Category blowing agent

What is the difference between EPS fire resistance levels A, B, and B1?

The difference between EPS fire resistance grades A, B, and B1:

  1. Fire resistance coefficient: Class A is non combustible; Level B is further divided into three levels, with B1, B2, and B3 having different levels of combustion.
  2. Flammability: Class A has zero flammability;, B1 is flame retardant, B2 is flammable, and B3 is flammable.
    At present, the common A-grade products in the market include phenolic aldehyde, rock wool, insulation mortar, foam ceramics, foam glass, and foam concrete. At present, the most advantageous A-grade material is foamed concrete, also known as foamed cement.
    EPS polystyrene board itself is a flammable material, so it is not a fireproof material in terms of fire rating. So it’s not at all A-level or B1 level. The fire resistance rating of polystyrene boards on the market is only B2 (flammable) and B3 (flammable).
    Extended Information:
    EPS physical and mechanical properties:
  3. Density
    The density of EPS is determined by the expansion ratio of polystyrene particles during the forming stage, which is generally between 10 and 45kg/m3. As EPS used in engineering, its apparent density is generally between 15 and 30kg/m3.
    At present, the density of EPS used as lightweight filling material in road engineering is 20kg/m3, which is 1% to 2% of that of ordinary road filling material. Density is an important indicator of EPS, and its mechanical properties are almost directly proportional to its density.
  4. Deformation characteristics
    When the confining pressure exceeds 60KPa, the yield strength significantly decreases, which is clearly different from the variation law of the soil. When axial strain ε When a ≤ 5%, regardless of the confining pressure, the volumetric strain ε V is close to axial strain ε a. The lateral deformation of EPS is small, which means the Poisson’s ratio is small.
    To minimize post construction settlement, after laying the EPS material layer, fill 1.2m of soil on it for preloading. The average compressive settlement of the EPS material layer is 32mm, and it can be calculated that the elastic modulus of EPS is 2.4MPa, and the EPS material is still in the elastic deformation stage.
  5. Self-reliance
    The self-sustaining nature of EPS is very beneficial for the stability of high slopes. Due to the small lateral pressure generated by the vertical compression of EPS, the use of EPS as filling material for the roadbed at the bridge head can greatly reduce the soil pressure behind the abutment, which is very beneficial for the stability of the abutment.
    The friction coefficient f between EPS block and sand is 0.58 (dense)~0.46 (loose) for dry sand and 0.52 (dense)~0.25 (loose) for wet sand; The range of f between EPS blocks is between 0.6 and 0.7.
  6. Water and temperature characteristics
    The closed cavity structure of EPS determines its good insulation performance. Its biggest characteristic when used as insulation material is its extremely low thermal conductivity, with various specifications of EPS boards having thermal conductivity ranging from 0.024W/m.K to 0.041W/m.K. EPS is a thermoplastic resin that should be used below 70 ℃ to avoid thermal deformation and strength reduction.
    Simultaneously utilizing this feature, electric heating wire processing can be used. Flame retardants can be added in production to form flame retardant EPS. Flame retardant EPS extinguishes itself within 3 seconds after leaving the ignition source. Due to the much lower bulk density of EPS compared to soil, the 1% to 10% increase in bulk density caused by water absorption can have negligible impact on engineering.
  7. Durability
    EPS has stable chemical properties in water and soil, and cannot be decomposed by microorganisms; The cavity structure of EPS also makes water infiltration extremely slow; If exposed to ultraviolet radiation for a long time, the surface of EPS will change from white to yellow, and the material will appear brittle to some extent; EPS has stable properties in most solvents, but can be dissolved in organic solvents such as gasoline, diesel, kerosene, toluene, acetone, etc. This indicates that EPS fillers require a good protective layer.

    Reference Source: JUNYUAN PETROLEUM GROUP – EPS Blowing Agent Department (Folystyrene Foam)

Expandable polystyrene (EPS)

Revolutionary patented polystyrene production method

Expandable polystyrene (EPS) consists of polystyrene micro-pellets or beads containing a blowing agent and other additives for foaming. We have developed a continuous production process in which the blowing agent is directly injected into the melt, combined with subsequent underwater pelletization.

Commercial EPS is manufactured with the addition of a blowing agent, typically a chlorinated hydrocarbon or a low-boiling petroleum-derived agent with the presence of pentane. These substances are highly flammable; by reducing the amount of flame retardant due to the addition of gypsum, they ignited during the flame propagation test, increasing the burn rate of the GPS.

Main benefits

  • The patented EPS process is economical, compact, and easy to operate
  • Continuous process for consistent product quality
  • Dispersing a wide range of additives and pigments is possible
  • Minimized waste production
  • Reduction of wastewater and process water
  • Recycling possibility for waste EPS pellets/beads/foam
  • Process allows developing innovative applications

Main applications

  • Expandable Polystyrene

EPS Panel

The self-extinguishing, fire-retardant EPS Panel foam is manufactured from 100% virgin bead and oven-cured after manufacture to ensure the resulting blocks are completely dry and free from all residual pentane.

EPS Panel is a lightweight, CFC-free, non-brittle, closed cell insulator with more consistent thermal performance over time. It has a high dimensional stability and low water vapor transmission.

A special chemical coated to the Expanded Polystyrene beads (raw material) distinguished it from standard/common EPS Panel. Fire-Retardant EPS Panel is a self-extinguishing, non-combustible material.

Fire-retardant EPS Panel with a density of 15 kg/m3 is used for clean rooms, food processing facilities and modular buildings, while the 20 kg/m3 is used for industrial and commercial cold storage.

Core

Width (cover mm)
Thickness (mm)
Length
Exterior Facing Skin
Internal Facing Skin
Standard Colors
Joint System
Finishes
Type of SkinEPS
(Expanded Polystyrene)
1,160
50, 75, 100, 125, 150, 200, 250
Up to 12 meters
0.5mm, 0.6mm G300 CRP Steel
0.5mm, 0.6mm G300 CRP Steel
Off White
Slip Joint
Plain, Ribbed, Diamond
Anti Bacterial (AB)
Food Grade (FG)
Xterior Roof and Wall (XRW)

Features and Advantages

  • Fire retardant
  • Meets safety requirements
  • Energy saving
  • Longer lifetime
  • Resistant to termites and rodents
  • Customized design
  • Easy to install saving cost of installation time
  • High performance on insulated panel

Properties of Pentane Blowing Agent and Properties of Rigid Polyurethane Foam

Polyurethane foam is widely used in construction, refrigeration, piping and other fields due to its low density, good thermal insulation, low water absorption, low toxicity, and good processability. The blowing agent is an important auxiliary agent for the production of polyurethane foam plastics. Since the second-generation blowing agent HCFC-141b has an ODP value of 0.11 and a GWP value of 725, it has a great impact on the ozone layer and the greenhouse effect, so it can only be used as a transitional agent. use of sex substitutes. According to China’s polyurethane foam industry HCFC-141b phase-out plan (second phase), the polyurethane foam industry will gradually reduce HCFC-141b consumption based on the results achieved in the first phase, and will achieve industry-wide phase-out by the end of 2025. At present, the commonly used substitutes for HCFC-141b blowing agent mainly include pentane, water, hydrofluorocarbon (HFC), liquid carbon dioxide, hydrofluoroolefin (HFO) and methyl formate. Among them, pentane is widely used due to its advantages of environmental protection, low price, and easy availability. However, pentane is flammable and explosive, and is a dangerous chemical. The use of this kind of blowing agent requires safety renovation of production equipment and workshops. Although the initial investment of pentane foaming replacement technology is relatively high, in the long run, the comprehensive economic benefits are obvious, and it is an ideal substitute for HCFC-141b.

The price of pentane blowing agent on 03.05.2023

In the Chinese market today, the price of pentane blowing agent (n-/Isopentane Blend 70-30%) is CNY7,950/MT, with a daily increase of CNY50/MT, with a daily increase of 0.63%.

US Dollar to Chinese Yuan Exchange Rate 03.05.2023

US Dollar to Chinese Yuan Exchange Rate is at a current level of 6.910, up from 6.865 the previous market day and up from 6.317 one year ago.

Pentanes and Pentane Blends

Junyuan Petroleum Group offers a large range of flammable and non-flammable blowing agents for Polyurethane (PU), Polystyrene (EPS, XPS) and Polyethelyne (PE) foams, which include liquids and blends.

Blowing Agent of Expendable Polystyrene, Polyurethane

ISOPENTANE, 95%

ISOPENTANE, 99%

PENTANE BLENDS

With know how in formulating, handling and packaging blowing agents, we can also offer special blends such as :

n-Pentane/Isopentane

Cyclopentane/Isopentane

Cyclopentane/n-Pentane

Cyclopentane/Isopentane/n-Pentane

Blowing Agents/Pentane Blends

ISOPENTANE AND CYCLOPENTANE BLENDS

ISOPENTANE 70%, CYCLOPENTANE 30%

ISOPENANE 50%, CYCLOPENANE 50%

ISOPENTANE 30%, CYCLOPENTANE 70%

ISOPENANE 25%, CYCLOPENANE 75%

ISOPENTANE 20%, CYCLOPENTANE 80%

ISOPENANE 15%, CYCLOPENIANE 85%

ISOPENANE 10%, CYCLOPENANE 90%

CYCLOPENANE,95%

CYCLOPENTANE,99%

Blowing Agents/Pentane Blends

ISOPENTANE AND NORMAL PENTANE BLENDS

ISOPENTANE 15%, NORMAL PENTANE 85%

ISOPENTANE 20%, NORMAL PENTANE 80%

ISOPENTANE 25%, NORMAL PENTANE 75%

ISOPENANE 30%, NORMAL PENANE 70%

ISOPENANE 40%, NORMALPENANE 60%

ISOPENANE 45%, NORMALPENANE 65%

ISOPENANE 50%, NORMALPENIANE 50%

ISOPENTANE 70%, NORMAL PENTANE 30%

ISOPENANE 75%, NORMAL PENANE 25%

NORMAL PENTANE, 95%

NORMAL PENTANE, 99%

PACKAGING

We offer a range of packaging from a bulk of 20 tonnes to a 1 litre sample.

BULK – up to 20 tonnes

CONTAINERS – 20″ GP container, 40″ GP container

DRUMS – 200 litres, 125KG, up to 150 KG

ISO Tanks – 14.5 MT, up to 17 MT

SAMPLE – 1 litre

Pentane Blend Market Price on September 09, 2022

The price of Pentanes in China has fluctuated greatly in the recent month. After a period of decline, it has been rising in the recent month, with a weekly price increase of about 100 CNY per ton The prices of n-/Isopentane and cyclo-/Isopentane also maintained an upward trend. Junyuan Petroleum Group believes that Pentane prices are now at a relatively low point this year, and manufacturers in urgent need of raw materials can start purchasing. In addition, the sea freight to all parts of the world has been reduced by half, compared with the same period last year.

Pentane products are widely used as blowing agent, solvent and chemical raw materials. At present, Junyuan Petroleum Group is the largest manufacturer of high-purity Isopentane, n-Pentane, Cyclopentane and Pentane Blends/Blowing Agents in the Chinese market, with an annual output of 800,000 tons.


Pentane Blend (Blowing Agent) Market Price on September 09, 2022

Product

City

Low End Price

High End Price

Mainstream Price

Rise and Fall

Incoterms

Remarks

n-/Isopentane

Dongying

7900

8050

7950

0

EXW

Cyclo/Isopentane

Dongying

7900

8050

7950

0

EXW

Remarks:
1. The price in this list is the price including tax in spot exchange, and the unit is CNY / ton;
2. Release time: before 17:00 on working days, for reference only;
3. The rise and fall are compared with the closing price of the previous working day.



n-/Isopentane Refrigeration Foaming

Refrigerant is the working medium of refrigeration, also known as refrigerant, snow. In the refrigeration system, it is vaporized by absorbing energy from the cooling medium in the evaporator, and transfers heat to air and water in the condenser to condense. The increase in the consumption of refrigerants in China also drives the demand for refrigerants. Another point is that the state promotes fluorite as a strategic resource for protective development. In combination with these reasons, the price of refrigerants gradually rises.

At present, there are more than 80 kinds of substances used as refrigerants, including ammonia, freon-12, Freon-22, R-134a, r-404a, R-410A, azeotropic and hydrocarbon refrigerants. Previously, with regard to the impact on the ozone layer, the production of CFC substances such as R11, R12, R113, R114, r115, R502 and R22 was restricted.

In the early days, most of the refrigerants were flammable or toxic, and some accidents often occurred due to excessive pressure. The history of the development of isobutane R600a refrigerant appeared in the middle of the 19th century. It was a vapor compression system using ether as the refrigerant. Carbon dioxide (CO2) and ammonia (NH3) were first used as refrigerants in 1866 and 1873, respectively. Other chemicals include chemical cyanide (petroleum ether and naphtha), sulfur dioxide (r-764) and methyl ether, which have been used as refrigerants for vapor compression. Its application is limited to industrial processes. Most foods are still preserved with ice cubes collected in winter or prepared industrially.

R290 refrigerant, propane refrigerant, is a hydrocarbon refrigerant, which has no damage to the ozone layer and has a very small greenhouse effect. It is actually an environmental protection refrigerant today. From the perspective of environmental protection, almost all countries in the world have no restrictions on the use of R290 refrigerant in the initial installation of new refrigeration equipment and after-sales maintenance. The product is mainly used to replace R22 and R502 refrigerants in low-temperature refrigeration equipment; Because R290 is flammable, it is usually only used in low-temperature refrigeration equipment with less liquid filling, or as a component of low-temperature mixed refrigerant; R290 is compatible with conventional lubricants. The R290 refrigerant steel cylinder for storage and transportation is a pressurized container, which is flammable and explosive. During storage, it should be kept away from kindling and heat sources and avoid direct sunlight exposure. It is usually stored in a cool, dry and ventilated warehouse; During handling, it shall be loaded and unloaded with care to prevent damage to steel cylinders, valves and other accessories. Matching refrigeration oil for the refrigeration engine oil matched with R290 refrigerant, it should follow the recommendations of the manufacturers of refrigeration compressors and refrigeration (air conditioning) equipment, or determine to use the refrigerator lubricating oil with the same design requirements according to the specific conditions of the refrigeration compressors and refrigeration equipment, that is, select the equivalent refrigeration engine oil.

The refrigerant in the refrigerator is added with fluorine in a fixed amount. Use a fixed amount dispenser to add fluorine according to the marked amount. When adding fluorine, feel whether the return pipe is cool by hand. If the return pipe is cold or slightly dewy, the evaporator can be basically covered with frost. When filling, first add less fluorine than the original amount and let it run. When the evaporator is full of frost, finally add it to the return pipe only to condense dew. Generally speaking, the steps of fluorinating the refrigerator are very simple. Vacuumize the refrigerator, pump out the air inside, and then add fluorine. Then seal the refrigerator.

The use of new environmentally friendly refrigerants does not destroy the ozone layer, and the refrigeration efficiency is higher than before. The use of new hydrocarbon refrigerants has also begun internationally, which fully meets the international standards for energy conservation, environmental protection and emission reduction. It is the ideal refrigerant in the world at present.

Mixed pentane blowing agent, in which n-pentane and isopentane account for 50%, i.e. pentane 50 / 50

PENTANE (ISO-NORMAL) PENTANE 50/50

n-Pentane

CAS NO. 109-66-0

Chemical formula C5H12

n-Pentane, a highly flammable alicyclic hydrocarbon. It has three structural isomers, n-Pentane isomer, isopentane (methylbutane) and neopentane (dimethylpropane).

Pentane blends is mixed by n-Pentane andIsopentane by certain ratio, mainly used as blowing/expandable agent, for EPS foaming, etc. Saturated acyclic hydrocarbons;
(ISO TANK) PENTANE (ISO-NORMAL) PENTANE 50/50  (ACYCLIC HYDROCARBONS)

Pentane 80/20 is a blend of 80% n-Pentane and 20% Isopentane.

Pentane 60/40 is a blend of 60% n-Pentane and 40% Isopentane.

Pentane 50/50 is a blend of 50% n-Pentane and 50% Isopentane.

Customer-taliored grade is avaliable.

2. Specification or COA

ItemUnitSpecificationTest Result
AppearanceClear colorlessClear colorless
Color-saybolt+30min+30min
PentaneWt%99min99.87
n-PentaneWt%84-8684.4455
IsopentaneWt%14-1615.4247
CyclopentaneWt%1max0.1132
Hexane and heavierWt%0.1max0
Butane and lighterWt%0.1max0
Benzeneppm10maxNon detected
Total Oleffinesmg/kg20maxNon detected
Total Sulfurppm1max0.25
Bromine IndexmgBr/100g10max1.5
Waterppm30max10
Non volatile mattermg/100mL0.5max0.01

3. Product Application

n-Pentane is mainly used as a primary blowing agent in the manufacturing of polystyrene foam like EPS, PIR etc. It is used because of its lower cost compared to other chemicals, low boiling point and relative safety when in use.

n-Pentane is also used as a solvent and in varied industrial applications such as pharmaceutical, petrochemical, paints & coatings.

4. Packing & Delivery

Standard export neutral packing in 15MT ISO TANK or 200-Liter drums.

Pentane Blends

Expansion of Expandable Polystyrene (EPS)
Expansion Basics • Heat Is Applied • Beads Expand • Beads Cool • Beads Age
Expansion – Behind the Scenes • Heat Is Applied • Blowing agent(s) vaporizes (28oC iso-pentane, 35oC normal-pentane, 49oC cyclo-pentane) • Blowing agent(s) permeate through the polymer (n-pentane<i-pentane<c-pentane)
Expansion – Behind the Scenes • Beads Expand • Polymer/blowing agent matrix reaches it’s glass transition temperature (Tg) (about 85oC, varies according to Mw & BA type) • Polymer chains become fluid • Internal pressure created by blowing agent vaporization push apart [unfold] polymer chains, creating cells
Expansion – Behind the Scenes
Expansion – Behind the Scenes • Beads Expand (cont.) • Air & steam permeate into the beads • As expansion continues, cell walls become thin and subjection to high heat can cause them to break and rupture
Expansion – Behind the Scenes • Beads Expand (cont.) • Throughout expansion, blowing agent(s) continue(s) to permeate out of the bead at an increasing rate [depending on temperature and thickness of cell walls] (When permeation rate =/> vaporization rate, expansion ceases)
Blowing agents begin to vaporize Polymer/blowing agent matrix reaches its Tg Cell walls begin to rupture Expansion begins after reaching Tg and proceeds rapidly Loss of blowing agent becomes more rapid as temperature increases
Primary Expansion Controls • Temperature • Time
Temperature Affects • Greater the temperature • Softer the polymer • Increased expansion rate • May result in uneven expansion due to inconsistent • pentane content • bead size • cell structure • raw material “carry over” [extreme cases] • Increased permeation rate of blowing agent
Expansion verses Temperature • <100oC • Expansion can be sluggish due to stiff polymer • >120oC • Polymer is too soft, blowing agent loss is too rapid • 110-120oC • Most efficient use of blowing agent, but beads become sensitive to shrinkage and heat • 100-110oC • Best compromise
Steam Quality • Key to Expansion • Consistent utilities are crucial to achieve consistent densities with consistent volatile content
Secondary Expansion Controls • Volume of Expander • Molecular Weight • Blowing Agent • Bead Size
Expander Volume Affects the total heat available to each bead • Things that can change it • Drop/charge weight • Lumps in expander that don’t discharge • Build up on walls or stir blades
Molecular Weight • The lower the molecular weight, • Increased expandability • Increased heat sensitivity • Increased permeation rate of blowing agent • Increased shrinkage • Increased collapse • Structural strength
Blowing Agent • Amount • Higher percentages give greater expandability (to a point) • Too high a percentage causes rapid permeation thus shrinkage, collapse and heat sensitivity
Blowing Agent • Type • The longer the blowing agent stays in the bead, • Increased expandability • Reduced shrinkage rate • Increased prepuff life (from expansion to mold) • Relative retention n-pentane < i-pentane < c-pentane

Blowing Agent • Degree of Distribution (has a direct affect on cell size) • Expandability • Heat sensitivity • Structural strength • R-Factor (insulation properties) • Permeation rate
Poor Distribution of Blowing Agent Blowing Agent Good Distribution of Blowing Agent
Bead Size • The larger the bead, the easier it is to achieve low densities • Less surface area for blowing agent to permeate out of
Expander Equipment • Continuous • Batch • Wet • Dry
Continuous Expanders • Description • Material is fed into the bottom of the expansion chamber where it is subjected to steam under agitation, material expands and as density decreases, material rises to the top and out the exit chute. • Rely on Time & Temperature
Continuous Expanders • Main Controls • Feed rate • Steam pressure (temperature) • Agitation rate • Outlet height • Fresh air introduction (temperature)
Batch Expanders • Description • A pre-weighed quantity of material is dropped (or charged) into the expansion chamber where either the expander walls are jacketed with steam (dry) &/or steam is injected into the chamber (wet). An agitator keeps material moving. Vacuum, purge or water inject may be used to stop the expansion. • Rely on time, temperature &/or volume
Batch Expanders • Main Controls • Steam pressure (temperature) • Volume or height • Time • Charge weight • Vacuum or purge time • Water inject
Density Check • Consistency is the Key • Procedure • Prepuff is overfilled into a known volume (pre-tared) container. The container is vibrated or tapped (vibration is more consistent). A straight edge is used to strike the top level with the canister. The canister is reweighed and the density calculated.
Expansion – Behind the Scenes • Beads Age, a.k.a. Maturing or Stabilizing • Internal moisture [from condensed steam] permeates out of the bead • Air permeates into the bead until internal and external pressures equal • Blowing agent(s) continue(s) to permeate out of the bead (n-pentane>i-pentane>c-pentane)
Why Age Prepuff? • Foam becomes more resilient after it’s stabilized • Internal vacuum makes beads susceptible to deformation • Reduces blowing agent levels • Too high a blowing agent level leads to excessive cool times and heat sensitivity during molding • Dry prepuff • Improves ease of transportation
Volatile Content on Aging
Aging • Key • A consistent environment is important to provide prepuff to mold with a consistent volatile content
Aging Time Controls • Environment • Air flow Time • Temperature Time • Density Time • Bead Size Time • Blowing Agent Type(boiling point & molecular complexity) Time • Polymer Mw Time
Expansion – Troubleshooting • High Density • Insufficient steam pressure/temperature • check traps, valves, accumulator pressure • steam flow restricted Note: by monitoring both steam pressure and steam temperature, you’ll know your steam quality. • Insufficient steam times • Too high a throughput through expander (continuous) gives raw material carry-over • Wet material
Expansion – Troubleshooting • High Density (continued) • Collapsed or over expanded prepuff • Low blowing agent content in raw EPS • Additive problem (block and shape EPS grades) • Increased drop weight • Electric eye level too low
Expansion – Troubleshooting • Low Density • High steam pressure/temperature • Longer steam times • Reduced drop/charge weight • Wet material • Over dried material • High blowing agent content • Surface additives (block & shape grade EPS) • Electric eye level too high
Expansion – Troubleshooting • Density Fluctuations • Inconsistent steam pressure/temperature • Inconsistent steam time • Erratic drop/charge weights • Inconsistent measuring techniques • Inconsistent blowing agent content • High static (affects electric eye)
Expansion – Troubleshooting • Density Fluctuations (continued) • Purge valve sticking • Vacuum problems • Inconsistent water inject volume • Poor additive distribution (block & shape grade EPS)
Expansion – Troubleshooting • Wet Prepuff • Common on expander start up • Wet steam • Purge valve or vacuum not working • Poor air flow through fluid bed dryer • Too much material in the fluid bed dryer
Expansion – Troubleshooting • Bead Collapse • Over-expanded • Excessive steam pressure/temperature • Excessive steam time • Too high an expansion rate • Thermal shock after expansion • Blades too close to walls or bottom of expansion chamber • Wrong additive package (block and shape grade EPS)
Expansion – Troubleshooting • Lumping • Too much moisture (condensate) • Inadequate stirring • Excessive steam pressure/temperature • Anti-lumping agent level too low • Hot spots in expander • Excessive steam time
Expansion – Troubleshooting • Irregular Prepuff (size/appearance) • Poor or irregular steam flow • Hot spots in expander • Insufficient time in expander • Contamination of prepuff in raw EPS (double pass) • Irregular raw EPS

Pentane

Pentane is a colorless, flammable liquid (the first liquid member of the alkanes) that is lighter than water. It has a pleasant odor that can be detected at 900 ppm, and a moderate odor intensity is observed at 5000 ppm. It occurs as two other isomers, including isopentane [(CH3)2CHCH2CH3] and neopentane [C(CH3)4]. Isopentane (2-methylbutane) apparently has physical and physiological characteristics similar to straight-chain pentane. Neopentane (2,2-dimethylpropane) is similar to butane in physical and physiological characteristics. In air, one part per million of C5 pentane is equivalent to 3 mg m−3.

Modifying Processing Characteristics: Blowing Agents

It is expected that the trend towards use of carbon dioxide will continue but, where it is not possible to achieve the necessary properties, flammable organic compounds will be used. Expensive, partially fluorinated HFCs with their relatively high GWP will only be used where non-flammability is essential. Chlorine-containing compounds, however, must be replaced completely.

Pentane presents itself as a possible solution to finding an efficient blowing agent which also meets environmental regulations, and years of experience in using it have shown that processing can be safe, as long as safety devices are fully implemented. Bayer’s PU machinery subsidiary, Hennecke GmbH, has developed a state-of-the-art system that monitors all critical control points along the processing chain, to ensure safe production. Among the features are:


completely encapsulated machinery and units (including in-line blenders, work tank, and high-pressure reaction casting machine), also aerated and fitted with exhaust devices, pentane gas sensors, and other safety devices;


a metering and blending supervisory system (Pentament), also permanently vented to prevent gas build up;


an electronic security system controlling all safety features, which can shut down operations, if necessary;


pentane gas warning sensors monitoring all critical components; and


an independent decentralized control system, alerted to all trouble indicators from primary and secondary sensors and monitors.

The modifications were designed to add safety checks to all critical points, first pinpointing all potential hazards (such as ignition sources, leakage points, and static charging) and then developing integrated safeguards.

Bayer and Apache Products have discovered that, by extrusion mixing of high levels of fillers and/or diluents in a PU formulation, loadings of 10–50% filler by weight can be achieved while maintaining or improving key physical properties. The technology makes it possible to handle high-viscosity dispersions effectively, which may reduce production costs of rigid boardstock. Use of solid fillers, solid combustion modifiers, and hollow fillers was studied, suggesting that the higher cost of hollow fillers can be offset by density reduction in the foam board and increase in compressive strength.

Use of this more environmentally friendly alternative may be facilitated for manufacturers of domestic appliances following the introduction of new safety features in the CycloFlex and LinFlex systems for refrigerator cabinet production. Hennecke Machinery has developed a comprehensive safety system for pentane-based foam production, meeting many of the reservations of US manufacturers of PU board.

The principle of Pentane Blowing Agent Use

Pentane blowing agent use the principle of foaming agent and foaming agent differentiation physical foaming agent. Chemical foaming agent is break down to form gas at high temperature decomposition ( N2, CO2, NH3, etc. ) Organic and inorganic substances. This is usually a exothermic decomposition process and irreversible. Physical foaming agent can be liquid, also can be in normal circumstances have vaporized material. The physical foaming agent including aliphatic, hydrocarbons ( Pentane, hexane, decane, etc. ) 。 Chlorine hydrocarbon ( A the methane of cl, methylene chloride, etc. ) 。 Chlorine – Fluorocarbon compounds ( Cross-linked with methane, a fluorine dichlorodifluoromethane, etc. ) CO2, N2, rare gas and air. Regular physical foaming is refers to the the physical foaming agent and resin matrix mixing by changing the conditions in the process of operation; According to the principle of thermodynamic instability that changes the physical foaming agent.Then the process of generating bubbles.

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THERMOSETTING FOAMS

Non–fluorinated blowing agents.

n–Pentane has been used in European countries, e.g., Germany, as a blowing agent for rigid urethane foams. According to Heiling and co–workers’ test results, it has been concluded that there were no indications of higher risks in the case of a real fire. Specifically, the fear concerning explosive–gas mixtures of pentane and air was not confirmed. Explosion–proof dispensing machines have been developed by some companies. Cyclopentane can also be used as a physical blowing agent.

Recently n–pentane–based blowing agents of a blend type have been patented. This patent claims the use of a blend of liquid hydrocarbon and chlorinated hydrocarbon, e.g., a blend of n–pentane and methylene chloride. This method is a convenient way to produce various rigid foams, e.g., polyurethane foams, polyisocyanurate foams, and polyoxazolidone foams. Methylene chloride and pentane have nearly equal boiling points and their blends act like a single solvent. The use of methylene chloride alone results in foam collapse, but a blend of the two solvents does not result in such collapse. A blend of 80/20–90/10 wt % of methylene chloride/pentane is substantially non–combustible, and can be used as the blowing agent for polyisocyanurate–based foams. For rigid polyurethane foams, a blend of about 50/50 wt % is suitable. These blends could solve the disadvantages of 100% water–blown rigid foams mentioned above.

What will be the next generation of blowing agents? Decaire et al. list the requirements for alternative blowing agents as follows: zero ozone depletion potential (ODP), non–flammable or moderately flammable, 50°C boiling point upper limit, and molecular weight below 180. In addition, the cost ($/mole) of a blowing agent is another important industrial factor.

The use of some azeotropic mixtures as blowing agents for rigid urethane foams have been proposed by Doerge. These blowing agents include CFC–11/methyl formate (238), and HCFC–141b/2–methyl butane. Ashida et al disclosed halogen–free azeotropes.

2–Chloropropane as blowing agent for rigid urethane foams has been developed by Recticel.

Mixed gas/liquid blowing agents for rigid urethane foams have also been proposed. The patent claims the use of hydrocarbons having boiling points (a) less than 10°C or (b) 20–30°C, or (c) an inert organic liquid having a boiling point of 35–125°C. Another mixed blowing agent for rigid urethane foams was proposed by a patent which claims the use of a mixture of cycloalkanes, e.g., cyclopentane and cyclohexane, and, if necessary, water The non–fluorinated blowing agents described above can also be applied to polyisocyanurate foams, polyoxazolidone foams, polyurea foams, etc.

Methylene chloride has been used as an auxiliary blowing agent for a long period of time. In some countries, however, due to possible occupational and environmental problems, increased restrictions have been placed on the use of methylene chloride. Therefore, other types of auxiliary blowing agents have been proposed.

Liquefied carbon dioxide is proposed as an auxiliary blowing agent for water–blown flexible urethane foams. Hydrocarbons having a boiling point of 38–100°C are proposed for use in self–skin foam production. Blends of hydrocarbons having a boiling point above −50°C and below 100°C have been proposed as auxiliary blowing agents for water–blown flexible foams.

Pentane blowing agents for polyurethane foams

Pentane blowing agents for polyurethane foams

Pentanes as blowing agents in insulating foams, which are largely responsible for the excellent performance of the insulating materials. All three isomers of Pentane are used: n-Pentanes, Isopentanes and Cyclopentanes. It is particularly important for manufacturers of insulating materials to have high quality, individual blend compositions and tailor-made formulations. Insulating materials for refrigerators or the construction industry depend on Pentanes as an important blowing agent for insulating foams. This makes it all the more important to have high-quality n-Pentanes, Isopentanes and Cyclopentanes from a reliable supplier:

Blowing Agent Manufacturer

Junyuan Petroleum Group is an ISO Certified company. Junyuan Petroleum Group is engaged in manufacturing and exporting specialty solvents. Our solvents caters to a large variety of EPS products manufacturers. We established ourselves as one of the leading manufacturers and exporters of Industrial chemicals and its derivatives in China. On strength of our competent, energetic, experienced, skilled and dedicate R&D team, we have evolved and provided several pentanes and their blends. We cater to the industries engaged in EPS product manufacturing. We cater to a variety of industrial chemical to reputed companies world wide. As we are industrial chemical manufacturer in China with the confidence put in our capabilities & services, we intend to grow as an honest & preferred co-partner to customers having requirements of regular and new molecules which require sophisticated plastic and construction chemistry.
Junyuan Petroleum Group has made its name as most trusted blowing agent manufacturer in Dongying, China. Blowing agents of all types are produced and supplied by Junyuan Petroleum Group all across China. As the best industrial chemical manufacturer in China, Junyuan Petroleum Group has always given importance to its client satisfaction. Timely delivery of our blowing agents are guaranteed by our company.We are dealing in n-Pentane, Isopentane, Cyclopentane, Pentane Blends, Blowing Agents, Pentane 80/20, Pentane 60/40, Pentane 75/25, Pentane 50/50, Pentane 70/30, Pentane 85/15 and Pentane 90/10 etc.

Blowing agent choice per application

In contrast to HCFC141b, where one blowing agent was chosen for all rigid foam applications, different blowing agent choices will be available after the HCFC phase out. Pentane is generally preferred when the foam consumption is high (e.g. in board or panel lamination). In the following figure, the blowing agent choice in industrialised countries is schematically given.
The three corners of the triangle represent a situation where a market segment has been entirely converted to pentane, HFC or to a fully water blown solution. Positions within the triangle indicate the relative amount of producers within a segment, that have chosen any of the three blowing agent options.

Blowing Agent, Pentane Blend, Blowing Agents, Pentane Blends
Blowing Agent, Pentane Blend, Blowing Agents, Pentane Blends

The physical properties of blowing agents are given in the table.

It is interesting to note the differences between the three pentane isomers. There are significant differences in boiling point, gas thermal conductivity and polyol solubility, which leads to very different foam properties and processing characteristics. Cyclo/iso pentane mixtures tend to produce the lowest thermal conductivity foams and are preferred in applications such as refrigerators. Cyclopentane is, in certain cases, preferred when local storage regulations are less stringent than for other pentanes.

Physical properties of blowing agents
Physical properties of blowing agents
Properties of other blowing agents relative to HCFC141b
Properties of other blowing agents relative to HCFC141b

What is Polyurethane Foam?

The great advantages of polyurethane foams are their ability to respond to specific requirements for each application (e.g. density, elasticity and durability) and at prices which make the end products well in reach of the average household. It is estimated that 90% of upholstered furniture has a polyurethane foam filling.

Blowing agent evolution
Blowing agent evolution

The gas phase thermal conductivity of pentane blowing agents

The gas phase thermal conductivity of Cyclopentanes is the lowest among alkane blowing agents. It has relatively high solubility in polyether polyols and is the largest amount of alkane blowing agent. Polyurethane rigid foam Cyclopentane foaming system was industrialized in 1993, mainly used as refrigerator insulation materials. According to Bayer company of Germany, more than 3 million refrigerators have been produced in Europe with its Cyclopentane foaming formula in 1994. Because the boiling point of Cyclopentane is higher than room temperature, part of the cycloalkane gas in the foamed cell condenses and plasticizes the polyurethane matrix. Therefore, in order to achieve the minimum compressive strength required for the stability of foam, the density of foam is higher than that of CFC 11. The foaming foam is more than 10% (the foam density of the refrigerator insulation layer should be more than 38 kg/mJ). Its thermal conductivity is also high.

Comparison of n-pentane, isopentane and cyclopentane foaming systems

n-Pentane and Isopentane are rich in natural resources, and their prices are lower than Cyclopentane. Due to their higher gas-phase thermal conductivity and low solubility in polyether, n-Pentane and Isopentane are rarely used alone in the refrigerator industry. n-/Isopentane mixture is mainly used as blowing agent for rigid polyurethane foam for construction. Since 1994, the company has adopted Isopentane (75/25) foaming system to reduce the minimum stable density of foam to 32, but the thermal conductivity has increased by about 10%. However, due to the uniform density distribution of Pentane blowing foam, the adiabatic energy consumption is only 2% to 5% higher than that of CFC-11 system. The n-/Isopentane (75/25) foaming system developed by Junyuan Petroleum Group also obtained similar results. The stable density of the refrigerator body is about 34, while the thermal conductivity of the foam at 10 ℃ is 2lmw/ (MK), only lmw/ (MK) higher than that of the cyclopentane foam.

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