TECHNICAL NOTE 4006 INVESTIGATION AT TRANSONIC SPEEDS OF DEFLECTORS AND SPOILERS AS GUST ALLEVMTORS ON A 35 SWEPT WING TRANSOIWC -BUMP

TECHNICAL NOTE 4006 INVESTIGATION AT TRANSONIC SPEEDS OF DEFLECTORS AND SPOILERS AS GUST ALLEVMTORS ON A 35 SWEPT WING TRANSOIWC -BUMP METHOD By Delwh R Croorn md Jarrett K Huffman Langley Aeronautical Laboratory Langley Field, Va Washington June 1957 AFM;c

TECH LIBRARY KAFB, NM z NATIONAL ADVISORYcowm TECBNICAL NO ZE4006 INVESTIGATION AT TRANSONIC SPEEDS OF DEEZECTORS MO SPOILERS AS GUST ALLEVIATORS OI?A 35 SWEF I WDK+ TRJNSONIC-BUMP METHOD By Deltin R Croom and Jarrett K IIuffman SUMMAKY An investigation was made in the Langley high-speed 7- by 10-foot tunnel by means of the transonic-bump method to determine the gustalleviation capabilities of spoilers and deflectors when mounted on a 35 swept semispan wing having NACA 65AO06airfoil sections The Mach ntier range was frcm OkO to 115, and the angle-of-attack range was from -8 to or beyond the stall The gust-alleviation capabilities (as indicated by the reduction in lift-curve slope) were almost constant (approx~tely a 20-percent reduction in lift-curve slope) throughout the Mach number range from O~ to 115 for both the deflector and the spoiler-deflector c-ination Increased drag resulted &cm the deflection of these controls and indicated that they would also be effective as aerodynamic brakes during slowdown to rough-air speed At low mibsonic speeds the wing with the deflector or the spoilerdeflector control caused no marked effect on the stability of the modelj however, at high stisonic speeds (Mach number above about 08) the controls caused a decrease in stability and a pitch-up was noted at an angle of attack of about 6 where the lift curve became nonlinear At supersonic speeds the wings with the controls were less stable than the plain w~j =dboth WhgS exhibited pitch-up, as did the plain wing, at an angle of attack of about 12 where the lift curve became nonlinear INTRODUCTION A previous investigation has shown that spoilers and deflectors when mounted well forward on an unswept-wimg airplane model would reduce the nomal acceleration due to gusts (See ref 1) As has been pointed out in reference 1, the reduction in normal acceleration is directly proportional to the reduction in lift-curve slope The investigation at low

2 NACA TN 4006 speeds of spoilers anddeflectors as gust alleviators was extended to include a wing having 35 of sweep and also a l/&scale model of the Bell X-5 airplsae having 35 swept wings and is reported in reference 2 From that investigation it was found that, in order for a deflector to have the same effectiveness on a sweptback wing as on an unswept wing, the control would have to be located in a more rearward position and would possibly require a larger projection Results obtained from reference 2 indicate that a deflector extending frcm the ~1-percent- to the 5$&percent-semispa station along the kl-percent-chord Hne (which corresponds to the 38-percent-chord line as defined in ref 2) when projected 15 percent of the chord would give *out 20-percent reduction in lift-curve slope * The purpose of the present investigation is to determine the liftcurve-slope reduction capabilities of a deflector control and a spoilerdeflector control on a 35 swept semispan wing at high subsonic andt?xmsonic speeds SYMBors AND comic!ients The forces and moments measured on the model are presented with respect to an orthogonal system of axes The longitudinal axis is parallel to the free airstrean, and the lateral axis is in the wing chord plane The origin of the sxes is at the intersection of the root chord and a line that is perpendicular to the root chord and passes through the quarter-chord point of the mean aerodym?mlc chord b b twice wing span of semispan model, 10 f% c E wing chord, ft mean aerodynamic chord of wing, 0255 ft Cav average wing chord, f% drag coefficient, lift coefficient, Twice semis~an draq qs Twice semispan lift qs CL lift-curve slope cm pitching-moment coefficient, Twice semispan PittM moment qse c

NACA TN 4006 incremental pit thing-mornentcoefficient M ~ R Mach nuder + -C pressure, >, lb/sq ft c Reynolds nwiber, based on 5 s twice wing area of semisp= model, 0250 sq ft b v a P free-stream air velocity, ft/sec angle of attack, deg lilassdensity Of air, slugs/cu ft MODEL AND APPARATUS The steel semispan wing model had an angle of sweep of 35 at the quarter-chord line, = aspect ratio 4, a taper ratio of 06, and an NACA 65AO06 airfoil section parallel to the free airstream A drawing of the wing with pertinent dimensions and data is shown in figure 1 The wing was equipped with a deflector and a spoiler-deflector conibination The projection of the deflector was 15 percent of the average local chord and extended from 041b/2 to 059b/2 along the 407-percent-chord line The projection of the spoiler was 25 percent of the average local chord, was of the same span as %he deflector, and extended along the 357-percent-chord-line on the upper surface The model was mounted on an electrical strain-gage balance enclosed within the bump, and the longitudinal aerodynamic forces and moments were recorded by means of calibrated recording potentiometers The model butt passed through a hole in the turntable in the bump surface Leakage through this hole was kept to a minimumby the use of a sponge seal fastened to the under surface of the bump turntable TESTS AND CORRECTIONS The model was tested in the flow field of a bump mounted on the floor of the Iangley high-speed 7- by 10-foot tunnel The Mach numibe~ range was from 040 to 115 and the angle-of-attack range was from -8 to or beyond the stall There is a small Mach nuzibervariation over the - -

4 NU2A!i?N4006 wing for a given test Mach number, and charts showing the Mach nuiber gradient over the bump with the model removed are given in reference 3 The variation with Mach number of mean test Reynolds number based on the me- aeroec chord is given in figure 2 h No corrections to the data have been applied The usual wind-tunnel blockage and jet-boundary corrections are considered negligible because of the small size of the model compared with the size of the tunnel test section RESULTS AND DISCUSS1ON The lift, drag, and pitching-moment coefficients exe presented as functions of angle of attack in figure 3 for the plain-wing) deflector, and spoiler-deflector configurations for Mach numbers from ObO to 115 A sumary plot of the lift-curve slope C% (measured at CL= 03~, the ~le of attack at CL = 03, and the incremental change in pitchingmment coefficient from a = 4 to a=8 is presented as a function of Mach nwtiberin figuxe 4 The wing with the deflector or the spoiler-deflector control reduced the lift-curve slope about 20 percent (measured at CL= 03 which approx- ~ imates the average slope between CL = O and the nonlinesr portion of the lif% curve which occurs between an angle of attack of 60 and 12 ) This reduction agrees very well with the lif%-curve-slope reduction obtained in the low-speed tests reported in reference 2 bamnuch as this type of control is effective in reducing the lift-curve slope on a swept-wing model throughout the Mach nuniberrange, it should be effective as a gust alleviator throughout the speed range It shouldbe noted, however, that the wing with the controls exhibited greater nonlinearities in aerodynamic characteristics between an angle of attack of 6 and 12 than did the plain wing configuration (See fig 3) The attitude change, a change in angle of attack for a given lift coefficient over the linear portion of the lift curve, was very small because of the addition of the controls ( At CL = 03 the maximum change was only 20) Some scatter was noted in the drag data at the lower Mach nunibers (See fig 3) However, the drag of the wing was increased by the addition of the deflector or spoiler-deflector controls; thus, this increase in drag indicates that the controls would also be effective as aerodynamic brakes during slowdown to rough-air speed

NACA TN 4006 5 At low subsonic speeds the deflector or the spoiler-deflector control had no marked effect on the longitudinal stabili~ of the model; however, at high subsonic speeds the controls caused a decrease in stability and a pitch-up was noted at an angle of attack of about 6 where the lift curves became nonlinear At supersonic speeds the wings with the control configurations were less stable than the plain wing; and both wings exhibited pitch-up, as did the plain wing, at an angle of attack of about 12 where the lift curve became nonlinear (See fig 3) The change in pitching-mnnent coefficient from a = 4 to a = 8, as shown in figure 4> in~cates that at -rate Iifi coefficients (CL - ()3 to CL* 06) the destab~zi~ effects due *O controls wouldbe largest at a Mach nunber of about 095 CONCLUDING REMAIVG # The gust-alleviation capabilities, as indicatedby the reduction in lift-curve slope, were almost constant (apprmhately a 20-percent reduction in lift-curve slope) throughout the Mach nuuiberrange from OkO to 115 for both the deflector and the spoiler-deflector combination Increased drag resulted from the deflection of these Controls and indicated that they would also be effective as aerodynamic brakes during slowdown to rough-air speed At low subsonic speeds the wing with the deflector or the spoilerdeflector control caused no marked effect on the stability of the model; however, at high subsonic speeds (Mach nunber above about 08) the controls caused a decrease in stability and a pitch-up was noted at an @e of attack of about @ where the lift curve bemxne nonlinear At su~ersonic speeds the wings with the controls were less stable than the plain -j and both wings exhibited pitch-up, as did the plain wing, at an angle of attack of about 12 where the lift curve became nonlinear Iangley Aeronautical Laboratory, National Advisory Ccmmittee for Aeronautics, Langley Field, Va, March 2 7,1957

NACA TN 4006 REFERENCES 1 Croom, Delwin R, Shufflebarger, C C, and Huffban, Jarrett K: An Investigation of Forward-located Fixed Spoilers and Deflectors as Gust Alleviators on an Unswept-Wing Model NACATN 37o5, 1956 0 8 2 Croom, DelWin R, and Huffman, Jarrett K: Investigation at M Speeds of Deflectors and Spoilers as Gust Alleviators on a Model of the Bell X-5 Airplane With 35 Swept Wings and on a High-Aspect-Ratio 35 SwePt-Wing-Fusekge Model NACATN 4007, 1957 3 Croom, DelWin R, and Wiley, Harleth G: Investigation at Transonic Speeds of the HingeWcment andlift-effectiveness Characteristics of a Single Flap and a Tandem Flap on a 60 Delta Wing NACA RML53E28a, 1953

General Dimensions Airfoil section NACA 65AO06 Sweepbock of the quorter-chard Ilne,deg 35 Semispon, in 600 Root chord, in 375 Tip chord, in 2Z5 Aspect ratio 4 Taper ratio 06 v / \\s\\\\~\~\~p\ 0357 chod tins chord MW Balance centu Iltw 1--1 I I Section A-A a LC--P- : Ptain-wing configurotkm Oeflector wnf@railon Spof4r-def&ctor confl~rutkm Figmx l- sktch Of mo&l BhOwing d&kct~ and spoiler-defleetor details

/!/x 9 1? 8 7 6 M Figure 2- Variation of mean test Reynolds mmiber with Mach nuniber

z NACATN 4006 x 4 2 0 Plain-wing con figura fion I= Deflector con figuruf ion o SDoi/er- deflector con fiuurof ion / cm o / 2 4 3 2 / /D o 8 6 $ 2 2 0-4 -6 -/2%-404 8/216202428 a,@ (a) M = 040 Figure 3- Aerodynamic characteristics in pitch of plain-wing, deflector, and spoiler-cleflector configurateions

10 o P/o/n-wing configuration a Deflector con figuro t ion o SDO i/er- def/ec t or con fiaurat ion cm 5 4,/ o -12-8-4048 12 16 20 24 28 aldeg (b) M = 060 Figure 3- Continued

NACA TN 4006 u 1 b O Pluin w ing con figurufion ~ De f/ector configuration o Spoiler det!ec tor configuration cm 5 4 3 2 c :/2-8 -4 0 4 8 /2 /6 20 24 28 Q, deg (C) M = 08 Figure 3- Continued

u NACA TN 4006 L o Plain-wing configuration D Deflector configuration o Spoiler-deflector configuration cm 5 4,3 CD 2 J o (d) M = 085 Figure 3- contji~edo

NACATN40U5 13 0 Plain-wing configuration Q De f/ector con figuro tion o Spoiler- def/ecfor con fiaumfion cm / o -/2-8 4 0 4 8 /2 /6 20 24 2t Q, deg 3 (e) M = OgO Figure 3- Continued

14 NACATN 4006 o plai~wi~g con figuratbn Def Iec tor configuration o Spoiler-deflector configuration c a, deg (f) M = 0% I I Figure 3- Continued

NAC!A~ 4ti 15 a 0 Pluin-wing configuration De fktor con figurm ion o Spoi/er-def/ecfor configdruf ion cm 6 5 4 3 co 2 / o q -/2 % -4 0 4 8/2i62024B Q,deg (g) M = 100 Figure 3- Continued

16 NAM m 4006 0 Pluikbwing configuration Deflector configuration O Spoiler- deflector COnf@UrO}iOn c c k c Q, deg (h) M = 105 Figure 3- Continued

z NAcAm40Q6 17 Q Plain-wing con ff gurotion De flecf or configuration o Spoiler-deflector configuration cm 6 5!4 3 2 a,/ o d ~12-8 -4 0 4 8 12 /6 20 24 Zt9 a, deg (i) M = 110 Figure 3- Continued

18 NACATN 4006 0 Plain wing con figurat ion Deflector con figuraf ion 0 Spoi/er deflector configuration c 6 5 4 3 2 / o c - -12-8-4048 12 /6 20 24 28 U,deg ($) M = 115 Figure 3- Concluded

NAC!Am 40C% 19 Pluin wing configuration Deflector con figuration Spoiler +eflec tor configuration @c 4 to -/ 8 6 23 4 2 0 /0 Ca5 CL* 06 04 02 Figure 4- Variation of lift-curve slope (slope taken at CL = O 3), angle of attack at CL = 03, and incremental pitching-mcment coefficient from a = 4 to CL= 8 as a function of Mach number liaca - Langley Field, VA