I n n o v a t I v e t e c h no l og y • e n a b l I n g n ew a p p l I c a t I o n s
ocv™ hIgh-peRFoRMance ReInFoRceMents
MaKIng hIgh-peRFoRMance coMposItes aFFoRDablepRovIDIng gReateR choIce FoR the cUstoMeR
OWENS CORNINGCOMPOSITE MATERIALS, LLCONE OWENS CORNING PARKWAYTOLEDO, OHIO 436591.800.GET.PINK™www.owenscorning.comwww.ocvreinforcements.com
EUROPEAN OWENS CORNING FIBERGLAS, SPRL.166, CHAUSSÉE DE LA HULPEB-1170 BRUSSELSBELGIUM322.674.8211
OWENS CORNING SHANGHAI COMPOSITES CO. LTD.OLIVE L.V.O. MANSION, 2ND FLOOR620 HUASHAN ROADSHANGAI 200122CHINA86.21.62489922
The information and data contained herein are offered solely as a guide in the selection of reinforcement. The information contained in this publication is based on actual laboratory data and field test experience. We believe this information to be reliable, but do not guarantee its applicability to the user’s process or assume any responsibility or liability arising out of its use or performance. The user agrees to be responsible for thoroughly testing any application to determine its suitability before committing to production. It is important for the user to determine the properties of its own commercial compounds when using this or any other reinforcement. Because of numerous factors affecting results, we make no warranty of any kind, express or implied, including those of merchantability and fitness for a particular purpose. Statements in this publication shall not be construed as representations or warranties or as inducements to infringe any patent or violate any law, safety code or insurance regulation.
Owens Corning reserves the right to modify this document without prior notice. OCV is a trademark of Owens Corning. WindStrand, ShieldStrand, FliteStrand, XStrand and Advantex are registered trademarks of Owens Corning. S-2 Glass is a registered trademark of AGY Holdings. Kevlar and Nomex are registered trademarks of DuPont.© 2009 Owens CorningPub. No. 10011498. Printed in U.S.A. September 2009
2
contents
3. Expanding the Market for Composites Through Innovation
4. Leveraging Technology for Breakthrough Innovations
6. ShieldStrand® Reinforcements for Lightweight Protection
8. XStrand® Reinforcements for Stronger, Stiffer and Lighter Composites
10. WindStrand® Reinforcements for Lower-Cost Power
12. FliteStrand® Reinforcements for Lighter Aircraft
14. Enabling More Possibilities
15. Glossary
Advantex® glass: Proprietary Owens Corning glass with higher corrosion and temperature resistance than conventional E-glass that is both an E-glass and a true E-CR glass according to ASTM D578, ISO 2078 and DIN1259-1.
Aramid: A generic name for aromatic polyamides (Kevlar® and Nomex® are examples of Aramid).
Bare glass: Glass fiber from the bushing before binder or sizing is applied.
Carbon fiber: Fibers made from an organic precursor by oxidation and carbonization and not having a graphite structure.
Composite: A combination of two or more materials (reinforcing elements, filler and resin) that retain their identities while acting in concert.
E-glass: A borosilicate glass commonly used in glass fibers for reinforced plastics; suitable for electrical laminates.
Fabric, non-woven: A textile structure produced by bonding or interlocking fibers by mechanical, chemical or solvent means.
Fabric, woven: Material constructed of interlaced yarns, fibers or filaments.
Filament: The smallest unit of fibrous material.
Glass fiber: An individual filament made by attenuating molten glass.
Kevlar®: Dupont’s trade name for an organic polymer composed of aromatic polyamides.
Knitted fabrics: Fabrics produced by interlooping strands of yarn, roving, etc.
Laminate: Material composed of layers of resin and reinforcement bonded together.
Modulus: The ratio of stress to strain in a material that is elastically deformed; if tensile strength of 1000 psi results in an elongation of 1 percent, the modulus of elasticity is 1000/.01 or 100,000 psi.
Polymer: An organic compound, natural or synthetic, whose structure can be represented by a repeated small unit, such as polyethylene, rubber, polyester and cellulose.
Pre-preg: Abbreviation for pre-impregnated reinforcement fibers ready for placement in a mold.
Reinforced plastics: Plastic parts consisting of resins to which reinforcing fibers, mats, fabrics, etc., have been added before the forming operation.
Resin: A solid or pseudo-solid organic material that exhibits a tendency to flow under stress. Most resins are polymers. In reinforced plastics, the material used to bind together the reinforcement material.
Roving: A number of strands or ends collected into a parallel bundle with little or no twist of fibers.
Roving yield: A measure of the linear density of a fiberglass roving in yards/lbs., the lower the number the larger the size of the roving bundle.
S-glass: A magnesia-alumina-silicate glass, especially designed to provide very high tensile strength glass filaments.
S-2 Glass® fiber: AGY Holdings Corp. brand of S-glass fibers.
Sizing: Any treatment consisting of starch, gelatin, oil, wax or other suitable ingredient that is applied to fibers at the time of formation to protect the surface, aid the process of handling and fabrication, and provide binding action, but no coupling agent.
Tensile strength: Maximum tensile stress sustained by a specimen prior to failure in a tensile test.
Tex: A unit for expressing linear density, equal to the mass in grams of 1,000m of yarn, filament, fiber or other textile strand.
Thermoplastic: Capable of being repeatedly softened by increase of temperature and hardened by decrease in temperature; applicable to those materials whose change upon heating is substantially physical rather than chemical and that in the softened stage can be shaped by flow into articles by molding or extrusion.
Thermoset: A plastics that, when cured by application of heat or chemical means, changes into a substantially infusible and insoluble material.
UHMWPE: Ultra-High Molecular Weight Polyethylene – a thermoplastic material composed of many molecules of ethylene and exhibiting extreme toughness and abrasion resistance.
Veil: A non-woven glass fiber mat used in a variety of applications to provide strength and enhance surface finish.
Yield: A term to describe weight per unit length in yards/lbs., for example a 113 yield product weighs 113 yards/lb.
glossaRy
Building on its heritage of leadership and innovation in glass fiber reinforcement and composite technology, Owens Corning has developed a new generation of reinforcement technology that redefines the availability and value of high-performance glass fiber materials.
Proprietary technology provides the nucleus for an extensive and growing array of products with special properties. This new era in reinforcements began in 1997 with the introduction of Advantex® glass, a patented boron- and fluorine-free platform that produces higher-performing glass fiber and a significantly smaller environmental footprint compared with standard E-glass processes.
By 2006, Owens Corning had extended the use of Advantex® technology to bring large-scale production to high-strength glass fiber, an achievement previously thought to be technically unfeasible. The company’s first application of this high-strength glass fiber technology was a family of high-performance reinforcements based on an R-glass formulation. The technology has now been extended again to include enhanced S-glass high-performance reinforcements.
Capacity for the new direct-melt process is about 50 times the size of paramelters typically used to produce high-strength glass. This scale production process was developed to make high-performance reinforcements widely available and achieve a level of value that enhances their competitiveness. Wider availability will provide greater choice and security of supply, encouraging the use of high-performance glass fiber reinforcements by designers and manufacturers. Improved competitiveness will enable composites to continue replacing traditional materials such as steel and aluminum.
The benchmarks for high-strength glass fiber reinforcements are now:
• ShieldStrand® reinforcements for defense• XStrand® reinforcements for industrial, sports and recreation• WindStrand® reinforcements for wind energy• FliteStrand® reinforcements for aerospace
Owens Corning has developed high-performance products to meet the specific needs of these markets.
Expanding thE MarkEt for CoMpositEsthrough innovation
3
• Innovative technology
• Redefining value
• Enabling new applications
4
5
LEvEraging tEChnoLogy for BrEakthrough innovationsFor more than 70 years, Owens Corning has pioneered the development of the glass fiber industry and transformed markets by replacing traditional materials – wood, steel and aluminum – with glass fiber composites in thousands of applications.
Since the company first commercialized the processes for making fiberglass reinforcements, Owens Corning has continued to deliver innovative solutions:
1938 DevelopedE-glass
1963 DevelopedS-glass
1968 DevelopedS-2Glass®†reinforcements
1980 DevelopedECRGLAS®reinforcements
1997 DevelopedAdvantex®glass
2006 Developeddirect-meltR-glasshigh-performancereinforcements,trademarked–ShieldStrand®,XStrand®,FliteStrand®andWindStrand®
2009 ReinventedS-glasswithproprietarymanufacturingtechnology
Owens Corning introduced S-glass in 1963 after four years of research and development. With high tensile strength and high operating temperature, S-glass reinforcements were initially used for filament-wound rocket motor cases. The new glass formulation required a new fiberizing process due to the elevated processing temperature; this led to development of the paramelt process still used today for some high-performance glass fibers.
In the nearly 50 years since S-glass was developed, Owens Corning has continued to advance fiber-forming science and redefine what is possible. The company now makes high-strength glass fibers with:
• New glass melting technology• New glass delivery technology• New glass fiberizing technology• New glass chemistry and application technology
Used in concert, this cutting-edge technology is enabling large-scale, direct-melt production of high-quality, high-strength glass fiber reinforcements for the most demanding applications.
Development of the new generation of high-performance glass fiber reinforcements is being driven by the composites industry’s need for large-volume production of high-strength, high-value material that will enable it to compete more effectively with traditional materials. The expanded platform underscores the company’s commitment to providing a broad range of innovative reinforcement products that meet global market needs.
Glass Composition
Owens Corning is the only company offering the full range of industrial glass materials globally.
While some companies are promoting reinforcements with enhanced sizing chemistry as “high performance,” Owens Corning high-performance reinforcements are
produced from glasses specifically formulated to yield higher tensile strength and stiffness. Owens Corning high-performance reinforcements are based on both R- and S-glass compositions. Bare S-glass properties are comparable to other commercial S-glasses. Due to advances in sizing and application technology, laminate properties can exceed previous standards.
Composite Properties
The following graph shows stress-strain curves typically obtained on a single filament according to ASTM D2101. Note that Owens Corning high-performance reinforcements, made with R- and S-glass, provide improved performance versus conventional E-glass properties with significantly higher strength, stiffness and strain to failure. Higher fiber toughness, which is almost twice the area (= strain energy) under the stress-strain curve, provides very good impact properties and damage tolerant behavior for parts subjected to impact such as ballistic panels, spall liners, pressure vessels and aircraft cargo liners.
Stress-strain curves for various fibers show that OCV S- and R-glass provide better impact resistance and compression strength in a composite part than conventional E-glass, carbon and aramid fibers. The area under the curve defines the strain to failure or impact resistance.
Carbon fiber has high modulus but fails at relatively low elongation compared to S-glass, resulting in lower overall strength and toughness. In addition, carbon does not perform well under compression.
† The trademark, technology and equipment for making S-2 Glass® fiber was spun off in 1998 in a venture that became AGY Holdings Corp., an independent and privately held enterprise * Not all product forms, sizings and secondary processes are available for every glass composition.
Delivering high performance
Owens Corning offers a broad range of product and property choices that enable the best materials solutions for your application.
Owens Corning high-performance reinforcements deliver high specific tensile modulus.
Owens Corning high-performance reinforcements deliver high tensile strength.
- 4 .0% - 2.0% 0 .0% 2.0% 4.0% 6. 0%
-4000
-2000
0
2000
4000
6000 MPa
Typical Stress-Strain Curves of Fibers
S-glass
R-glassAdvantex®
E-glass
AramidHS Carbon
3.6538
K49Aramid
5.0769
6.00
5.00
4.00
3.00
2.00
1.00
0.00
AS4Carbon
1.453
CompetitiveS-glass
1.433
OCV™
S-glass
Glass Type
1.36
OCV™
R-glass
1.127
Advantex®
1.232
E-glassYarn
Spec
i�c
Fibe
r Ten
sile
Mod
ulus
10
8 in
Fiber Speci�c Tensile Modulus 108 in
9.00
10.00
7.00
6.00
4.00
8.00
5.00
3.00
2.00
1.00
0.00
Fiber Speci�c Tensile Strength 106 in
Spec
i�c
Fibe
r Ten
sile
Str
engt
h 10
6 in 8.92
K49Aramid
9.62
AS4Carbon
7.82
CompetitiveS-glass
8.427
OCV™
S-glass
Glass Type
7.22
OCV™
R-glass
5.73
Advantex®
5.37
E-glassYarn
oCv™ rEinforCEMEnts produCts
Available in various product forms and multiple sizing chemistries to deliver optimum performance in processing and in the finished composite part.
Advantex®
R-glass• ShieldStrand® reinforcements • XStrand® reinforcements
• WindStrand® reinforcements
S-glass• ShieldStrand® S reinforcements • XStrand® S reinforcements
• FliteStrand® S reinforcements
4
5
LEvEraging tEChnoLogy for BrEakthrough innovationsFor more than 70 years, Owens Corning has pioneered the development of the glass fiber industry and transformed markets by replacing traditional materials – wood, steel and aluminum – with glass fiber composites in thousands of applications.
Since the company first commercialized the processes for making fiberglass reinforcements, Owens Corning has continued to deliver innovative solutions:
1938 DevelopedE-glass
1963 DevelopedS-glass
1968 DevelopedS-2Glass®†reinforcements
1980 DevelopedECRGLAS®reinforcements
1997 DevelopedAdvantex®glass
2006 Developeddirect-meltR-glasshigh-performancereinforcements,trademarked–ShieldStrand®,XStrand®,FliteStrand®andWindStrand®
2009 ReinventedS-glasswithproprietarymanufacturingtechnology
Owens Corning introduced S-glass in 1963 after four years of research and development. With high tensile strength and high operating temperature, S-glass reinforcements were initially used for filament-wound rocket motor cases. The new glass formulation required a new fiberizing process due to the elevated processing temperature; this led to development of the paramelt process still used today for some high-performance glass fibers.
In the nearly 50 years since S-glass was developed, Owens Corning has continued to advance fiber-forming science and redefine what is possible. The company now makes high-strength glass fibers with:
• New glass melting technology• New glass delivery technology• New glass fiberizing technology• New glass chemistry and application technology
Used in concert, this cutting-edge technology is enabling large-scale, direct-melt production of high-quality, high-strength glass fiber reinforcements for the most demanding applications.
Development of the new generation of high-performance glass fiber reinforcements is being driven by the composites industry’s need for large-volume production of high-strength, high-value material that will enable it to compete more effectively with traditional materials. The expanded platform underscores the company’s commitment to providing a broad range of innovative reinforcement products that meet global market needs.
Glass Composition
Owens Corning is the only company offering the full range of industrial glass materials globally.
While some companies are promoting reinforcements with enhanced sizing chemistry as “high performance,” Owens Corning high-performance reinforcements are
produced from glasses specifically formulated to yield higher tensile strength and stiffness. Owens Corning high-performance reinforcements are based on both R- and S-glass compositions. Bare S-glass properties are comparable to other commercial S-glasses. Due to advances in sizing and application technology, laminate properties can exceed previous standards.
Composite Properties
The following graph shows stress-strain curves typically obtained on a single filament according to ASTM D2101. Note that Owens Corning high-performance reinforcements, made with R- and S-glass, provide improved performance versus conventional E-glass properties with significantly higher strength, stiffness and strain to failure. Higher fiber toughness, which is almost twice the area (= strain energy) under the stress-strain curve, provides very good impact properties and damage tolerant behavior for parts subjected to impact such as ballistic panels, spall liners, pressure vessels and aircraft cargo liners.
Stress-strain curves for various fibers show that OCV S- and R-glass provide better impact resistance and compression strength in a composite part than conventional E-glass, carbon and aramid fibers. The area under the curve defines the strain to failure or impact resistance.
Carbon fiber has high modulus but fails at relatively low elongation compared to S-glass, resulting in lower overall strength and toughness. In addition, carbon does not perform well under compression.
† The trademark, technology and equipment for making S-2 Glass® fiber was spun off in 1998 in a venture that became AGY Holdings Corp., an independent and privately held enterprise * Not all product forms, sizings and secondary processes are available for every glass composition.
Delivering high performance
Owens Corning offers a broad range of product and property choices that enable the best materials solutions for your application.
Owens Corning high-performance reinforcements deliver high specific tensile modulus.
Owens Corning high-performance reinforcements deliver high tensile strength.
- 4 .0% - 2.0% 0 .0% 2.0% 4.0% 6. 0%
-4000
-2000
0
2000
4000
6000 MPa
Typical Stress-Strain Curves of Fibers
S-glass
R-glassAdvantex®
E-glass
AramidHS Carbon
3.6538
K49Aramid
5.0769
6.00
5.00
4.00
3.00
2.00
1.00
0.00
AS4Carbon
1.453
CompetitiveS-glass
1.433
OCV™
S-glass
Glass Type
1.36
OCV™
R-glass
1.127
Advantex®
1.232
E-glassYarn
Spec
i�c
Fibe
r Ten
sile
Mod
ulus
10
8 in
Fiber Speci�c Tensile Modulus 108 in
9.00
10.00
7.00
6.00
4.00
8.00
5.00
3.00
2.00
1.00
0.00
Fiber Speci�c Tensile Strength 106 inSp
eci�
c Fi
ber T
ensi
le S
tren
gth
106 i
n 8.92
K49Aramid
9.62
AS4Carbon
7.82
CompetitiveS-glass
8.427
OCV™
S-glass
Glass Type
7.22
OCV™
R-glass
5.73
Advantex®
5.37
E-glassYarn
oCv™ rEinforCEMEnts produCts
Available in various product forms and multiple sizing chemistries to deliver optimum performance in processing and in the finished composite part.
Advantex®
R-glass• ShieldStrand® reinforcements • XStrand® reinforcements
• WindStrand® reinforcements
S-glass• ShieldStrand® S reinforcements • XStrand® S reinforcements
• FliteStrand® S reinforcements
6
7
shiELdstrand® rEinforCEMEnts for LightwEight protECtionIncreasing global warfare and the need for security are driving demand for solutions that can defeat increasing threats. At the same time, enhancing safety and security must be balanced with practical constraints such as weight and cost. The result is the need for armor that can withstand increasing threat levels while weighing less and delivering greater value to protect the necessary number of vehicles and structures.
Now there are solutions that can satisfy the performance needs of a variety of applications and threats. The solutions are ShieldStrand® (made with R glass) and ShieldStrand® S reinforcements, a family of high-strength, high-modulus glass fibers that are available and redefine the value of high-performance glass fiber reinforcements. ShieldStrand® reinforcements provide significantly enhanced fiber properties for better finished part performance. They increase ballistic protection while lowering weight, meeting threat levels and stretching budgets.
ShieldStrand® reinforcements combine state-of-the-art technology and formulation in a revolutionary manufacturing process to achieve high performance at a value that is much more attractive than current materials. As a result, it is now possible to produce composite armor that will meet a variety of threat levels. In addition Owens Corning manufacturing technology provides substantial capacity to meet growing demand.
ShieldStrand® reinforcements are available at two levels of performance and value. Standard ShieldStrand® reinforcements are made with R-glass for lower threat levels, and ShieldStrand® S reinforcements are made with S-glass and for protection against higher threat levels. Compared to competitive high-strength glass fibers, ShieldStrand® S reinforcements offer the same level of ballistic performance.
Unlike aramid and ultra-high-molecular-weight polyethylene (UHMWPE), ShieldStrand® reinforcement offers superior mechanical properties, delivering structural performance as well as protection.
ShieldStrand® S reinforcements are made from a boron-free glass formulation that meets S-glass standards defined by ASTM C162, DIN 1259, ISO 2078, ASTM D578 and JIS R3410. The glass formulation is designed for excellent mechanical properties (tensile strength and modulus). ShieldStrand® S reinforcement offers a balanced solution that is one-half the weight of steel and one-third the cost of UHMWPE at the same level of performance. These benefits result in both lighter and more affordable armor systems.
ShieldStrand® reinforcements are qualified under MIL-DTL-64154B Class B. Qualification is pending for ShieldStrand® S glass fibers under MIL-DTL-64154B Class A. ShieldStrand® and ShieldStrand® S reinforcements do not burn or melt and meet fire, smoke and toxicity (FST) requirements.
ShieldStrand® S reinforcements are available in fiber, fabric, pre-preg and armor panels, either from Owens Corning or our customers.
ShieldStrand® and ShieldStrand® S reinforcements meet MIL-spec ballistic V50 (30 caliber FSP) performance levels.
ShieldStrand® S high-performance reinforcements provide a balanced solution – one-half the weight of steel and one-third the cost of UHMWPE. (+++ = best in class, --- = worst in class.)
MarkEt: dEfEnsE
Need:• Light weight solutions• Lower unit cost • Integrated structure with armor protection
Solution: Ballistic and blast-resistant panels using ShieldStrand® and ShieldStrand® S reinforcements
Stronger:
• XStrand® S Glass is up to 50 percent stronger, 20 percent stiffer and 80 percent tougher than traditional E-glass
• ShieldStrand® S reinforcements provide the same level of ballistic performance as competitive S-glass reinforcements
• ShieldStrand® reinforcements provide structural as well as ballistic solutions
• ShieldStrand® reinforcements meet fire, smoke and toxicity requirements
Lighter: • Significant weight reduction over E-glass, steel and
aluminum
Available:
• ShieldStrand® and ShieldStrand® S reinforcements are produced in large quantities and are available today
high-strEngth MatEriaLs for LightwEight, intEgratEd struCturEs and protECtion
Delivering Performance• Validated MIL-spec ballistic performance• Up to 40 percent weight savings versus aluminum for
equivalent FSP protection could increase vehicle payload and mobility
• Easily used with a steel or ceramic strike face to provide protection when armor piercing and multi-hit capability is required or an overmatched threat exists
• Meets fire, smoke and toxicity requirements• Provide excellent durability in high-temperature,
corrosive and high-humidity environments
Readily Available• Produced on a large scale using innovative OCV glass
fiber technology • Production can support surges common in defense
applications• As a fabricated product, historical pricing of glass fiber
reinforcements has been less volatile than the specific aluminum alloys used in protection applications
Enabling Possibilities• ShieldStrand® and ShieldStrand® S reinforced panels can
provide structure as well as protection, allowing armor to be integrated into the vehicle, reducing overall vehicle weight
• Can be molded into large complex-shaped structural parts using proven large scale composite manufacturing technologies
• Because it is one-third the cost of UHMWPE, more vehicles can be protected, increasing survivability
ShieldStrand® high-performance reinforcements make lightweight protection affordable.
a BaLanCEd soLution – haLf thE wEight of stEEL, onE-third thE Cost of uhMwpE
Ballistic Performance of ShieldStrand® per MIL-DTL-64154B
2900
3000
2700
2600
2400
2800
2500
5.0 5.1 5.2 5.3 5.4 5.5
MIL-DTL-64154B (Class B)
MIL-DTL-64154B (Class A)
2300
2200
2100
2000
Areal Density (psf)
V50
(fp
s)
ShieldStrand®
ShieldStrand® S
+
+
++---
-++
++
++
++
++
+
+
+
+
--
++++++
--
+++
+++
++
-
+++++
-
++
++
++
+++
----
-
-
--
---
++++
+
.30 cal FSP at 2455fps
ShieldStrand® S S-2 Glass®
Performance
Weight
Cost
StructuralCapability
Part Thickness(+ = thin)CorrosionResistance
Fire, Smoke,Toxicity
TemperatureResistance
Steel Aluminum Aramid UHMWPolyethylene
Armor Material Cost vs. Weight(.30 cal FSP at 2455fps)
$50.00
$60.00
$30.00
$20.00
$40.00
$10.00
0 2 4 6 8 10 12$-
Weight required to meet MIL-DTL-64514B (lbs/sf)
Cos
t ($
/lb)
ShieldStrand®
ShieldStrand® S
Aramid
Advantex® (E-glass)5083 AL RHA Steel
UHMWPE
6
7
shiELdstrand® rEinforCEMEnts for LightwEight protECtionIncreasing global warfare and the need for security are driving demand for solutions that can defeat increasing threats. At the same time, enhancing safety and security must be balanced with practical constraints such as weight and cost. The result is the need for armor that can withstand increasing threat levels while weighing less and delivering greater value to protect the necessary number of vehicles and structures.
Now there are solutions that can satisfy the performance needs of a variety of applications and threats. The solutions are ShieldStrand® (made with R glass) and ShieldStrand® S reinforcements, a family of high-strength, high-modulus glass fibers that are available and redefine the value of high-performance glass fiber reinforcements. ShieldStrand® reinforcements provide significantly enhanced fiber properties for better finished part performance. They increase ballistic protection while lowering weight, meeting threat levels and stretching budgets.
ShieldStrand® reinforcements combine state-of-the-art technology and formulation in a revolutionary manufacturing process to achieve high performance at a value that is much more attractive than current materials. As a result, it is now possible to produce composite armor that will meet a variety of threat levels. In addition Owens Corning manufacturing technology provides substantial capacity to meet growing demand.
ShieldStrand® reinforcements are available at two levels of performance and value. Standard ShieldStrand® reinforcements are made with R-glass for lower threat levels, and ShieldStrand® S reinforcements are made with S-glass and for protection against higher threat levels. Compared to competitive high-strength glass fibers, ShieldStrand® S reinforcements offer the same level of ballistic performance.
Unlike aramid and ultra-high-molecular-weight polyethylene (UHMWPE), ShieldStrand® reinforcement offers superior mechanical properties, delivering structural performance as well as protection.
ShieldStrand® S reinforcements are made from a boron-free glass formulation that meets S-glass standards defined by ASTM C162, DIN 1259, ISO 2078, ASTM D578 and JIS R3410. The glass formulation is designed for excellent mechanical properties (tensile strength and modulus). ShieldStrand® S reinforcement offers a balanced solution that is one-half the weight of steel and one-third the cost of UHMWPE at the same level of performance. These benefits result in both lighter and more affordable armor systems.
ShieldStrand® reinforcements are qualified under MIL-DTL-64154B Class B. Qualification is pending for ShieldStrand® S glass fibers under MIL-DTL-64154B Class A. ShieldStrand® and ShieldStrand® S reinforcements do not burn or melt and meet fire, smoke and toxicity (FST) requirements.
ShieldStrand® S reinforcements are available in fiber, fabric, pre-preg and armor panels, either from Owens Corning or our customers.
ShieldStrand® and ShieldStrand® S reinforcements meet MIL-spec ballistic V50 (30 caliber FSP) performance levels.
ShieldStrand® S high-performance reinforcements provide a balanced solution – one-half the weight of steel and one-third the cost of UHMWPE. (+++ = best in class, --- = worst in class.)
MarkEt: dEfEnsE
Need:• Light weight solutions• Lower unit cost • Integrated structure with armor protection
Solution: Ballistic and blast-resistant panels using ShieldStrand® and ShieldStrand® S reinforcements
Stronger:
• XStrand® S Glass is up to 50 percent stronger, 20 percent stiffer and 80 percent tougher than traditional E-glass
• ShieldStrand® S reinforcements provide the same level of ballistic performance as competitive S-glass reinforcements
• ShieldStrand® reinforcements provide structural as well as ballistic solutions
• ShieldStrand® reinforcements meet fire, smoke and toxicity requirements
Lighter: • Significant weight reduction over E-glass, steel and
aluminum
Available:
• ShieldStrand® and ShieldStrand® S reinforcements are produced in large quantities and are available today
high-strEngth MatEriaLs for LightwEight, intEgratEd struCturEs and protECtion
Delivering Performance• Validated MIL-spec ballistic performance• Up to 40 percent weight savings versus aluminum for
equivalent FSP protection could increase vehicle payload and mobility
• Easily used with a steel or ceramic strike face to provide protection when armor piercing and multi-hit capability is required or an overmatched threat exists
• Meets fire, smoke and toxicity requirements• Provide excellent durability in high-temperature,
corrosive and high-humidity environments
Readily Available• Produced on a large scale using innovative OCV glass
fiber technology • Production can support surges common in defense
applications• As a fabricated product, historical pricing of glass fiber
reinforcements has been less volatile than the specific aluminum alloys used in protection applications
Enabling Possibilities• ShieldStrand® and ShieldStrand® S reinforced panels can
provide structure as well as protection, allowing armor to be integrated into the vehicle, reducing overall vehicle weight
• Can be molded into large complex-shaped structural parts using proven large scale composite manufacturing technologies
• Because it is one-third the cost of UHMWPE, more vehicles can be protected, increasing survivability
ShieldStrand® high-performance reinforcements make lightweight protection affordable.
a BaLanCEd soLution – haLf thE wEight of stEEL, onE-third thE Cost of uhMwpE
Ballistic Performance of ShieldStrand® per MIL-DTL-64154B
2900
3000
2700
2600
2400
2800
2500
5.0 5.1 5.2 5.3 5.4 5.5
MIL-DTL-64154B (Class B)
MIL-DTL-64154B (Class A)
2300
2200
2100
2000
Areal Density (psf)
V50
(fp
s)
ShieldStrand®
ShieldStrand® S
+
+
++---
-++
++
++
++
++
+
+
+
+
--
++++++
--
+++
+++
++
-
+++++
-
++
++
++
+++
----
-
-
--
---
++++
+
.30 cal FSP at 2455fps
ShieldStrand® S S-2 Glass®
Performance
Weight
Cost
StructuralCapability
Part Thickness(+ = thin)CorrosionResistance
Fire, Smoke,Toxicity
TemperatureResistance
Steel Aluminum Aramid UHMWPolyethylene
Armor Material Cost vs. Weight(.30 cal FSP at 2455fps)
$50.00
$60.00
$30.00
$20.00
$40.00
$10.00
0 2 4 6 8 10 12$-
Weight required to meet MIL-DTL-64514B (lbs/sf)
Cos
t ($
/lb)
ShieldStrand®
ShieldStrand® S
Aramid
Advantex® (E-glass)5083 AL RHA Steel
UHMWPE
8
xstrand® rEinforCEMEnts for strongEr, stiffEr and LightEr CoMpositEsDesign engineers, composite fabricators, original equipment manufacturers and consumers have been asking for material solutions that provide the performance of high-strength reinforcements, but more readily available and at a better value.
Owens Corning XStrand® reinforcements are now available to provide significantly enhanced fiber properties for better finished part performance. XStrand® reinforcements have outstanding fatigue and impact performance, superior mechanical properties and offer significantly higher thermal performance and excellent corrosion resistance. These characteristics make XStrand® reinforcements ideal for a host of industrial, sports and recreation applications, including use in the growing alternative fuel industry.
XStrand® reinforcements are available at two levels of performance and value. Standard XStrand® reinforcements are made with R-glass for economical solutions, and XStrand® S reinforcements are made with S-glass for even higher levels of performance. The two products are redefining the value in existing composites applications and making new market solutions possible.
XStrand® S reinforcements are a balanced solution with one-half the weight of steel and one-half the cost of carbon fiber-reinforced composites.
XStrand® S roving provides excellent performance in demanding industrial applications that require high-strength reinforcements and long life. Compared to conventional E-glass fibers, XStrand® S reinforcement glass fibers are up to 50 percent stronger, 20 percent stiffer and 80 percent tougher.
XStrand® S reinforcements are available both as a continuous, direct roving product and in fabric form. XStrand® S reinforcement can also be provided in a pre-preg from our customers.
A growing application that illustrates the value of XStrand® S reinforcement is in compressed natural gas (CNG) tanks for transportation. A composite Type 4 cylinder made with XStrand® S reinforcement is one-half the weight of a steel tank with the same storage capacity. The 50 percent weight savings means up to an additional two-ton reduction of CO2 emissions over the lifetime of a mid-size car. In addition, XStrand® S reinforcement provides as much as 40 percent cost savings versus aramid and carbon fibers.
Pressure vessels that use XStrand® S fibers as a replacement for E-glass fibers in the over-wrap improve pressure vessel performance in types II, III and IV.
• Higher performance can reduce warranty cost and lower weight
• Higher-strength glass can reduce total glass fiber content and improve processing speed
• In the case of automotive tanks, lower weight could result in improved vehicle range and handling
• XStrand® S is also more damage- and corrosion-resistant, extending pressure vessel life
Other areas where XStrand® S reinforcements can provide specialty performance and value include high-performance marine vessels, rubber reinforcement and friction applications, communication and power cable, high temperature environments and cured-in-place pipe rehabilitation.
XStrand® S reinforcement delivers the benefits and value that will enable customers to do things they previously thought were not possible.
OCV™ high-performance S-glass fiber provides superior performance in acid and alkaline environments.
Type 4 – 190-liter CNG cylinders: • XStrand® reinforcement enables up to 40 percent cost reduction versus Carbon/Epoxy type 4 solution but with weight penalty. • XStrand® cylinder is half the weight of a typical steel tank and up to 20 percent lighter than equivalent E-glass solution at similar cost (saving in resin and manufacturing time).
XStrand® reinforcements provide CNG pressure vessel manufacturers the opportunity for overall manufacturing cost saving by using less resin and reducing winding cycle time. (Based on production of a 190-liter, 200 bar CNG cylinder)
Strength Retention % vs. pH Exposure for 24 hrs at 96ºC
80
100
40
20
60
00 2 4 6 8 10 12
pH
Stre
ngth
Ret
entio
n (%
)
OCV™ S-glassCompetitive S-glassStd E-glass
40%
30%
60%
50%
80%
70%
100%
90%
0 2502001501005020%
Vessel Weight (kg)
Rel
ativ
e Ve
ssel
s C
ost XStrand®
(Type 4)XStrand® S
(Type 4)
Steel(Type 1)
E-Glass (Type 4)
Carbon (Type 4)
Low ResinPrice
High ResinPrice
CNG Tank – Cost to Weight Comparison of Materials(CNG Tank, 190 lit.)
40%
60%
80%
100%
E-glass (**)
(*) Safety factor 2.35(**) Safety factor 3.65
XStrand® (**)Carbon (*)
20%
0%
Dir
ect
Rel
ativ
e C
ost
%
Cost Structure of Type 4 CNG CylinderCNG T4 Cylinder – Cost Study
ResinFiber
Mfr. direct
9
MarkEts: industriaL, sports and rECrEation
Need:• High strength• Impact resistance• Lighter weight• Lower system cost
Solution: Pressure vessels, high-performance boats, tennis rackets, skis and snow boards made with XStrand® S reinforcements
• Enables up to 50 percent weight savings versus steel• Enables up to 40 percent cost saving versus
carbon fiber• Excellent fatigue and impact resistance• Provides opportunity to translate benefits into
value for end-use customers
8
xstrand® rEinforCEMEnts for strongEr, stiffEr and LightEr CoMpositEsDesign engineers, composite fabricators, original equipment manufacturers and consumers have been asking for material solutions that provide the performance of high-strength reinforcements, but more readily available and at a better value.
Owens Corning XStrand® reinforcements are now available to provide significantly enhanced fiber properties for better finished part performance. XStrand® reinforcements have outstanding fatigue and impact performance, superior mechanical properties and offer significantly higher thermal performance and excellent corrosion resistance. These characteristics make XStrand® reinforcements ideal for a host of industrial, sports and recreation applications, including use in the growing alternative fuel industry.
XStrand® reinforcements are available at two levels of performance and value. Standard XStrand® reinforcements are made with R-glass for economical solutions, and XStrand® S reinforcements are made with S-glass for even higher levels of performance. The two products are redefining the value in existing composites applications and making new market solutions possible.
XStrand® S reinforcements are a balanced solution with one-half the weight of steel and one-half the cost of carbon fiber-reinforced composites.
XStrand® S roving provides excellent performance in demanding industrial applications that require high-strength reinforcements and long life. Compared to conventional E-glass fibers, XStrand® S reinforcement glass fibers are up to 50 percent stronger, 20 percent stiffer and 80 percent tougher.
XStrand® S reinforcements are available both as a continuous, direct roving product and in fabric form. XStrand® S reinforcement can also be provided in a pre-preg from our customers.
A growing application that illustrates the value of XStrand® S reinforcement is in compressed natural gas (CNG) tanks for transportation. A composite Type 4 cylinder made with XStrand® S reinforcement is one-half the weight of a steel tank with the same storage capacity. The 50 percent weight savings means up to an additional two-ton reduction of CO2 emissions over the lifetime of a mid-size car. In addition, XStrand® S reinforcement provides as much as 40 percent cost savings versus aramid and carbon fibers.
Pressure vessels that use XStrand® S fibers as a replacement for E-glass fibers in the over-wrap improve pressure vessel performance in types II, III and IV.
• Higher performance can reduce warranty cost and lower weight
• Higher-strength glass can reduce total glass fiber content and improve processing speed
• In the case of automotive tanks, lower weight could result in improved vehicle range and handling
• XStrand® S is also more damage- and corrosion-resistant, extending pressure vessel life
Other areas where XStrand® S reinforcements can provide specialty performance and value include high-performance marine vessels, rubber reinforcement and friction applications, communication and power cable, high temperature environments and cured-in-place pipe rehabilitation.
XStrand® S reinforcement delivers the benefits and value that will enable customers to do things they previously thought were not possible.
OCV™ high-performance S-glass fiber provides superior performance in acid and alkaline environments.
Type 4 – 190-liter CNG cylinders: • XStrand® reinforcement enables up to 40 percent cost reduction versus Carbon/Epoxy type 4 solution but with weight penalty. • XStrand® cylinder is half the weight of a typical steel tank and up to 20 percent lighter than equivalent E-glass solution at similar cost (saving in resin and manufacturing time).
XStrand® reinforcements provide CNG pressure vessel manufacturers the opportunity for overall manufacturing cost saving by using less resin and reducing winding cycle time. (Based on production of a 190-liter, 200 bar CNG cylinder)
Strength Retention % vs. pH Exposure for 24 hrs at 96ºC
80
100
40
20
60
00 2 4 6 8 10 12
pH
Stre
ngth
Ret
entio
n (%
)
OCV™ S-glassCompetitive S-glassStd E-glass
40%
30%
60%
50%
80%
70%
100%
90%
0 2502001501005020%
Vessel Weight (kg)
Rel
ativ
e Ve
ssel
s C
ost XStrand®
(Type 4)XStrand® S
(Type 4)
Steel(Type 1)
E-Glass (Type 4)
Carbon (Type 4)
Low ResinPrice
High ResinPrice
CNG Tank – Cost to Weight Comparison of Materials(CNG Tank, 190 lit.)
40%
60%
80%
100%
E-glass (**)
(*) Safety factor 2.35(**) Safety factor 3.65
XStrand® (**)Carbon (*)
20%
0%
Dir
ect
Rel
ativ
e C
ost
%
Cost Structure of Type 4 CNG CylinderCNG T4 Cylinder – Cost Study
ResinFiber
Mfr. direct
9
MarkEts: industriaL, sports and rECrEation
Need:• High strength• Impact resistance• Lighter weight• Lower system cost
Solution: Pressure vessels, high-performance boats, tennis rackets, skis and snow boards made with XStrand® S reinforcements
• Enables up to 50 percent weight savings versus steel• Enables up to 40 percent cost saving versus
carbon fiber• Excellent fatigue and impact resistance• Provides opportunity to translate benefits into
value for end-use customers
10 11
windstrand® rEinforCEMEnts for LowEr-Cost powEr
MarkEt: wind EnErgy
Need:• Achieve price parity with traditional fuels
• Lower cost of electricity per kilowatt hour (Kwh)
Solution: Wind turbine generator blades made with Owens Corning WindStrand® reinforcements:
• Enables blade manufacturer to reduce blade weight by up to 10 percent
• Enables up to 6 percent longer blades with no increase in weight
• Provides opportunity to translate benefits into more power
• Ultimately results in a lower cost per Kwh
WindStrand® Reinforcement ValueHigher modulus enables lower blade weight or longer blades:
• Offers option of moving the center of gravity of the blade out for a more stable turbine system
Lighter blades:
• Enable lower cut-in speed to capture more wind power and lower the cost of energy (COE)
• Help reduce transportation and installation costs
• Help reduce wear and tear on the system and extend turbine life, further reducing the COE
Improved fatigue properties enhance blade durability
WindStrand® reinforcement is designed to enable wind blade fabricators to make longer, lighter and stiffer blades that can be paired with larger turbines to generate more electricity efficiently and thereby reduce the cost of a kilowatt-hour of energy.
WindStrand® reinforcement provides significant performance increases versus E-glass and offers substantial design benefits, including significantly increased stiffness, better strength and excellent fatigue properties. These benefits will help blade designers achieve superior performance in blade deflection and wind resistance, as well as help increase the life and energy conversion of a typical wind turbine installation. This enables blade manufacturers to push the glass fiber design further without using more expensive materials from the aerospace or military sectors.
As a result of their enhanced performance attributes, WindStrand® reinforcement provides blade weight savings of up to 17 percent versus conventional E-glass blades of the same design, depending on the size of the blade. Designers can increase blade lengths as much as 6 percent at the same weight to deliver up to 12 percent more power. WindStrand® reinforcement can also provide a direct manufacturing cost savings of up to 20 percent compared to any other competing carbon-glass hybrid solution currently on the market. The end result is a lower cost of energy.
Tests comparing Owens Corning WindStrand® reinforcements in a new generation epoxy sizing versus. Owens Corning Advantex® glass reinforcement – both in unidirectional fabric laminates of the type used in blade spar caps – found that laminates with WindStrand® reinforcement exhibited 28 percent higher
tensile strength and 12 percent higher stiffness. It should be noted that Advantex® glass exhibits a 4 to 5 percent higher average stiffness than conventional E-glasses. The tensile-tensile dynamic fatigue (R=0.1) performance as illustrated in the following chart demonstrate a 38 percent higher fatigue strength at 1 million cycles for WindStrand® reinforcement, leading to more than 20 percent higher allowable strain.
Time to failure is increased by more than a decade for WindStrand® reinforcements compared to Advantex® glass at a given stress level.
In addition to its performance benefits, WindStrand® reinforcement provides more ease in fabrication and is less sensitive to process issues like fiber misalignments or ply drops that are often a concern with other high-performance materials such as carbon fiber. WindStrand® roving is a direct, single-end roving available in Tex ranging from 300 to 2400. WindStrand® fabrics are also available.
Owens Corning WindStrand® reinforcement is an easy-to-work-with solution that reduces costs and makes wind energy more competitive. WindStrand® reinforcement allows design engineers to take full advantage of the potential benefits of larger blades designed and constructed entirely of glass.
windstrand® rEinforCEMEnt propErty (vs. ConvEntionaL E-gLass)
rEsuLts in:
Up to 20 percent higher stiffness Larger load for same deformation
Up to 35 percent higher strength Larger load (higher wind speed)
More than 10 times greater fatigue life at same load
Improved durability, reliability and lower maintenance cost
Up to 12 percent higher strain to failure Higher deformation allowable
Up to 40 percent higher strain energy density
Better impact and damage tolerance
8-17 percent weight savings, depending on blade length
For similar design
Higher tensile strength Ability to take larger load (higher wind speeds)
Higher tensile modulus Stiffer, lighter blades
Higher specific modulus/Lower density reinforcement
Further improvement on lowering the weight
Higher fatigue Longer blade durability
WindStrand® high-performance reinforcements provide a 28 percent increase in tensile strength in composites versus E-glass.
WindStrand® high-performance reinforcements provide a 12 percent increase in tensile modulus in composites versus E-glass.
1000
900
1200
893.35
945.57
1211.09
1100
1400
1300
800
Advantex®
Glass (warp)
Tensile Strength (Adjusted for FVF 55%)
E-glass WindStrand®
Tens
ile S
tren
gth
(MPa
)
WindStrand® Tensile Strength vs. Advantex® & E-Glass
40.0
37.5
45.0
38.16
41.63
46.72
42.5
50.0
47.5
35.0Advantex®
Glass
Tensile Modulus (Adjusted for FVF 55%)
E-glass WindStrand®
Tens
ile M
odul
us (
GPa
)
WindStrand® Tensile Modulus vs. Advantex® & E-Glass
10 11
windstrand® rEinforCEMEnts for LowEr-Cost powEr
MarkEt: wind EnErgy
Need:• Achieve price parity with traditional fuels
• Lower cost of electricity per kilowatt hour (Kwh)
Solution: Wind turbine generator blades made with Owens Corning WindStrand® reinforcements:
• Enables blade manufacturer to reduce blade weight by up to 10 percent
• Enables up to 6 percent longer blades with no increase in weight
• Provides opportunity to translate benefits into more power
• Ultimately results in a lower cost per Kwh
WindStrand® Reinforcement ValueHigher modulus enables lower blade weight or longer blades:
• Offers option of moving the center of gravity of the blade out for a more stable turbine system
Lighter blades:
• Enable lower cut-in speed to capture more wind power and lower the cost of energy (COE)
• Help reduce transportation and installation costs
• Help reduce wear and tear on the system and extend turbine life, further reducing the COE
Improved fatigue properties enhance blade durability
WindStrand® reinforcement is designed to enable wind blade fabricators to make longer, lighter and stiffer blades that can be paired with larger turbines to generate more electricity efficiently and thereby reduce the cost of a kilowatt-hour of energy.
WindStrand® reinforcement provides significant performance increases versus E-glass and offers substantial design benefits, including significantly increased stiffness, better strength and excellent fatigue properties. These benefits will help blade designers achieve superior performance in blade deflection and wind resistance, as well as help increase the life and energy conversion of a typical wind turbine installation. This enables blade manufacturers to push the glass fiber design further without using more expensive materials from the aerospace or military sectors.
As a result of their enhanced performance attributes, WindStrand® reinforcement provides blade weight savings of up to 17 percent versus conventional E-glass blades of the same design, depending on the size of the blade. Designers can increase blade lengths as much as 6 percent at the same weight to deliver up to 12 percent more power. WindStrand® reinforcement can also provide a direct manufacturing cost savings of up to 20 percent compared to any other competing carbon-glass hybrid solution currently on the market. The end result is a lower cost of energy.
Tests comparing Owens Corning WindStrand® reinforcements in a new generation epoxy sizing versus. Owens Corning Advantex® glass reinforcement – both in unidirectional fabric laminates of the type used in blade spar caps – found that laminates with WindStrand® reinforcement exhibited 28 percent higher
tensile strength and 12 percent higher stiffness. It should be noted that Advantex® glass exhibits a 4 to 5 percent higher average stiffness than conventional E-glasses. The tensile-tensile dynamic fatigue (R=0.1) performance as illustrated in the following chart demonstrate a 38 percent higher fatigue strength at 1 million cycles for WindStrand® reinforcement, leading to more than 20 percent higher allowable strain.
Time to failure is increased by more than a decade for WindStrand® reinforcements compared to Advantex® glass at a given stress level.
In addition to its performance benefits, WindStrand® reinforcement provides more ease in fabrication and is less sensitive to process issues like fiber misalignments or ply drops that are often a concern with other high-performance materials such as carbon fiber. WindStrand® roving is a direct, single-end roving available in Tex ranging from 300 to 2400. WindStrand® fabrics are also available.
Owens Corning WindStrand® reinforcement is an easy-to-work-with solution that reduces costs and makes wind energy more competitive. WindStrand® reinforcement allows design engineers to take full advantage of the potential benefits of larger blades designed and constructed entirely of glass.
windstrand® rEinforCEMEnt propErty (vs. ConvEntionaL E-gLass)
rEsuLts in:
Up to 20 percent higher stiffness Larger load for same deformation
Up to 35 percent higher strength Larger load (higher wind speed)
More than 10 times greater fatigue life at same load
Improved durability, reliability and lower maintenance cost
Up to 12 percent higher strain to failure Higher deformation allowable
Up to 40 percent higher strain energy density
Better impact and damage tolerance
8-17 percent weight savings, depending on blade length
For similar design
Higher tensile strength Ability to take larger load (higher wind speeds)
Higher tensile modulus Stiffer, lighter blades
Higher specific modulus/Lower density reinforcement
Further improvement on lowering the weight
Higher fatigue Longer blade durability
WindStrand® high-performance reinforcements provide a 28 percent increase in tensile strength in composites versus E-glass.
WindStrand® high-performance reinforcements provide a 12 percent increase in tensile modulus in composites versus E-glass.
1000
900
1200
893.35
945.57
1211.09
1100
1400
1300
800
Advantex®
Glass (warp)
Tensile Strength (Adjusted for FVF 55%)
E-glass WindStrand®
Tens
ile S
tren
gth
(MPa
)
WindStrand® Tensile Strength vs. Advantex® & E-Glass
40.0
37.5
45.0
38.16
41.63
46.72
42.5
50.0
47.5
35.0Advantex®
Glass
Tensile Modulus (Adjusted for FVF 55%)
E-glass WindStrand®
Tens
ile M
odul
us (
GPa
)
WindStrand® Tensile Modulus vs. Advantex® & E-Glass
12 13
fLitEstrand® rEinforCEMEnts for LightEr airCraft
MarkEt: aErospaCE
Need:• Lower operating costs
• Increase fuel economy
• Lighter aircraft
Solution: Composite applications made with FliteStrand® S reinforcements
• Enable weight savings up to 20 percent
• Offer excellent fatigue, impact and temperature resistance
• Reduce overall cost of ownership
As airlines struggle with the twin challenges of lowering operating costs and increasing environmental stewardship, aerospace engineers are looking for ways to design lighter components to decrease overall aircraft weight and achieve better fuel economy.
With the planned introduction of FliteStrand® S reinforcement in 2010, Owens Corning researchers will deliver a high-performance fiber solution that meets the stringent fitness-for-use requirements of the aerospace market while simultaneously enhancing value.
FliteStrand® S reinforcements will be made with S-glass and used for high-strength, low-weight applications. Composite aircraft parts manufactured with FliteStrand® S reinforcement will enable up to 20 percent lighter or stronger laminates versus conventional E-glass.
Owens Corning has tested laminates made with FliteStrand® S reinforcement coupled with its new generation epoxy-compatible sizing and found their flexural modulus and impact performance to be comparable to laminates made with other high-performance glass fibers. In pre-preg processing with epoxy resin, FliteStrand® S reinforcements provided fast wetting and low twist. FliteStrand® S reinforcement will be available in outside pull multi-end roving as well as fabric.
The combination of high performance and value will offer aerospace engineers new material choices to enable them to design lighter and stronger aircraft. FliteStrand® S reinforcement will provide comparable performance to metals with less weight and better fatigue performance. This will allow engineers to address two of their top challenges – lowering both fuel consumption and CO2 emissions.
FliteStrand® S reinforcement is designed for demanding aerospace applications, such as aircraft ceilings, side walls, overhead storage bins, galleys, floor panels, bulkheads, vertical partitions, cargo liners, nacelles, radomes, flight control surfaces, fairings, winglets, ailerons, flaps, landing gear doors, vertical and horizontal stabilizers, and helicopter rotor blades.
Owens Corning high-performance FliteStrand® S reinforcement will be made from a boron-free glass formulation that meets S-glass standards as defined by ASTM C162, DIN 1259, ISO 2078, ASTM D578 and JIS R3410. This glass formulation is designed for excellent mechanical properties (tensile strength and modulus) and offers significantly better thermal and corrosion resistance properties than conventional E-glass. FliteStrand® S reinforcement also meets the tensile strength requirements for MIL-R-60346 Type 4, Classes 1 and 2.
12 13
fLitEstrand® rEinforCEMEnts for LightEr airCraft
MarkEt: aErospaCE
Need:• Lower operating costs
• Increase fuel economy
• Lighter aircraft
Solution: Composite applications made with FliteStrand® S reinforcements
• Enable weight savings up to 20 percent
• Offer excellent fatigue, impact and temperature resistance
• Reduce overall cost of ownership
As airlines struggle with the twin challenges of lowering operating costs and increasing environmental stewardship, aerospace engineers are looking for ways to design lighter components to decrease overall aircraft weight and achieve better fuel economy.
With the planned introduction of FliteStrand® S reinforcement in 2010, Owens Corning researchers will deliver a high-performance fiber solution that meets the stringent fitness-for-use requirements of the aerospace market while simultaneously enhancing value.
FliteStrand® S reinforcements will be made with S-glass and used for high-strength, low-weight applications. Composite aircraft parts manufactured with FliteStrand® S reinforcement will enable up to 20 percent lighter or stronger laminates versus conventional E-glass.
Owens Corning has tested laminates made with FliteStrand® S reinforcement coupled with its new generation epoxy-compatible sizing and found their flexural modulus and impact performance to be comparable to laminates made with other high-performance glass fibers. In pre-preg processing with epoxy resin, FliteStrand® S reinforcements provided fast wetting and low twist. FliteStrand® S reinforcement will be available in outside pull multi-end roving as well as fabric.
The combination of high performance and value will offer aerospace engineers new material choices to enable them to design lighter and stronger aircraft. FliteStrand® S reinforcement will provide comparable performance to metals with less weight and better fatigue performance. This will allow engineers to address two of their top challenges – lowering both fuel consumption and CO2 emissions.
FliteStrand® S reinforcement is designed for demanding aerospace applications, such as aircraft ceilings, side walls, overhead storage bins, galleys, floor panels, bulkheads, vertical partitions, cargo liners, nacelles, radomes, flight control surfaces, fairings, winglets, ailerons, flaps, landing gear doors, vertical and horizontal stabilizers, and helicopter rotor blades.
Owens Corning high-performance FliteStrand® S reinforcement will be made from a boron-free glass formulation that meets S-glass standards as defined by ASTM C162, DIN 1259, ISO 2078, ASTM D578 and JIS R3410. This glass formulation is designed for excellent mechanical properties (tensile strength and modulus) and offers significantly better thermal and corrosion resistance properties than conventional E-glass. FliteStrand® S reinforcement also meets the tensile strength requirements for MIL-R-60346 Type 4, Classes 1 and 2.
14
OCV™ HIGH-PERFORMANCE REINFORCEMENTSMAKING HIGH-PERFORMANCE COMPOSITES AFFORDABLE
PROVIDING GREATER CHOICE FOR THE CUSTOMER
Advantex® glass: Proprietary Owens Corning glass with higher corrosion and temperature resistance than conventional E-glass that is both an E-glass and a true E-CR glass according to ASTM D578, ISO 2078 and DIN1259-1.
Aramid: A generic name for aromatic polyamides (Kevlar and Nomex are examples of Aramid).
Bare glass: Glass fiber from the bushing before binder or sizing is applied.
Carbon fiber: Fibers made from an organic precursor by oxidation and carbonization and not having a graphite structure.
Composite: A combination of two or more materials (reinforcing elements, filler and resin) that retain their identities while acting in concert.
E-glass: A borosilicate glass commonly used in glass fibers for reinforced plastics; suitable for electrical laminates.
Fabric, non-woven: A textile structure produced by bonding or interlocking fibers by mechanical, chemical or solvent means.
Fabric, woven: Material constructed of interlaced yarns, fibers or filaments.
Filament: The smallest unit of fibrous material.
Glass fiber: An individual filament made by attenuating molten glass.
Kevlar®: Dupont’s trade name for an organic polymer composed of aromatic polyamides.
Knitted fabrics: Fabrics produced by interlooping strands of yarn, roving, etc.
Laminate: Material composed of layers of resin and reinforcement bonded together.
Modulus: The ratio of stress to strain in a material that is elastically deformed; if tensile strength of 1000 psi results in an elongation of 1 percent, the modulus of elasticity is 1000/.01 or 100,000 psi.
Polymer: An organic compound, natural or synthetic, whose structure can be represented by a repeated small unit, such as polyethylene, rubber, polyester and cellulose.
Pre-preg: Abbreviation for pre-impregnated reinforcement fibers ready for placement in a mold.
Reinforced plastics: Plastic parts consisting of resins to which reinforcing fibers, mats, fabrics, etc., have been added before the forming operation.
Resin: A solid or pseudo-solid organic material that exhibits a tendency to flow under stress. Most resins are polymers. In reinforced plastics, the material used to bind together the reinforcement material.
Roving: A number of strands or ends collected into a parallel bundle with little or no twist of fibers.
Roving yield: A measure of the linear density of a fiberglass roving in yards/lbs., the lower the number the larger the size of the roving bundle.
S-glass: A magnesia-alumina-silicate glass, especially designed to provide very high tensile strength glass filaments.
S-2 Glass® fiber: AGY Holdings Corp. brand of S-glass fibers.
Sizing: Any treatment consisting of starch, gelatin, oil, wax or other suitable ingredient that is applied to fibers at the time of formation to protect the surface, aid the process of handling and fabrication, and provide binding action, but no coupling agent.
Tensile strength: Maximum tensile stress sustained by a specimen prior to failure in a tensile test.
Tex: A unit for expressing linear density, equal to the mass in grams of 1,000m of yarn, filament, fiber or other textile strand.
Thermoplastic: Capable of being repeatedly softened by increase of temperature and hardened by decrease in temperature; applicable to those materials whose change upon heating is substantially physical rather than chemical and that in the softened stage can be shaped by flow into articles by molding or extrusion.
Thermoset: A plastics that, when cured by application of heat or chemical means, changes into a substantially infusible and insoluble material.
UHMWPE: Ultra-High Molecular Weight Polyethylene – a thermoplastic material composed of many molecules of ethylene and exhibiting extreme toughness and abrasion resistance.
Veil: A non-woven glass fiber mat used in a variety of applications to provide strength and enhance surface finish.
Yield: A term to describe weight per unit length in yards/lbs., for example a 113 yield product weighs 113 yards/lb.
GLOSSARy
ENABLING MORE POSSIBILITIESOwens Corning high-performance reinforcements offer these benefits:
• Strength – Up to 50 percent higher strength with S-glass versus conventional E-glass• Modulus (stiffness) – Up to 20 percent higher modulus with S-glass versus conventional E-glass fibers• Fatigue – End-use parts have higher fatigue properties, a key requirement for high-performance
composite applications• Impact Resistance – Up to 80 percent better impact resistance than conventional E-glass fibers• Aging and Corrosion Resistance – Better aging and corrosion resistance than E-CR and conventional
E-glass fibers• Temperature Resistance – Better resistance at elevated temperatures than conventional E-glass fibers
R-Glass
MARKET BALLISTICS/ARMOR INDUSTRIAL WIND ENERGyHigh-Performance Reinforcements ShieldStrand® Roving XStrand® Roving WindStrand® Roving
Available Direct Roving 12μ - 600 tex 24μ - 2400 tex 17μ - 2400 tex 17μ - 1200 tex 17μ - 600 tex 12μ - 300 tex
24μ - 2400 tex 17μ - 2400 tex 17μ - 1200 tex 17μ - 600 tex 12μ - 300 tex
S-Glass
MARKET BALLISTICS/ARMOR INDUSTRIAL AEROSPACEHigh-Performance Reinforcements ShieldStrand® S Roving XStrand® S Roving FliteStrand® Roving
Available Roving 9μ - 360 tex 24μ - 2400 tex 17μ - 2400 tex 17μ - 1200 tex 17μ - 600 tex 12μ - 660 tex* 12μ - 300 tex 9μ - 360 tex* 9μ - 340 tex 9μ - 337 tex* * Only available in a multi-end
roving with outside pull
12μ - 600 tex 12μ - 300 tex 9μ - 675 tex* 9μ - 337 tex* * Only available in a multi-end
roving with outside pull
OCV high-performance reinforcements are available for use with epoxy and multi-compatible resins.
HIGH PERFORMANCE AND VALUE THROUGH INNOVATION
14
OCV™ HIGH-PERFORMANCE REINFORCEMENTSMAKING HIGH-PERFORMANCE COMPOSITES AFFORDABLE
PROVIDING GREATER CHOICE FOR THE CUSTOMER
Advantex® glass: Proprietary Owens Corning glass with higher corrosion and temperature resistance than conventional E-glass that is both an E-glass and a true E-CR glass according to ASTM D578, ISO 2078 and DIN1259-1.
Aramid: A generic name for aromatic polyamides (Kevlar and Nomex are examples of Aramid).
Bare glass: Glass fiber from the bushing before binder or sizing is applied.
Carbon fiber: Fibers made from an organic precursor by oxidation and carbonization and not having a graphite structure.
Composite: A combination of two or more materials (reinforcing elements, filler and resin) that retain their identities while acting in concert.
E-glass: A borosilicate glass commonly used in glass fibers for reinforced plastics; suitable for electrical laminates.
Fabric, non-woven: A textile structure produced by bonding or interlocking fibers by mechanical, chemical or solvent means.
Fabric, woven: Material constructed of interlaced yarns, fibers or filaments.
Filament: The smallest unit of fibrous material.
Glass fiber: An individual filament made by attenuating molten glass.
Kevlar®: Dupont’s trade name for an organic polymer composed of aromatic polyamides.
Knitted fabrics: Fabrics produced by interlooping strands of yarn, roving, etc.
Laminate: Material composed of layers of resin and reinforcement bonded together.
Modulus: The ratio of stress to strain in a material that is elastically deformed; if tensile strength of 1000 psi results in an elongation of 1 percent, the modulus of elasticity is 1000/.01 or 100,000 psi.
Polymer: An organic compound, natural or synthetic, whose structure can be represented by a repeated small unit, such as polyethylene, rubber, polyester and cellulose.
Pre-preg: Abbreviation for pre-impregnated reinforcement fibers ready for placement in a mold.
Reinforced plastics: Plastic parts consisting of resins to which reinforcing fibers, mats, fabrics, etc., have been added before the forming operation.
Resin: A solid or pseudo-solid organic material that exhibits a tendency to flow under stress. Most resins are polymers. In reinforced plastics, the material used to bind together the reinforcement material.
Roving: A number of strands or ends collected into a parallel bundle with little or no twist of fibers.
Roving yield: A measure of the linear density of a fiberglass roving in yards/lbs., the lower the number the larger the size of the roving bundle.
S-glass: A magnesia-alumina-silicate glass, especially designed to provide very high tensile strength glass filaments.
S-2 Glass® fiber: AGY Holdings Corp. brand of S-glass fibers.
Sizing: Any treatment consisting of starch, gelatin, oil, wax or other suitable ingredient that is applied to fibers at the time of formation to protect the surface, aid the process of handling and fabrication, and provide binding action, but no coupling agent.
Tensile strength: Maximum tensile stress sustained by a specimen prior to failure in a tensile test.
Tex: A unit for expressing linear density, equal to the mass in grams of 1,000m of yarn, filament, fiber or other textile strand.
Thermoplastic: Capable of being repeatedly softened by increase of temperature and hardened by decrease in temperature; applicable to those materials whose change upon heating is substantially physical rather than chemical and that in the softened stage can be shaped by flow into articles by molding or extrusion.
Thermoset: A plastics that, when cured by application of heat or chemical means, changes into a substantially infusible and insoluble material.
UHMWPE: Ultra-High Molecular Weight Polyethylene – a thermoplastic material composed of many molecules of ethylene and exhibiting extreme toughness and abrasion resistance.
Veil: A non-woven glass fiber mat used in a variety of applications to provide strength and enhance surface finish.
Yield: A term to describe weight per unit length in yards/lbs., for example a 113 yield product weighs 113 yards/lb.
GLOSSARy
ENABLING MORE POSSIBILITIESOwens Corning high-performance reinforcements offer these benefits:
• Strength – Up to 50 percent higher strength with S-glass versus conventional E-glass• Modulus (stiffness) – Up to 20 percent higher modulus with S-glass versus conventional E-glass fibers• Fatigue – End-use parts have higher fatigue properties, a key requirement for high-performance
composite applications• Impact Resistance – Up to 80 percent better impact resistance than conventional E-glass fibers• Aging and Corrosion Resistance – Better aging and corrosion resistance than E-CR and conventional
E-glass fibers• Temperature Resistance – Better resistance at elevated temperatures than conventional E-glass fibers
R-Glass
MARKET BALLISTICS/ARMOR INDUSTRIAL WIND ENERGyHigh-Performance Reinforcements ShieldStrand® Roving XStrand® Roving WindStrand® Roving
Available Direct Roving 12μ - 600 tex 24μ - 2400 tex 17μ - 2400 tex 17μ - 1200 tex 17μ - 600 tex 12μ - 300 tex
24μ - 2400 tex 17μ - 2400 tex 17μ - 1200 tex 17μ - 600 tex 12μ - 300 tex
S-Glass
MARKET BALLISTICS/ARMOR INDUSTRIAL AEROSPACEHigh-Performance Reinforcements ShieldStrand® S Roving XStrand® S Roving FliteStrand® Roving
Available Roving 9μ - 360 tex 24μ - 2400 tex 17μ - 2400 tex 17μ - 1200 tex 17μ - 600 tex 12μ - 660 tex* 12μ - 300 tex 9μ - 360 tex* 9μ - 340 tex 9μ - 337 tex* * Only available in a multi-end
roving with outside pull
12μ - 600 tex 12μ - 300 tex 9μ - 675 tex* 9μ - 337 tex* * Only available in a multi-end
roving with outside pull
OCV high-performance reinforcements are available for use with epoxy and multi-compatible resins.
HIGH PERFORMANCE AND VALUE THROUGH INNOVATION
I n n o v a t I v e t e c h no l og y • e n a b l I n g n ew a p p l I c a t I o n s
ocv™ hIgh-peRFoRMance ReInFoRceMents
MaKIng hIgh-peRFoRMance coMposItes aFFoRDablepRovIDIng gReateR choIce FoR the cUstoMeR
OWENS CORNINGCOMPOSITE MATERIALS, LLCONE OWENS CORNING PARKWAYTOLEDO, OHIO 436591.800.GET.PINK™www.owenscorning.comwww.ocvreinforcements.com
EUROPEAN OWENS CORNING FIBERGLAS, SPRL.166, CHAUSSÉE DE LA HULPEB-1170 BRUSSELSBELGIUM322.674.8211
OWENS CORNING SHANGHAI COMPOSITES CO. LTD.OLIVE L.V.O. MANSION, 2ND FLOOR620 HUASHAN ROADSHANGAI 200122CHINA86.21.62489922
The information and data contained herein are offered solely as a guide in the selection of reinforcement. The information contained in this publication is based on actual laboratory data and field test experience. We believe this information to be reliable, but do not guarantee its applicability to the user’s process or assume any responsibility or liability arising out of its use or performance. The user agrees to be responsible for thoroughly testing any application to determine its suitability before committing to production. It is important for the user to determine the properties of its own commercial compounds when using this or any other reinforcement. Because of numerous factors affecting results, we make no warranty of any kind, express or implied, including those of merchantability and fitness for a particular purpose. Statements in this publication shall not be construed as representations or warranties or as inducements to infringe any patent or violate any law, safety code or insurance regulation.
Owens Corning reserves the right to modify this document without prior notice. OCV is a trademark of Owens Corning. WindStrand, ShieldStrand, FliteStrand, XStrand and Advantex are registered trademarks of Owens Corning. S-2 Glass is a registered trademark of AGY Holdings. Kevlar and Nomex are registered trademarks of DuPont.© 2009 Owens CorningPub. No. 10011498. Printed in U.S.A. September 2009