The fuselage (/ˈfjuːzəlɑːʒ/; from the Frenchfuselé "spindle-shaped") is an aircraft's main body section. It holds crew, passengers, or cargo. In single-engine aircraft, it will usually contain an engine as well, although in some amphibious aircraft the single engine is mounted on a pylon attached to the fuselage, which in turn is used as a floating hull. The fuselage also serves to position the control and stabilization surfaces in specific relationships to lifting surfaces, which is required for aircraft stability and maneuverability.
Some older types of aircraft design utilized open truss structure constructed of wood, steel, or aluminum tubing.[1]: 3–3
This type of structure is still in use in many lightweight aircraft using weldedsteel tube trusses. A box truss fuselage structure can also be built out of wood—often covered with plywood. Simple box structures may be rounded by the addition of supported lightweight stringers, allowing the fabric covering to form a more aerodynamic shape, or one more pleasing to the eye.
Geodesic airframe fuselage structure is exposed by battle damage
Geodesic structural elements were used by Barnes Wallis for British Vickers between the wars and into World War II to form the whole of the fuselage, including its aerodynamic shape. In this type of construction multiple flat strip stringers are wound about the formers in opposite spiral directions, forming a basket-like appearance. This proved to be light, strong, and rigid and had the advantage of being made almost entirely of wood. A similar construction using aluminum alloy was used in the Vickers Warwick with less material than would be required for other structural types. The geodesic structure is also redundant and so can survive localized damage without catastrophic failure. A fabric covering over the structure completed the aerodynamic shell (see the Vickers Wellington for an example of a large warplane which uses this process). The logical evolution of this is the creation of fuselages using molded plywood, in which multiple sheets are laid with the grain in differing directions to give the monocoque type below.
In this method, the exterior surface of the fuselage is also the primary structure. A typical early form of this (see the Lockheed Vega) was built using molded plywood, where the layers of plywood are formed over a "plug" or within a mold. A later form of this structure uses fiberglass cloth impregnated with polyester or epoxy resin as the skin, instead of plywood. A simple form of this used in some amateur-built aircraft uses rigid expanded foam plastic as the core, with a fiberglass covering, eliminating the necessity of fabricating molds, but requiring more effort in finishing (see the Rutan VariEze). An example of a larger molded plywood aircraft is the de Havilland Mosquito fighter/light bomber of World War II. No plywood-skin fuselage is truly monocoque, since stiffening elements are incorporated into the structure to carry concentrated loads that would otherwise buckle the thin skin. The use of molded fiberglass using negative ("female") molds (which give a nearly finished product) is prevalent in the series production of many modern sailplanes. The use of molded composites for fuselage structures is being extended to large passenger aircraft such as the Boeing 787Dreamliner (using pressure-molding on female molds).
Monocoque construction uses stressed skin to support almost all loads much like an aluminum beverage can.
Semi-monocoque construction, partial or one-half, uses a substructure to which the airplane’s skin is attached.
Sectioned fuselage showing frames, stringers and skin all made of aluminium
This is the preferred method of constructing an all-aluminum fuselage. First, a series of frames in the shape of the fuselage cross sections are held in position on a rigid fixture. These frames are then joined with lightweight longitudinal elements called stringers. These are in turn covered with a skin of sheet aluminum, attached by riveting or by bonding with special adhesives. The fixture is then disassembled and removed from the completed fuselage shell, which is then fitted out with wiring, controls, and interior equipment such as seats and luggage bins. Most modern large aircraft are built using this technique, but use several large sections constructed in this fashion which are then joined with fasteners to form the complete fuselage. As the accuracy of the final product is determined largely by the costly fixture, this form is suitable for series production, where many identical aircraft are to be produced. Early examples of this type include the Douglas Aircraft DC-2 and DC-3 civil aircraft and the Boeing B-17 Flying Fortress. Most metal light aircraft are constructed using this process.
Both monocoque and semi-monocoque are referred to as "stressed skin" structures as all or a portion of the external load (i.e. from wings and empennage, and from discrete masses such as the engine) is taken by the surface covering. In addition, all the load from internal pressurization is carried (as skin tension) by the external skin.
The proportioning of loads between the components is a design choice dictated largely by the dimensions, strength, and elasticity of the components available for construction and whether or not a design is intended to be "self jigging", not requiring a complete fixture for alignment.
Materials
Inside view of the wooden, fabric-covered fuselage of a Fisher FP-202.
Early aircraft were constructed of wood frames covered in fabric. As monoplanes became popular, metal frames improved the strength, which eventually led to all-metal-structure aircraft, with metal covering for all its exterior surfaces - this was first pioneered in the second half of 1915. Some modern aircraft are constructed with composite materials for major control surfaces, wings, or the entire fuselage such as the Boeing 787. On the 787, it makes possible higher pressurization levels and larger windows for passenger comfort as well as lower weight to reduce operating costs. The Boeing 787 weighs 1,500 lb (680 kg) less than if it were an all-aluminum assembly.[citation needed]
Windows
Cockpit windshields on the Airbus A320 must withstand bird strikes up to 350 kn (650 km/h) and are made of chemically strengthened glass. They are usually composed of three layers or plies, of glass or plastic : the inner two are 8 mm (0.3 in.) thick each and are structural, while the outer ply, about 3 mm thick, is a barrier against foreign object damage and abrasion, with often a hydrophobic coating. It must prevent fogging inside the cabin and de-ice from −50 °C (−58 °F). This was previously done with thin wires similar to a rear car window but is now accomplished with a transparent, nanometers-thick coating of indium tin oxide sitting between plies, electrically conductive and thus transmitting heat. Curved glass improves aerodynamics but sight criteria also needs larger panes. A cockpit windshield is composed of 4–6 panels, 35 kg (77 lb) each on an Airbus A320. In its lifetime, an average aircraft goes through three or four windshields, and the market is shared evenly between OEM and higher margins aftermarket.[2]
Cabin windows, made from much lighter than glass stretched acrylic glass, consists of multiple panes: an outer one built to support four times the maximum cabin pressure, an inner one for redundancy and a scratch pane near the passenger. Acrylic is susceptible to crazing : a network of fine cracks appears but can be polished to restore optical transparency, removal and polishing typically undergo every 2–3 years for uncoated windows.[2]
A blended wing body can be considered a mixture of the above. It carries the useful load in a fuselage producing lift. A modern example is Boeing X-48. One of the earliest aircraft using this design approach is Burnelli CBY-3, which fuselage was airfoil shaped to produce lift.
Gallery
Interior rear-end of the main passenger level on an Airbus A340, showing the rear bulkhead as well as a doorway opening
^ abAlex Derber (Nov 28, 2016). "What Passenger Cabin Windows Will Future Airliners Have?". Inside MRO. Aviation Week.
External links
Wikimedia Commons has media related to Aircraft fuselages.
Jörg Fuchte, Björn Nagel, Volker Gollnick (2012). "Automatic Fuselage System Layout using Knowledge Based Design Rules" (PDF). DLR kongress.{{cite web}}: CS1 maint: uses authors parameter (link)
M.N. Roelofs, TU Delft (5 July 2016). Semi-Analytical Composite Oval Fuselage Mass Estimation (Thesis).
March 04, 2023
fuselage, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, june, 2015, learn. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Fuselage news newspapers books scholar JSTOR June 2015 Learn how and when to remove this template message The fuselage ˈ f juː z el ɑː ʒ from the French fusele spindle shaped is an aircraft s main body section It holds crew passengers or cargo In single engine aircraft it will usually contain an engine as well although in some amphibious aircraft the single engine is mounted on a pylon attached to the fuselage which in turn is used as a floating hull The fuselage also serves to position the control and stabilization surfaces in specific relationships to lifting surfaces which is required for aircraft stability and maneuverability Fuselage of a Boeing 737 shown in brown Contents 1 Types of structures 1 1 Truss structure 1 2 Geodesic construction 1 3 Monocoque shell 1 4 Semi monocoque 2 Materials 3 Windows 4 Wing integration 5 Gallery 6 See also 7 References 8 External linksTypes of structures Edit Piper PA 18 welded tube truss fuselage structure Truss structure Edit Main article Truss Some older types of aircraft design utilized open truss structure constructed of wood steel or aluminum tubing 1 3 3 This type of structure is still in use in many lightweight aircraft using welded steel tube trusses A box truss fuselage structure can also be built out of wood often covered with plywood Simple box structures may be rounded by the addition of supported lightweight stringers allowing the fabric covering to form a more aerodynamic shape or one more pleasing to the eye Geodesic construction Edit Main article Geodesic airframe Geodesic airframe fuselage structure is exposed by battle damage Geodesic structural elements were used by Barnes Wallis for British Vickers between the wars and into World War II to form the whole of the fuselage including its aerodynamic shape In this type of construction multiple flat strip stringers are wound about the formers in opposite spiral directions forming a basket like appearance This proved to be light strong and rigid and had the advantage of being made almost entirely of wood A similar construction using aluminum alloy was used in the Vickers Warwick with less material than would be required for other structural types The geodesic structure is also redundant and so can survive localized damage without catastrophic failure A fabric covering over the structure completed the aerodynamic shell see the Vickers Wellington for an example of a large warplane which uses this process The logical evolution of this is the creation of fuselages using molded plywood in which multiple sheets are laid with the grain in differing directions to give the monocoque type below Monocoque shell Edit The Van s Aircraft RV 7 of semi monocoque construction In this method the exterior surface of the fuselage is also the primary structure A typical early form of this see the Lockheed Vega was built using molded plywood where the layers of plywood are formed over a plug or within a mold A later form of this structure uses fiberglass cloth impregnated with polyester or epoxy resin as the skin instead of plywood A simple form of this used in some amateur built aircraft uses rigid expanded foam plastic as the core with a fiberglass covering eliminating the necessity of fabricating molds but requiring more effort in finishing see the Rutan VariEze An example of a larger molded plywood aircraft is the de Havilland Mosquito fighter light bomber of World War II No plywood skin fuselage is truly monocoque since stiffening elements are incorporated into the structure to carry concentrated loads that would otherwise buckle the thin skin The use of molded fiberglass using negative female molds which give a nearly finished product is prevalent in the series production of many modern sailplanes The use of molded composites for fuselage structures is being extended to large passenger aircraft such as the Boeing 787 Dreamliner using pressure molding on female molds Semi monocoque Edit Monocoque and semi monocoque design 1 3 9 Monocoque construction uses stressed skin to support almost all loads much like an aluminum beverage can Semi monocoque construction partial or one half uses a substructure to which the airplane s skin is attached Sectioned fuselage showing frames stringers and skin all made of aluminium This is the preferred method of constructing an all aluminum fuselage First a series of frames in the shape of the fuselage cross sections are held in position on a rigid fixture These frames are then joined with lightweight longitudinal elements called stringers These are in turn covered with a skin of sheet aluminum attached by riveting or by bonding with special adhesives The fixture is then disassembled and removed from the completed fuselage shell which is then fitted out with wiring controls and interior equipment such as seats and luggage bins Most modern large aircraft are built using this technique but use several large sections constructed in this fashion which are then joined with fasteners to form the complete fuselage As the accuracy of the final product is determined largely by the costly fixture this form is suitable for series production where many identical aircraft are to be produced Early examples of this type include the Douglas Aircraft DC 2 and DC 3 civil aircraft and the Boeing B 17 Flying Fortress Most metal light aircraft are constructed using this process Both monocoque and semi monocoque are referred to as stressed skin structures as all or a portion of the external load i e from wings and empennage and from discrete masses such as the engine is taken by the surface covering In addition all the load from internal pressurization is carried as skin tension by the external skin The proportioning of loads between the components is a design choice dictated largely by the dimensions strength and elasticity of the components available for construction and whether or not a design is intended to be self jigging not requiring a complete fixture for alignment Materials Edit Inside view of the wooden fabric covered fuselage of a Fisher FP 202 Early aircraft were constructed of wood frames covered in fabric As monoplanes became popular metal frames improved the strength which eventually led to all metal structure aircraft with metal covering for all its exterior surfaces this was first pioneered in the second half of 1915 Some modern aircraft are constructed with composite materials for major control surfaces wings or the entire fuselage such as the Boeing 787 On the 787 it makes possible higher pressurization levels and larger windows for passenger comfort as well as lower weight to reduce operating costs The Boeing 787 weighs 1 500 lb 680 kg less than if it were an all aluminum assembly citation needed Windows EditCockpit windshields on the Airbus A320 must withstand bird strikes up to 350 kn 650 km h and are made of chemically strengthened glass They are usually composed of three layers or plies of glass or plastic the inner two are 8 mm 0 3 in thick each and are structural while the outer ply about 3 mm thick is a barrier against foreign object damage and abrasion with often a hydrophobic coating It must prevent fogging inside the cabin and de ice from 50 C 58 F This was previously done with thin wires similar to a rear car window but is now accomplished with a transparent nanometers thick coating of indium tin oxide sitting between plies electrically conductive and thus transmitting heat Curved glass improves aerodynamics but sight criteria also needs larger panes A cockpit windshield is composed of 4 6 panels 35 kg 77 lb each on an Airbus A320 In its lifetime an average aircraft goes through three or four windshields and the market is shared evenly between OEM and higher margins aftermarket 2 Cabin windows made from much lighter than glass stretched acrylic glass consists of multiple panes an outer one built to support four times the maximum cabin pressure an inner one for redundancy and a scratch pane near the passenger Acrylic is susceptible to crazing a network of fine cracks appears but can be polished to restore optical transparency removal and polishing typically undergo every 2 3 years for uncoated windows 2 Wing integration Edit Flying wing aircraft such as the Northrop YB 49 Flying Wing and the Northrop B 2 Spirit bomber have no separate fuselage instead what would be the fuselage is a thickened portion of the wing structure Conversely there have been a small number of aircraft designs which have no separate wing but use the fuselage to generate lift Examples include National Aeronautics and Space Administration s experimental lifting body designs and the Vought XF5U 1 Flying Flapjack A blended wing body can be considered a mixture of the above It carries the useful load in a fuselage producing lift A modern example is Boeing X 48 One of the earliest aircraft using this design approach is Burnelli CBY 3 which fuselage was airfoil shaped to produce lift Gallery Edit Interior rear end of the main passenger level on an Airbus A340 showing the rear bulkhead as well as a doorway opening Rough Boeing 747 interior airframe Fuselage of a CubCrafters Carbon Cub The fuselage can be short and seemingly unaerodynamic as in this Christen Eagle Glider fuselage schematicSee also EditAeronautics Airframe Empennage Nose art Aviation accidents and incidentsReferences Edit a b Pilot s Handbook of Aeronautical Knowledge Federal Aviation Administration August 24 2016 Retrieved 16 January 2023 a b Alex Derber Nov 28 2016 What Passenger Cabin Windows Will Future Airliners Have Inside MRO Aviation Week External links Edit Wikimedia Commons has media related to Aircraft fuselages NASA page on fuselage Institute of Aircraft Design and Lightweight Structures IFL Jorg Fuchte Bjorn Nagel Volker Gollnick 2012 Automatic Fuselage System Layout using Knowledge Based Design Rules PDF DLR kongress a href Template Cite web html title Template Cite web cite web a CS1 maint uses authors parameter link M N Roelofs TU Delft 5 July 2016 Semi Analytical Composite Oval Fuselage Mass Estimation Thesis Retrieved from https en wikipedia org w index php title Fuselage amp oldid 1134028416, wikipedia, wiki, book, books, library,
