries, and several other manufacturers.

CFC-11 is used in the production of iso to generate rapid expansion of foam with a closed-cell structure and to provide high R-values—about R-7 per inch. (This R-value drops slowly over time as air leaks into the cells and as CFC-11 leaks out.) Most iso foams are 11 to 15 percent CFC-11 by weight. In the past two years, manufacturers have succeeded in reducing the amount of CFC-11 in these foams by improving manufacturing efficiencies, reducing waste, and adding water to the mixture, which generates CO₂ during the foaming process. Throughout the poly­isocyanurate insulation industry, the CFC-11 content has dropped by as much as a third—from 15% to 10-12%, according to Jared Blum of the Polyisocyanurate Insulation Manufacturers Association.

While short-term efforts to reduce CFC-11 use by improving efficiency and adding water to the chemical mixture have been moderately successful, most efforts are focusing on the intermediate future—from 1994 through 2015. In this time-period iso manufacturers are expected to switch to hydrochlorofluorocarbon (HCFC) foaming agents. The industry has identified HCFC-141b as the most promising replacement for CFC-11. (Another likely candidate, HCFC 123, was dropped when early toxicity testing turned up tumor formation in laboratory rats.) Results of performance testing of HCFC-141b-based iso foams have been quite positive. Although the resulting R-value is 4% to 8% lower than that of foam produced using CFC-11, the drop in R-value over time appears to be slower.

Extruded Polystyrene

Extruded polystyrene was invented in Sweden, but the product was further developed in the United States during the 1940s. It is produced by four manufacturers in North America, all of which claim an insulating value of R-5 per inch. Extruded polystyrene has become the insulation of choice for most below-grade applications, and it is widely used for wall sheathing as well.

Originally, methyl chloride was used as the blowing agent, but manufacturers switched to CFC-12 during the 1960s. CFC-12 was less toxic, nonflammable, and provided a higher R-value. The foam is approximately 10 percent CFC-12 by weight at the time of manufacturing, with roughly 85 percent retained after production. In 1986, use of CFC-12 for extruded polystyrene totaled approximately 39 million tons worldwide.

By the late 1980s, with increasing pressure to eliminate CFC use, most extruded polystyrene manufacturers began switching to a mixture of HCFC-142b and ethyl chloride as the foaming agent. HCFC-142b is approximately 15 percent more expensive than CFC-12, thus raising the cost (or reducing the profit margin) of foam produced with it, but its ozone depletion potential is 94% less than that of CFC-12.

Amoco Foam Products fully converted to the HCFC-142b/ethyl chloride mixture in its Amofoam® product line by January 1990. Dow Chemical completed the conversion with its Styrofoam® product line by July 1990 (with a slightly different mixture from Amoco’s). The two other manufacturers, UC Industries and Diversifoam, continue to use CFC-12. UC Industries, maker of FoamulaR™, had converted approximately 50 percent of its production away from CFC-12 by mid-1992 and intends to complete the conversion by the end of the year. Diversifoam Products, maker of Certifoam®, is also in the process of conversion but did not provide a timetable for phasing out CFC-12. In addition to leading the way in eliminating CFC-12, Amoco Foam Products has also just introduced the Amofoam-RCY product, made with 50 percent recycled polystyrene.

Phenolic Foam

Even though it was quite popular with some energy-conscious builders because of its very high R-value, phenolic foam insulation is no longer in production in the United States. Manville Corporation, which purchased the phenolic foam production rights from Koppers a few years ago, suspended production of its Ultra Guard Premier in February of this year. Bert Emory of the company cited a limited customer base and lack of profitability for the decision to cease production, but another source indicated that the reason had to do with the cost of replacing the CFCs.

Two companies in Canada still produce phenolic foam insulation: Domtar and Fiberglas Canada. With no iso manufacturers in Canada, phenolic foam has a sizeable share of the Canadian boardstock insulation market.

The Fiberglas Canada product, Perma-Therm, is sold only for commercial roofing applications at this time, though the company is considering expanding into residential roofing and wall applications. Their product, which is actually a “modified resol” product (resol is a type of phenol resin), was made until 1990 using CFC-114 as the blowing agent. Jim Sidwell, Fiberglas Canada’s Business Manager for Commercial Roofing Products, said that the company has already reduced its CFC-114 use by 80% and is now producing the foam insulation using a 20:80 mix of CFC-114 and an unspecified HCFC. Legislation in Ontario calls for a 50% reduction in CFC use by 1992, a 75% reduction by 1993, and a 100% reduction by 1994. Sidwell expects the company to complete its switch to HCFCs by the first half of 1993.

Domtar produces a phenolic foam insulation board under the R_x brand name (the same brand name Koppers used, since identical technologies were licensed to the two companies). Domtar sells about 50 million board feet of the product per year for both wall and roof applications. Domtar’s R_x phenolic board is produced using a 50:50 mixture of CFC-11 and CFC-113. Because of the manufacturing process, they have been able to use recycled CFC-113, even with some impurities. (By using recycled foaming agents, they satisfy the Ontario requirement for 50% reduction in CFC use this year.) Domtar expects to have eliminated use of CFCs totally by the end of the year.

Just How Bad are CFCs for the Environment, Anyway?

Pretty bad. The realization that CFCs could deplete the Earth’s stratospheric ozone layer has led to unprecedented international cooperation in banning these compounds. It was first suggested in 1974 that CFCs could destroy ozone in the stratosphere. CFCs are highly stable chlorine-containing compounds that do not break down under normal exposure to sunlight and moisture as most organic compounds do. According to current understanding, once released into the atmosphere they gradually make their way up to the stratosphere where high-energy ultraviolet light can break the molecules apart, releasing chlorine atoms. The chlorine atoms then react with ozone (O₃) by bonding with one oxygen atom to form chlorine monoxide. The chlorine monoxide itself is unstable and quickly breaks down by reacting with another ozone molecule. A single chlorine atom can destroy as many as 100,000 ozone molecules.

After a dozen years spent challenging the underlying theories and making only minor progress toward eliminating the harmful compounds, international interest was piqued in 1985 with the discovery of a hole in the ozone layer over Antarctica. This led to passage of the Montreal Protocol in 1987 calling for a 50% reduction in CFC production by 1998. Following the discovery that ozone thinning was taking place over the far-more-populated Northern Hemisphere, the Montreal Protocol was strengthened in 1990. The so-called London Amendments call for a total phaseout of CFCs and halons (fire-extinguishing agents) by the year 2000 and phaseout as well for carbon tetrachloride and methyl chloroform. By 1992, more than 70 countries, representing 90% of the world’s CFC production, had signed onto the strengthened Montreal Protocol.

Such rapid and decisive international action has been taken because of the serious threat posed by ozone depletion. Stratospheric ozone protects us by blocking out high-energy ultraviolet radiation (UV_b), which has harmful health and environmental effects. According to a report compiled for the U.S. Environmental Protection Agency, the extra UV_b radiation reaching the Earth’s surface because of ozone depletion will cause over 900,000 cases of nonmelanoma and melanoma skin cancer in the United States (including 14,600 fatalities) and 160,000 cases of cataracts among people born prior to 1986—even with the CFC phaseout treaty currently in place. Had CFC controls not gone into effect, total cases of skin cancer would exceed 6 million, including more than 120,000 fatalities, and over 1.8 million cases of cataracts among U.S. citizens born prior to 1986. In addition, increased UV_b radiation would be expected to harm marine organisms (including commercial fisheries), agricultural crops, and polymers exposed to sunlight. The report doesn’t attempt to evaluate damage to natural ecosystems that do not have recognized commercial value, but the harm to all ecosystems would likely be significant.

Sources:

1. D. Fisher, et al., “Model calculations of the relative effects of CFCs and their replacements on stratospheric ozone,” Nature, Vol. 344, 5 April 1990. One-dimensional model numbers from DuPont.

2. Regulatory Impact Analysis: Compliance with Section 604 of the Clean Air Act for the Phaseout of Ozone Depleting Chemicals, Prepared for the U.S. Environmental Protection Agency by ICF, Inc., March 12, 1992. Global Warming Potentials based on infinite time horizon.

Not all foaming agents are equally destructive of ozone. Some CFCs last longer than others in the atmosphere, some contain more chlorine, and HCFCs contain hydrogen in addition to chlorine, making them less stable and more likely to break down before reaching the stratosphere. “Ozone depletion potential” (ODP) is a measure of the relative potency of different chemicals in terms of ozone destruction. ODPs are generally measured relative to CFC-11, which is defined to have an ODP of 1.0. Ozone depletion potentials of various foaming agents are shown in Table 1. Note that the alternatives to CFCs for foam insulation materials (HCFC-141b and HCFC-142b) have considerably lower ODPs than the CFCs, but even these compounds have a sizeable effect on ozone.

One could argue that CFCs from foam insulation materials are not that much of a concern since the CFC gas is locked up in the foam. Indeed, some measurements show that CFC-11 in iso foam has a half-life of more than 100 years. (The drop in R-value over time observed with CFC-blown insulation materials, according to an expert at DuPont Corporation, is more a result of air leaking into the cell structure than CFC-11 leaking out.) The long lifetime of CFCs in foam insulation, however, does not absolve them from environmental concern. In fact, one could argue equally well that the long lifetime of CFCs makes them worse from an environmental standpoint, because even when all CFC production halts, these foams will continue releasing CFCs into the atmosphere for hundreds of years.

Along with depleting ozone, CFCs are potent greenhouse gases that are implicated in global warming. Carbon dioxide (CO₂) is the most significant contributor to global warming because of the enormous amounts generated. Pound for pound, however, CFCs are far more significant contributors to global warming. One pound of CFC-11 is equivalent to 1600 pounds of CO₂ in terms of global warming potential, and a pound of CFC-12 is equivalent to 4400 pounds of CO₂. While the HCFCs are not as bad as CFCs, they are still far worse than CO₂. In fact, HCFC-142b, which is being used in extruded polystyrene, is nearly a third as detrimental as CFC-11 from a global warming standpoint.

Table 2 shows the relative global warming impact of houses with different wall and roof insulation systems, relative to comparable CO₂ emissions. The results are striking and frightening. An average-size house with 1” of iso foam on the walls will introduce 27 pounds of CFC-11 into the atmosphere over time, which is comparable to 22 tons of CO₂ emissions. A foam-core panel house, with 4¹/₂” isocyanurate-core panels, contains 238 pounds of CFC-11 with as much global warming impact as 190 tons of CO₂ emissions! If that house uses 500 therms of natural gas per year for heating, it would take 63 years for the CO₂ emissions from the natural gas combustion to equal the global warming potential in the foam.

The widespread use of foam in commercial roofing is even more troubling, since common roofing practices scrap the entire mass of insulation each time the roofing surface is replaced. This insulation, then, has a useful life of only about twenty years, after which it becomes a part of the landfill problem, while continuing to release CFCs into the atmosphere.

HCFC foams are better relative to global warming than CFC-based foams, but their impact is still significant.

What are the Alternatives?

If we accept that rigid foam insulation materials produced with CFCs and HCFCs are not acceptable from an environmental standpoint, what are the alternatives? Currently, the only non-CFC and non-HCFC boardstock insulation materials on the market are rigid fiberglass and expanded polystyrene (commonly called EPS or beadboard). EPS is produced using pentane as the foaming agent.

From an environmental standpoint, rigid fiberglass—produced from glass fibers held together with a binder—is probably the best boardstock insulation material (though some embodied energy studies indicate that EPS may be superior—this issue will be addressed in a later issue of EBN). Unfortunately, rigid fiberglass is not marketed widely for residential construction in the U.S., though it is available in Canada (Glas­Clad, produced by Fiberglas Canada, 4100 Younge St., Willowdale, Ontario M2P-2B6). In the U.S., rigid fiberglass is produced for commercial applications by all three major fiberglass manufacturers: Owens Corning, Man­ville, and Certainteed. Some companies have also worked out cladding systems allowing rigid fiberglass to be used below grade as foundation insulation.

Expanded polystyrene (EPS) is the only foam boardstock insulation made entirely without CFCs or HCFCs. To manufacture EPS, pentane-filled polystyrene beads are expanded using heat, releasing most of the pentane into the atmosphere. A hydrocarbon, pentane emissions contribute to localized air pollution (smog), but its impact on global warming is negligible due to its short lifetime in the atmosphere, and it has no effect on stratospheric ozone.

EPS has long been considered a lower quality product than extruded polystyrene. Its perceived drawbacks relative to extruded polystyrene include lower R-value, inferior structural properties, and possible disintegration over time in below-grade applications. While some low-cost 1 lb/ft³ EPS may indeed have these drawbacks, EPS is also available in higher densities. At 2 lb/ft³, EPS is much closer to extruded polystyrene in its performance and considered an acceptable substitute in both above- and below-grade applications. EPS boardstock is generally available directly from the manufacturers, of which there are several hundred in North America, and some building supply yards may stock it. Because EPS pricing is generally proportional to its density, 2 lb/ft³ EPS will be close to extruded polystyrene in cost.

The other alternative to CFC and HCFC foam insulation materials is to eliminate rigid boardstock insulation from construction details altogether. Fiber insulation materials, including fiberglass, mineral wool and cellulose, are all free of CFCs and HCFCs. To achieve comparable R-values with these materials, you have to build thicker walls, but the higher framing costs should be largely offset by eliminating the expensive rigid foam and the labor required to install it. [See page 8 for one example of a high-R-value wall detail using cellulose.] For heated basements, interior foundation insulation using a studwall with batt or blown-in insulation is better thermally than exterior insulation, and conversion into living space will be much easier.

Foam insulation provides a good example of how a well-meaning push toward energy conservation has led to other problems. Clearly, energy use for heating and cooling buildings is a major cause of pollution, and efforts to reduce that energy use are necessary— indeed a high priority. As new discoveries are made about the effects of our actions on the global environment, however, we have to be willing to adapt our practices in response. Right now, the appropriate response is to develop ways of building that don’t use CFC- or HCFC-based insulation materials. Our challenge is to do so without sacrificing energy efficiency.

– Alex Wilson

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