GB2190888A - Airfoil sections - Google Patents

Abstract

An airfoil having improved aerodynamic characteristics incorporates a leading edge (13) and a trailing edge (14) longitudinally displaced therefrom. A continuous lower surface (21), defining the lower camber of the airfoil, extends from the leading edge (13) to the trailing edge (14). The upper surface of the airfoil incorporates a first upper surface (22) extending rearwardly from the leading edge (13) and terminating in an offset (20), and at least a second upper surface (23) extending rearwardly therefrom. The first upper surface (22) defines a first upper camber portion of the airfoil and the second upper surface (23) defines a second upper camber portion thereof. In Figure 6 the second upper surface (123) meets a third upper surface (140) at a discontinuity in the profile. The airfoil may be used for a wing, a propeller, or a hydrofoil blade. <IMAGE>

Description

SPECIFICATION Airfoil Technical field The present invention relates generally to an airfoil having improved aerodynamic characteristics.

Particularly the present invention relates to an airfoil having improved lift coefficients at operational angles of attack. More particularly, the invention relates to an airfoil having improved liftto drag ratios at operational angles of attack.

Furthermore, the present invention relates to an airfoil capable of operating at greater angles of attack without experiencing stalling conditions.

Background art The aerodynamic principles of airfoils have been the subject of continuing study sincethe mid-l 800's.

Scientists, engineers and experimentalists have continually sought to understand and improve on the aerodynamic characteristics of the airfoil. Much ofthis development has been spurred by the growing interest in flying and the desire to build a safer aircraft.

The primary concern with any airfoil design is two-fold: first, to produce a greateramountoflift without detrimentally increasing drag and, second, to enablethe airfoil to function atgreater angles of attack without stalling. Coupling these desired parameters with the wide range of airspeeds to which the airfoil may be exposed results in a multitude of airfoil designs, each with its own aerodynamic characteristics to perform optimally at a specific flight condition. With respect to the wing of an airplane, for example, a design suitable for producing substantial lift at low airspeeds inherently produces excessive drag at high airspeeds.On the other hand, a wing designed to fly with minimal drag at high airspeeds generally failsto produce sufficient liftatlowairspeedsto maintain flight, as during takeoffs and landings. This latter condition results in a stalling ofthe wing as the angle of attack ofthe wing is increased, in an effort to produce greater lift, until the critical angle of attack is exceeded. It is recognized, of course,thatan airfoil will stall atany airspeed whenever the angle of attack ofthe airfoil to the free stream airflow exceeds the critical angle of attackforthe particular airfoil.

In an effort two improve the overall aerodynamic characteristics of the airplane wing throughout a wide variety offlight conditions, designers have turned to movable slots and/orflaps on the leading and trailing edges of the wing which change the cross-sectional profile of the wing. These slots and/orflaps may be adjusted during flight four optimum performance of the wing at various flight conditions. For example, at high airspeeds, the slots and/or flaps are fu lly retracted to give the wing a relatively thin, streamlined profile thereby reducing the drag acting thereon. At lower airspeeds, however, the slots and/or flaps are extended downward to produce a greater camber on the wing which permits the wing to develop greater lift, albeit with greater drag.Such use of slots and/orflaps, therefore, increase the aircraft's operational angles of attack, i.Q,the angles of attackthrough which the aircraft can safely operate. However, because of the increase in drag, the extension of slots and/orflaps is only advisable at relatively low airspeeds and, thus, they are unableto improvethe lift and stall characteristics ofthe wing at high, cruising airspeeds.

Efforts have been made to design an airfoil having improved stall characteristics at high airspeeds. One ofthe most interesting designs is an airfoil having a substantiallywedge-shaped profile with a step-like discontinuity on the under surface thereof. While this design exhibits improved stall characteristics, tests have shown that such is accomplished at the expense of lift and with substantial reductions in the liftto drag ratio ofthe airfoil.

Despite the extensive work conducted in this field, no airfoil, as yet, has been developed which provides improved stall characteristics at virtually all operational airspeeds while simultaneously providing improved lift and lifttodrag ratios.

Disclosure ofthe invention It is, therefore, a primary object ofthe present invention to provide an airfoil having improved stall characteristics at virtually all operational airspeeds.

It is another object of the present invention to provide an airfoil having functional lift coefficients over a broader range of operational angles of attack.

It is a further object ofthe present invention to provide an airfoil having functional lift to drag ratios over a broad range of operational angles of attack.

It is yet another object of the present invention to provide an airfoil suitable for use with aircraft of the fixed-wing type and, also, of the rotary wing type.

These and other objects of the invention, as well as the advantages thereof over existing and prior art forms,whichwill be apparent in viewofthe following specification, are accomplished by means hereinafter described and claimed.

In general, an airfoil according to the concept of the present invention includes a leading edge and a trailing edge located longitudinally rearward thereof. A continuous lowersurfaceextendsfrom the leading edgetothetrailing edgeand definesa lower camber. Afirst upper surface extends rearwardlyfrom the leading edge and terminates in anoffset,forwardlyofthetrailing edge. Thefirst upper surface defines a first upper camber portion.

At least a second upper surface extends rearwardly fromtheoffsetanddefinesasecond uppercamber portion.

One preferred, and one alternative, embodiment of an airfoil incorporating the concept of the present invention are shown by way of example in the accompanying drawings without attempting to show all the various forms and modifications in which the invention might be embodied, the invention being measured by the appended claims and not by the details ofthe specification.

Briefdescription ofthe drawings Figure lisa partial perspective view of an airfoil embodying the concept of the present invention, shown in relation to the fuselage of a fixed-wing aircraft; Figure2 is a cross-section ofthe airfoil taken along line 2-2 of Figure 1; Figure 3 is a cross-section of an airfoil embodying the prior art; Figures4A through 4C, inclusive, are lift coefficient curves of the airfoil of Figure 1 depicted in comparison to corresponding curves for the prior art airfoil of Figure 3 taken at various free stream velocities; Figures5A through 5C, inclusive, are liftto drag ratio curves of the airfoil of Figure 1 depicted in comparison to corresponding curves for the prior art airfoil of Figure 3 taken at various free stream velocities;; Figure 6, located on sheet 1, is a cross-section of an alternative embodiment for an airfoil embodying the conceptofthe present invention; Figures 7A through 7C, inclusive, are lift coefficient curves ofthe airfoil of Figure 6 depicted in comparison to corresponding curves for the prior art airfoil of Figure 3,taken at various free stream velocities; and Figures 8A through 8C, inclusive, are lift to drag ratio curves ofthe airfoil of Figure 6 depicted in comparison to corresponding curves forthe prior art airfoil of Figure 3,taken at various free stream velocities.

Exemplary embodiment ofthe invention An airfoil according to the concept of the present invention is indicated generally by the numeral 10 in Figure 1,particularlyasawing memberofa fixed-wing aircraft. As a wing member, the airfoil generally includes a root section 11, by which it is secured to the fuselage 17 of the aircraft, and a wing tip 12 laterally distal ofthe root section 11. A leading edge 13and a longitudinally displaced trailing edge l4extend betweentherootsection 11 andthewing tip 12, and, together therewith, define the planform of the airfoil 10. Control surfaces, such as an aileron 15 and flap 16may, likewise, be incorporated in the airfoil 10.

A lateraliy extending offset 20 is carried by the upper surface of the airfoil 10. While the offset 20 is shown as extending fully from the root section 11 to the tip 12, it should be appreciated that such is not a requirement. Thefundamental principle ofthe subject invention should be understood to include a lateral offset extending over an appreciable amount of the upper surface of the airfoil 10. Forexample, severai segmented lateral offsets may be positioned laterally along the upper surface of airfoil 10.

Furthermore, particularly on high-wing aircraft, the lateral offset may extend continuously across the top of the fuselage region. Likewise, although offset 20 is shown to be positioned longitudinally proximate the mid-point of the chord length of the airfoil 10, this is but an exemplary position as will be discussed more fully below.

The profile of airfoil 10 with offset 20 is shown in more detail in Figure 2. Specifically, airfoil 10 includes a lowersurface 21 extending from leading edge 13 to trailing edge 14. While it is preferred that lower surface 21 defines a negative camber, as shown, other configurations, including a flat planar surface and a positive camber surface, are likewise contemplated.

The upper surface, in toto, of airfoil 10is defined by a first upper surface 22 which extends from leading edge 13 rearwardlyto offset 20; and, a second upper surface 23 continuing rearwardly from offset 20 to trailing edge 14. The rearward end of first upper surface 22 is elevationally displaced from the forward end of second upper surface 23 as a result of offset 20.

First upper surface 22 generally defines a positive camber as normally found on existing airfoils. As is appreciated by one skilled in the art of aerodynamics, when the free stream flow encounters an airfoil, part of the flow passes above the airfoil alongtheuppersurfacewhilepartofthe flow passes below the airfoil along the lower surface.

The two flow paths act upon the airfoil to generate the desired lift. Particularly, the flow, above the airfoil moves at higher velocity than the flow below the airfoil due to the positive camber of the upper surface; and,assuch,causesanareaofpressureto exist along the upper surface which is less than the area of pressure along the lower surface.

The difference in pressure is the principle behind the generation of lift by the airfoil. The magnitude of the lift, therefore, is dependent upon the velocity of the free stream, relative to the airfoil, and the amount of positive camber of the upper surface of the airfoil, as well as other related factors such as the free stream flow striking the lower surface of the airfoil.

As such, while the amount of positive camber offirst upper surface 22may be relatively small for an airfoil suitable for operating at high velocity free streams, a positive camber, nonetheless, is preferred.

The second upper surface 23, on the other hand, may define otherthan a positive camber. Indeed, Figure 2 shows second upper surface 23 as being a substantially continuous planar, rearwardly inclined surface substantially impermeable to airflow. Other configurations, such as a negative camber or a forwardly inclined surface, are likewise contemplated within this disclosure to effect desired flight characteristics by the airfoil 10in specific free stream conditions. The common factor in each configuration is that second upper surface 23 is a substantially continuous, impermeable member.

Offset 20 is shown in Figure 2 as being a substantially continuous impermeable vertical surface 24 which, with first upper surface 22, defines an abrupt aerodynamic structural change on the uppersurfaceofairfoil 10. Aswould be appreciated by one skilled in fluid mechanics, such an abrupt aerodynamic structural change is achieved as a result of the pronounced elevational difference between first upper surface 22 and second upper surface 23. This being the case, the configuration of offset 20 can vary considerably yet accomplish the desired result, i.e., define an abrupt aerodynamic structural change in the upper surface ofthe airfoil 10.

The advantages of the disclosed airfoil 10 may be more fully appreciated by considering performance curves thereof. In particular, comparison is made between the disclosed airfoil 10 and a pre-existing airfoil 30, as shown in Figure 3.

The exemplary pre-existing airfoil 30 has been classified by the National Advisory Committee for Aeronautics (NACA), the predecessor to the National Aeronautical and Space Administration (NASA), as series 23012. So as to provide a true comparison, the disclosed airfoil 1 tested was dimensionally equivalentthereto. The offset 20 was located at 50 percent of the chord length, with an elevational difference of 25 percent of the thickness ofthe airfoil 10 at that location. Second upper surface 23 was substantiallyplanarandextendedtotrailingedgel4.

Figures 4A, 4B and 4C compare the lift coefficient (C) at various angles of attack (a) at free stream velocities of 100 feet per second (f.p.s.) (31 meters per second (m .p.s.)),150 f.p.s. (46 m.p.s.) and 200 f.p.s. (61 m.p.s.), respectively. In each case, the NACA 23012 airfoil 30 achieved a maximum lift coefficient between approximately 14 to 19 angle of attack, as shown by curve I. Moreover, a sudden substantial loss of lift was experienced after achieving maximum lift. This sudden loss of lift indicated that the NACA 23012 airfoil 30 was stalling.

The disclosed airfoil 10 attained equivalent or greater maximum lift coefficients and was ableto do so at largerangles of attack, approximately 25"to 30", asshown bycurvell in Figures4A,4Band4C.

Furthermore, upon attaining maximum lift, airfoil 10 did not experience stall but rather continued generating substantial lift at even greater angles of attack, and only gradually reduced liftasthe angle of attack increased. In addition, at lower, operational angles of attack, less than 12", airfoil 10 generated substantially greater lift than did NACA 23012 airfoil 30.

Figures 5A, 5B and 5C show a comparison ofthe liftto drag ratios (L/D)forvarious angles of attack at airspeeds of 100 f.p.s. (31 m.p.s.), 150 f.p.s. (46 m.p.s.) and 200 f.p.s. (61 m.p.s.), respectively. Again, curve I indicates the performance of NACA 23012 airfoil 30 and curve II indicates the performance of disclosed airfoil 10. It should be recognized that at operational angles of attack less than approximately 12' the lift to drag ratio of the disclosed airfoil 10 exceeded that of NACA 23012 airfoil 30. And, while NACA 23012 airfoil 30 experienced a greater maximum liftto drag ratio this occurred effectively at the critical angle of attack immediately preceding the stall.In all practicality, such maximum liftto drag ratios for NACA23012 airfoil 30 will not be utilized because ofthe inevitable stalling. As such, for operational angles of attack, less than 12 , the liftto drag ratios of the disclosed airfoil 10 are superior to those of the comparable NACA 23012 airfoil 30. In addition, airfoil 10 produced acceptable liftto drag ratios well beyond the point where NACA 23012 airfoil 30 stalled, thereby indicating that airfoil 10 was still functioning.

It should be evident from the foregoing that an airfoil ofthe preferred embodiment possesses unexpectedly improved aerodynamic characteristics as compared to a similar, pre-existing airfoil.

Particularly, the disclosed airfoil 10 generates greaterliftwith improved liftto drag ratios.

Furthermore, the disclosed airfoil 10 is capable of operating atgreaterangles of attackwithout experiencing stall conditions.

Improved aerodynamic characteristics are likewise associated with the alternative embodiment airfoil 110, depicted in Figure 6. Theonlysignificant difference between airfoil 10 and airfoil 110 is represented bythesecond upper surface 123. Rather than extending rearwardlytotrailing edge 114, as in the case of airfoil 10, second upper surface 1 23 breachesthe uppersurface of airfoil 1 lOforwardlyof trailing edge 114.third upper surface 140 continues rearwardly of second upper surface 123 to trailing edge 114. Third upper surface 140 may represent a continuation of the first upper surface 122 as would exist if a prior art airfoil 30 is modified to embody the present invention.

While it is preferred that third upper surface 140 define a camber equivalentto the camber of priorart airfoil 30 in the same region, such is not a neccesity and a variety ofplanarorcambered surfaces may be suitable. It is desired, however, that the thickness of airfoil 110 between third upper surface 140 and lower surface 121 be greaterthan that of airfoil 10 in the same region. Such increased thickness provides greater interior space within airfoil 1 for locating and routing control devices and linkages for operating control surfaces such as flaps and ailerons. Such thickness, of course, will depend on the structural integrity of the airfoil as well as the design of the control devices.

It should be appreciated that the aerodynamic characteristics of airfoil 110 are improved over pre-existing ai rfoils as a resu It of offset 120, similar to the effect of offset 20 in airfoil 1 Q. Primarily, offset 120 constitutes an aerodynamic discontinuity in the uppersurface of airfoil 110 in the same manners offset 20 in airfoil 10. Thus, because ofthese similarities, the discussion, hereabove, pertaining to the physical structure of offset 20 are likewise pertinent to the physical structure of offset 120.

The improved aerodynamic characteristics of airfoil 110 may be more fully appreciated by, again, considering performance data thereof in comparison with a dimensionally equivalent pre-existing airfoil. Again, NACA 23012 airfoil 30 was chosen as the airfoil configuration for such comparative testing. Offset 120 in airfoil 110 was located at 50 percent ofthe chord length, with an elevational difference of 33 percent of the thickness ofthe airfoil 110 atthat location. Second upper surface 123 was substantially planar and breached the upper surface of airfoil 110 at approximately 70 percent ofthe chord length rearwardlyfrom the leading edge 113. Third upper surface 140 had a profile equivalentto NACA 23012 airfoil 30 through the same region.

Figures 7A, 7B and 7C compare the lift coefficient (CL) at various angles of attack (a) a free stream velocities of 100 f.p.s. (31 m.p.s.), 150 f.p.s. (46 m.p.s.) and 200 f.p.s. (61 m.p.s.), respectively. The performance of NACA 23012 airfoil 30 is represented bysurve 1', and thatofairfoil 110 byourve 11'.

It should be recognized that airfoil 110 consistently was able to perform at greater angles of attackthan NACA23012 airfoil 30. However, itshould also be recognized that airfoil 110 does stall, at least atfree stream velocities of 100 f.p.s. (31 m.p.s.) and 150 f.p.s. (46 m.p.s.), Figures 7A and 7B, respectively, as indicated bythe sudden drop in the lift coefficient subsequent to attaining a maximum value. Also, a slight loss of lift for airfoil 110 was experienced at lower, operational angles of attack.

Figures 8A, 8B and 8C show a comparison ofthe liftto drag ratios (UD) forvarious angles of attack (a) at airspeeds of 100 f.p.s. (31 m.p.s.), 150 f.p.s. (46 m.p.s.) and 200 f.p.s. (61 m.p.s.), respectively. Again, curve I' represents the performance of NACA 23012 airfoil 30 and curve II' represents the performance of airfoil 110. It should be recognized that although a lower liftto drag ratio is attributableto airfoil 110 at lower, operational angles of attack, this being a result ofthe lower lift coefficients at these angles, airfoil 110 continued to provide usable flight characteristics well beyond the stall angle of NACA 23012 airfoil 30. In short, airfoil 110 continued to fly at angles of attack well after NACA 23012 airfoil 30 had stopped flying and stalled.

An overview of the foregoing performance characteristics of airfoil 110 demonstrates its inferiority to airfoil 10, though an improvement in many respects over NACA 23012 airfoil 30. Such performance of airfoil 110 may be attributable to the fact that its cross-sectional configuration is more similarto that of NACA 23012 airfoil 30 and, as such, would be more susceptible to the inherent problems thereof, i.e., stalling and reduced lift. Furthermore, airfoil 10 may, indeed, be approaching an optimum configuration of an airfoil embodying the concept of the present invention and, as such, should exhibit superior performance curves.

These tests results indicate exemplary embodiments of the disclosed airfoil and, the performance characteristics attributable thereto.

They are not, however, limiting factors in the instant disclosure. Indeed, it has been determined that unexpectedly improved aerodynamic performance is attainable when the offset is located within a range of 40 to 60 percent ofthe chord length from the leading edge ofthe airfoil, and with an elevational difference within the range of 10 to 60 percent ofthe thickness ofthe airfoil at the location ofthe offset.

Therefore, the appreciable improvement in aerodynamic performance of an airfoil embodying the concept ofthe present invention is expected for a wide variety of offset locations and configurations.

It should further be noted that the location, size and configuration of the offset may find limiting parameters solely in the structural integrity of the airfoil. That is, sufficient body ofthe airfoil will be required so as to maintain the necessary mechanical strength thereof, irrespective of the offset. In this regard, a plurality of distinct offsets may be disposed laterally along the airfoil or the internal rib structure ofthe airfoil may not carry the offset but rather protrude into the offset and section it into aerodynamically distinct segments. Likewise, it may bedesirabletoemploya plurality of longitudinally displaced offset along the upper surface of the airfoil.

Furthermore, the depth of the offset may vary along the span of the airfoil, such as being tapered from root to tip thereof. These modifications, of course, while contributing to the structural integrity of the airfoil, also are contributing factors in the aerodynamic performance thereof. Indeed,the boundary layer characteristics of the flow stream at any point along the airfoil will govern the configuration and location of the offset at that particular point.

The foregoing discussion demonstrates that, contrary to expectations developed by the prior art and theory of aerodynamics, an aerodynamic discontinuity generated by an offset in the upper surface of an airfoil results in substantial improvements in the aerodynamic characteristics thereof. Such improvements are directly attributable to the offset, itself, and the effect it has on the flow stream abouttheairfoil.Assuch,itwould be conjectured that the exact location and configuration ofthe offset may bevaried along the upper surface of the airfoil while still favorably affecting the aerodynamic characteristics ofthe airfoil.It would be expected, however, that for a specific flow condition and boundary layer characteristics, a specific range of locations and configurations for the offset will produce optimum performance of the airfoil.

Furthermore, while the foregoing discussion has been directed primarily to an airfoil, such is but an exemplary model of the disclosure. It should be understood that other lifting bodies such as, for example, hydrofoils, sails, and vanes, are likewise contemplated within the scope of the invention as disclosed. In addition, the disclosed airfoil would also prove advantageous in use on rotor blades of rotary-wing aircrafts and propellers offixed-wing aircrafts as well as on a winglet in conjunction with, or independent of, other airfoils on the aircraft. In short, virtually any body which interacts with a free stream flow will experience improvements in its performance characteristics upon incorporation of the disclosed invention therein.

Thus it should be evidentthatan airfoil embodying the concept of the invention disclosed herein carries outthevarious objects ofthe invention and otherwise constitutes an advantageous contribution totheart.

Claims (26)

1. A lifting body comprising: a leading edge; atrailing edge located longitudinally rearward of said leading edge; a continuous lower surface extending from said leading edge to said trailing edge, said lower surface defining a lower camber; a first upper surface extending rearwardlyfrom said leading edge and terminating in at least one offset forwardly of said trailing edge, said first upper surface defining a positive upper camber portion; and at least a second upper surface extending rearwardlyfrom a said offset, said second upper surface defining a negative upper camber portion.

2. Alifting body according to claim 1, in which said second upper surface has a forward end elevationally displaced from said first upper surface.

3. A lifting body according to claim 2, in which said offset is a substantially vertical surface extending from said first upper surface to said second upper surface.

4. Alifting body according to claim 1, in which said second upper surface extends rearwardlyto said trailing edge.

5. Alifting bodyaccording to claim 1,further comprising: a third upper surface extending rearwardlyfrom said second upper surface to said trailing edge, said third uppersurfacedefining a third camber portion.

6. A lifting body according to claim 5, in which said third upper surface defines a positive camber.

7. An airfoil comprising: a leading edge; a trailing edge located longitudinally rearward of said leading edge; a continuous lower surface extending from said leading edge to said trailing edge, said lowersurface defining a lower camber; a first upper surface extending rearwardlyfrom said leading edge, said first upper surface defining a first upper camber portion; a second upper surface extending rearwardly of said first uppersurface, said second upper surface being a substantially continuous impermeable member defining a second upper camber portion;; at least a third upper surface intersecting said second upper surface and extending rearwardly therefrom, said third upper surface defining a third upper camber portion, said intersection representing an abrupt, significant change in the disposition of each said second and said third upper surfaces so as to define a visible demarcation therebetween; and, means for producing an aerodynamic discontinuity, said means for producing being a substantially continuous impermeable member interposed between said first upper surface and said second upper surface.

8. An airfoil according to claim 7, in which said means for producing is an offset.

9. An airfoil according to claim 8, in which said second uppersurfacehasaforwardend elevationally displaced from said first upper surface.

10. An airfoil according to claim 9, in which said offset is a substantially vertical surface extending from said first upper surface to said second upper surface.

11. An airfoil according to claim 7, in which said third upper surface represents a continuation of said firstuppersurface.

12. An airfoil according to claim 7, in which said second upper surface is substantially planar.

13. An airfoil according to claim 7, in which said first upper surface defines a positive camber.

14. An airfoil according to claim 7, in which said third upper surface defines a positive camber.

15. Alifting body comprising: a leading edge; atrailing edge located longitudinally rearward of said leading edge; a continuous lower surface extending from said leading edge to said trailing edge, said lower surface defining a lower camber; a first upper surface extending rearwardlyfrom said leading edge and terminating in at least one offset forwardly of said trailing edge, said first upper surface defining a first upper camber portion; a second upper surface extending rearwardlyfrom a said offset, said second upper surface defining a second upper camber portion; and, at least a third upper surface intersecting said second uppersurfaceand extending rearwardly therefrom, said third upper surface defining a third upper camber portion, said intersection representing an abrupt, significant change in the disposition of each said second and third upper surfaces so as to define a visible demarcation therebetween; said offset and said second upper surface each being substantially continuous impermeable members.

16. A lifting body according to claim 15, in which said second upper surface has a forward end elevationally displaced below said first upper surface at said offset.

17. A lifting body according to claim 16, in which said third upper surface represents a continuation of said first upper surface.

18. A lifting body according to claim 17, in which said offset is a substantially vertical surface extending from said first uppersurfaceto said second upper surface.

19. A lifting body according to claim 18, in which said second upper surface is substantially planar.

20. A lifting body according to claim 18,inwhich said second upper surface defines a negative camber.

21. Alifting body comprising: a leading edge; a trailing edge located longitudinally rearward of said leading edge; a continuous lower surface extending from said leading edge to said trailing edge, said lower surface defining a lower camber; a first upper surface extending from said leading edge to said trailing edge, said first upper surface defining an upper camber; at least one substantially continuous impermeable offset carried by said first upper surface forwardly of said trailing edge; and, a substantially continuous impermeable second upper surface extending rearwardlyfrom said offset toward said first upper surface and intersecting said first upper surface forwardly of said trailing edge; wherein said intersection represents an abrupt, significant change in the disposition of said second upper surface relative to said first upper surface so as to define a visible demarcation therebetween.

22. A lifting body according to claim 21, in which said second upper surface has a forward end elevationaily displaced below said upper surface at said offset.

23. A lifting body according to claim 22, in which said offset is a substantially vertical surface extending from said first upper surface to said second upper surface.

24. A lifting body according to claim 23, in which said second upper surface is substantially planar.

25. A lifting body according to claim 23, in which said second upper surface defines a negative camber.

26. Either ofthe airfoils substantially as herein described with reference to Figures 1,2, 4A, 4B, 4C, 5A,5B,5C,orFigures6,7A,7B,7C,8A,8B,8C,ofthe accompanying drawings.