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Composites materials for aerospace applications
Abstract:
Fibre-reinforced polymer composite materials are fast gaining ground as preferred materials for construction of aircrafts and spacecrafts. In particular, their use as primary structural materials in recent years in several technology-demonstrator front-line aerospace projects world-wide has provided confidence leading to their acceptance as prime materials for aerospace vehicles. This paper gives a review of some of these developments with a discussion of the problems with the present generation composites and prospects for further developments. Although several applications in the aerospace vector are mentioned, the emphasis of the review is on applications of composites as structural materials where they have seen a significant growth in usage. A brief review of composites usage in aerospace sector is first given. The nature of composite materials behaviour and special problems in designing and working with them are then highlighted. The issues discussed relate to the impact damage and damage tolerance in general, environmental degradation and long-term durability.
Keywords: Composite materials; aerospace applications.
1. Introduction
The range of materials can be classified into the categories: Metals, Polymers, Ceramics and inorganic glasses and composites. Metals lose their strength at elevated temperatures. High-Polymeric materials in general can withstand still lower temperatures. Ceramics outstrip metals and polymers in their favourable melting points, ability to withstand high temperatures, strength and thermal expansion properties, but due to their brittleness they are often unsatisfactory as structural materials. This lead to the exploration of composites. One may define a composite as material as a materials system which consists of a mixture or combination of two or more micro constituents mutually insoluble and differing in form and/or material composition. Examples of composites are steel reinforced concrete (metals + ceramics), vinyl-coated steel (metals + polymers), fibre reinforced plastics (ceramics + polymers).
Emergence of strong and stiff reinforcements like carbon fibre along with advances in polymer research to produce high performance resins as matrix materials have helped meet the challenges posed by the complex designs of modern aircraft. The large scale use of advanced composites in current programmes of development of military fighter aircraft, small and big civil transport aircraft, helicopters, satellites, launch vehicles and missiles all around the world is perhaps the most glowing example of the utilization of potential of such composite materials.
2. The aerospace structures and features
Important requirements of an aerospace structure and their effect on the design of the structure are presented in table 1.
Table 1. Features of aircraft structure.
Requirement Applicability Effect
Light-weight All Aerospace Programmes Semi-monocoque construction
* Thin-walled-box or stiffened structures
Use of low density materials:
* Wood * Al-alloys * Composites
High strength/weight, High stiffness/weight
High reliability All space programmes Strict quality control
Extensive testing for reliable data
Certification: Proof of design
Passenger safety Passenger vehicles Use of fire retardant materials
Extensive testing: Crashworthiness
Durability-Fatigue and corrosion
Degradation: Vacuum Radiation Thermal Aircraft
Spacecraft Extensive fatigue analysis/testing
* Al-alloys do not have a fatigue limit
Corrosion prevention schemes
Issues of damage and safe-life, life extension
Extensive testing for required environment
Thin materials with high integrity
Aerodynamic performance Aircraft
Reusable spacecraft Highly complex loading
Thin flexible wings and control surfaces
* Deformed shape-Aero elasticity * Dynamics
Complex contoured shapes
* Manufacturability: N/C Machining; Moulding
Multi-role or functionality All Aerospace programmes Efficient design
Use: composites with functional properties
Fly-by-wire Aircrafts, mostly for fighters but also some in passenger a/c Structure-control interactions
* Aero-servo-elasticity
Extensive use of computers and electronics
* EMI shielding
Stealth Specific military aerospace applications Specific surface and shape of aircraft
* Stealth coatings
All-Weather operation Aircraft Lightning protection, erosion resistance
Further, the structure has to meet the requirements of fuel sealing and provide access for easy maintenance of equipments. Passenger carriage requires safety standards to be followed and these put special demands of fire-retardance and crash-worthiness on the materials and design used. For spacecraft the space environment vacuum, radiation and thermal cycling-has to be considered and specially developed materials are required for durability.
Two key developments in scientific-technological world have had a tremendous influence on the generation and satisfaction of the demands raised by the aerospace community: one, the advances in the computational power and the other, composites technology using fibre reinforced polymeric materials.
3. Use of composites in aerospace structure
It is to be realized that in order to meet the demands in table 1, it is necessary to have materials with a peculiar property-set. The use of composites has been motivated largely by such considerations.
The composites offer several of these features as given below:
Light-weight due to high specific strength and stiffness
Fatigue-resistance and corrosion resistance
Capability of high degree of optimization: tailoring the directional strength and stiffness
Capability to mould large complex shapes in small cycle time reducing part count and assembly times: Good for thin-walled or generously curved construction
Capability to maintain dimensional and alignment stability in space environment
Possibility of low dielectric loss in radar transparency
Possibility of achieving low radar cross-section
These composites also have some inherent weaknesses:
Laminated structure with weak interfaces: poor resistance to out-of-plane tensile loads
Susceptibility to impact-damage and strong possibility of internal damage going unnoticed
Moisture absorption and consequent degradation of high temperature performance
Multiplicity of possible manufacturing defects and variability in material properties
Even after accepting these weaknesses, the projected benefits are significant and almost all aerospace programmes use significant amount of composites as highlighted in the figure below.

All this is, of course, not without its share of hassles. Challenges of using composites on such a large scale are many. The composites are not only new but also non-conventional: they are anisotropic, inhomogeneous, have different fabrication and working methods and also different controls for quality assurance. They have a complex material behaviour under load requiring new and complicated analysis tools. Moreover, the behaviour is not always predictable by analysis and this makes reliance on several expensive and time consuming tests unavoidable.
The routes to meet these challenges have evolved around use of the advances in computer technology and analysis methods to implement schemes based on computer aided design, computer aided engineering, finite element methods of analysis and building computer interfaces amongst all aspects of development, namely, design, analysis and manufacturing. These should provide fast transfer of information including graphics and accurate analysis methods for a reasonable prediction of complex behavioural patterns of composites. It is only by harnessing the vast computational power for various purposes that the aircraft structural design of today can meet the challenges posed by the required performance.
4. Materials for aerospace composites:
The materials systems which have been considered useful in aerospace sector are based on reinforcing fibres and matrix resins given in table 2 and 3, respectively. Most aerospace composites use prepregs as raw materials with autoclave moulding as a popular fabrication process. Filament winding is popular with shell like components such as rocket motor casings for launch vehicles and missiles. Oven curing or room temperature curing is used mostly with glass fibre composites used in low speed small aircraft. It is common to use composite tooling where production rates are small or moderate; however, where large number of components are required, metallic conventional tooling is preferred. Resin injection moulding also finds use in special components such as radomes. Some of the popular systems are given in table 4 along with the types of components where they are used in a typical high-performance aircraft.
Table 2. Reinforcing fibres commonly use in aerospace applications.
Fibre Density (g/cc) Modulus (GPa) Strength (GPa) Application areas
Glass
E-glass
S-glass
2.55
2.47
65-75
85-95
2.2-2.6
4.4-4.8
Small passenger a/c parts, air-craft interiors, secondary parts; Radomes; rocket motor casings
Highly loaded parts in small passenger a/c
Aramid
Low modulus
Intermediate
modulus
High modulus
1.44
1.44
1.48
80-85
120-128
160-170
2.7-2.8
2.7-2.8
2.3-2.4
Fairings; non-load bearing parts
Radomes, some structural parts; rocket motor casings
Highly loaded parts
Carbon
Standard modulus
(high strength)
Intermediate
modulus
High modulus
Ultra-high strength

1.77-1.80
1.77-1.81
1.77-1.80
1.80-1.82
220-240
270-300
390-450
290-310

3.0-3.5
5.4-5.7
2.8-3.0
4.0-4.5
7.0-7.5
Widely used for almost all types of parts in a/c, satellites, antenna dishes, missiles, etc.
Primary structural parts in high performance fighters
Space structures, control surfaces in a/c
Primary structural parts in high performance fighters, spacecraft
Table 3. Polymeric matrices commonly used in aerospace sector.
Thermosets Thermoplastics
Forms cross-linked networks in polymerization curing by heating No chemical change
Epoxies Phenolics Polyester Polyimides PPS, PEEK
Most popular
80% of total composite usage
Moderately high temp.
Comparatively expensive Cheaper
Lower viscosity
Easy to use
High temp usage
Difficult to get good quality composites Cheap
Easy to use
Popular for general applications at room temp High temp application 3000C
Difficult to process
Brittle Good damage tolerance
Difficult to process as high temp 300-4000 C is required
Low shrinkage (2-3%)
No release of volatile during curing More shrinkage
Release of volatile during curing High shrinkage (7-8%)
Can be polymerized in several ways giving varieties of structures, morphology and wide range of properties Inherent stability for thermal oxidation
Good fire and flame retardance
Brittle than epoxies Good chemical resistance
Wide range of properties but lower than epoxies
Brittle
Low Tg
Good storage stability to make prepregs Less storage stability-difficult to prepreg Difficult to prepreg Infinite storage life. But difficult to prepreg
Absolute moisture (5-6%) causing swelling and degradation of high temp properties
Also ultra violet degradation in long term Absorbs moisture but no significant effect of moisture in working service range Less sensitive to moisture than epoxies No moisture absorption
Density (g/cm3) 1.1-1.4 Density (g/cm3) 1.22-1.4 Density (g/cm3) 1.1-1.4 Density (g/cm3) 1.3-1.4
Tensile modulus 2.7-5.5 GPa Tensile modulus 2.7-4.1 GPa Tensile modulus 1.3-4.1 GPa Tensile modulus 3.5-4.4 GPa
Tensile strength 40-85 MPa Tensile strength 35-60 MPa Tensile strength 40-85 MPa Tensile strength 100 MPa
5. Concerns with composite usage
The concern in use of composites arises mainly due to demands of high degree of reliability and safety of aerospace structures as against the complexity of composite behaviour and consequent difficulties in building prediction models. This creates an excessive reliance on testing at all stages; design and development, proving and certification, and in-service inspection and repairs. The costs of such testing are sometimes enormous and this had led to some skepticism in use of composites. Two major issues in this regard are briefly discussed below.
5.1 Impact damage and damage tolerance
The laminated structure of the composites and the fibre-matrix interfaces provide weak interfaces for delamination and debonding to take place. This is further aggravated by practical structural features such as discontinuous plies to create thickness changes and sharp bends required in stiffening members. Of particular concern is the proneness exhibited for damage due to impact. The issue is not merely the reduction in strength (particularly in compression) but also that the damage is inside the material and not visible at the structure. This is particularly so where the impact is due to blunt objects at low to medium velocities. Common instances are dropping of tools, hail-stones, runway debris and impacts and jolts while handling (even before the assembly of the air craft). Such hidden damage can be extensive- both in terms of planar dimensions and through the thickness. The damage mostly occurs as delamination, but may sometimes be accompanied by fibre-breaks in back plies which are not visible from outside. In the shop, such damages can be found by ultra-sonic C-scan method and a barely visible impact damage can cause a reduction in compressive strength by almost 60%. The fatigue resistance of carbon composites stands it in good stead, however, and no further significant reduction in strength or growth of damaged is observed under in-plane loads.
The current philosophy to handle impact damage problem is as follows: (i) design the structure to have alternate load paths to have damage tolerance against impact of moderate severity. This is generally taken care by designing the structure as a framework of stiffening members or as boxes; (ii) lower the design allowable strength values to an extent where the barely visible impact damage (BVID) can be sustained even at the highest load and for all the time with no degradation in performance; (ii) any damage that exceeds the BVID level (i.e. visible damage) may lower the intermediate performance and should be repaired immediately. The basic safety of aircraft with damage is ensured due to (i) and (iv) the structure may not cater to very severe impact.
There is, of course, a penalty in lowering the allowables but for the present systems, this is considered to be not too excessive in view of the similar reduction of allowables required for fastener holes. With improved processing to get large parts integral with stiffeners and other complex shapes and with availability of high strength fibres the limitations due to impact damage would be more perceptible and prohibitive.
Another consequence of the impact damage issue which the aeronautical community is, perhaps, not yet fully exposed to is in terms of the inspection intervals and defining levels of repairs etc. when the presently developed aircraft go in full service. Extensive studies and gathering of experience through testing is presently underway to tackle this problem.
5.2 Environmental degradation
The presently used epoxy resins absorb about 5-6% moisture by weight when fully saturated. This leads to about 1.5-1.8% moisture weight gain in carbon-epoxy composites with the usual 60% fibre volume fraction. In practice, under the normal operating conditions, the maximum equilibrium moisture gain in an aircraft component can be about 1.0-1.4%. This moisture gain can cause (a) swelling and dimensional changes, (b) lowering of the gas transition temperature (Tg) of the resin matrix, and © degradation of matrix dominated properties of composites such as shear and compression strengths.
The dimensional changes and weight gain by itself are generally not significant in many aircraft structures but may be of considerable significance where extreme precision is required such as in antennae panels and in aircraft structures is the degradation of the shear and compressive strength properties-particularly at high temperatures close to Tg which in itself is now reduced due to moisture absorption. The design of a structural component, therefore, generally proceeds by reducing allowables for moisture degradation.
This single issue of environmental degradation due to moisture absorption has made development of composite components for aerospace quite expensive and tedious. Moreover, associated with the already complex behaviour of composites particularly in the long run.
Apart from the moisture absorption, the other significant aspects relate to the UV degradation and radiation effects in the long term. These are particularly important in space structures. The current studies on the subject have provided some solutions to these problems even though the concern about long term behaviour exists.
Table 4. Typical composite material systems in aerospace.
Material system Application area
1750C curing high strength-carbon-epoxy
Zero-bleed (neat resin content) UD prepregs
5 HS or 8 HS bi-directional fabric prepreg
toughness, good out-life and shelf-life Structural components of fighter aircraft and helicopters. e.g. wing skins, spars, fin, rudder, elevons, doors, etc.
1750C curing intermediate modulus carbon with epoxy + BMI / cynate-ester
Zero-bleed (neat resin content) UD prepregs
5 HS or 8 HS bi-directional fabric prepreg
high toughness, good out-life and shelf-life
low environmental degradation Frames, stiffeners, rotor blades
1200C curing HS-carbon-epoxy
Zero-bleed (neat resin content) UD prepregs
5 HS or 8 HS bi-directional fabric prepreg
toughness, good out-life and shelf-life Structural components of helicopters or transport aircraft. e.g. spars, fin, rudder, elevons, doors, etc. Frames, stiffeners
Aramid fibre in low-loss polyester / cynate esters Radome
Cu-mesh epoxy prepreg For Lightning Strike protection Wing-skin, others
E-glass fabric in epoxy resins
High temp curing
RT / moderate temp curing Fighters fairings, fin-radome, drop-tanks, Small transport air craft structural components : Fuselage, wing, others

Some other aerospace applications are illustrated above:
Fig. A : Two seater transport aircraft
Fig. B : Space launch vehicles (Space Shuttles)
Fig. C : Satellites
Fig. D : Advanced helicopters (Military & Civilian)
6. Advances in materials for composites
6.1 Reinforcements
The carbon fibre technology continues to improve harnessing the versatility of carbon fibre and new varieties in terms of better combinations of modulus and strength are becoming available. The developments seem to be in two directions: one, for aircraft applications, is aimed basically at higher strength (>5 GPa) with concurrent improvements in modulus to a moderate level (>300 GPa) and the other, for space applications, is aimed at high modulus (>500 GPa) with moderate strength (3.5 GPa). The higher failure strain for the fibre is expected to result in composites with better damage tolerance. The developments in aramid fibres also aim at higher modulus with concurrent increase in strength. However, the major thrust in improving reinforcements for composites comes from the requirements of multidirectional weaving. Several processes (weaving, knitting, braiding) have been developed for this purpose and performs with multidirectionally woven fibres have now been made. Simplification and cost reductions appear to be the major motives for further developments.
The higher properties of basic fibres (such as carbon) cannot, however, be fully exploited in the composite without concurrent developments in the matrix materials and the intermediate products such as prepregs or performs. It is to be noted here that the carbon fibre composites which use a carbon fibre with a strength of 3 GPa as reinforcement result in an allowable stress of only 0.3 GPa in a composite. Significant scope thus exists for translating high fibre properties into high performance of composites.
6.2 Matrix resins
A significant effort in improving composites is focused on improving matrix materials. The two major concerns mentioned earlier viz. impact damage tolerance and hygrothermal degradation, provide the main motivation for improvement. A major direction of improvement appears to be an improvement in the toughness, which should result in higher resistance in to delamination and against impact. High failure strain of matrix resin would help in translating the higher performance of the improved fibre to the composite. Higher resin shear modulus would help in achieving better transfer of load from fibre to resin and again to fibre and should therefore improve compression strength. For polymeric materials a possible figure of 5 GPa should be achievable as against the current resins with shear modulus of about 2 GPa. As far as hygrothermal degradation is considered, newer systems based on cynate ester look very promising and some of these have already found some application. Another route being investigated is the use of thermoplastic resins and their blends. Poly-ether-ether-ketone (PEEK) has been considered very promising, but the industry needs to resolve the problems associated with high temperature (> 350 0C) processing of a material. Current approaches to new resins appear to be directed towards producing polymeric systems which can be processed in the way composites industry is used to (such as autoclave curing upto 180 0C).
7. Conclusions
Hence we can finally conclude that:
Composite materials offer high fatigue and corrosion resistance.
Composite materials have high strength to weight ratio.
So they are best suited for various aerospace applications.
8. References
Introduction to Engineering Materials by V.B.John; Chemistry of Engineering Materials by C.V.Agarwal; Bulletin of Material Science- Published by Indian Academy of Sciences in collaboration with Material Research Society of India and Indian National Science Academy.
9. Acknowledgements
Our sincere thanks go to Dr. M.R.S.Satyanarayana and Shri S.Kamaluddin for their valuable guidance and encouragement.

Abstract:
Fibre-reinforced polymer composite materials are fast gaining ground as preferred materials for construction of aircrafts and spacecrafts. In particular, their use as primary structural materials in recent years in several technology-demonstrator front-line aerospace projects world-wide has provided confidence leading to their acceptance as prime materials for aerospace vehicles. This paper gives a review of some of these developments with a discussion of the problems with the present generation composites and prospects for further developments. Although several applications in the aerospace vector are mentioned, the emphasis of the review is on applications of composites as structural materials where they have seen a significant growth in usage. A brief review of composites usage in aerospace sector is first given. The nature of composite materials behaviour and special problems in designing and working with them are then highlighted. The issues discussed relate to the impact damage and damage tolerance in general, environmental degradation and long-term durability.
Keywords: Composite materials; aerospace applications.
1. Introduction
The range of materials can be classified into the categories: Metals, Polymers, Ceramics and inorganic glasses and composites. Metals lose their strength at elevated temperatures. High-Polymeric materials in general can withstand still lower temperatures. Ceramics outstrip metals and polymers in their favourable melting points, ability to withstand high temperatures, strength and thermal expansion properties, but due to their brittleness they are often unsatisfactory as structural materials. This lead to the exploration of composites. One may define a composite as material as a materials system which consists of a mixture or combination of two or more micro constituents mutually insoluble and differing in form and/or material composition. Examples of composites are steel reinforced concrete (metals + ceramics), vinyl-coated steel (metals + polymers), fibre reinforced plastics (ceramics + polymers).
Emergence of strong and stiff reinforcements like carbon fibre along with advances in polymer research to produce high performance resins as matrix materials have helped meet the challenges posed by the complex designs of modern aircraft. The large scale use of advanced composites in current programmes of development of military fighter aircraft, small and big civil transport aircraft, helicopters, satellites, launch vehicles and missiles all around the world is perhaps the most glowing example of the utilization of potential of such composite materials.
2. The aerospace structures and features
Important requirements of an aerospace structure and their effect on the design of the structure are presented in table 1.
Table 1. Features of aircraft structure.
Requirement Applicability Effect
Light-weight All Aerospace Programmes Semi-monocoque construction
* Thin-walled-box or stiffened structures
Use of low density materials:
* Wood * Al-alloys * Composites
High strength/weight, High stiffness/weight
High reliability All space programmes Strict quality control
Extensive testing for reliable data
Certification: Proof of design
Passenger safety Passenger vehicles Use of fire retardant materials
Extensive testing: Crashworthiness
Durability-Fatigue and corrosion
Degradation: Vacuum Radiation Thermal Aircraft
Spacecraft Extensive fatigue analysis/testing
* Al-alloys do not have a fatigue limit
Corrosion prevention schemes
Issues of damage and safe-life, life extension
Extensive testing for required environment
Thin materials with high integrity
Aerodynamic performance Aircraft
Reusable spacecraft Highly complex loading
Thin flexible wings and control surfaces
* Deformed shape-Aero elasticity * Dynamics
Complex contoured shapes
* Manufacturability: N/C Machining; Moulding
Multi-role or functionality All Aerospace programmes Efficient design
Use: composites with functional properties
Fly-by-wire Aircrafts, mostly for fighters but also some in passenger a/c Structure-control interactions
* Aero-servo-elasticity
Extensive use of computers and electronics
* EMI shielding
Stealth Specific military aerospace applications Specific surface and shape of aircraft
* Stealth coatings
All-Weather operation Aircraft Lightning protection, erosion resistance
Further, the structure has to meet the requirements of fuel sealing and provide access for easy maintenance of equipments. Passenger carriage requires safety standards to be followed and these put special demands of fire-retardance and crash-worthiness on the materials and design used. For spacecraft the space environment vacuum, radiation and thermal cycling-has to be considered and specially developed materials are required for durability.
Two key developments in scientific-technological world have had a tremendous influence on the generation and satisfaction of the demands raised by the aerospace community: one, the advances in the computational power and the other, composites technology using fibre reinforced polymeric materials.
3. Use of composites in aerospace structure
It is to be realized that in order to meet the demands in table 1, it is necessary to have materials with a peculiar property-set. The use of composites has been motivated largely by such considerations.
The composites offer several of these features as given below:
Light-weight due to high specific strength and stiffness
Fatigue-resistance and corrosion resistance
Capability of high degree of optimization: tailoring the directional strength and stiffness
Capability to mould large complex shapes in small cycle time reducing part count and assembly times: Good for thin-walled or generously curved construction
Capability to maintain dimensional and alignment stability in space environment
Possibility of low dielectric loss in radar transparency
Possibility of achieving low radar cross-section
These composites also have some inherent weaknesses:
Laminated structure with weak interfaces: poor resistance to out-of-plane tensile loads
Susceptibility to impact-damage and strong possibility of internal damage going unnoticed
Moisture absorption and consequent degradation of high temperature performance
Multiplicity of possible manufacturing defects and variability in material properties
Even after accepting these weaknesses, the projected benefits are significant and almost all aerospace programmes use significant amount of composites as highlighted in the figure below.

All this is, of course, not without its share of hassles. Challenges of using composites on such a large scale are many. The composites are not only new but also non-conventional: they are anisotropic, inhomogeneous, have different fabrication and working methods and also different controls for quality assurance. They have a complex material behaviour under load requiring new and complicated analysis tools. Moreover, the behaviour is not always predictable by analysis and this makes reliance on several expensive and time consuming tests unavoidable.
The routes to meet these challenges have evolved around use of the advances in computer technology and analysis methods to implement schemes based on computer aided design, computer aided engineering, finite element methods of analysis and building computer interfaces amongst all aspects of development, namely, design, analysis and manufacturing. These should provide fast transfer of information including graphics and accurate analysis methods for a reasonable prediction of complex behavioural patterns of composites. It is only by harnessing the vast computational power for various purposes that the aircraft structural design of today can meet the challenges posed by the required performance.
4. Materials for aerospace composites:
The materials systems which have been considered useful in aerospace sector are based on reinforcing fibres and matrix resins given in table 2 and 3, respectively. Most aerospace composites use prepregs as raw materials with autoclave moulding as a popular fabrication process. Filament winding is popular with shell like components such as rocket motor casings for launch vehicles and missiles. Oven curing or room temperature curing is used mostly with glass fibre composites used in low speed small aircraft. It is common to use composite tooling where production rates are small or moderate; however, where large number of components are required, metallic conventional tooling is preferred. Resin injection moulding also finds use in special components such as radomes. Some of the popular systems are given in table 4 along with the types of components where they are used in a typical high-performance aircraft.
Table 2. Reinforcing fibres commonly use in aerospace applications.
Fibre Density (g/cc) Modulus (GPa) Strength (GPa) Application areas
Glass
E-glass
S-glass
2.55
2.47
65-75
85-95
2.2-2.6
4.4-4.8
Small passenger a/c parts, air-craft interiors, secondary parts; Radomes; rocket motor casings
Highly loaded parts in small passenger a/c
Aramid
Low modulus
Intermediate
modulus
High modulus
1.44
1.44
1.48
80-85
120-128
160-170
2.7-2.8
2.7-2.8
2.3-2.4
Fairings; non-load bearing parts
Radomes, some structural parts; rocket motor casings
Highly loaded parts
Carbon
Standard modulus
(high strength)
Intermediate
modulus
High modulus
Ultra-high strength

1.77-1.80
1.77-1.81
1.77-1.80
1.80-1.82
220-240
270-300
390-450
290-310

3.0-3.5
5.4-5.7
2.8-3.0
4.0-4.5
7.0-7.5
Widely used for almost all types of parts in a/c, satellites, antenna dishes, missiles, etc.
Primary structural parts in high performance fighters
Space structures, control surfaces in a/c
Primary structural parts in high performance fighters, spacecraft
Table 3. Polymeric matrices commonly used in aerospace sector.
Thermosets Thermoplastics
Forms cross-linked networks in polymerization curing by heating No chemical change
Epoxies Phenolics Polyester Polyimides PPS, PEEK
Most popular
80% of total composite usage
Moderately high temp.
Comparatively expensive Cheaper
Lower viscosity
Easy to use
High temp usage
Difficult to get good quality composites Cheap
Easy to use
Popular for general applications at room temp High temp application 3000C
Difficult to process
Brittle Good damage tolerance
Difficult to process as high temp 300-4000 C is required
Low shrinkage (2-3%)
No release of volatile during curing More shrinkage
Release of volatile during curing High shrinkage (7-8%)
Can be polymerized in several ways giving varieties of structures, morphology and wide range of properties Inherent stability for thermal oxidation
Good fire and flame retardance
Brittle than epoxies Good chemical resistance
Wide range of properties but lower than epoxies
Brittle
Low Tg
Good storage stability to make prepregs Less storage stability-difficult to prepreg Difficult to prepreg Infinite storage life. But difficult to prepreg
Absolute moisture (5-6%) causing swelling and degradation of high temp properties
Also ultra violet degradation in long term Absorbs moisture but no significant effect of moisture in working service range Less sensitive to moisture than epoxies No moisture absorption
Density (g/cm3) 1.1-1.4 Density (g/cm3) 1.22-1.4 Density (g/cm3) 1.1-1.4 Density (g/cm3) 1.3-1.4
Tensile modulus 2.7-5.5 GPa Tensile modulus 2.7-4.1 GPa Tensile modulus 1.3-4.1 GPa Tensile modulus 3.5-4.4 GPa
Tensile strength 40-85 MPa Tensile strength 35-60 MPa Tensile strength 40-85 MPa Tensile strength 100 MPa
5. Concerns with composite usage
The concern in use of composites arises mainly due to demands of high degree of reliability and safety of aerospace structures as against the complexity of composite behaviour and consequent difficulties in building prediction models. This creates an excessive reliance on testing at all stages; design and development, proving and certification, and in-service inspection and repairs. The costs of such testing are sometimes enormous and this had led to some skepticism in use of composites. Two major issues in this regard are briefly discussed below.
5.1 Impact damage and damage tolerance
The laminated structure of the composites and the fibre-matrix interfaces provide weak interfaces for delamination and debonding to take place. This is further aggravated by practical structural features such as discontinuous plies to create thickness changes and sharp bends required in stiffening members. Of particular concern is the proneness exhibited for damage due to impact. The issue is not merely the reduction in strength (particularly in compression) but also that the damage is inside the material and not visible at the structure. This is particularly so where the impact is due to blunt objects at low to medium velocities. Common instances are dropping of tools, hail-stones, runway debris and impacts and jolts while handling (even before the assembly of the air craft). Such hidden damage can be extensive- both in terms of planar dimensions and through the thickness. The damage mostly occurs as delamination, but may sometimes be accompanied by fibre-breaks in back plies which are not visible from outside. In the shop, such damages can be found by ultra-sonic C-scan method and a barely visible impact damage can cause a reduction in compressive strength by almost 60%. The fatigue resistance of carbon composites stands it in good stead, however, and no further significant reduction in strength or growth of damaged is observed under in-plane loads.
The current philosophy to handle impact damage problem is as follows: (i) design the structure to have alternate load paths to have damage tolerance against impact of moderate severity. This is generally taken care by designing the structure as a framework of stiffening members or as boxes; (ii) lower the design allowable strength values to an extent where the barely visible impact damage (BVID) can be sustained even at the highest load and for all the time with no degradation in performance; (ii) any damage that exceeds the BVID level (i.e. visible damage) may lower the intermediate performance and should be repaired immediately. The basic safety of aircraft with damage is ensured due to (i) and (iv) the structure may not cater to very severe impact.
There is, of course, a penalty in lowering the allowables but for the present systems, this is considered to be not too excessive in view of the similar reduction of allowables required for fastener holes. With improved processing to get large parts integral with stiffeners and other complex shapes and with availability of high strength fibres the limitations due to impact damage would be more perceptible and prohibitive.
Another consequence of the impact damage issue which the aeronautical community is, perhaps, not yet fully exposed to is in terms of the inspection intervals and defining levels of repairs etc. when the presently developed aircraft go in full service. Extensive studies and gathering of experience through testing is presently underway to tackle this problem.
5.2 Environmental degradation
The presently used epoxy resins absorb about 5-6% moisture by weight when fully saturated. This leads to about 1.5-1.8% moisture weight gain in carbon-epoxy composites with the usual 60% fibre volume fraction. In practice, under the normal operating conditions, the maximum equilibrium moisture gain in an aircraft component can be about 1.0-1.4%. This moisture gain can cause (a) swelling and dimensional changes, (b) lowering of the gas transition temperature (Tg) of the resin matrix, and © degradation of matrix dominated properties of composites such as shear and compression strengths.
The dimensional changes and weight gain by itself are generally not significant in many aircraft structures but may be of considerable significance where extreme precision is required such as in antennae panels and in aircraft structures is the degradation of the shear and compressive strength properties-particularly at high temperatures close to Tg which in itself is now reduced due to moisture absorption. The design of a structural component, therefore, generally proceeds by reducing allowables for moisture degradation.
This single issue of environmental degradation due to moisture absorption has made development of composite components for aerospace quite expensive and tedious. Moreover, associated with the already complex behaviour of composites particularly in the long run.
Apart from the moisture absorption, the other significant aspects relate to the UV degradation and radiation effects in the long term. These are particularly important in space structures. The current studies on the subject have provided some solutions to these problems even though the concern about long term behaviour exists.
Table 4. Typical composite material systems in aerospace.
Material system Application area
1750C curing high strength-carbon-epoxy
Zero-bleed (neat resin content) UD prepregs
5 HS or 8 HS bi-directional fabric prepreg
toughness, good out-life and shelf-life Structural components of fighter aircraft and helicopters. e.g. wing skins, spars, fin, rudder, elevons, doors, etc.
1750C curing intermediate modulus carbon with epoxy + BMI / cynate-ester
Zero-bleed (neat resin content) UD prepregs
5 HS or 8 HS bi-directional fabric prepreg
high toughness, good out-life and shelf-life
low environmental degradation Frames, stiffeners, rotor blades
1200C curing HS-carbon-epoxy
Zero-bleed (neat resin content) UD prepregs
5 HS or 8 HS bi-directional fabric prepreg
toughness, good out-life and shelf-life Structural components of helicopters or transport aircraft. e.g. spars, fin, rudder, elevons, doors, etc. Frames, stiffeners
Aramid fibre in low-loss polyester / cynate esters Radome
Cu-mesh epoxy prepreg For Lightning Strike protection Wing-skin, others
E-glass fabric in epoxy resins
High temp curing
RT / moderate temp curing Fighters fairings, fin-radome, drop-tanks, Small transport air craft structural components : Fuselage, wing, others

Some other aerospace applications are illustrated above:
Fig. A : Two seater transport aircraft
Fig. B : Space launch vehicles (Space Shuttles)
Fig. C : Satellites
Fig. D : Advanced helicopters (Military & Civilian)
6. Advances in materials for composites
6.1 Reinforcements
The carbon fibre technology continues to improve harnessing the versatility of carbon fibre and new varieties in terms of better combinations of modulus and strength are becoming available. The developments seem to be in two directions: one, for aircraft applications, is aimed basically at higher strength (>5 GPa) with concurrent improvements in modulus to a moderate level (>300 GPa) and the other, for space applications, is aimed at high modulus (>500 GPa) with moderate strength (3.5 GPa). The higher failure strain for the fibre is expected to result in composites with better damage tolerance. The developments in aramid fibres also aim at higher modulus with concurrent increase in strength. However, the major thrust in improving reinforcements for composites comes from the requirements of multidirectional weaving. Several processes (weaving, knitting, braiding) have been developed for this purpose and performs with multidirectionally woven fibres have now been made. Simplification and cost reductions appear to be the major motives for further developments.
The higher properties of basic fibres (such as carbon) cannot, however, be fully exploited in the composite without concurrent developments in the matrix materials and the intermediate products such as prepregs or performs. It is to be noted here that the carbon fibre composites which use a carbon fibre with a strength of 3 GPa as reinforcement result in an allowable stress of only 0.3 GPa in a composite. Significant scope thus exists for translating high fibre properties into high performance of composites.
6.2 Matrix resins
A significant effort in improving composites is focused on improving matrix materials. The two major concerns mentioned earlier viz. impact damage tolerance and hygrothermal degradation, provide the main motivation for improvement. A major direction of improvement appears to be an improvement in the toughness, which should result in higher resistance in to delamination and against impact. High failure strain of matrix resin would help in translating the higher performance of the improved fibre to the composite. Higher resin shear modulus would help in achieving better transfer of load from fibre to resin and again to fibre and should therefore improve compression strength. For polymeric materials a possible figure of 5 GPa should be achievable as against the current resins with shear modulus of about 2 GPa. As far as hygrothermal degradation is considered, newer systems based on cynate ester look very promising and some of these have already found some application. Another route being investigated is the use of thermoplastic resins and their blends. Poly-ether-ether-ketone (PEEK) has been considered very promising, but the industry needs to resolve the problems associated with high temperature (> 350 0C) processing of a material. Current approaches to new resins appear to be directed towards producing polymeric systems which can be processed in the way composites industry is used to (such as autoclave curing upto 180 0C).
7. Conclusions
Hence we can finally conclude that:
Composite materials offer high fatigue and corrosion resistance.
Composite materials have high strength to weight ratio.
So they are best suited for various aerospace applications.
8. References
Introduction to Engineering Materials by V.B.John; Chemistry of Engineering Materials by C.V.Agarwal; Bulletin of Material Science- Published by Indian Academy of Sciences in collaboration with Material Research Society of India and Indian National Science Academy.
9. Acknowledgements
Our sincere thanks go to Dr. M.R.S.Satyanarayana and Shri S.Kamaluddin for their valuable guidance and encouragement.