*10 cc DAVID W. TAYLOR NAVAL SHIP RESEARCH AND … · 2020. 2. 18. · *10 cc david w. taylor naval...
Transcript of *10 cc DAVID W. TAYLOR NAVAL SHIP RESEARCH AND … · 2020. 2. 18. · *10 cc david w. taylor naval...
*10
cc DAVID W. TAYLOR NAVAL SHIPRESEARCH AND DEVELOPMENT CENTER
Bethesda. Md. 200134
AERODYNA'MIC CHA.RACTL..STICS OF THE CLOSE-COUPLED CANARIDAS APPLIED TO LOW-TO.MODERATE SWEPT WINGS
VOLUME 2: SUBSONIC SPEED REGIME
by
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C' AVIATION AND SURFACE EFFECTS DEPARTMENTRESEARCH AND DEVELOPMENT REPORT
Ja- nuary 1979 DTN~3RDC-79/002'U
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ORIGINALDOCUMENT
MAJOR DTNSRDC ORGANIZATIONAL COMPONENTS
COMMANDE R00
TECHNICAL DI RECTORF7 01
OFFICER-IN-CHARGE OFFICER-IN.CHARGECADEOC ANNAPOLIS ,0
CRROK05 04;IsDEVELOPMENT
DkPARTMENT
SHIP PERFORMANCE AVIATION ANDDEPARMENT - - SURFACE EFFECTS
15PR NDEPARTMENT 1
STRUCTURES COPTATONDEPARTMENT - - MATHEMATICS AND
17 LOGISTICS DEPARTMENT
SHIP ACOUSTICS 1PROPULSION ANDDEPARTMENT AUXILIARY SYSTEMS
S,19. EPARTMENT27
ENGINEERING - INSTRUMENTATION
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I I I i I I I I I I ,
UNCLASSIFIEDSIECURITV CloWF7ICATIOp4 Of' THIS PAOE (When Date Entered)
R' PORT DOCUMENTATION PAGE BEFORE COMPLETING FORM
r~ HNSr-c9/21 2. GOVT ACCESSION NO, 3 RECIPIENT'S CATALOG NUJMBER
~ ,AROYAIC .CHARACTERISTICS OF THE,.CLOSE- /iaCOUPLED CýAIARD AS.APPLIED TO MOW-TO- *jiB1 4 - /
M$ODERATESWEPTINS S. PERFORMING OftG. REPORT NUMBER
JVOLUME 2. SUBAONIC SPEED REGIME,* Aero Report 12577. UTO~f) -~'---- U CN.AT GGRANT NUM1191(e)
/David -u./Lacey
S.PRFRIG RAIIATION NAME 5 GRS 0 R~rM1EETPOET TASK
David W. Taylor Naval Ship Research Air A, "Pp" 4O6UNTNU0
and Development Center Program Tfletaent 6224IN
Bethesda, Maryland 200F4 Work Arui M 1 4]-21-0
II. CONTA060.IPO OFFICE- A-Wr j-.6001
i-.~~IS J..1.11 OF 0-________
Naval Air Systems Command UCASFE
AIR 320 UCASFE
Washington, D.C. 20361 094ASSW7tCA-rioN7OVIOWRWIINT
1S, 011TAISUTION TATEMENT7 (.t Ohl1.Report) 1 ,
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17. 01ST R IHaU TI1N 17 A T fM E T h~I I. sh~e f(. nt 14* 4411 1 ft¶ ork " 2t'. Nit~Sllernt ttarn~pnpetl
16 SUP161.1MENTARY NOTES
12 KEY WOROS (Continue on reverse side If oecessary and Identify. by block i'umbet)
Canards, subsonic, lift, drag, pit~ching moment, research models10. AiS IE T Con tinuean re verse aid. II meceseery end iIdentity by block number)An analysis of the' effects of canard size, shape, position ind deflec-
tion on the aerodynamic characteristics of two general research modelshaving leading edge sweep nnglem. of 25 and 50 degrees is presented. Theanaiysict qumlrn.ri?,,es the findinpi; of four experimental subsonic wind-tunnel.programs conducted at the David W. Taylor Naval Ship Research and Development.Center between 1970 and 1974. The analysis is based on four canard geome-tries varying In planform from a 60-degree delta to a 25-degree swept wing
-Continued on reverse side)
DD IAi31473 E-omor IFINov as isoS OLtTF. UNCLASSIFT ED-~ . -SECURITY CLASSIFICATION OF TAsS PAGE (ften bt~e Entered)
UNCLASSIFIED• O4Il Y CLASStIC&TION OF TP41S PAGE(W*h- Del. Enit**d)
(Block 20 continued)
""Ihigh aspect ratio canard. The canards were located at seven differentpositions and deflected from -LU to 25 degrees.
Significant findings Include: the excellent correlation between canardexposed area ratio and changes in lift, drag, and pitching moment; the deL-rimental effect of positive canard deflection; and the optimum longitudualposition for each canard shape for maximum improvements in lift and drag.It is further concluded that the favorable aerodynamic changes caused byitLerference of the close-coupled canard are not significantly dependent onwing leading edge sweep or wing leading edge modifications.
L
UNCLASSIFIEDlllCLrU ITY CL SI FI,'CATION OFi TMISI pAGE(Wlhle DOMli I•'¢li, d,)
L-7
tzr
FOREWORDThis report summarizes the findings of close-
coupled canard research performed by the Aviation
and Surface Effects Department of the David W.
Taylor Naval Ship Research and Development Center.The work was performed between 1970 and 1974 and was4
funded by the Naval Air Systems Command (AIR 320).Ft The purpose of the report is to provide a summary of
the aerodynamic findings obtained from a series of
wind tunnel evaluations involving three general re-
search models and the F-4 aircraft. The report Is
presented in four volumes--Volume 1: General
Trends; Volume 2: Subsonic Speed Regime; Volume 3:
Transonic-Supersonic Speed Regime; and Volume 4:
F-4 Phantom II Aircraft.
lii
TABLE OF CONTENTS
Page
I[ST OF FIGURES ........................ ........................... vi
LIST OF TABLES ................. ........................... ix
NOTATION ..................... ............................... x
ABSTRACT ....................... ........................... .. 1
ADMINISTRATIVE INFORMATION ....... ..............................
INTRODUCTION ........................... ............................ I
LIFT ............... .......................... ..... ............ 4
SIZE .............................. .............................. 5
SHAPE ........................... .............................. 6
POSITION .......................... ............................. 9
DEFLECTION .................... ........................... . . 1.6
WING LEADING EDGE CHANGES ........... .................... .. 25
PITCHING MOMENT ................ ........................... .. 28
SIZE ............................ ............................... 30
SHAPE ........................... .............................. 35
POSITION .................. ............................. .. 35
DEFLECTION .................. ............................ .. 43
WING LEADING EDGE CHANGES .................... . 50
DRAG ....................... ................................ 51
SIZE .......................... ............................... 514
SHAPE ......................................................... 58
POSITION ................ ............................. ... 60
DEFLECTION .......................... ........................... 70
WING LEADING EDGE CHANGES ................. .................... 79
FLOW VISUALIZATION ............... ......................... .. 84
SUMMARY ...................... .............................. .. 89
SIZE ...................... ............................... .. 90
SHAPE ......................... ............. ................. ... 9)
v
V1
~?
Page
IPOSITI[ON ........................ ............................. 90
1)FFI, ('IUT [ ON . . . . . ... . 9 1
WING LEADING EDGE ChANGCES . . . . . ... .
ACKNOWLEDGMENTS ............. ......................... * . . 92
APPENDIX - MODEL GEOMETRY ............ ..................... .... 93
REFERENCES .................. ............................. .... 101
LIST OF FIGURLS
1 - Sketch of Models........ ... ................ ... 2
2- Canards .......................... ..................... .... 2
3 - Geometrically Similar Canards ................ .......... .. 3
4 - Canard Positions ..................... ................. .... 3
5 - Typi'al Lift Characteristics ............ ........... ...... 4
6 - C versus Canard Exposed Area Ratio ................... 5L20
7 - Incremental Lift Characteristics of the VariousCanard Shapes ....... ............................. 7
8 - Lift Characteristics of 25- and 50-Degree WingModels ........... ............................. . . 8
9 - Position Effects of Incremental Lift. .............. 10
1O - Maximum Incremental Lift Variation i.th CanardPosition ......................... .......................... 13
1. - Incremental Lift at 32-Degree Angle of Attack ... ......... ... 15
12 - Variation in Lift Coefficient at a - 20 Degreesversus Canard Deflection Angle 6. ..... ............... ... 17
c
1.3 - Incremental Lift Variation with Canard Deflection ......... ... 19
14 - Variation of a ACL with Canard Deflection ... .......... ... 22
15 - Variation of a AC with Canard-Wing Vertical Gap ....... .... 23
vi
Page
16 - Vrlration of' a AC /AC with Caaard-WnIngVert EI al (iap . . .M 1. . . . . . . . . . . . . . . . . . . . . 24
17 - Geometry of Wing Leading Edge Droops and Radii ............ ... 25
18 - Effect of Wing Leading Edge Droop and Radiuson Lift Chara.teristics ......... .................... .. 26
19 - Lift Characteristics of 25-Degree Model Modifiedwith -9-Degree Wing Leading Edge Droop .... ............. ... 27
20 - Incremental Lift due Lu Canard for Basic and-9-Degree Droop, 25-Degree Wing Model .... ............. .. 28
21 - Typical Pitching Mov.ent Characteristics .... ........... .. 29
22 - Variation of Pitching Moment Coefficient atZero Lift C with Canard Deflection
Ang o , 6 .. . . . . . . . . . . . . . . . . . . . . . . . . .. . 31
23 - Zero Lift Pitching Moment versus ProjectedArea Ratio ................ ........................... ... 33
24 - Zero Lift Pitching Moment versus ExposedArea Ratio ................ ........................... ... 33
25 - Zero Lift Pitching Moment Variation withCanard Exposed Volume Coefficient .. ............... 34
26 - Neutral Point Shift Variation with CanardExposed Volume Coefficient ........ ................... ... 34
27 - Incremental Moment Variation with CanardShape ................... ............................. .. 36
28 - Incremental Moment Variation with CanardPosition .................. ............................ .. 37
29 - Variation of a ACM32 with Canard Position ... ........... .. 40
30 - Incremental Moment Slope Variation withCanard Position ............... ........................ .. 42
31 - Correlation of Neutral Point Change withCanard Exposed Volume Coefficient ........... ............... 43
vii
Pt_
Page
K' - Inc rcml'rnta I Moment Change dche to Canard Didl-I ,k_:t Lon . . . .i. . 44
3 1 - Va LLaL i ouis o1 a Ac with Canard VcflecLtiu. ..... ..... 48
34 - Canard Control Power . . . . . . . . . . . . . . . . . . . . . . 49
35 - Moment Characteristics of Basic 25-Degree Wingand 25-Degree Wing with -9-Degree Droop .... ............ .. 51
36 - Lncremental Moments due to Canard on Basicand Modified 25-Degree Wing ......... .............. ..... 52
37 -Typical Drag Characteristics ........ .................. .. 53
38 - Typical Lift-to-Drag Ratio Characteristics ...... ........... 54
3) - Effect of Deflect tun on Zero Lift Drag C. ... ........... 56D)0
40 - Variation of Canard Drag Coefficient withCanard Lift ................. .. ........................ 57
41 - Variation of (L/ID) with Canard Exposed AreaRatio ........................... ............................ 57
42 - I lt-to-Drag Ratio Varlation with Canard,'-lh. . . . . .................... 59
43 - Tndu,',d Drag F,'actor ................... .. .................... 61
44 - LI ft-to-Drag Ratio Variation with CanardLIlcitionl .... . ...................... ....................... 62
45 - E,'fett of Canard Post tinn on MI.nimum Drag(:ucfl•i'c nt. ................ ......... . 66
4h - I.dticLed I)rag Ira tor Var Iint-Ion wlLE h (CaIIILrdI'OStIOt[n fr tihe 50-Dogrve WIng . . . . . . . . . . ..... 7
47 - [iLduced l1rIg Factor Vrlmntloin witLi Canardtucuoltton fur Lhl 25-I)egrc*'u WInl. ........ .......... 69
48 - Lm..iiM H of HItlnli •i Irid Jlk. d Drag Vm.ti or . .. . . , . . . . . . .. . 71
49 - Iw lot-tn-Iri, Rat jun Vxir llloin wl ii C('anmrdl) (,- l eci t lnm . . r . . . . i . n. . . t . . . . . .. . 7 2
A 0 - ý1t 1. 1mliu Drop Vitr io l Itlm w ith (Itimn rd 1)(If lt, 11 . . . . . . ... 71.5
Vill
Page
51 - 1, f fec t of :;i nard rl'f Icct it on 0 i1 InducedDrag F ict.or . . . . . . . . . . . . . . . . . . . . . . . . . . . 76
52 - Effect of -9-Degree Droop on Lift-to-Drag Ratio ......... 80
53 - Incremental Change in Lift-to-Drag Ratiodue to -9-Degree Droop .............. ..................... .. 83
54 - Tuft Patterns of the 50-Degree Wing ..... ............... ... 85
55 - Effect of Canard on Unseparated Flow Region ......... ......... 86
56 - Effect of Canard Shape .............. ..................... .. 88
57 - Effect of Po,41lton ................ ....................... .. 88
58 - Research Aircraft Fuselage ............ ................... .. 96
59 - Platform View of the Wings .......... .................... .. 97
60 - P tanform View of the Canards .......... .................. 98
61 - Canard PivoL Locations .............. ..................... .. 99
62 - Wir1 Tutinel Model Componients ......................... 100
LIST OF TABLES
.i - ometrIc, Characteristics of the Wing ..ds .......... ............ 94
2) - rcometric CharacterItLics of the Canards.. ............ .......... 95
LKI
NOTATTON
AR AAspvct ratto
Ii lv I,
Canard pro-ected span
CD Drag coefficient, D/qSw
CDc Drag coefficient of canard referenced to total canardC exposed area
CD Minimum drag coefficient
C' Canard
CI• I,ift coefflcient, ],/qS
CwU Lift coefficient of body alone
Cl ~~T~ft coefficient of body ond canard i'B+C
GI, MaxLimunI Lift coefficienta
iIX
'Lift coefficient of wing iand bodywB
C ift coefficient evaluated at minimum drag value
C, 2fL coefficient evaluated at a - 20 degrees
C2LIft coefficient evaluated at a - 32 degrees
{: -l~ift curve slope of canard, referenced to(i canard exposed area .
XII
x!
- .!
C1 t curve slope of ,nnard due to def lect ion
C Pitching moment coefficient, pitching moment/qSM w
MB+ Pitching moment coefficient of body alone
C Pitching moment coefficient of body and canardMB+C
C Pitching moment coefficient of body and wingMWB
C Zero lift pitching moment
C Pitching moment coefficient evaluated at a 3 32 degrees32
M MN N
c Mean aerodynamic chord, inches
D Drag, pounds
i Canaud shape
J Canard position
L Lift, pounds
L/D Lift-to-draj; ratio
(L/D) ma Maximum lift-to-drag ratio
Distance between center of grality of wing and canardc pivot location, inches
P Canard position
q Dynanic pressure, pounds per square foot
xi
L..-
SC Canard Projected area, squace feet
s. Xa11ard cxpose' area, square feet
S W Wing reference area, square feet
W Wing
Longitudinal distance, inches
z Vertical distance, inches
z t Vertical gap measured from canard trailing edge to
wing upper surface, inches
Angle of attack, degrees
ACL CL - CLw
ACL L - C'C B+C 8
AC Maximum value of incremental liftLMIX
AC3 Incremental lift evaluated at a = 32 degrees3.)
A-CM C M -- C~A-MWB
CMM CM
C B+C B
AC AC evaluated at a =32 degrees
Canard deflection angle, degrees
k Wing leading edge sweep angle, degrees
x 25 Quarter chord sweep angle of canard, degrees
xii
•-:.
ABSTRACT
An analysis of the effects of canard size, shape,po,0it Ion and dcef lection on the aerodynamic character-lstics of two general research models having leadingedge sweep angles of 25 and 50 degrees is presented.The analysis summarizes the findings of four experi-mental subsonic wlnd-tunnrl programs conducted at theDavid W. Taylor Ship Research and Development Centerbetween 1970 and 1974. The analysis is based on fourcanard geometries varying in planform from a 60-degreedelta to a 25-degree swept wing high aspect ratiocanard. The canards were located at seven differentpositions and deflected from -10 to 25 degrees.
Significant findings include: the excellent cor-relation between canard exposed area ratio and changesin lift, drag, and pitching moment; the detrimentaleffect of positive canard deflection; and the optimumlongitudual position for each canard shape for maxi-mum improvements In lift and drag. It is further con-cluded that the favorable aerodynamic changes causedby interference of the close-coupled canard are notsignificantly dependent on wing leading edge sweep orwing leading edge modifications.
ADMINISTRATIVE INFORMATION
This work was undertaken by the Aircraft Division of the Aviation and
Surface Effects Department of the David W. Taylor Naval Ship Research and
Development Center. The program was sponsored by the Naval Air Systems
Command (AIR 320) and was funded under WF 41432-09, Work Unit 1600-078.
INTRODUCTION
This Is the second volume of a four-volume report summarizing the
close-coupled canard work accomplished at the David W. Taylor Naval Ship
Research and Development Center between 1970 and 1974. This volume summa-
rizes the findings of a series of wind-tunnel programs conducted at subsonic
speeds.
Volume 1 of this report presented the general trends of close-coupled
canards on aircraft of low to moderate wing sweep. It was shown that close-
coupled canards con significantly improve stall angle of attack, increase
j 1
, •::•"~m•• W • • lr • :"• • • '-- • • .. . , ',•. .. . ,4 •'r '-•- •-•r: • •:• • . ... .. . . . ..... . • . ...... ..... . .= • ,.
the maximum lift coefficient, and reduce drag. The extent to which these
imprOVeCl'ftS occiir Is ai function of canard size, shape, position, and de-
f ltct ion. l'Ihu.se variablcs, as well as the influence of wing leading edge
modifications, are discussed in detail in this volume.
The discussion is based on four wind-tunnel programs conducted in the
DTNSRDC 8 x 10 foot subsonic wind tunnel. Two general research models were
utilized in this program. The models had leading edge sweep angles of 25
and 50 degrees. Skatches of the models are shown in Figure 1. Four canards
S 50.DEGREE SWEPT WING
25-DEGREE SWEPT WING
Figure I - Sketch of Models
of dlffprent planform wore evaluated. The shapes were a 45-degree clipped
delta designated Co, a 60-degree pure delta CV, a 45-degree high aspect
ratio canard C2 , and a 25-degree canard C3 , as shown in Figure 2. In addi-
Figure 2 - Canards
LJon, Four geometrirally similar versions of canard C were evaluated with
projected area ratios of 0.10, 0.15, 0.20, and 0.25. Relative sizes of the
four canards are shown in Figure 3.
2
- - ---- BODY C'
- A - 24(6.10)iTYP
. . . AIRFOIL SECTION60A00d
II.• PIVOT DISTANCE VAN TIP CHORD MOOTCHOAD CANARD AREASA 6 C 0
IN. C_ IN . CM. IN, CM. N CM. IN, CM,'I
0.10 1.311 31111 2.74 1t.96 0.38 0,97 3.12 7.92 30,8 196.6
0 ,15 1.75 4.44 3. 61 9.93 0.44 1 ,12 4.35 11.02 46.7 294.6020 2.25 5.72 4.4 12.29 o.. 1.42 19140 13.62 slo $ 3.5
026 262 6.66 6.74 14.56 0.66 1.10 6,33 161.0 7ls 4 .0
Figure 3 - Geometrically Similar Canards
The models have seven positions at which the canards can be located
(see Figure 4). Positions are numbered from fore to aft and top to bottom.
Position I Is the highest, most forward and position 7 is the lowest posi-
Lion. Deflection range varied from -10 to 25 degrees. Detailed dimensions
of the models, canards, and positions are given in the Appendix.
NOTE: ALL DIMENSIONS ARE IN INCHES (CENTIMETERS)
I i110100I42.50-'- .0 w4-.----+11.3 12 so36 V
1,35 16,3615.
(26.401 MOMENT
+ + REFERENCEP1 P P3 POINT
1,0012.541
("54•p0 CHORDPLANE 13.5-
Figure 4 - Canaird P'ositions
The discussion is organized into major topics of lift, pitching moment,
and drag. Subtopics include the effect of canard size, shape, position,
deflection, and wing leading edge changes. The data are primarily pre-
sunted Ls incremontat changes in lilft and pitching moment due to the above
parameters. Drag is presented primarily as lift-to-drag ratio at constant
lift coefficient. Data for both 25- and 50-degree wings are presented to
indicate that the favorable effects of close-coupled cana:ds are applicable
to aircraft of relatively arbitrary wing planforms.
LIFT
Typical variation of lift coefficient with angle of attack for the
25- and 50-degree wing are presented in Figure 5. Data are shown for three
- W ingDLGRIE WING
1.4- 0 W+c_
1,2 -VW C3
'
110-
II.-DEORER WING
0.4 -
0-
-0.2
-a,2 L • , t I I I-4 0 4 a 0 4 8 12 16 20 24 28 32 36
"ANGLE OF ATTACK (DEGREES)
Figure 5 - Typical Lift Characteristics
canard shapes: a 60-degree delta, a 45-degree high aspect ratio canard,
and a 25-degree high aspect ratio canard. For all configurations there is
aI 4izeablc increase in lift when the canard is installed to the basic
4
wing-body. The increase in lift varies somewhat with the particular canard
size, shape, position, and deflection. These differences in lift are dis-
cussed in thie following sections.
SIZE1*
One of the prime variables of the first canard wind tunnel program
conducted at DTNSRDC was the effect of canard size on the aerodynamic char-
acteristics of the 50-degree research model. Four geometrically similar
canards having projected ar'ea ratios of 0.10, 0.15, 0.20, and 0.25 were
evaluated. Relative sizes of each canard are shown in ligure 3. Data from
this wind tunnel evaluation were limited to an angle of attack of 20 de-
grees. The variation of lift coefficient at 20 degrees is presented in
Figure 6 for seven canard positions.
8./sw
u 01 0 Olb 010| 0 2II e
S 0 11.. 0i
0.0
wLe
o IRot 0.04 0d O6 0go 0.10 0.11 Old 0ai
Figure 6 - CL20 versus Canard Exposed Area Rntio
A compleLe listing of references is given on page 101.
The effect on canard size varied somewhat with canard position. At
those positions where the canard iw fairly close to the wing, P2. P3, P5'1 thiere is a distinct curvature to the data, however, as the canard is
moved Furthler forward L1h0 varl[ato of t It'C with size becomes I inear.120
Little favorable effect would be expected because the interference is mini-
mized. Included In the figure is the value of the lift coefficient for
the 0.25 canard and wing body if no interference were present.
Comparison between this value and the data shows favorable interfer-
ence for the high canard locations (PI, P29 P3 ), and unfavorable inter-
ference when the canard is in the plane of the wing (P 7 ).
SHAPEIncremental lift is presented in Figure 7 for the various canard
shapes. The canard location is position P for all four canard shapes.3
As stated in Volume I., P3 was near optimum for all canard shapes. The
figure is for both 25- and 50-degree research models and contains Isolated
data for each canard shape. I
The most significant conclusion which can be drawn from the figure
is that the large difference in incremental lift bctween 25- and 50--degree
wing configurations Is in the angle of attack range between 12 and 28 de-
grees. This difference is attributable to the poor stall characteristics
at the 25-degree wing.
A comparison between the canard-off characteristics of the two con-
figurations is given in Figure 8. The 25-degree wing configuration ex-
hibits as expected a higher lift curve slope than the 50-degree configura-
tion but the stall angle of attack is only 10 dagrees for the 25-degree Iwing versus 20 degrees for the 50-degree wing.
The favorable interference between canard and wing, therefore, delays
stall at a lower angle of attack for the 25-degree wing.
Lhis reduction in angle of attack due to favorable interference is
clearly seen in the low cross-over point between the isolated Lanard data
6
0,6
04 1,/C . / '-
/ "° -I //
0.2 - ISOLATI/ / /°LA7ED
op ~-.0-
25 U,11
/ " /#- " " " i 4E•B
0.4 /
0.2 -' INOLA 0 ISOLATED
- - 1I I
0 1i 24 32 0 a 24A"OLk OF ATTACK DEIUREEB) . ANGLE OF ATTACK (DEGREES)
Figure 7 - Incremental Lift Characteristics ofthe Various Canard Shapes
7
IT
I
1.6!
1.4-
1.2 50 DEGREES
S1025oDEREESL.• .-- •,,SSW•S•S• ••
U.. .U.LU
0.4
0.2
4 8 12 16 20 24 28 32 36a, ANGLE OF ATTACK (DEGREES)
Figure B - Lift Characteristien of 25- and 50- Degree Wing Models
and the complete configuration. Favorable interferunce occurs at approxi-
mately 12 degrees for the 25-degree wing, whereas favorable interferencu
does not occur until thu angle of attach reaches approximately 16 to 20
degrees for the 50-degree wing. It can be said that the poorur the wing
design, the more the canard can help.
Examination of the data with regard to the individual canard shape
indicates that the 60-degree dltL-i canard G maximizes the increase in ilft
for both win.-ig. 'rhi, hO-dv-rLc 'nanrd Is (lotiely followed by the 45-degree
hi 0,61 aspo't ratio canard a and the 45-degree (1J. ppUd del tl COU
The low sweep canard C3 exhibited the lowest incremental lift for ýhe
25-degree sweep model, and, in fact, the canard appear& to have stalled at
approximately 20-degree angle of attack.
Incremental lift for th, low sweep canard is approximately the same
as the other canards for the 30-degree wing model, It thus appears that
while low sweep canards are Inadequate for the low sweep wing, the low
sweep canard doem delay separatiLn Aufficiently for the wing of higher
sweep if located at the proper pusittion. The effect of position change
on incremental lift for the various canard shapes and the two wing sweepm
id discussed in the next section.
POSITION
Incremental lift versus angle of attack is presented in Figure 9 for
both 25- and 50-degree sweep research models. Data 2 are presented for
seven positions for the 50-degree model and three positions for the 25-
degree model. The data are for the four canard configurations at zero
degrees canard deflection.
Incremental lift was, in general, maximized at 28-degrees angle of
attack for the canards on the 50-degree model and between 20- and 24-
degrees angle of attack for the 25-degree model.
The variation of maximum incremental lift with canard position is
shown in Figure 10. The interference free value of canard lift at the cor-responding angle of attack for each position are also shown in the figure.
For all configurations, as the canard was moved to the most forward
position, Z/ - 1.5 for the 50-degree wing, X.//c 1.30 for the 25-degreec
wing, the maximum incremental lift dropped off. Similarly, lowering the
canard reduced maximum incremental lift. The only exceptions to the latter
statement were the low sweep 25-degree canard C3 , and the high aspect ratio
45-degree canard C Canard C3 had an increase in maximum lift at the low-
est, most aft position for both 25- and 50-degree wing models. Similarly,
lift was maximized at P 6 for the 45-degree high aspect ratio canard C2.
9
' IIur! , 9 - l',) iL himI EI" cL' ,c L )I- Ilnur mlI nL , lif t
0.6
S0.4
0,2
ANGLE OF ATTACK (DEGREES)
Figuru 9a - Canard C on 50-1)egree "ing0
1, IOE4
0,2
0 B 15 24 .12
0, ANGLk OF ATTACK MOELUS)
Figure 9b - Canard C L un 50-Degree Wing
i0
Figure 9 (Continued)
0.4 P
0,0
0 8 0 8 0 0 lS24 32
k, ANGLE OF ATTACK (DEGREES)
Figure 9c - Canard C9 on f50-Degree Wing
0,4 -
0.2\
Pt Pp0 16 0 16 0 I 16 24 32
t, ANOLE OF ATTACK (DEGRE•SI
Figure 9d - Canard C3 on 50-Degree Wing
3I
a j-1
Figure 9 (ConLinued)
0.,
0 .4 .-
0.4 ./
0.2 '
- I-
0,II. - --
040 /
0 4 8 12 16 20 24 2R 32 0 8 10 24 32ANGL2 OF ATTACK (DEGREES) ANGLE OF ATTACK (DEGREES)
Figure 9e - Cannrds on 25-Degree Wing
12
0.4 .. II ,DLAI .J I ,IOAL It I ,
00.75 1.00 1.25 1.50 0.75 1,00 1.25 150 0.75 1,00 1.25 1.50 0,75 1,00 1.25 1, b0
C~!e 1.2/'eU,=' I,'/1
Figure lOa - Lift on 50-Degree Wing
J J
0.4 0Ope
ISOLATWD0.2 "IILAD- ILAtKD
,10 LAW TaIr/
,%.5 1,00 1.25 1.50 0.75 1.00 1 IS 1.0 0.1 100 1.25 1.60 0.75 1,00 1.25 1',0
Figure 10b - Lift on 25-Degree Wing
Figure 1.0 - Maximum Incremental Lift Variationwith Canard Position
13
Examination of the data relative to the interference free value indi-
%avsC, that the incremental lift is approximately double that of the inter-
icrc , O ' 1. i LIt , if the canard is properly I y I cated. Improper location,
i.e., too far forward or too low, reduces the value of the incremental lift
to approximaLely I l/z times the interference free value.
The value of Incremental lift obtained is approximately the same for
both 25- and 50-degree research models for properly located canards. The
only exception is the 45-degree high aspect ratio canard which had signifi-
cantly higher values of incremental lift when mounted on the 25-degree
research model.
The data presented in Figure 10 are not at a constant angle of attack,
hence, they do not represent the maximum lift coefficient obtained by the
complete configuration. The angle of attack where waximum lift for the
c:ompleLe configurations occurred was generally at 32 degrees. Figure 11
presents the canard incremental lift at 32 degrees versus canard position,
thus also showing the influence of canard placement on the maximam lift
cUefficienLt. Included in each figure is the interference free lift for
each canard shape. In Figure 10, the incremental lift was always greater
than the interference free lift. This is not the czse at 32 degrees, par-
ticiularly for the 50-degree research model. For all but the 60-degree
delta canard CI, there are canard locations where the incremental lift is
less than what would be obtained from the interference free value, thus
indicating unfavorable interference. The onset of this unfavorable inter-
ference occurs at Z. /c of approximately 1.4 for canards C0 and C, and ap-
proximately Z /c of 1.2 for canard C3 . Lowering the canard further movedc
the intersection point aft and reduced the lift.
Thr, trends for the 25-d-gree rcsearc'h model are similar to those of
the 50-degree model, although the only intersection point noted is for the
25-degree canard C. This intersection point occurs at approximately the
same Z /c value as that of the 50-degree wing model.c
14i
---- - .2 - -
0.4-
SIOLATED I•OLATED ISOLATED%
0.75 1.00 1.25 1.50 0.75 1.00 1.25 1.50 0.75 1.00 1.25 1.50 0,75 1.00 1.25 1.50
voltFigure Ila - Lift on 50-Degree Wing
0.2
0 ISOLTE ISOLATE ISA IED
0.
0.75 1.00 1.26 1,50 0.75 1.00 1.5 1.50 0.75 1.00 1.25 1.50 0.75 1.00 1.25 1.50
Figure l1b - Lift on 25-Degree Wing
Figure 11 - Incremental Lift at 32-Degree Angle of Attack
1.5 •_• .I
DEFLECTION
Canard deflection has direct Influence on the maximum lift generated.
This inf-lue nc e, either favorab• c or unfavorable, Is dependent on canard
position and size.
The variaticn of lift coefficient at 20-degree angle of attack are
presented In Figure 12 for the four sizes of the 45-degree truncated delta
canard C 0. In general at low deflection angles, 6c -< 10 degrees, there is
little change in the lift coefficient for all positions and sizes. As de--
flection is increased different trends occur. The smaller canards S c/Sw
0.10, and 0.15 located in the high positions PIV P2 9 P 3 exhibit little
change in lift coefficient with increasing deflection angle. As the canard
size is increased or moved closer to the wing, there is a decrease in lift
coefficient with increasing deflection angle. This reduction in lift
occurs primarily at P 6 and P 7 for the smallest canard Sc /S - 0.10, and
Positions 3, 6 and 7 for larger sizes. Thus, for canards which might be
used for control purposes, i.e., removed from the wing, there is little
lift loss due to the canard. Canards which are located close to the wing,
however, exhibit lift losses with increasing deflection angle. The previ-
ous discussion is based on data at 20-degree angle of attack. At higher
angles of attack it should be remembered that when the canard is moved
longitudinally away from the wing the likelihood of canard stall increases
and, thus, the above discussion is not likely to hold.
The effect of canard deflection on the incremental lift characteristics
of the four different canard shapes is presented in Figure 1.3 for both 25-
and 50-degree research models. Data are presented for canard deflection
angles of + 10, + 5, and 0 degrees for the 50-degree wing and 0 and -10
degrees for the 25-degree wing model. Canard positions represented are
Positions 3 and 6 (Z /c / 1.0).
Canard deflection has little effect on the incremental lift character-
istics at low angle of attack and, as reported in Volume 1, CL is approxi-LImate]y 1/2 C1 of the isolated canard. At higher angles of attack distinct
differences in incremental lift appear as shown in Figure 14 for the case
of 32-degree angle of attack. Examination of the figure reveals the large
16
.-
04
LIDI
"i l ' I I, i
C, - 4
- -I I.i'I / .
LIU
4-4
MI IIi "17
,I • I I
"-,I
-h7
,.*1
II1111 ~a 'I18t
Figure 13 - Incremental Lift Variation with Canard Deflection
0.4
5 (DEGREES)- 0-~ 5
0.2 -- 10
00
WOW- -10
,r ANGLE OF ATTACK (DEGREES)
l IFiga;re 13a -Canard GO on• 50-Degree Wing
19
-,
t+ +
I --'° I !' /
0 0
0
-j
r, 0U 0 00m
01
Figure 13 (Continued)
( IDEGREES) h, IDEUREESý.,4
,% 1+ 10
- K -I0 2
0-
0. -1-
0
I I .L.________L____________
0 Is 24 32 a B Is 24 32SANULE OP ATTACK (DEGREES) ., ANGLE OF ATTACK (DEOREES)
Figure 13d Canard C on 50-Degree Wing
/ o-.0.4 //
O'C,
o, JI
0 21 4 32ANGLE OF ATTACK IMAM)
0.4 PA c i
Figure Ile - Canards on 25-Degree Wing
20.
oxA I I I• . I ,
O I 2 4 i 32a l / H i i M. . .
LU
ww 9
I 41WW40
--- r4P-4
~6_ _ _ _
2,
a:
do 0_j
66
0 b0
- U.~cc
- I ,
22a
dependence of position on lift at equal canard deflection angles. This is
seen most clearly for the 60-degree delta canard C1 and for both 25- and
50-degree model s. When thLI canard is at the low position P 6' positive de-
fiuctions cause a severe lift loss v.ead negative deflections cause a lift
gain. Similar trends occur for both the high aspect ratio canards C and2
C3 on the 50-degree wing model.
Figure 15 utilizing the data from Figure 14 presents Incremental lift
versus the canard trailing edge gap measured between the wing upper surfaceand the canard trailing edge. The gap was made nondimensional with respect
to projected canard span.
0.6
0 C20.4 - o 1O.. ... ...-J V
0.2-
0 0.04 0.08 0.12 0.16 0.20 0.24ZT/balnard
Figure 1.5 - Variation of A Ct3 with Canard-Whng
VcrLical Gap
Without taking into account differences in canard lift curve slope, a
pattern of incremental lift versus gap height can be seen whltch is somewhat
similar to a ground effect plot albeit in an invested sense. In true
ground effect, CL increases with respect to proximity to the ground. I1na
the case of the canard, close proximity of the canard to the wing causing
a lift loss.
2.3
By taking the Incremental momenr data presented in a later section at
the ammv angle of attack and dv [ding by the correspondding InCrementalrift, FigurL, 16 has been dowlopvd-
4
3 0 C2
0 C3
SiI I I I
0 0.04 0.08 0.12 0116 0.20 0.24ZT/ibanhord
Figure. 16 VarI.aticn of ACM/AC with Canard-Wing Vertical Cap
It is seen that at gap ratios greater than 0.1 the ratio ACM/ACt in
approximately I which is where the canards are locatel, ie,, ,/c - I,.
However, as gap height is decreased AC /AC moves rapidly forward Indicat-M 11
Ing that the canard Is very highly loaded (typical of ground effect) and
the wing ig unloading. This behavior of the wing Is perhaps due to the
canard downwash having an unfavorable effect on the lift. It thus appears
that for good high angle of attack characteristics the canard should be aLleast 0.10 canard spans above the wing plane.
24
WING LEADING EDGE CHANG;ES
The reisearch models LitlItzed In the previous dlscussLonHs had symmetrl-
al enad log edigs and tho nfortieil Iedidf og edge rad IL. assoc.lati.-d WItLI tOLe
MA008 airftul. It is well known that increases in performance can be ob- ...
tained by suitable changes in wing leading edge radius or droop. In order
to examine the effect of such changes on the aerodynamic characteristics,
three radius changes ond four leading edge droops were evaluated onl the
50-degree model. Details of the radius changes and droops are given In
Figure 17.
LEADING EDGE DROOP LEADING EDGE RADIUS(RADIUS * RI) (DROOP - 0 DEGREE)I R0 DEGREE 0.0044a
R2 0,[o088co - 3 DEGREES
U ~ DEGEESR 4 -0,0176cS '• • 6 DEGREES
I 15 PERCENT CHORD
"•-• • -•ll •9 DEGREES
Figure 1.7 - Geometry of Wing Leading Edge Droops and Radii.
,II25
L M. --. . ;-;T~ • Y - ,'-;:L:;•: X .m " =::.--•••,..,-:'•':
1AL tVer,40-i .3igle OF at t~nk is p ri4ntLd In F'l~gure 1.8 for the 50-
d~grUL' wing hot I withI and wilithot th c~ anard I-or the varying rad ION and
d run 11) i H; ThO curd f. x Lw 4 5-deg,_LL r L trunci ed de.Ito C0 I ocat ed at pos it on
1, ankld L li'grt-L diit IOt hii A!; r~Lm bV ncel In the fiIgurO, iielthur radiuH
change nor drOOP CdUuSe any apprecitable change in lift for either canard-on
or -of f conf igurat ions.
1ANA1113 r.ANAUDi
A A
n1.4
1) 4 1 I 21 2A vs 12 16
1AN(tIL (IF At TACK WORKI~~
Figurc l8a - lrouPs
1.4
.2 -
I, 0 01
L I _II 4 It 12 Is 20 24 09 * 36
ANIIIA OF1 At tACK IL11468PI
Figure 18b - Radius
Figure t8 -IlffL'c.t oII Wing Lunding Edge Dlroop andRadl~us on Lift. ChrdictL'rts~tk
26
I - ~ ...ZX
T~Li h8i ck Of Cihange W.11- Hot the case for the 25-degrue ruNaui I11UMLL
as 41iowil in F iguri.' 14. In Llie case of thu 2 ¶-dvgruv model, OILe -9-degree.
-- -,EQE DRO CANARD LAnJ~U
1,2 - do
0. BASICLEADING EDGE
0.4 CNR ATP0tlITION 2I f013E i CANARiD DEFLE~CTION
0 4 8 12 18 20 24 28 32
F igki rt 1.9 - I t ('hnroeter tyt:l' (31'I 2 5-lDg rue Model Mod if tucdW it i 9-lg e Wing Leald i g ikLgu Droop
droop (It'm I t 4tal IIby approx im-itLfly 4-dL'grev angl1e of a~ttaok miid 1 ImprOVe!H
a ~ thu maxi~muni tif coeff [I-eent by 0.24. Thu of fect of oiddhltg tHo omviird to,
tho mud lfied modl~d IsN prelsvotud In Figure 19~. MaL- 11r` presented f'ol tho
60-devrc~ delitn cnnard C1 locate'd at p and 0 degreti dul uttion, I oc rv-3
men tIl, I If t versu atSnag.c o f attack. for LhuV hasvui tu and -9-degreo droop
modeI.is is prciiwntc'd i~n Fl~gurp. 20 fur the 60-dlegree canai-rd at PUIkoIt loaN 3
anid 6 for dif I ct ons of LI and -1I I degrees.
le t t or c Lll.i. a aeLu r I st 1tM of Lhu wliiit , modil ted With HIitLe -9-du1gIrue
drmopl) dllayH the' off'ovL or the conard by ;ipproxhimatolIy 4-degree na1g IL' of7
at toek. Au angie~ ofI attack is I n(reaised bey01nd H tol I 1 augI (If : oit tack; 01L,
value or I ncremeiuta.1 I i f 1H appvnximatolIy the i4;.mu ort s I Ight Iy lv~lioihv for
the mcodi fled wing. [t 1I Ho tisNovn that as thei I)OsIC wingý! chilrnl Or l-lH IC
arv Improved the hl"fI tience of the( cLnAimird is cie layod to Iiiglier mng1 iv of'
alac k.
27
0.6 -___________ _____________________
BASIC LEADING EDGE
0.4 9 DEGREE LEADING EDGE
0.2
0.
0.2
000
eANGLE OF ATTACK (DEGREES)
Figure 20 -Incremental Lift due to Canard for Basic and
-9-DegrLýe Droop, 25-Degree Wing Model *PITCHING MOMENT
The variation of pitching moment with angle of atLack is pres~iited inI
Figure 21. The data are for the same three canard geome'trieo anda positions
as~ those presented In Figure 5 of the section of 11f'-., mainly. the 60-
degree delta, and the 45-degeee and 25-deg~ree sweep hIgh aspec.t ratio on
28
0.7
, 0,5- •W+q3
0.5 -o, 25 DEGREE WINO
0.3
X 0.2
00.1
0,3-
50 DEGREE WINO
0.2
0.1
0
-0.1
-0.2 - ' I _I I I I-4 0 4 8 12 1( 20 24 23 32 36
', ANGLE OF ATTACK (DEGREES)
Figure 21 - Typical Pitching Moment Characteristics
canards. As with lift, differences occur due to canard shape. The data,
howe2ver, indicate a fairly linear variation of pitching moment over the
angle of attack range when the canards are installed. The influence of
size, shape, and l)Siltion on pitching moment are discussed in this suc.Lion,
Examinatioll of the data presented in Figure 21 indicaLeh that the
pitching momenL behavior of the basic wing-body Is not linear. This
29* -'~ ~ 'fl~..Lt. IX~W*-l s;a-,~.~ ~s
nonlinear behavior is most pronounced for the 50-degree sweep wing model.
To determine the effect of the canard, incremental pitching moments ACM
wiLl be used almost exclusively La the folLowing discussion. The basic
data from which these incremental moments have been obtained can be found
in the references.
SIZE
The influence of canard size on pitching moment at zero lift C is
presented in Figure 22. Shown is C versus deflection for canard pro-
jected area ratios SU/Sw from 0.10 to 0.25. As indicated, the increase
in moment with deflection is reasonably linear for each canard poasi'ion
and size.
Figure 23 presents zero lift pitching moment at 1.0-degree deflection .1
versus canard area ratio at Positions I and 3. As shown, the data do notintercept the zero value at zero canard size, therefore, indi.asting that '•the canard projected area ratio is too large a parameter for good agree-
ment. The data, when plotted versus canard exposed area ratio, converge
to zero at zero canard size as indicated in Figure 24. Data are presented
for each of the seven canard positions evaluated and, as shown, linear
fits of the data are obtaincd at each position. As expected, moving the
canard forward increases the pitching moment; not so *xpected is the fact
that lowering the canard reduces the magnitude of the pitching moment
change.
The data from Positions 1, 2, and 3 have been plottad versus canard
exposed volume coefficient anud are presented in Figure 25, Catiard "olume
coefficient is defined as /c/ x S /Sw, where Z, is measured from thb 0.27e
Sposition of the wing to the 40 percent exposed root chord of the canard.
The variation in C with exposed volume coefficient is linear as shown.
The forward shift in neutral point due to canard size is presented in
Figure 26. The parameters chosen are incremental moment slope evaluated
at zero lift versus canard exposed volume coefficient. Data are presented
30
VNC)
4I C L~
LU 6U
0 1
0 I
on cc w ww U.
a~UJ
'4- C
C.V)
44.
IN II31
uUu
LUL
I..
CC
No u
0 0.9j
LO U.U
U 6U
CC w
Un 0
0 Ci
LN3W'~OW~ DNIHDJ.Ld LN3WiOWIDJ NIHDJ.ld' WO
32
El
0 006 010 0,15 0,20 0.26 0,30
lc/swý PROJECTED ARIA RATIO
Figure 23 - Zero Lift Pitching Moment versusProjected Area Ratio
- 0 Pl,4
C P2,.7
P 1,2,3 •ic -10 DEGREES
U.1 0.1
U.
0
P7
0.1
0 0.04 0.08 0.12 0.16SC Sw, EXPOSED AREA RATIO
Figure 24 - Zero Lift PitchinK Moment versusExposed Area Ratio
33
U.
VcU CANARD__ EXPOSEDVOLUME__COEFFICIENT
0.4 0..212 016 02
0 C Ic CANARD EXPOSED VOLUME COEFFICIENT
Figure 26 -Zero ralf PointcShingMft Variation
with Canard Exposed Volume Coefficient
M 10
c -
to aHilft figu2 e 26 fo theutral Pointr ahit Variaotifonwrosto
wit Caar 1.p5,e Voum Co/Sf0.2)t
at - nd10dere cnad afletio. hevaiaio o ~ACM)234i
S HAPEThu.I variation t i Incremntal moment with canard shape i!: SihoWL- in
Figure 27. Data are presented for the four canard shapes located at P3 for
both 25- and 50-degree sweep models. Included on each figure are the val-
ues for each Isolated canard shape at P36
As with incremental lift, the most significant changes noted are the
early differoaces between the 25-degree data and the isolated duta. This
is undoubtdly due to the early stall of the 25-degree wing.
At low angles of attack the incremental moment has the same value and
slope as that of the isolated canard data for the four canard shapes andboth wings, thum indicating little if any upwash effects due to the wing.
As angl, of attack is increased, significant differences occur primarily in
magnitude. This is due to the fact that the canard is delaying stall over
the root position of both wings. Thus, the center of pressure has moved
inboard and forward for each wing thereby generating increased, nose-up
moments.
Comparison between the incremental and isolated canard data indicates
reasonable up.reement between the slopes and general shape of the curves for
each canard shape--most notably for the 25-degree sweep model. For example,
the isolated 25-degree higlh aspect ratio canard C has a stall at angles of
attack between 12 and 16 degrees; similarly, the incremental data indicate
a reduction in slope In this angle of attack region. Reductions in slope
are also evident for both the 45-degree high aspect. ratio canard C2 and the
45-degree truncated delta canard C0 and these reductions occur for both
Isolated and incremental data, No reduction in slope is evident for the
60-degree canard isolated data and no reduction is seen for the incremental
data.
It is thus apparent that the general shape of the incremental moment
curve is the same as that of the isolated surface.
POSITION
Incremental moment versus angle or attack is presented in Figure 28
for seven positions for the 50-dogree wing model mnd three positions fnr
35
V *Wu,
- I
'0.3 50 D8EGREE WING 0,
L.
000 OlP go 0
rr
0 1i 24 20U4
.,ANGLE OP ATTACK (DIGANIE111) •.,ANGLE OP ATTACK 1010RI•ESI
Figure 27 - Incremental. Moment Variatioil with Canard Shape
36
]02 7
Figure 28 -Incremental Mome~nt Variation with Canard Position
0.4
0. 4 - 2
3) 0.4
16 203 24 2 3
04
ANL FATTACK (DEQREES) 2 I 0 2 6 3
Figure 28a Canard C2 on 50-Degree Wing
a , I0 4 a 12 4 a 12 4 a 12 1s 20 24 2 B 32
ANGLE OF ATTAI.CK (DEOREEB)
Figure 28b Canard C3 mi 50-flegrBee Wing
2,
rEI Figure 28 (Continued)
0A
4~000
M2 - .01
0 4 0 0 4 6 12 16 210 24 26 32• 36
,,ANCILE OP A1'TACI( (OEUF10U•8
F•igure 28d - OCanard COon 50-Dgree Wing :
I
0 ,000
ii0 23--
- ANGLEO A.TTACK. (DEUMI "
Figure 28dL - Canard C 0 n 25-Dgres Wing
""8
• • • ,,•. :•... < "•r•• :•"'••' w'-- "•' lt L• .• "JM • ::•4•, ,:•,i • .•.q•¥•;• :-:••. b••.:l• •; • ,.:-•... .- .0,
Figure 28 (Continued)
0A -I: ~0.3 / -
~.0200
0,2•.1 'A
I t I I I Ia 4 8 12 1 0 24 m a
ANGLE OF ATTACK (DERESI)
ligurw 28f Ci.nard C2 on 25-1IXgr-e Wtng2
0,.4
(2)
0,10
0 II 1 24 32,., ANGLE OF ATTACK (DEUREES)
Figure 2Hg - Cniird C2 on 25-Degree Wing
39
the 25-degree wing configuration. The data are for Lhe four canards at 0-
degroo ronivrd dcf lec tion. III gene.ral., the inc rementa I moments behave as
iexpu Li Ld ;I t low itng I es oF at t ac k, that Is, moving the canlard forward in-
(r'I Lhe hibi' itii nt~a momtflt I or ;i I coot igurahIlotlS4. At higher angiles
of attack, the effectiveness of the forward position drops off and the
incremental moment is Often l~ess than that generated by the canards at fur-
ther Lift positions. This is shown in Figure 29 where incremental, pitching
Figure 29 -Variation of AC with Canard PositionM32
0.5 P7 pl,2,3
04- P4,5,6
0.3
0.4
0.3
0.2 I I0.9 1.0 1.1 1.2 1.3 1.4 1.5 0.9 1.0 1.1 1.2 1,3 1.4 1.5 *qo/-Uka/I
Figure 29a - Moment on a 5O-Degree Wing
40
F 5 __F_ I" ýIj gtrV2(CO I II nued)
010
0.24
0.3 . . . . . .
LV . g'rv 29~.b - )MV 1ilt. on a 29- Dug tLL WhI I
iiihl~utlit 1I 32-cdogrec' aiig I of LiILacLk 1,4 prusuanud . Anq heýu tic un, maxhi.min
IL [nremnwita I 1Moment OC'Cllr aL 0 IleMooL 1"orwaid powlL ion III 01n]y 0111. CALin
Llinit rcdi.u bo lug Llhe 60-dug rec duIe.1.1 canard C I0Oc~ ed II tho hlug lenL mooLl
For-wird poii)IP V M1X II'll 11unwimc.L In genural. OCcULITUC AL 1) for 11on CI
contig~r(.101 ne 011Ce [XUIIon to) lue ulu iiWas the 25-dugruu high aspeet
ratLi 0 canard C' whe rv minx imum momeicaL occur-rud In the ,[owumL most L )0H1N.1 -F ~Li on.* It [El In Le rvn ig Lo coniliiii cj lt hip the Flicof00Vii r t~t-11 (o31' l I ii]InIiiii
.lift ýoo ff1 ci nvt with unnoa d pansition sholvi II u F Lgurv 10 "Ind the, 11bul'var VI.-
iaLI COf 1 .ncerLemuulta.I 10MoiLllt .1.11 h Lbul Inn LIA1CUN L110 HIMlICHil 0o LAhe CurIIvL'
for uachI canard airo uxt rQt'me. S 1.11111,1r * T1IHa It appen rs Ltm L It IN thle A1 1.1. L
bu Ing gune rat:uid by thV L'Olan~t ri L ir than L he abso Latc oanard rl posi-L oil
which Is the primary do L-vrmlfn lg [actor ail the vmlumeo L gfunerated.
Re turn Lug Lo F'tgure 28 fL bi Heun tha t thW .InlI'' rilWietA It.Lp [LelLg 11101i1011
81.0 ) )C. I sl r eLi Ho nLI a .y I I i lu ll r w t I t1 41 ng.1. of 1 11 m i aIt u1Ll.I Ii to nlg 1. u i. f i at La i I t,
app ruximaituly 8 degrteus. ThIN vor: ation of ine.rumenL.u . plitching momilenlt
shlopc Is prc.Henteil II' Figure '30 f'or both 2'j- nflid 50-de0gree iilUdc.I N. III roi-
t rant wILhi the molonunLt data aLt 32-dog rue itngle of a L Lak , t iO voirint ion of
4 1
ACM hilhaves in a linear manner, In that increasing moment arm increases
incremental pitciliing momlnat slope. As noted, lowering the canard rLduces
t he slope sli -;t'lv, T h'h dati from F igure 30 show a varying degree of slope
change with canard shape as expected, due to the diffcrence8 in canard lift
curve slope ard canard exposed area. The data from Figure 30 have been
divided by the isolated canard lift curve slope and plotted in Figure 31.
against canard exposed volume coefficient.
The plotted data fit a straight line reasonably well, thus indicating
very little upwash with canard position and that the linear approximation
C X V is reasonabl2i at low angles of attack.•T
Q.02 0 25-DEGREE WING r2
"" . % eS~Ij- ZC 2
0.02 -
I0.01 0
/C3
o . I t I I I , I , I I
0.9 1.1 1.3 1.5 0.9 1.1 1.3 1.5
Figure 30 - Incremental Moment Slope Variation
with Canard Position
42
I = "". .,
0.3 FLAGGED SYMBOLS 25DEGREE
WING BASED ON POSITIONS 1,2,3
0 co '
VC1
I Dcl
0.2 C2C.
0.11olm
00.1 0.2 0.3
VCe
Figore 31 - Correlation of Neutral Point Change w:ithCanord Exposed Volume Coefficient
DEFLECTION
The vatiation of incremental moment with canard deflection is pro-
sented in Figure 32. Data are presented for both 25- and 30-0egree sweep
models and the four canard shapes. The canards are located at Positions
Sand 6 and the deflection range is from -10 to +10 degrees for the 50-
degree mode] and -10 to 0 degr.ees for the 25-degree model. When The ca-
nards are located in the high position P3, there Ls little change in incre-mental slope throughout the deflection range. An exception to this is the
25-degree high aspect ratio canard C3 at low angles of attack. This canardhas a varying incremental slope which is progressively reauced with in-
creasing canard deflwctiun. This reduction in slope is due to stall of
the canard.
43
-' .n- a ,1
FI gorc '32 -I IUL MVentalJ. Moment Change due to(Xi iird 1h' f 1.ct ion
0.4 +. __ _ _ __ _0___ _ _
II.
S0.2 01
I~.j
0 4 a 12 16 20 24 28 3ANGLE OF~ ATTACK (DE(AREES)
Figue 3a CaardC 0 an 50-Dogree Wing
0,2
U.4 ,
.0 .
UI;,0,10
0.10
0.1 0 01
A oL p 01 ATAK(LPHE 1
Vigure~ ~ ~ ~~~~d 32 0nrdCo S-I0ge~W
44 1
FI igure. 32 (Corit Inued)
0.1
1-1
00 a
Figure 32d00 - -~nr --n 50 e inG
450
Figure 32 (Continued)
-~L.0,3
0.10
0.2 ~ ~ - 00.0000Cow o o0
0.0
0 4 0 2 1 0 2 8 3
ANGLE OF ATTACK IDEGREBS)
Figure 32c Canard C2 on 25-Degree Wing
A, (DOAR46
,'lgtirV '2 (Continued)
wo 0,- - d '- je m mqm m iam
.. ___ __ __ __ __I __ __ __, ___.__ __ ___ __ __ __0 4 . 0 4 .2 12 1 20 24 do 32
.,ANGLE OP ATTACK (OEORME8I)
Figure 32g - Canard C3 on 25-lI)egree Wing
While the data indicated little change in incremental moment slope
with deflection at Position 3, this is not the case at the lower positio•n
P At this position the inc~remental slope is decreasing with Increasingdeflection angle indicating that the interfer~ence between canard and wing
is no l~onger favorable or that the canard is stalled. This decrease, inmoment is seen more clear~ly In F~kgure 33 when incremental pitching moment
at 32-degree angle of attack is presented versus canard deflection angi.l~,i
At the high position P3 incremental moment increases with canard defloc- .
tion, however, at the low position P6the converse is true. This is most•notable for the 60-degree canard CI, and for the 45-degree high aspect ;i,
ratio canard C2. These canards have a reduction in incremental moment sL -
positive deflection angles. Similar trends were noted for the incrementol '
lift at 32 dlegrees due to deflection presented in the previous section,U The incremental lift presented in Figure 14 showed a reduction inlift of approximately 0.28 due to a positive 10-degree deflection for the
60-degree canard at P6. The incremental moment, however, does not indi-
cate a change of this magnitude, for, if all the incremental lift were due,
to the canard stalling, the expected change in moment would he AC1 * i /c
47
N
t
L
I I•J I ° /-
too
-LLc
48
}:~
-I'-.4'
NI %( ,�
0I4
I I 11� w/ ,�
I If' a�
I I H �S -�
- a a = - S Cd
rc�II Nj "1
(III II /1
'I 7/ S� ,�
I 8
49
or approximately 0.28. Thus it appears that while the canard may have
suffered a slight reduction in lift (hence a reduction in moment) the major
I s -8 or I Ift Ls on tili' wing.
'the variation of control power C , with angle of attack is shown inM6
Figure 34 for both 25- and 50-degree wing models. The data are evaluated
from 0 to +10 degrees and from 0 to -10 depreeos.
At P3 no significant differences in'C occur if the value of C is3 M M 6
computed from either positive or negative deflections, although differences
do occur at low angles of attack for the 25-degree sweep canard C3 which,
as noted is due to canard stall. More significant differences occur at P6.
At P6' CM is higher ihen computed with the negative deflection than with
positive, thus indicating a possible canard stall. In general, there are
only slight differences in control power between the 25- and 50-degree
sweep models over most of the angle of attack range.
Control power was not as sunsitivw to canard position for the 25-
degree wing model as was the 50-ddgree sweep model. Control power for the
25-dogrw Hwvwvp model was bas.'d only on negativw deflection and thus the
IinfluVelce Of positive defleut•lon is not known.
WING LLADI.NU LAGE CFIANUJZS
Tlhe effect of a -9-degree leading edge droop on the 25-degree wing
model is preiiented in Figure 35. As fur the previously discussed lift, the
-9-dagree droop delays stall of the basic wing by approximately 4-degree
angle of attack. The incremental moments due to the canard, presented in
Figure 36, reflect this change in staLl hecause In the region between 8 to
20-degrce angle of attack the canard, located on the normal wing, has a
tslight increase in incremental moment when compared with the drooped leading
edge configuration, This increase in moment is not as large as that. which
would be expected from the incremental lift data, i.e., AC - AC /N L iC,
thus indicating that the primary moment change is due to delay of separAtion
on the wing rather than a lift increase on the canard.
50
........................................- ]=,.-R-
Sm ODEGREE DROOP0.101
0 4 8 12 18 20 24 28 32a, ANGLE OF ATTACK (DEGREES5
Figure 35 - Momont Characteristics of Basic 25-Degree Wing
cand 25-Degtee Wing withl -g-Degree Droop
DRAG
The primary aerodynamic influence of the close-coupled canard iA to
delay separation on the wing. This delay in separation results in a size-
able reduction in induced drae at moderate to high angles of attack. Thimreduction in induced drag is seen quite dramatically in Figures 37 and 38, ,
Figure 37 presents the variation of drag with lift coefficient for
the 60-degree delta canard C1 , the 45-degree high aspect ratio cninard C2 ,#
51I
z 0.3
-- ODEGRqEE D~ROOP- --- 9.REE DROOP
02
a.;p
000j
20 24 23
~,ANGLE OF 4TTACK (DEGREES)
Pimure '36n - iomition 3
S 0.3
0.2 0
0 U. 00
0
4 12 16 20 24 2 32~cl, ANGLE OF ATTACK MEGREES)
F~igure 36b - Position 6
Fi1gure 36 -Incremental Momun~ts duv to Cainat~d onBasic and Modified 25-Dfegree Wing
52
1.48 wc
1.0
I:: 25.DECIREE WING
0.4
0
0 0.1 0.2 0 0,1 0,2 0,3 0.4 0.8 0,6 0.7 0,e 0,9 1,0CD, DRAG COEFPICIMT
FLigro 37 - ypLcaL Dlrag CharntcteristicH
25- e.nd 50-degree mweep models and the canard is locatud at P 2. As seen in]
the figure the canard coilfigured vehicles have lemm drug at l~ift couffi-
rwspectivL'ly. F'lgUrr 38 prCL1LINt the correspondIng vnriutlon of lift-Lo-drgrati-o versus Lift coeffirient for the data presented In Figure 317, At4
noted in the figures, there is a decrease in maximum l~ift-to-drag ratio
(L/D) when the canard is installed. The magnitude of this reduction it-,max(L/D) in a function of ctinard planiform, position, and de'flection. ThLc
maxinfluence of tnese parameters on lift-to-drag ratio and induced drag wil~l
be discussed in the following sections.
9
8 - W1'C 1
14
i-J3,
2
1 I
-0.2 u 0.2 0.4 0.6 0.8 t.o 1.2 1.4 1.6
CL, LIFT COEFFICIENT
Figure 38a - Lift-to-Drag Ratio for a 50.,Degree Wing
14
CW3
12 Q 0 W2+CAwg•c
10- w2+C,
2 S" /C/ /C
L 0, 1 .... I , I .... 1., t I L
-0.2 0 0.2 0,4 0,6 0,8 1,0 1.2 1,4 1.6
CL, LIFT COEFFICIENT
Figure 38b - ,.rL-to-Drug Rat Lo for a 25-flegree. Wing
N.1gure 38 - Typical. Lift-to-Drag Ratio Characteristics
54
"---. .... ..,Q 0, ------ ---
SIZE
The daL-ta alV labl,, on thL1 Vffec t of carnard sixe noi drtig, nrL' HOtllIt411t
L imited. 0111y MW, WfilM -tt ull. [I 'Q rogoi; it I'INSII)MC Uva tI tiL('d ',iii;Ird 0IV,
as a parameter and the angle of attack was limited to 20 degreus, Slgnl.l 1.-
cant data regarding drag was obtained only with t:he two largent c•inards
having projected area ratios of 0.20 and 0.25. Certain trends, hIwvver,
can be obtained from these data. The first trend noted is the b3haviorof the drag developed on the canard due to deflection at zero lift coeffl-
cient. Figure 39 presents this variation of drag versus deflection for the
two canard sizes. As indicated in the figure, rhe shape of C0 veraus de-
flectLon Is approxhI [rt ly parabol[.c in shape suggemtLing that the da•t may
be analyzed in tho form of GD ( + K (C)2
Utilizing the zero Iift moment data due to dot -ect ion and dividing by
the correspondtrng canard diStaMcV ratio, GL 6 has been obtained. The vanr-
ation of C D with (G L )2 Im presented in Figure 40, Data have buen refur-
anced to the caniard LVXl1 Mx.d area. Vor up to approximaitely 1.5 dugrues dQ-
flection, tihe dati approximates a linear fit. At deflectLon LilgloUs grvaLur
than 15 degrees, the slope becomHs Steper indicating canard stall., It
thus appears that as with the incrementa.l. lift anid moment, drag duu to the
canard is a function primarily of expUHed area ratio rather than totnol aroa
ratio, This is further verified by Figure 41, which preseats t0he wvritat:ion
of aircraft lift-to-drag ratio at a lift coefficient (if .1.0) versus exposrd
area ratio. As shown, t~he change is linear albeit based on only throch datat
points, Data, however, from the 1'-4 •ircraft where can:vrd expoesed rut los
of 0.05 and 0.10 wore voaluatfed a1.s) exhibit this increae Lin I i
ratio with canard exposed area ratio. Thus, for at lertst up to 20-deg1ree,
angle of attack., a l.inear increase In l.ift-to-drag ratio with caeard vx-
posed area ratio appears to be valid.
55
W w
'P2
. P5 P1 P3P7. ... . P4 -, pe
0.06 /
0 M42--
CLEAN
0 5 10 15 20 25 0 510152026 0 5 10 15 20 25b, CANARD DEFLECTION 6, CANARD DEFLECTION 6, CANARD DEFLECTION
ANGLE (DEGREES) ANGLE (DEGREES) ANGLE !DEGREES)
Fig-tre 39a - Drag for a 0.20 Ca,,
P2
-P' P1 P3
P- P4 P_
0.00
==0.04 •
0.02
0 5 10 15 20 26 2 5 10 15 20 25 0 5 10 15 20 256., CANARD DEFLEM.TON 6, CANARD DEFLECTION 6, CANARD DEFLECTION
ANGLE (DEGREES) ANGLE (DEGREES) ANGLE (DEGREES)
Figure 39b - D-ag for a 0.25 Canard
Figure 39 - Effect of Deflection on Zero Lift Drag CD DI56
-..------- .--~--.-.- - - --- ~ -j
0.40 Sc/Sw a 0.26
O" S/S 0.20 I0.3 BASED ON TOTAL
EXPOSED CANARD AREA
0.2I
0.1 10 0,1 0.2 0.3 0.4 0.5 0.6 0.7 0.8
(CL5 6)2
Figure 40 - Variation of Canard Drag Coefficientwith Canard Lift
3 P 3
0 7 WING BODY
LIFT COEFFICIENT - 1.0
0 0.02 0.04 0.06 0.08 0.10 0.12 0.14 0.18SC/Sw
Figure 41 - Variation of (L/D) with CanardExposed Area Ratio
57
SHAPE
The effects of canard shape on maximum lift-to-drag ratio (l,/D)max and
lift-to-drag ratio at lift coefficients of 0.b, 0.8, and 1.2 are presented
Sin Figure 42. Lift-to-drag ratio is plotted versus the quarter chord sweep
angle of each canard 25" Data are presented for both 25- and 50-degree
sweep models, The tanards are located at P 3 at 0-degree canard deflection.
Also presented in the figure are the correspondiog lift-to-drag ratios of
the individual wing-bodies. Maximum lift-to-drag ratio is lower for the
canard configurations than for the wing-body alone for both sweep models.
This is to be expected since a penalty must be paid for the zero lift drag
increase due tu the canard. The penalty in lift to drag varies from 9
percent to 15 percent for the 25-degree wing model and from 4 to 7 percent
for the 50-degree model. These losses in (L/D)max can be reduced by proper
placement and deflection which will be discussed in following sections. As
angle of attack and thus lift coefficient are increased, the canard config-
urations have better lift-to-drag ratios than the basic wing-body. The
lift coefficient where this increase first occurs is approximately 0.7 for
tho 25-degree wing and 0.4 for the 50-degree wing model.
At low lift coefficients C < 0.6 the loss in lift-to-drag ratio isL
clearly a function of the quarter chord sweep angle as shown by the linear
variation. At hIgher lift coefficients this is not the case because the
amount of variation with canard quarter chord sweep angle is minimal for
the 50-degreu wing model. The canards on the 25-degree model exhibit a
nonlinear behavior with canard sweep angle at a CL of 0.8 (a w 10 degrees),
L/D increased with decreasing sweep angle up to X of 40 degrees and then
decreased. This behavior is due to the early stall of the 25-degree canard
C3 when located on the 25-degree wing model.
The improvement in lift-to-drag ratio is due to a reduction in induced
drag. Using the definition of drag as
CD C + K C
D~ I LO.L
CL
58
IJ_-.-
25.DEGREE WING
13
L/DMAx WB
12
50-DEGRE t WING
L WING BODY
10 CL 0 'B WB W
9C L -0 -8 W F ,,• •.•,, '', •..'. . . . L/D M A x ,
e o -L/DMAX 9
C,7 7
"CL Os 0W ,CL 0'a
63 CL
CL~C 1.2BWB,
2Oc ClC3 c ?). C2 l , C012 C1
20 40 60 0 20 40 60
A, SWEEP (DEGREES) X, SWEEP (DEGREES)0.25 CHORD 0,21 CHORD
F i g~ u re 4 2 - L if t- Lo - D ra g [Ra L :Lo V a.rl a.t'.lo n w i th C n aa rd S ha pe -
59?
Figure 43 has been developed foir the four canard shapes on each model as
well n; each wing-hodv. The val ti l (i C T is approximately zero for each
tont i tIrat ion. At the value 0f CL [or (L/D))mx (c• '% 4 degrees), the in-
duced drag factor is higher than the basic wing-body for all configurations.
This is due to the unfavorable interference of the canard on the wing.
Then the angle of attack is increased, the canards have a lower induced
drag factor than the basic wing-body. This reduction occurs at an angle
of attack of approximately 8 degrees. No strong influence of shape on the
induced drag factor is seen for the 50-degree wing model,
Shape does influence the induced drag on the 25-degree wing. At low
lift coefficients, the 25-degree canard C3 had the lowest induced drag and
the 60-degree canard CI the highest. As angle of attack is increased, their
trends were reversed and the C3 canard had the highest induced drag and the
C1 canard the lowest.
POSLTiON
The eflect of canard position on maximum lift to drag ratio (L/D)max
and lift to drag ratios at Lift coefficients of 0.6 and 1.2 are presented
in Figure 44. Data are presented for both 25- and 50-degree sweep models.
Shown for eaich canard is the position where the canard exposed root trail-
Ing edge lnitially overlaps the exposed wing root leading edge.
For all configurations maximum lift to drag ratio occurs at a position
forward of" the exposed overlap position. In general the maximum value oc-
currud at P2, however, the 60-degree delta canard had a maximum value at P
for the 50-degree wing model. Lowering the canard reduced (L/D)max except
tL the cNIsu iof the 6(1-degree canard as mentioned above. A comparison with
dota for the basic wing-body shows only small losses in (L/D)max for each
canird if the canard Is at the optimum position. These losses in (L/D)max
were on the order of 3 and 7 percent for the 50- and 25-degree sweep models,respecLLvely. As Lift coefficient is increased, canard configurations have
Less drag than the basic wing-body for the 50-degree wing model. LifL to
drn; ratio In still optimized at positions forward of the canard wing over-
hip. As wlth, ([,/I))mx, lowering the canard reduced the lift to drag ratio.
Oigue 43 ,
0.H
0,7
CAI
D. . .| 10 1 ,4 N.N
0.6
CL., LIFT COEFFICIENT
Figure 43b - Drag for a 50-Degree Wing
G .9 o] .
0.1 '
! 0P3
0 I l 1 1 ,,' 0.4 0A8 O , , 1,4 1.0
UtL, LIFT COEiFFICIENI'D
Figure 43a Drag for a 25-Degree Wing
16
C, •
i'tgurl2 44 -LI f L-to-Draig Ra"tio Variat [nWI Lf) Canard Posi8tion
1,2,3WING BODY
- - -4,5,0CANARD-WING OVERLAPL 37
CO9 19.0 - - w
8 - WO wo.
7 7.0
OCLfO 0, L '6 (86.0cc~
9 0
4 - co t4.0 (1
3 L-1.2 3.0 -
2 2.0 -CL .2
0.0 1 1
019 1.0 ill 1.2 1.3 1.4 1.5 0.9 1.0 1.1 1.2 -1.3 1,4 1.5
[U gurc 44a - Canard G on Figure 44b -Canard Co5 fl-Degree Wing 5 0-Degree Wing
62
Figure 44 (Contl-iued)
1,2,3 " WING BODY" P4 ,5, 6 CANARD.WING OVERLAP
SP7
10 10
-9 9
Fiue4 e- Cnr 2onFg r - Caad-3o
4A1
3 63
2 2
0 -- 01-I I0.9 1.0 1.1 1.2 1.3 1,4 1. 5 0.9 1.0 1.1 1.2 1.3 1.4 1.5
Figure 44c - Can rd C on F~igure 44d - Canard C on50-Degree Wing 250-Degree Wing3
63
..............................
Figure 44 (Continued)
P,3 3 WING BODY
O P6 CANARD.WING OVERLAP
WB L/Dm"
12 ~ I..DMAX
CL
/ /C3]
i 8 0 ,,
.c~
2.1
ii 4 -
S~CL - 0 ,e8
C' 0NOTECL 1,2 NOTOBTAINED ATPO .SITION 2
0.8 1.0 1.2 o's 0, 10 1,2 0,8 10 1.2
Figure 44e - Canards on 2 5 -Oegree Wing
i 6
6 4 :
.:i . . .. . .. . = .i i • ..- ... - --- -- ------ ...- --V-WR-ZR'• • - • •¸' ' •
At CL 1.2, only slight changes occur in the lift-to-drag ratio, the loca-
tion for maximum value of L/D has, however, moved aft of Lhe overlap Junc-
ture. Lift-to-drag ratio at this C tended to be lower at the forward and
low positions.
The effect of position on the minimum drag coefficient C0 is presented
in Figure 45. Position has a minimal effect of C but moving the canard
and downward increased minimum drag. 0
As stated earlier the major effect of the canard on drag is to reduce
the induced drag component of the total drag. The effect of canard posi-tion on the induced drag factor KI, is presented in Figure 46 for the 50-
degree model. The influence of canard position on induced drag is somewhat
dependent on canard geometry. The 60-degree delta canard C1 has the small-est change in K due to position. Minimum K1 occurred at P over most ofthe angle of attack range.
Moving the canard aft increased induced drag. The three other canards
show a greater dependence on canard position. Maximum induced drag occurredat the most forward positions P1 and P4. Minimum induced drag occurred at
P2 for the 45-degree sweep canards C0 and C2 and P3 for the 25-degree canard
C 3 For all canards lowerlng the canard increased the induced drag factor.
Figure 47 presents similar data for the 25-degree wing model. More
variation of K1 with position is evident for the canards on the 25-degree
wing model than for the 50-degree wing model. At low lift coefficients K
did not vary significantly for the 50-degree model, whereas for the 25-
degree model these differences are more evident. At low CL P2 clearly has
a lower induced drag factor for all three canards. As lift coefficient Is
increased the induced drag factor at P increases to larger valijes than2
those obtained at Positions 3 and 6 for the 45- and 25-degree canards, C.
and C3. and Position 3 for the 60-degree canard CI. This increase in K
was relaLively large for both C2 and C indicating a large loss in effec-2 3
tiveness of the canard at P The increase in K for the 60-degree canard
was relatively small. Over most of the angle of attack range evaluatod,
lowering the canards to position P6 increased the induced drag factor.
65
0.02 -• - --- -•_ _ __ __ _=- - -'
V 13
0.01 ,:aC p
MV{EGRIE WING
0.02 _________
0
II I I I
0,9 1.0 1.1 1.2 1.3 1.4 1,5 0,9 1,0 1.1 1.2 1,3 1.4 1,5
0.02 - _______
-, m a, -, 4 a
0 L I I . .p
25-DEGRfEU WING0.02 p
wepe•/ W8N
j 0.0 I I I
0.8 0, 9 1.0 1.1 1.2 1,3 0,8 0.9 1.0 1. 1 1, 2 1, 3
Fi1 00gure 45 - Effect of C.mird rloitihn on Minimum ,, ng Coeff-iient
ii Z•/ilI/I//r/f/fl// WE •/II,///z//'//H,/H~//b6W
Av 'tý -aFigure. 46 Induced Drag F~actor Variation with Canard
Position for tha 5O-Degrem Wing
0.4 ICAidAt4
0.2
0 00 0.4 nfl. 0A I. .O 1 2 1. 1.8CL0. UrTUM CIN
Figure 46a -CanardC
0.3 - --
Ug -
01
0 Cýt
0.1 D M 01".CI.
11. 1A 1. INI0(:L 0400 001? CIE11
r •
Figure 46 (Continued)
Q.5
03
j !2 D U:o 0.1 1" j 1*4 1,0
Ct, LIF T tCULPPICILNI
lFigure 46c - Canard C2
or
0.4
. I , ,
PM, 01"C .i T I I t I
Figure 46d - Canard C3
68
0.6
0.5
0.4
• 0,20,13
p6
0.2
01,1
0-
0.1
I L I I Io 0.2 0.4 0.6 0,8 1,0 1.2 1,4 1.0
CL, LIFT COEFFICIENT
Figur., 47 - Induced D)rag Factor V.riaition with CGnnrdPosition For the 25-De1gruo Wing
69
=MO .
Figure 48 indicates Lh1L minimum level of induced drag obtainable for
ecwh canard. The fivure is a Locus of the minimum induced drag factor
bas (I io ll' canard posit ions. Miininum induced dr;/, ka 1'btali:cd foIr tic
25-degree ciirard at low lift coeflicionts for both research models regard-
Less of canard position.
The 60-degree canard iad the highest value of induced drag at low lift
coefficients and the lowest value at lift coefficients near (C L)mx. T.e
Intermediate canards C0 and L2 have values between the 25- and 60-degree
canards. Thus, for goou low llft performanct! characteristics, i.e., range
and enduratnce, the low sweep canard Is best. When maneuvering capability
is; the dominant design factor, the highly swept canard gp.nerates the best
performance. The Intormediate canards are good compromises having lower
Lnduced drag 1han tile 60-degree delta at low lift cOeffic Lnts and slightlV
higher values of induced drag near maximum l ift. ExaminaLion of the figures
naoicates that while the range of Induced drag between the 25- and bO-degree
canards is not large for the 50-degree sweoip mo'-el, large differences in
induced draig pIus the peor stL:',l characteristics ux. ýbitad by the 25-degrec
canard preclude its use on tLhe 25-degree swept wing model.
Dh, IECTI ON
PossIt i ve caard def Iect ions ri:duce (L/D)1X s igni f icanitly, wh,._reas
small negative deflection improves (1/D)ml * This bch.iv.i or is illustrated
I.n Figure 49 which presents the varia-ion of lift-to-drag ratio versus ca-
nard deflection. DaLa are presented for Positicnv 3 and 6 for a canard
defl-cciion range frow -I( to +10 degrees in 5-degree increments for the SD-
aegrec 'WeLt IrOdc I and at -10 and 0 degrees for thlc 2g-,logree sweep model.
At btoth positions and for all canard S.a;lO;es, a l()-degvre deiflect[un
claUses a loss in (I,/D) of approx matel 40 percent. The ititliuenco ofZl.I~X
nc-gattivi canard deflection oi (LI/D) Max varied somewhat with canard posi-
ton 11nd shapc . For nearly all configurations on the 50-degree wing model,
a cans rd - leOction of -') dcgrees increased (lI/D) MI. lI'e sole exception
Lo Li, is was a sl ight decrease iii (LID)MAx when the 45-degree high aspect
riiti I rinar(I C2 waa; at 11
)70
0,6
321 INCRIEA&INCANARD LEADING0.5 21EDGE SWEEP
0.4A
S0.3
01
S0 WEI
0.1 0 c.
00C
CC,
0.4 2 0.4 0. 0.8 1.0 1.2 1.4 1.6 1.eCL, LIFT COEFFICIENT
Figure 48a -Drag for a 50-Degree Wing
06-
, 0.4
0.2 INCHE CA LzIINCESN A~U I SWL
0 0.2 n,4 0.6 0.9 10 12 1.4:L, hF r COEPFICIENT
FigurLe 48b - Drag for a 25-i)grec Wing
Figurc 4M - Iocus of Minimum Induced Drag F'actor
71
Ft gurc 49 L- ft-LO-Drag Ratio Var Lat ionwi t h Canard I)ef I uv ti on
•.• L/DMAx WING BODY
10 10
I B L/DMAX88 8 - ' 8C)7 0 7
-- ix 6CL O.6
CL 0-0
0 0 c,4 4-~
CLI
2c2 - .2
" 0 2 .I 2 - P___-10 .0 10 -10 0 10
Sc, CANARD DEFLECTION 6C, CANARD DEFLECTIONANGLE (DEGREES) ANGLE (DEGREES)
Figure 49a - Canard C on Figure 49b - Canard C on50-Degree Wing 0 50-tlegr e Wing 3
IL
72
2111H I
Figure 49 (Continued)
10 10
___________ 9 -,L/DMAX
U -- •' "WING BODY
weo
3- 3
2 62
-10 0 10 -10 0 106c, CANARD DEFLECTION bc, CANARD DEFLECTION
ANGLE (DEGREES) ANGLE (DEGREES)
Figure 49c - Canard C., on Figure 49d - Canard C on
50-Degree Wing 50-Ihegree Wing
14
13 L-UMA%- WING 3ODY
12
iii A °"10
0 ,.........
C, C
2-
2 !
.10 0 -10 0 .10 0
A,, CANARD DEFLECTION ,• CANARD DCFLECTION A , CANARD DEIFLECTIONANGLI IDIOM$1) ANGLE InEGREM ~ ANGLE MDURFE81
Figure 49e - Canards on 25-1h'gree Wing
73
A deflection of -I0 degrees caused a reduction in (L/D) for all
maxcanards with the 0x-teption of the 6U-degree delta canard C1. On the 25-
degru.e modul, negative 10-degree deflection caused reductions in (L/D))Mx
tor LlieU 25-dugrou C;i nard at both pusitions. The 45-degree high aspu•ct ratioI
canard C2 and a slight increase in (L/D)max at the low position P 6 and a
decrease at the high position P3' The value of (L/D)max was increased for
both positions of the 60-degree canard %ith negative deflections.
With Increasing lift coefficient the effect of canard deflections be-
comes less dramatic, Positive deflections still cause reduction in lift-
to-drag ratio yet the magnitude of these losses is reduced. Lift-to-dragratio w'is improved by a negative 5-degree canard on the 50-degree swept wingmodel.. Canard deficction had only a small effect on lift-to-drag ratio at
maneuverIng lift coefficients (CL>1.O). Slight losses do occur, however,
due to positive deflection. Negative deflections had little effect on L/D
at C[ - 1.2 on the 50-degree model. Negative deflections had a detrimental
eff'ect on lift-to-drag ratio for canards C1 and C2 on the 25-degree model.
'1h1 1 Lft-to-drag rat to wag slightly increased for the 25-degree canard C3
(in this model.
The losses in (l,/D) and L/D occurring at positive defluctions are
due to an increaue in minimum drag and an Lncrease in the induced drag fac-
tor KI. The slight gain in L/D uccurring at negative duflections is duL to
a decrease in The variation of C with canard deflection is shown in
Figure 50. The curves are roughly parabolic in shape and the minimum value
in general. occurs at 0-degree deflection. The curves, however, have a
slight bHas in that the drag coefficient for negative values of deflection
Is, In general, slightly less than that of the corresponding positive do.-
f lection. 'his bi.as may be due to the downwash of the canard when posi-
tively deflected causing an increase in drag of the wing.
the effect of canard deflection on the induced drag factor (K1 ) Is
presented in Figure 51 for deflections of -5, 0, and 5 degrees in the 50-
degree sweep model and -10 and 0 degrees for the 25-degree sweep model. As
IndicaLed In the figure a postLive 5-degree deflection increases induced
drag signiflcantly over that of the basic wing-body at low lift coefficients.
74
- - ~- -~- - --
0.03 .-- P3• /
0.02
0.01 c
0 1 L, .I I. I .-10 0 -10 -10 0 -10 -10 0 10 -10 0 100c, CANARD0 DEFLECTION 0 c, CANARD DEFLECTION ",, CANARD DEFLECTION1
ANGLE (DEGREES) ANGLE (DEGREES) ANGLE (DEGREES) ANGLE (DEGREES)
Figure 50a - [)rag for a 50-Degree Wing
0,04
/3 P3_ -- --P| . BASIC
000 -10 0 -10 0 -10h., CANARD DEFLECTION h.,o CANARD DEFLECTION h.e, CANARD DEFLECTION
ANGLE (DEGREES) ANGLE (DEGREES) ANGLE (DEGREES)
Figure 50b -Drag for al 25-Degree Witng
Figure 50 - Minimum Drag Variation with Canard Defluction
75~
Figure 51 - Effect of Uanard Deflection on Induced Drag Factor
0.4
at
0 w
I I _.
I
i
i
O . 0.4 D' s I 1.0 , 1.4 1.6
CL, LIFI COEFFICIENt
Figure 51a - Canard C0 on 50-Degree Wing
0.9
0 A0 0.6 1.0 1 1.4
4j, UFT COMIPIUNT
F-igure 511 - inard C1 on 50-Degre Wing
76
_ __
__
__
Fiue51 (Continued)]
0.4 32J
0.2 0, . .
0.4 -
~,.IN
C3, LIFT COEFFICiENT
Figure 51.c C anard C~ on 5O-!Dugrue Wing
27
Figure 51 (Continued)
0.2 /
0,4 -
- ~ I
0,3 /0
-- I/
". 0,1 0
• //I
0 We ,
0.1 - o ooOi/
02
0,010 . -1o D I
,
0.1 ,do" • ow op -00lo0
0 ,02 0 0,2 0 0,12 014 Oe0, .8 O l 'O, 1,2 1.4CL, LIFT COIIFFICIENT
Figure 51a Canards on 25-Degree. Wing
78• . "h •I
V]
T1he canard is carryfng much of the t.oad at these lift coofficlents andcl
thus has s gnficaL I induced drag of Its own. in addiLtion, the downwashll
from Lhisi hiLgh loading [,n modify ing the load distrir butimn if tid wt! g iLW :i F-g
unfavorable manner. Lift is being suppressed on the inboard position of
the wing causing a nonelliptical distribution. With increasing angle of
attack the favorable effects of the canard become evident and ;he induced
drag factor is less than that of the basic wing-body.
A negative 5-degree deflection of the canards reduced the induced drag
factor to values below the basic wing-body and O-degree deflection canard
configurations throughout most of the angle of attack range. Positive de-
flection configurations had higher values of induced drag than the O-degree
canard configurations. At high lift coefficients only small differences in
KI occur for either positive or negative deflections when compared to the
0-degree deflection canard configuration.
Negative 10-degree deflections on the 25-degree sweep model reduced
K1 at low lift coefficients. Negative deflection caused an increase In K
at high lift coefficients when the canards were located at 1' 'Thie hin-rease
in K did not occur to any extenL when the canards were located at the lowerLL position nor did it occur to the 25-degree sweet) canard C3. A possible
explanation of this behavior Is that the canard trailing edge gap may le
too laLte and thus the favorable interference effect from the wing may be
diminished somewhat,
WING LEADING EDGE CHANGES
In the earlier section on lift, it was stated that wing ,ludhIig edgo
modifiL.cations can have a beneficial effect on aircraft performanco. The
increases in performance, in gennral, take the form of an Increase In .lift-
to-drag ratio and increases in lift and stall angle of attack. I icrease!4
in lift and stall angle of attack did occur for the 25-dogrec wIng modul.,
howevor, leading edge droop and radius changes and little eiffc.t 1on 1l1e
50-degree wing. Leading edge droop increased .Ift-to-drag ratio r'or both
the 29- and 5U-degree swept wing models. The variation in L/I) with li Isprvsented In Figure 52. Data are presented for a -9-dugre droop with and
79
Figure 52 - Effect of -9-Degree Droop on Lift-to-Drag Ratio
1.4
1.4
',0.6
0.4 %%
- BASIC WB
•m BASIC WB PLUS CANARD
0.2 -"9DEGREE DROOP
-9 DEGREE DROOP PLUS CANARD
0 2 4 a 8 10
L/D, LIFT-TO.DRAG RATIO
I0igure 5ýa - Drug of 50-Owgree Wing
8o
Ftg~iri 52 (Continued)
1.4
1.29DERI DROOP PLUS CANARD 0DGE
1.0
3
WB PLUS CANARD %4%~ -U-OOEREE DROOP
0.4
U.6
8 0 -g DEOPEE DROOP PLUS CANARD 6c 0 DEGREE
-c-10 DEGREES6
0.8S WPLUS CANARD %~Cl P3
0,4
0.2 6c -10 DE001E1S
0 2 4 a 8 10 12 14 1LID, LIFT-TO.DflAG RATIO
I1l.gurvi 52.b - rag of 25-Ikigrei Wing
.81 ...... .....
without the close-coupled canard install.ed. The data for the 50-degree
wing are based 0n the 45-degree truncated delta canard C0 at 0-degree de-
fI t''ct i[o ll ILoci t ed at I'P
The 60-degree delta canard Cl, located a P31 was used for the 25-degree
wing. The data are for deflection angles of -10 and 0 degrees.
Adding the droop to the 50-degree wing increased lift-to-drag ratio
for both canard on and off configurations throughout the angle of attack
range evaluated 4 < (i < 33 degrees. The incremental change in 1,/I) due to
the addition of the -9-degree droop is shown in Figure 53. At low lift co-
cfficients the droop improved the Lift-to-drag characteristics of the basic
configuration by AL/D ,1\.5 or approximately 14 percent. The gain in L/D
for the canard configuration with droop was approximately tO percent.
These improvements in lift-to-drag ratio remained fairly constant with in-
creasing CL for the canard configuration but were reduced for the wing-body.
The gains in lift-to-drag ratio due to the droop are far more impres-
slve on tho 29-degree wing model than those increases noted for the 50-
dugree model. Maximuin lift-to-drag ratio was increased rrom 12.5 to 14.8
when the droop was installed. The value of lift cuefficlent where (L/D) MIAX
occurred was increased for C from 0.3 to 0.54.
The iamoualt or increase in L/D due to the droop of the canard cont ig-
uritlon was dinepondnt on the canard dvf iection ongle as can be He0n In
Figure 53 which presents the change in L/D due to the droop for the three
configurationa. As shown, the gains in L/D exhibited by thc -10-degree
canard configuration are similar In shape and magnitude to those of the
basic wing-body. The zero degree canard configuration data has th saNme
gener'al shape as that of the -l-degree cAniard con figurati ton but the mag-
nitude or F the .increase INs ýignif.lcantLy small, r. A pialbl OI xpIl.anati n
for these differunces Is thatL the combination or the droolp and dOwnwnshI
froin the canard are having a detr, imental effect on the improvewd i ow cru-
antd by the droop. Similar rnsults were seen on the 11-4 when the inboard
Hi.at; and canaird were both IrisLaltted, 1')ef [iecctiog the cainard ngntfvL.*y,
8 2 .i
AL/D DUE TO DROOP DR 9 DEGREES2401
II0.3 0,5 0,7 0.9 1.1 1.3 1.5
CL, LIFT COEFFICIENT
Figure 53,1 - hllL f t Drnr' fuor 50-I1)uogrutu W.hig,
VVB C1P3, DR 9 DEGREES
fie -10 DEGREES
6
[ 404 0DEGR~EE\
2
0.3 0.5 0.7 0.9 1.1 1.3CL, LIFT COEFFICIENT
,' 1urc 531h - II'IL L0 1)r '0 1ur 2 5-1I)L'IuL' WIulg
Ilr tiro 539 - I tIrLI' 101n tilI Chliugu In 11 L -L-lriag Rnt 1uLIM! lo -11-lgrovu I)ruoop
83
.. . .........
however, will not change the wing flow significantly at low angles of a,-.
tack--hence, the similarity of improvements in lift-to-drag ratio for the
basic wing-body and the -10-degree canard configuration.
Thus it appears that it is possible to overdo the canard interference
at low angles of attack and the full performance potential of the canard
wing interaction will not be attained.
FLOW VISUALIZATION
The previous discussion presented in this volume has been based pri-
marily on force and moment data. A limited amount of flow visualization
data has also been obtained on the 50-degree sweep model in the angle of
attack range between 0 and 20 degrees. Tufts were installed on canards
and wing atid photographed with a motion picture camera. Results from these
motion pictures, at angles of attack of 10, 15, and 20 degrees, are shown
in the accompanying figures. The canards were, in general, located at P 6.
Sketches of the tuft directions for the basic 50-degree wing with
canard off are shown in Figure 54 for ct - 10, 15, and 20 degrees. At 10
degrees the basic wing has a region of flow near the body where the tufts
are in the streamwise direction (unseparated) and a leading edge vortex
which starts off the body. Increasing the angle of attack to 15 degrees
reduces the streamwise flow area and causes the wing leading edge vortex
to break down at approximately half the semispan. The outboard portion of
the wing is stalled. At 20-degree angle of attack the region of streamwise
flow is very small and most of the surface of the wing is in reverse flow,
The primary influence of the canard is to increase the area of stream-
wise flow (unseparated) and move the point where the wing leading edge vor-
tex begins outward. This increase in unseparated flow is seen in Figure 55.
Figure 55a shows the boundaries of unseparaued flov for the 60-degree canard
located at P6' Data are shown for canard deflection angles of -10, 0, and
10 degrees. Also shown on the figure are the corresponding boundaries for
the basic wing-body. As indicated, the area of unseparated flow is greatly
increased when the canard is installed; in addition, the vortex initiation
point is moved outward. The line of flow is approximately at the location
84
'AIIsI
Is
Lsm
411
ID 4-4
Lr
85
. .- -
Lu3'I
INIw *U
* wC3
LL
0
UU
LW wW to
an U
ItL6 8L
Ln
LU
Luu
LU.cc (DII'
LL
ccs-CD L
Cc t
87.
Lu
LU
LLI LIUA
U, u 0n
o A:
4- 4,4.
LUn
a4 z
bo,4r344*
gj I* I
S W U.*~~~ a. *.
88
of the canard tip for deflections of 0 and 10 degrees. Negative deflec-
Lions moved this location Inboard, whereas a positive deflection moved the
Iine outboard. rhe region of unseparated flow is relatively constant with
angle of attack for LhL 60-degree canard.
The same trend with deflection occurred for the 45-degree high aspect
ratio canard C and the 25-degree canard C as seen in Figures 55h and 55c.2 3
The separation point is, again, at approximately the canard tip but moves
rapidly inboard with angle of attack. Both of these canards exhibited early
stall on the upper surface and the region of unseparated flow tended to move
inboard as the canard stnll progressed towards the root. The 60-degree
delta canard did not exhibit any pronounced stall and the region of unsepa-
rated flow did not change to any great extent.
A comparison ul the three canards at zero-degree deflection is shown
in Figure 56. At 1.0-degree angle of attack the largest region of unsepa-
rated flow is due to the 25-degree canard with the 60-degree canard having
the smallest region. At 15 degrees there is little difference between the
3 canards. At 20 degrees the 60-degree canard had the greatest influence
on increasing the area of unseparated flow.
The 60-degree canard was also evaluated at PV Data from P2 are com-
pared with data at P6 in Figure 57. Moving the canard upward and forward
to P2 muved the vortex initiation point inwards, however, the surface area
of unseparated flow is relatively unchanged.The limited flow data are in agreement with the results obtained from
the force data in that the effectiveness of the higher aspect ratio canards
declines with increasing angle of attack, and that the 60-degree canardhas only minimal Loss in UffeCtIveness with increasing angle of attack.
SUMMARY
in the preceding analysis it will be noted that the presence of a
close-coupled canard modifies the aerodynamic characteristics of the basic
wing-body on which it is mounted. These changes, which are due to favor-
able interference, occur regardless of canard shape, size, position, or
wing planform. The aerodynamic changes consist primarily of an increase in
89
stall angle of attack and maximum lift coefficient, and a decrease in drag
at angles of attack greater than approximately 8 degrees. The extent to
which these aerodynamic improvements occur is a function of 'anard size,
shape, positioun, and deficction. A summary of the effects of 'he z'bov-.
parameters is given below:
SIZE
I. Changes in lift and pitching moment at low-to-moderate angles ol
attack (a < 20) are proportional to canard exposed area ratio S /Sw andSC We
exposed volume coefficient S /Sw * c/, respectively, for canards of geo-C W C
emetrically similar planform.
2. Neutral point shift at low angles of attack is proportional to
exposed volume coefficient.
3. Incremental changes in lift-to-drag ratio are proportional to
canard exposed area ratio.
SHAPE
1. Lift is maximized by high sweep canards X nu 60 degrees.
2. The incremental moment characteristics of each canard shape were
similar in shape and magnitude to the isolated characteristics of eachcanard.
3. At low lift coefficients, incremental changes in lift-to-drag ratio
are proportional to the quarter chord sweep angle of the canard for canards
of equal exposed area.
4. Induced drag factor is reduced by the canard
5. Induced drag factor was lowest for low sweep canards at low lift
coefficients and highest at high lift coefficients. High sweep canards
exhibit opposite trends.
POSITION
1. Moving the canard longitudinally forward and downward reduces
maximum lift increments.
2. Maximum lift increments occur when the canard exposed root trail-
ing edge Is slightly forward of the exposed wing root leading edge.
90
3. At low lift coefficients, moving the canard forward increases
increment~al moment. Maximum Incremental moments, in general, occur at the
sam vt' ) o t I o1n where max i mum I I f L occurs. 43(AcM)
4. At low angles of attack, incremental pitching slope - Is a
linear function of isolated canard lift curve slope multiplied by the ca-
nard exposed volume coefficient.
5. Lift-to-drag ratio was maximized at the same location where lift
was maximized.
6. Moving the canard forward and downward increased winimum drag.
DEFLECTION
1. Neither positive ncr negative deflections of the canard have any
significant effect on lift if the gap between canard trailing edge and wing
surface divided by canard span is greater than 0.1. Reducing this gap ratio
by positive canard deflection caused large reductions in maximum lift.
2. Similar reductions in Incremental moment occurred if the gap was
reduced. The reductions in incremental moment were not as correspondingly
large as the reductions in lift. These characteristics indicate a loss of
effectiveness of the canard on delaying wing itall.
3. Positive deflectioas cause a large increase in drag and a reduc-
tion in maximum lift-to-drag ratio.
4. The increase in drag with positive deflection is due' to an increase
in minimum drag and in the induced drag factor.
5. Small negative deflections (6c ' -5) can increase maximum lift-to-
drag ratio and reduce the induced drag factor when compared with zero-
degree deflection configurations.
6. The gains or penalties in lift-to-drag ratlo at large, lift coeffi-
cients C1 > 1.0 ýire small for either positive or negative deflections.
WING LEADING EDGE CHANGES
1. Increasing the canard-off stall characteristics of the 25-degree
wing by 4 degrees, delayed the favorable influence of the canard by a simi-
lar amount. Maximum incremental lift due to the canard was the same for
both basic and improved configurations.
91
2. Incremental improvements in lift-to-drag ratio due to installation
of a -9-degree droop were approximately the same for both canard on and off
configurations of the 50-degree wing.
3. A similar -9-degree droop on the 25-degree wing model required a
-10-degree canard setting to obtain the incremental improvement due to the
droop.
4. Neither droops nor wing leading radii change significantly modi-
fied the benefits in lift, drag, or pitching moments due to the canard.
ACKNOWLEDGMENTS
The author wishes to thank Stephen J. Chorney, John R. Krouse, and
Jonah Ottensoser for their help in obtaining and evaluating the data pre-
sented in this report. Additional acknowledgment is given to James H.
Nichols and Dr. Roger J. Furey for their guidance and support.
92
APPENDIX
MOI)DE C;EOMETRY
The data presented in this report are based on two research models.
The models consist of steel wings and a steel central core. Fuselages are
wooden fairings surrounding the central core. The canards and horizontal
tall are wood and fiberglass fairings built up around a steel spar. Attach-
ment of the canards and horizontal tail is provided by steel plates flush
with the fuselage. Seven canard and three horizontal tail mounting posi-
tLions are provided. Each canard can be rotated through a deflection range
from -10 to +25 degrees in 5-degree increments. Horizontal tail deflection
range is from -25 to +10 degrees. Rotation point for both canards and horl-
Zontal tail is 40 percent of the exposed surface root chord. Moment refer-
ence point for both research models is 0.27 c.
Detailed dimensions of the wings are given in Table 1. Table 2 pre-
sents dimensions of the four canards. Figure 58 shows the common fuselage
shape for both models. Wing planform geometries are given in Figure 59.
Canard geometry is given in Figure 60. Canard locations are presented in
Figure 61. A photograph of the various model components is shown in
Figure 62.
4l
93 Z S. X
TABLE I - GEOMETRIC CHARACTERISTICS OF THE WINGS
WI(A - 50 [)'grees) W2(A = 25 D)Lgrees)
Alrfoii Section (NACA) * 64AO08
Projected Area, square inches 304 295
Span, inches 35.50 42.00
Chord, inches
Root (centerline) 15.38 12.20
Tip 1.90 1.90
Mean Aerodynamic Chord, inches
Length 10.30 8.30
Spanwise Location from 6.70 7.90Body Centerline
Aspect Ratio 4.15 6.00
Taper Ratio 0.12 0.16
Sweepback Angle, degrees
Leading Edge 50.0 25.0
Quarter Chord 45.5 20.0
Trailing Edge 23.5 -1.5
Incidence Angle, degrees 0 0
Dihedral Angle, degrees 0 0
Twist Angle, degrees 0 0
*64A008 Airfoil swept 25 degrees around 0.27c chord line.
94
......................
TABLE 2 - GEOMETRIC CHARACTERISTICS OF THE CANARDS
"C23
A M " Io I Scot oti ( NACA ) '4A0)08 04A006 64AO08 (14AU)%0
Exposud Area, square Inchcs 39.8 39.8 47.2 /49. 1
Projected Area, square inches 76.0 89.5 76.0 76.0
Exposed Semi-Span, inches 5.74 4.79 7.60 7.60
Total Span, inches 16.28 14.38 20.00 20.00
Chord, inches
Root (centerlLne) 8.73 12.45 6.70 6.12
Root (exposed) 6.33 8.30 5.31 5.00
Tip 0.59 0 0,90 1.,8
Aspect Ratio 3.50 2.31 5.26 5.26
Taper Ratio 0.07 0 0.13 0. 24
SweepbaCk Angle, degrees
Leading Edge 45 60 45 25
Trailing Edge 0 0 22.8 0
Dihedral Angle, degrees 0 0 0 0
S95
NOTE: VERTICAL TAIL WAS NOT TESTED WITH THE25-DEGREE LEADING-EDGE SWEEP-WING (W2)
IA -- J
(a) '[up View
SECTION A-AD ALL DIMENSIONS ARE IN INCHES (CENTIMETERS)
WIDTH - 4,75 (12.06); HEIGHT = 4.15 (10,54)UPPER CORNER RADIUS = 1,00 (2.54)LOWER CORNER RADIUS 0,25 (0.64)
25.12(63.80)
45.62I (115.87)
(b) Side Vi•,w
Flgure 58 - R•search Aircraft Fuselage,
96
IJ
1 10.77 (27.35)
SA 50 DEGREES
AR - 4.15" • " 0.12
ww
5.2(15.05)
p -
•\=25 DEGREESAR - 6.00
0.18
AIRFOIL:NACA 64AOWS W2
Figure 59 - Pianform View of the Wings
97
I A *45 DEGREESIAR - 3.50 A -48 DEGREESx 1 0.07 AR - 5.26AIRFOIL: A a 0.13NACA 64A00a I AIRFOIL:[ NACA 64A00B
I \
tU
AR - 5.26I h - 0.24
AIRFOIL:A - 60 DEGREES NACAI4AFO
AR - 2.31 NAA
AIRFOIL:NACA 64AOO6
Figure 60 - Planform View of the Canards
98
1614
Sito
994
a..-.
I94
4 1I
I I
I II II II
I
II II
I i gLIrL' h2 - WI tilt Itiiiiit� I Mtitltj I ( (Hflj)Ot1(Ilt H
I
I I
II
REFERENCES
1. Lacuy, I).W. and S.,J. Chorney, "Subsonic Acrodynamic Character-
istics of Close-Coupled Canards with Varying Area and Position Relative
to a 50-Degree Swept Wing," Naval Ship Research and Development Center,
DTNSRDC ASED-199, AD 882-702 (Mar 1971).
2. Krouse J.R., "Effects of Canard Planform on the Subsonic Aero-
dynamic Characteristics of a 25-degree and a 50-Degree Swept-Wing Research
Aircraft Model," Naval Ship Research and Development Center Evaluation
Report, AL-91, AD909-459 (May 1972).
J
10
103
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