Wooden construction Early aircraft used spars often carved from solid
spruce or
ash. Several different wooden spar types have been used and experimented with such as spars that are box-section in form; and laminated spars laid up in a
jig, and compression glued to retain the wing
dihedral. Wooden spars are still being used in light aircraft such as the
Robin DR400 and its relatives. A disadvantage of the wooden spar is the deteriorating effect that atmospheric conditions, both dry and wet, and biological threats such as wood-boring insect infestation and
fungal attack can have on the component; consequently regular inspections are often mandated to maintain
airworthiness. Wood wing spars of multipiece construction usually consist of upper and lower members, called
spar caps, and vertical sheet wood members, known as
shear webs or more simply
webs, that span the distance between the spar caps. Even in modern times, "homebuilt replica aircraft" such as the replica Spitfires use laminated wooden spars. These spars are laminated usually from spruce or douglas fir (by clamping and glueing). A number of enthusiasts build "replica" Spitfires that will actually fly using a variety of engines relative to the size of the aircraft.
Metal spars 'D' box
leading edge A typical metal spar in a
general aviation aircraft usually consists of a sheet
aluminium spar web, with L- or T-shaped spar caps being welded or
riveted to the top and bottom of the sheet to prevent buckling under applied loads. Larger aircraft using this method of spar construction may have the spar caps sealed to provide
integral fuel tanks.
Fatigue of metal wing spars has been an identified causal factor in aviation accidents, especially in older aircraft as was the case with
Chalk's Ocean Airways Flight 101.
Tubular metal spars The German
Junkers J.I armoured fuselage ground-attack
sesquiplane of 1917 used a
Hugo Junkers-designed multi-tube network of several tubular wing spars, placed just under the corrugated
duralumin wing covering and with each tubular spar connected to the adjacent one with a space frame of triangulated duralumin strips — usually in the manner of a
Warren truss layout — riveted onto the spars, resulting in a substantial increase in structural strength at a time when most other aircraft designs were built almost completely with wood-structure wings. The Junkers all-metal corrugated-covered wing / multiple tubular wing spar design format was emulated after by American aviation designer
William Stout for his 1920s-era
Ford Trimotor airliner series, and by Russian aerospace designer
Andrei Tupolev for such aircraft as his
Tupolev ANT-2 of 1922, upwards in size to the then-gigantic
Maksim Gorki of 1934. A design aspect of the
Supermarine Spitfire wing that contributed greatly to its success was an innovative spar boom design, made up of five square concentric tubes that fitted into each other. Two of these booms were linked together by an alloy web, creating a lightweight and very strong main spar. A version of this spar construction method is also used in the
BD-5, which was designed and constructed by
Jim Bede in the early 1970s. The spar used in the BD-5 and subsequent BD projects was primarily aluminium tube of approximately in diameter, and joined at the wing root with a much larger internal diameter aluminium tube to provide the wing structural integrity.
Geodesic construction In aircraft such as the
Vickers Wellington, a
geodesic wing spar structure was employed, which had the advantages of being lightweight and able to withstand heavy battle damage with only partial loss of strength.
Composite construction Many modern aircraft use
carbon fibre and
Kevlar in their construction, ranging in size from large
airliners to small
homebuilt aircraft. Of note are the developments made by
Scaled Composites and the German
glider manufacturers
Schempp-Hirth and
Schleicher. These companies initially employed solid
fibreglass spars in their designs but now often use carbon fibre in their high performance gliders such as the
ASG 29. The increase in strength and reduction in weight compared to the earlier fibreglass-sparred aircraft allows a greater quantity of
water ballast to be carried.
Multi-spar construction Aircraft utilizing three or more spars are considered
multi-spar aircraft. Using multiple spars allows for an equivalent overall strength of wing, but with multiple, smaller, spars, which in turn allow for a thinner wing or tail structure (at a cost of increased complexity and difficulty of packaging additional equipment such as fuel tanks, guns,
aileron jacks, etc.). Although multi-spar wings have been used since at least the 1930s (for example, the World War 2-era
Curtiss P-40 had 3 spars per wing), they gained greater popularity when the increasing speed of jet fighters demanded thinner wings to reduce drag at high speeds. The
Mach 2 F-104 Starfighter used numerous slender spars to allow for a wing of unusually thin section; the
F-16 Fighting Falcon uses a similar construction. Other aircraft like the
F-4 Phantom,
F-15 Eagle and others use 3 or more spars to give sufficient strength in a relatively thin wing, and thus qualify as multi-spar aircraft. ==False spars==