Lesson 10: AIRCRAFT STRUCTURAL MATERIALS

The different methods of aircraft structural repair procedures


AIRCRAFT  STRUCTURAL MATERIALS


The importance of knowing the different methods of aircraft structural repair procedures is readily apparent given today’s tight fiscal environment. As a maintenance officer, you will be expected to understand many areas of aircraft structural repair. This lesson concentrates on the different types of aerospace materials used on today’s aircraft and their application.

Key Points:

Structural materials;
Non-ferrous metals;
Filamentary composite materials;
Advanced composites;
Advanced composite repair techniques;
Additional aerospace materials;
Techniques for aircraft structural fabrication and repair;
Temporary structural repair requirements.


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Click here for the previous lessons, to learn about: Principle of Airframe; Principles of Aerodynamics; Airfoil Characteristics; Primary Flight Control Surfaces; Description and Operation of Helicopter; Miscellaneous Components of an Aircraft…

Structural Materials

 METALS.

The metals that are used in the make up of an aircraft must be strong and be able to withstand the stress related with flight. The density of metal is the weight of the metal per volume, measured in pounds per square inch. Strength is the maximum stress that a material can withstand before failure. Here is a basic list of the type of stress or forces that can affect aircraft surfaces:

• Tensile strength is pulling force occurs.

• Compressive strength is pushing force.

• Strain is referred to as the strain of any force over the length of the surface. • Modulus elasticity is referring to the stiffness of the material.

 Ferrous.

 Ferrous metals are those containing iron as the main metal. Iron, itself is heavy, relatively soft, and not used on aircraft. However, steel is an alloyed metal that contains iron, carbon and other non-ferrous metals. Steel, especially stainless steel, is very useful in certain airframe applications. Steel alloys take on the conductive and magnetic characteristics of a ferrous metal.

 Steel.

Steel is rated by its carbon content:

• Low carbon steel (0.1-0.3%) is seldom used except as secondary structural parts and clamps.

• Medium carbon steel (0.3-0.5%) has high strength and is used in landing gear and flight control components.

• High carbon steel (0.5-2.0%) is hard and brittle, rarely used on aircraft, mostly used on coil springs.

Stainless steel is a special class of steel, containing chromium and nickel, and is used in high temperature applications. It can be found in exhaust systems and the hydraulic lines of many aircraft. Stainless steel has a high strength to weight ratio and resists corrosion and heat as well.

Non-Ferrous Metals

 Aluminum.

Aluminum is a light; but strong metal used extensively in structural members and aircraft skin (especially in older aircraft). Aluminum is malleable and relatively easy to work with. Different types of aluminum have been given industry-wide designations by their alloy type. Common alloy-types:

• 2024 – used on many aircraft for secondary structure and skin. • 7075 – found in areas that high strength is required.

Titanium.

Titanium is 43% lighter than stainless steel but stronger. The most popular type of alloy used in the aerospace industry is 6AL-4V (meaning that the titanium is alloyed with 6% aluminum and 4% vanadium). Titanium is very corrosion resistant and is unattached by most acids, by moist chlorine gas, or by common salt solutions. Titanium resists heat extremely well and is therefore used in many high speed aircraft as shown in figure 1-49. It is also expensive, and replacements for titanium are being researched. New alloys for titanium, even composites mixed with titanium (or titanium-matrix’s) are being researched and tested, particularly for use as replacements for steel landing gear actuators and struts.

    

Magnesium.

Magnesium is the lightest structural metal. It is very brittle, porous and seldom used in its pure state. Used widely by aircraft builders in the past, magnesium is being phased out of military aircraft for three reasons: 1. It corrodes easily

2. It is difficult to work with

3. It is highly flammable

Other non-ferrous metals include to clad pr plate parts to protect them from corrosion. Cadmium is commonly used for many parts, though it has a bad reaction with titanium. Nickel, Zinc, and even Aluminum are used to protect parts as well.

NON-METALS.

Nonmetals used in aircraft construction vary widely in type, composition, and application. The earliest aircraft were built with wood and cloth, with some metal parts. New aircraft are being made of advances composite materials, ranging from graphite to experimental uses of titanium/composite matrix to replace steel components.

 Plastics/Acrylics.

 Used for decades in aircraft, plastics offer many advantages over wood and metal structures. Plastics are light, have good strength, and may be used in many non-load bearing areas. Canopies, consoles, and other aircraft parts are frequently made of plastic. There are many different plastics in use today including synthetic resins (such as acrylic, nylon, and vinyl), cellulose plastics (used on older aircraft), thermosetting plastics (those which retain their shape after manufacturing and are not re-formable, such as polyester), and thermoplastics (plastics which may be reheated and reformed).

 Phenolic.

Phenolic


Phenolic is a special type of plastic; it is actually a combination of plastic and wood or paper. When wood based material is set in plastic, it becomes harder and stiffer then plastic alone, but does not have the strength or heat resistance necessary to be used in a primary structure. Phenolics are found in computers (as circuit boards), flight control rigging (pulleys), hydraulics (as clamps to hold lines in place), and many other areas. The advantage of a Phenolic clamp for a hydraulic line over steel on is the pheniloc one will not chaff (scratch) the steel line. The Phenolic clamp will take the damage induced by aircraft vibrations, but will save the hydraulic line from being damaged.

Filamentary Composite Materials

Filamentary Composite Materials


A material consisting of two or more physically different solid constituents, each of which largely retains its original structure and identity. Composites are distinct from alloys in that their structure is engineered by mixing two materials in an intimate solid mixture, with one component being embedded in the other, usually an adhesive or epoxy type of material and a fibrous type of material. A common feature of composite materials is the use of small quantities of a relatively expensive, strong, often fibrous material to reinforce the bulk of a cheap matrix material. The properties of the resulting composite are usually intermediate to those of the components from which it is made. However, certain properties, notably toughness or resistance to fracture, are much better than those of either of the components, giving composites with unique properties. A simple example of a composite is clue on a piece of fabric; it is stronger than either material by itself, but now is a more solid surface type of material. Refer to Figure 1-50, 1-51 and 1-52.

Desired Characteristics of Matrix Resins

Mechanical & Thermal Processing Characteristics

-High strength

-High elastic elongation

-High shear strength

-High modulus

-High heat distortion temp

-Low creep at use temp

-High toughness/impact strength -Thermal expansion near fiber -Resistance to thermal degradation -Low thermal conductivity

 

Chemical Properties:

Good bond to fiber (directly or with coupling agent)

Resistance to solvents & chemicals

-Low enough melt or solution viscosity and surface tension to permit thorough fiber wet-out

-Good flow characteristics

-Rapid cure or solidification

-Suitable for pre-coated reinforcement

-Cure temp. not greatly above use temp

-Low shrinkage during and after molding

-Long shelf life and pot life

Other Factors:

Low cost

Low density

Low dielectric constant

Low moisture absorption

Comparison of Thermoset and Thermoplastic Resins

Thermosets Thermoplastics  

-Most used

-No flow under heat and pressure after cure; scrap discarded

-Amorphous

-Applied to reinforcement as low viscosity liquids or varnishes

-Phenolics and most polyimides emit volatiles on curing

-Stepwise cure possible to permit control of viscosity & handling

-Post curing often necessary for optimum properties

-Higher strength, modulus and average use temperature

-Used with continuous fiber and discontinuous fiber (usually >1/4”) possible with some plastic yielding

-Used mostly with discontinuous fiber (Length usually <1/2”), though much Activity in last 10 years on TP prepregs

-Relatively high tensile elongations -High variability in mechanical properties

-Most suited to automated production

-Softening and/or melting points remolding of scrap usually possible

-May be crystalline

-High viscosity even in the melt; reinforced by dry or melt compounding

-No volatiles emitted during molding

-Viscosity varied only by increase in temperature and/or shear rate

-Post molding shrinkage may be severe due to slow crystallization

-Tougher, less brittle and lower cost -Low tensile elongations

-Variability in mechanical properties  

 Figure 1-50, Figure 1-51, Tensile Strength of Composites Elasticity of Composites

ADVANCED COMPOSITES


Figure 1-52, Strength of Composites


ADVANCED COMPOSITES

Composites referred to by type of fiber/type of matrix, layers can be fiber only for later “wet” lay-up (adding resin), or can be “prepreg” (already containing the resin)

 Tape - all fibers aligned in single direction

Cloth - fibers aligned in multiple (usually two) directions

Plain weave: over and under one fiber at a time

Satin weave: over several then under one fiber

 Graphite/Epoxy.

Graphite epoxy is produced by subjecting strands of synthetic materials (graphite) to intense heat and pressure, after which the filaments (containing 3,000 to 16,000 strands each) are organized into unidirectional tapes or woven into fabrics. Graphite epoxy materials are extremely stiff, have high tensile strength, and low density. Components made of graphite epoxy are lighter than aluminum, or woven fiberglass, but strong enough to be used as primary structures (and frequently as flight control surfaces or weapons bay/landing gear doors due to their low radar signature). Many newer aircraft are using a substantial amount of graphite epoxy in their primary structures; resulting in lighter, more fuel efficient aircraft.

 Aramid/Epoxy (Kevlar).


Aramid/Epoxy (Kevlar).


 Aramid epoxies are a lightweight polymer material with exceptional tensile strength. They are usually yellow-gold in color. Aramids were developed in 1965 during a research project to design a strong and lightweight fiber.

Used in flight suits and hazardous-material handling gear, Nomex is an example of an Aramid, the most common Aramid used in aircraft, though, is known as Kevlar. Kevlar is 30-35% lighter than fiberglass, but not stiff enough to be used in primary aircraft structure. A distinguishing feature of Kevlar fibers is their low compression strengths, giving the material good energy absorption characteristics. As a result, Kevlar is often used to replace titanium or steel armor plating, being much lighter and having better impact resistance than most metals. Examples of use included bulletproof aircrew seats, high strength ropes, personal armor, helmet, rotor blade bullet resistant coatings, flight control surfaces, and aircraft cowlings. Aramids are repaired with methods similar to those used on fiberglass, though extra care must be taken to limit ultraviolet (sunlight) and moisture penetration on Aramid structures.

 Boron/Epoxy.

Boron epoxy is formed by depositing boron trichloride (as a vapor) onto 0.005-inch tungsten fiber. Boron fibers are stiffer, stronger, harder, and lighter (one-fourth the weight of steel) than conventional metals. In hardness, boron ranks second to only diamonds. Due to its high stiffness, twice that of steel, boron cannot be formed onto a tight radius, that is, parts made of boron are limited to flat surfaces (such as vertical/horizontal stabilizers). Working with boron can be hazardous. The fibers are thin enough and stiff enough to pass through a technician’s hand, or become airborne, if broken off or inhaled. Boron composite materials are easily distinguished by their grayish-black color.

 Figure 1-53, C-17 Composite Material

Newer materials.

Composite materials, as shown in figure 1-53, 1-54 and 1-55 such as carbon- fiber or glass-fiber reinforced plastics, are now widely used, due to their superiority over metals, in applications requiring high stiffness and strength as well as low weight. A major concern about the use of composite laminates for structural applications is however their low-resistance to out-of-plane localized impact loadings, likely to occur during manufacture, service or maintenance. While metal structures may absorb impact energy by plastic deformation, usually without any major effect on the load carrying performance, energy dissipation in composite materials mainly occurs through a combination of fracture modes such as matrix cracks, delaminating and fiber fracture, which may cause significant reductions of residual strength and modify the structural response of the component.

Glass epoxy, glass polyamide, fiberglass polyamide and graphite peek

are just some of the newer materials that are used in construction of modern-day aircraft. Glass epoxy is more of a protective coating for certain panels, used in areas that need less than 400 degree. Glass polyamide and fiberglass polyamide are used for their high temperature resiliency, mainly used in engine areas. Graphite peek is mainly used for its strength and rigidity, works particularly well because its temperature limits, (350– 400°C) is compatible with the range of forming temperatures, 360–500°C, of the super plastic sheets; the sheets used are aluminum alloy 2004.

  

Glass epoxy, glass polyamide, fiberglass polyamide and graphite peek

 

Figure 1-54,  Composite Material

     

Advanced Composite Repair Techniques

 Repairing today’s advanced materials can be labor some, time consuming and expensive. In many cases a diamond-dusted tools must be used in order to cut the materials for machining. This type of tool also aids in preventing micro-cracks on the surface of the material, this would allow moisture to possibly penetrate the material.  The temperature that is required to repair and cure (dry) some of the epoxies can be very high, 190-500 degrees. This requires not only special equipment, but a controlled environment as well. Moisture is one of the major causes of failure in any composite, great care must be taken to prevent this when repairing.

Advanced Composites Require Special Safety

Not only are special tools required to make the repairs, but we must also have the proper equipment to protect our personnel making the repairs. Graphite dust can be corrosive, when using, control; must be maintained to prevent the dust particles from escaping, the dust can cause galvanic corrosion. Here is a list of the most common items that are required; goggles, dust respirator and, gloves

 

Additional Aerospace Materials

HONEYCOMB.

Honeycomb, figure 1-56, is a structure sandwich construction that consists of three or more laminations of different materials. Many aircraft use a honeycomb type of construction.

Honeycomb construction is light in weight and used in flight controls and trailing edges of wings. Figure below shows an example of honeycomb construction. Honeycomb structural sheets may be made from many materials, such as fiberglass, plastic, metal (aluminum or steel), graphite or carbon fiber composite.


aircraft structural Honeycomb


Figure 1-56, Honeycomb

These materials may be used for both the outer faces and the core. This material is light in weight but very strong.

Many supersonic aircraft use stainless steel and titanium on surfaces and for the core. The metal honeycomb (hexagonal) core is bonded or glued to the faceplates. The material cannot be formed or shaped by bending. The advantage of honeycomb construction is that it has an exceptionally high strength, but very lightweight. Caution is advised when working on or around these surfaces. Stepping on these areas can easily damage them. Aircraft surfaces will be marked or stenciled to show walkway areas. ”No Step” will be stenciled in areas where walking is prohibited.

OTHER MATERIALS.

 Many other materials are utilized in design and manufacture of aircraft. These include protective coatings such as Teflon and rain erosion covers on radomes and metal treatments like a nickel, cadmium, or aluminum plating to protect surfaces from damage and corrosion. Aircraft with special missions such as the F-117 and B-2 utilize Radar Absorbent Materials (RAMS) to complete their stealth features. Ceramics are a class of material that has been used for some time in electrical components and high heat areas, such as augmenter linings and the convergent/divergent exhaust nozzles of afterburning jet engines. Advances in ceramics, such as mixing with certain silicones, are adding strength and flexibility to the otherwise brittle material. These advances are intended to take advantage of the heat resistance properties of ceramics and make them available for use in future engine components to include combustor lines and turbine blades.

Techniques For Aircraft Structural Fabrication And Repair

The following is an example of how detailed and labor some the repair process can be:

Compressed air is applied to the airside diaphragm (for higher pressures, nitrogen gas may also be used). At the same time, air is evacuated from the sandwich pack. Using an electrically heated platen-press, the die and diaphragms are warmed to the forming temperature. Heat and pressure combine to stretch and form the diaphragms to the geometry of the die. By this process, we form the two diaphragms with the composite between them and draw, drape and consolidate the composite between the conforming diaphragms. Forming is not accomplished in a rapid motion like in a stamping operation. Here, the forming operation is relatively slow, making it easier for the fibers to slide into place without breaking or buckling out of the plane. The frictional effect of trying to pull fibers in rapidly can break them. We can make a single monolithic part by integrating multiple details and can co-consolidate parts by raising a finished detail back to its melt point and fusing it together with a new piece. An alternative joining method is dual-resin (amorphous) bonding. This technique is important in bonding the hat-stiffened sections: the hats would collapse if the fabricated section were brought back to their melting temperature. In this case, a plain outer skin and a hat-stiffened inner skin will be bonded together at a temperature below the melting point of the PEEK, using Ultem or another polyetherimide (PEI) interface. Ultem, a product of GE Plastics in Pittsfield, Massachusetts, flows well at a temperature of 265°C to create a 100% bond.

Ply lay-ups are a combination of balanced ply arrangements.

For instance, unidirectional and biaxial material may be arranged to form a 0/90/±45° orientation of the fibers. Parts on the F-22 have thicknesses from 1 mm (0.040 inches) to more than 12.7 mm (0.5 inches) for the main landing-gear doors; each door has more than 100 plies, built up by a combination of co-consolidation and dual bonding of part details.  Many of the materials used to make repairs cannot be just made; they must be formed into replacement parts. The molds or casts to produce the replacement part can be very costly, this greatly limits the type and frequency that certain repairs can be accomplished.

 Permanent repair requirements.

 Repairs must maintain original weight, strength and aerodynamics in order to be effective; changing any portion of this may have catastrophic effects. Many aircraft surfaces are subject to different kinds of stress and forces not only wind but also drag and shock. The aircraft specific –3 TO will list the specific requirements for weight and balance of each component with specifics about the particular component

 Permanent repairs are designed to just that, permanent. Extra time and care is taken so not only the repair is done correctly and right, but will last.

Temporary structural repair requirements.

There are two areas of temporary repairs: primary and secondary aircraft structure. With a primary structure is damage to an integral part of the aircrafts structure causing a safety of flight issue. A temporary repair is mainly made to move an aircraft or to fly it to a depot repair facility. This repair must restore original strength and structural integrity to the surface or aircraft. A RED “X” goes into the aircraft’s forms, only the MXG/CC, AFMC airframe managers must approve this type of repair. A secondary structure is more of a true temporary repair that allows the aircraft’s mission to continue until more down time can be scheduled for a permanent repair. This does not affect any safety of the aircraft’s structure; commonly a diagonal write-up is placed in the aircraft forms. The most common is stop drilling, this prevents a crack from continuing to spread or lengthen.

 

This is an Aerospace engineering concerned with the development of aircraft and spacecraft, focused on designing aeroplane and space shutlle and it is a study of all the flying wing used within the earth's atmosphere. Also dealing with the Avionic systems that includes communications, navigation, the display and management of multiple systems. Also dealing with Aircraft mishap such as Accident and Serious Incident