The Fuselage Structure

The Fuselage Structure
   The word fuselage is based on the French word fuseler, which means "to streamline." The fuselage must be strong and streamlined since it must withstand the forces that are created in flight. It houses the flight crew, passengers, and cargo.

   Fuselages are classified according to the arrangement of their force-resisting structure. The types of fuselages we will study are the truss and the semimonocoque. Five types of stress act on an aircraft in flight: tension, compression, bending, shear, and torsion. Let's look at each one individually (see animation or figures 1-2, to see the animation press on the icon or the figure).
Tension
  Tension is the stress which tends to pull things apart. When you try to break a length of rope, you exert a type of stress which is called tension. (see animation or figure 1-2a)

Compression


   Compression is the opposite of tension. It is the stress which tends to push materials together. When you grasp a football at both ends and push, the ball is subject to compression. The landing gear struts of an aircraft are also subject to compression. (see animation or figure 1-2b)

 Bending

   This type of stress combines tension and compression. You put a bending stress on a bar when you grasp it with both hands and push the ends together or when you bend a paper clip. The wing spars (interior structural members) are subjected to bending while the aircraft is in flight. The lower side of the spar is subjected to tension, while the upper side is subjected to compression. Obviously, some materials will break before they bend and often are unacceptable for aircraft construction. (see animation or figure 1-2c which shows the upper side as the tensile side)

Shear
     
   Shear stress is caused by forces tending to slip or slide one part of a material in respect to another part. This is the stress that is placed on a piece of wood clamped in a vise and you Chip away at it with a hammer and chisel. This type of stress is also exerted when two pieces of metal, bolted together, are pulled apart by sliding one over the other or when you sharpen a pencil with a knife. The rivets in an aircraft are intended to carry only shear. Bolts, as a rule, carry only shear, but sometimes they carry both shear and tension. (see animation or figure 1-2d)

Torsion

   Press to see Animation 1-2e                                       

 Torsion is the stress which tends to distort by twisting. 

You produce a torsional force when you tighten a nut on a bolt. The aircraft engine exerts a torsional force on the crankshaft or turbine axis.

   All the members (or major portions) of an aircraft are subjected to one or more of these stresses. Sometimes a member has alternate stresses, such as compression one instant and tension the next. Some members can carry only one type of stress. Wire and cables, for example, normally carry only tension.(see animation or figure 1-2e) 
                                                                                           
   Since any member is stronger in compression or tension than in bending, members carry end loads better than side loads. In order to do this, designers arrange the members in the form of a truss, or rigid framework (see figure 1-3). In order for a truss to be rigid, it must be composed entirely of triangles. When the load on a truss acts in one direction, every alternate member carries tension while the other members carry compression. When the load is reversed, the members which were carrying compression now are subjected to tension and those which were carrying tension are under compression. The truss itself consists of a welded tubular steel structure with longerons (horizontal members) and diagonal braces. These features make it rigid, strong, and light.
   The truss is covered with a metal or fabric cover so that less drag will be generated. To produce a smooth surface, the fabric cover is put on fairing strips, which are thin flat strips of wood or metal. These fairing strips run the length of the fuselage in line with the direction of flight.
                                                                                           
   The semimonocoque is the most often used construction for modern, high-performance aircraft. Semimonocoqueliterally means half a single shell. Here, internal braces as well as the skin itself carry the stress (see figure 1-4). The internal braces include longitudinal (lengthwise) members called stringers and vertical bulkhead.
   The semimonocoque structure is easier to streamline than the truss structure. Since the skin of the semimonocoque structure must carry much of the fuselage's strength, it will be thicker in some places than at other places. In other words, it will be thicker at those points where the stress on it is the greatest.


 Go to first page....

For any query comment your question here and for contect me mail me at faiyazpatel555@gmail.com.


Comments

Post a Comment

Popular posts from this blog

Empennage

Image
Empennage     The empennage, commonly called the tail assembly (see figure 1-7), is the rear section of the body of the airplane. Its main purpose is to give stability to the aircraft.  The fixed parts are the horizontal stabilizer and the vertical stabilizer or fin. The front, fixed section is called the  horizontal stabilizer  and is used to p revent the airplane from pitching up or down .   The rear section is called the  elevator  and is usually hinged to the horizontal stabilizer. The elevator is a movable airfoil that  controls the up-and-down motion of the aircraft's nose.    The vertical tail structure is divided into the  vertical stabilizer and the rudder . The front section is called the  vertical stabilizer and is used to prevent the aircraft from yawing back and forth .  The principle behind its operation is much like the principle of a deep keel on a sailboat. In light, single-engine aircraft, it also serves to offset the tendency of the air
Read more

Top 10 Best Aeronautical Engineering Colleges in The World - 2018

Image
Aeronautical engineering involves the study of aircrafts and spacecraft’s. This course prepares the Top 10 Richest students to design and engineer flight-capable.    This course has a vast scope for employment. Many universities have included this course in their schools to equip the enrolling students with sufficient knowledge and prepare them to serve the field of science. This course is the passport to the future because of the various developments happening in this space and in aerodynamic research. Here is the list of top universities which have successfully made use of the room available for developed to offer quality education. Students from all over the world are competing to get an admission in these universities. They are becoming their better selves every day to become worthy of selection by these universities. Students aspiring to become a good aeronautical engineer will have these universities set as their goals and in their wish list. Below are the Top 1
Read more

Power Plant

Image
 Power Plant    The power plant may be an engine and propeller combination or a jet engine. The most commonly used power plant in personal aircraft is the gasoline engine, which will be studied in detail later in this chapter. It is mounted in position against a fire wall in the front section of the airplane. The fire wall provides separation of the power plant from the remainder of the fuselage. The engine cowling is the metal covering which encases the engine and its accessories, streamlining the plane and conducting air around the engine cylinders for cooling. Because the action of the pistons is an up-and-down movement, this engine is called a reciprocating engine or a piston engine. In multiengine aircraft, the engines are usually mounted on the leading edges of the wings.   The jet engine gives the airplane a thrust (push forward) because of the jet exhaust gas coming out of the back of the engine. The moving part of this engine is a turbine. Jet engines may be mounte
Read more