SUMOOK, MICHAEL_AMT2-1_AMCR ACT1.pdf

Transcript

AIR LINK INTERNATIONAL AVIATION COLLEGE
Air Link Building, Domestic Road, Domestic Airport, Pasay City
1301 Philippines
UNDERGRADUATE STUDIES DEPARTMENT
First Trimester, A.Y. 2024-2025
Aircraft Maintenance and Construction and Repair II
(Composites)

AIRCRAFT MATERIALS, CONSTRUCTION & REPAIR II (AMCR)
INSTRUCTOR: MR. JOHN BRAYN C. PARDALES

ACTIVITY #1

NAME: Michael Angelo Sumook DATE: 09/02/24

Based on our conversation last week, please prepare a report covering the topics we discussed.
Doing this exercise may help you with the quiz scheduled for tomorrow! USE YOUR OWN
WORDS

DEADLINE OF SUBMISSION: SEPTEMBER 3, 2024

TOPICS:

LAMINATED STRUCTURE

Composite materials consist of a combination of materials that are mixed together to achieve
specific structural properties. The individual materials do not dissolve or merge completely in the
composite but act together as one. Normally, the components can be physically identified as
they interface with one another. These materials can be applied to aircraft structures like on its
fairings, flight control surfaces, landing gear doors, interior components, stabilizers, propellers,
and more.

Types of Materials

Isotropic

These are materials that do not change with direction
Example: Metal and glass.

Anisotropic

These are materials that change in perpendicular directions
Example: Wood and composites.

Orthotropic

These are properties that change in all directions.
Example: Wood and structure.
 AIR LINK INTERNATIONAL AVIATION COLLEGE
Air Link Building, Domestic Road, Domestic Airport, Pasay City
1301 Philippines
UNDERGRADUATE STUDIES DEPARTMENT
First Trimester, A.Y. 2024-2025
Aircraft Maintenance and Construction and Repair II
(Composites)

WHAT ARE THE MAJOR COMPONENTS OF COMPOSITES

Major Components of Composites

Fiber: The main component of the composite material that carries the load. The
reinforcing material is solid.
Matrix: The matrix supports and holds together the fibers to bond them with the
composite material.

Structural properties, such as stiffness, dimensional stability, and strength of a composite
laminate, depend on the stacking sequence of the plies.

Fiber Orientation

The orientation sequence of the plies determines the stiffness and strength of a composite build.
In advanced composite materials, selecting the ply orientation correctly is essential to producing
a solid structural design. For the part to respond to axial loads, it might need 0° plies, ±45° plies
for shear loads, and 90° plies for side loads.

Warp Clock
Warp: shows the longitudinal fibers of a fabric
Warp Clock: Indicates the way the fibers are oriented on a manufacturer's sheet, spec
sheet, or diagram. When the fabric comes off the roll, the orientation defaults to zero if
the warp clock is not present on the fabric.

Fiber Forms

All product forms generally begin with spooled unidirectional raw fibers packaged as continuous
strands.

Filament: A single fiber. It can also be called a “strand”.
Tows, Yarns, or Rovings: Bundles of filaments. Kevlar yarns are not twisted, fiberglass
yarns are.
 AIR LINK INTERNATIONAL AVIATION COLLEGE
Air Link Building, Domestic Road, Domestic Airport, Pasay City
1301 Philippines
UNDERGRADUATE STUDIES DEPARTMENT
First Trimester, A.Y. 2024-2025
Aircraft Maintenance and Construction and Repair II
(Composites)

Tows and Rovings: Do not have any twists. Most fibers are available as dry fiber that
needs to be impregnated with a resin before use or prepreg materials where the resin is
already applied to the fiber.

Roving

A roving is a single set of filament or fiber ends, such glass rovings with 20 or 60 ends. There is
no twisting and every filament is pointing in the same direction. Typically, carbon rovings are
designated as 3K, 6K, or 12K rovings—K standing for 1,000 filaments.

Unidirectional (Tape)

For a long time, unidirectional prepreg tapes have been the norm in the aerospace sector.
Thermosetting resins are usually used to impregnate fibers. The most popular manufacturing
process involves pulling collimated raw, or dry, strands into an impregnation machine, which
uses pressure and heat to mix the strands with hot, melted resins.

Matrix Materials

Thermosetting Resins

Strengthen when heated and cannot be remolded or reheated after the initial forming.
Examples include Polyester Resin, Vinyl Ester Resin, Phenolic Resin, Epoxy Resin,
Polyimides, Polybenzimidazoles (PBI), and Bismaleimides (BMI).

Thermoplastic Resins

Can be reheated, remolded, and cooled as necessary without causing any chemical
changes.
Semicrystalline Thermoplastics: Possess inherent flame resistance, superior
toughness, good mechanical properties, and low moisture absorption.
Amorphous Thermoplastics: Known for their processing ease and speed, high-
temperature capability, good mechanical properties, toughness, impact strength, and
chemical stability.
Polyether Ether Ketone (PEEK): A high-temperature thermoplastic with outstanding
thermal and combustion characteristics.

TYPES OF FIBERS
 AIR LINK INTERNATIONAL AVIATION COLLEGE
Air Link Building, Domestic Road, Domestic Airport, Pasay City
1301 Philippines
UNDERGRADUATE STUDIES DEPARTMENT
First Trimester, A.Y. 2024-2025
Aircraft Maintenance and Construction and Repair II
(Composites)

Types of Fibers

Fiberglass

Often used for secondary structures on aircraft, such as fairings, radomes, and wing tips.
Electrical Glass (E-glass): Identified for electrical applications, made from borosilicate
glass.
S-glass and S2-glass: Structural fiberglass with higher strength than E-glass, produced
from magnesia-alumina-silicate.

Kevlar®

DuPont’s name for aramid fibers is characterized by their yellow color.
Kevlar® 49: High stiffness.
Kevlar® 29: Low stiffness.

Advantages include high resistance to impact damage, making them ideal for areas prone to
such damage. Disadvantages include weakness in compression and hygroscopy, with some
parts absorbing up to 8 percent of their weight in water.

Carbon/Graphite

Black graphite/carbon fiber is very strong, stiff, and used for primary structural
components like ribs and floor beams.
Advantages include high strength and corrosion resistance.
Disadvantages include lower conductivity than aluminum, necessitating lightning
protection for aircraft parts prone to lightning strikes, and high cost.

Boron

Very stiff with high tensile and compressive strength.
Used primarily in military aviation applications, particularly for repairing cracked
aluminum aircraft skins due to its thermal expansion properties, similar to aluminum.

Ceramic Fibers

Used for high-temperature applications, such as turbine blades in gas turbine engines,
withstanding temperatures up to 2,200 °F.

Goodluck and Stay Safe Everyone!