aerodynamics class
assignment 5.doc
1
Exercise 5: Aircraft Performance
For this week’s assignment you will revisit your data from previous exercises, therefore please make sure to review your results from the last modules and any feedback that you may have received on your work, in order to prevent continuing with faulty data.
1. Selected Aircraft (from module 3 & 4):
2. Aircraft Maximum Gross Weight [lbs] (from module 3 & 4):
Jet Performance
In this first part we will utilize the drag table that you prepared in module 4.
Notice that the total drag column, if plotted against the associated speeds, will give you a drag curve in quite similar way to the example curves (e.g. Fig 5.15) in the textbook. (Please go ahead and draw/sketch your curve in a coordinate system or use the Excel diagram functions to depict your curve, if so desired for your own visualization and/or understanding of your further work.)
Notice also that this total drag curve directly depicts the thrust required when it comes to performance considerations; i.e. as discussed on pp. 81 through 83, in equilibrium flight, thrust has to equal drag, and therefore, the thrust required at any given speed is equal to the total drag of the airplane at that speed.
Last but not least, notice also that, so far, in our analysis and derivation of the drag table in module 4, we haven’t at all considered what type of powerplant will be driving our aircraft. For all practical purposes, we could use any propulsion system we wanted and still would come up with the same fundamental drag curve, because it is only based on the design and shape of the aircraft wings.
Therefore, let’s assume that we were to power our previously modeled aircraft with a jet engine.
A. What thrust [lbs] would this engine have to develop in order to reach 260kts in level flight at sea level standard conditions? Notice again that in equilibrium flight (i.e. straight and level, un-accelerated) thrust has to be equal to total drag, so look for the total drag at 260kts in your module 4 table. (In essence, this example is a reverse of the maximum speed question – expressing it graphically within the diagram: We know the speed on the X-axis and have the thrust required curve; that gives us the intercept point on the curve through which the horizontal/constant thrust available line must go.)
B. Given the available engine thrust from A. above, what is the Climb Angle [deg] at 200kts and Maximum Gross Weight? (Notice that climb angle directly depends on the available excess thrust, i.e. the difference between the available thrust in A. above and the required thrust from your drag curve/table at 200kts. Then, use textbook Eq. 6.5b relationships to calculate climb angle).
C. What is the Max Endurance Airspeed [kts] for your aircraft? Explain how you derived at your answer.
Prop Performance
In this second part we will utilize the same aircraft frame (i,e, the same drag table/graph), but this time we will fit it (more appropriately and closer to its real world origins) with a reciprocating engine and propeller.
D. To your existing drag table, add an additional column (Note: only the speed column, the total drag column and this third new column will be required – see below). To calculate the Power Required in the new column, use textbook p. 115 equation and the V and D values that you already have: Pr = D*Vk / 325
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V (KTAS) |
DT = Tr (lb) |
Pr (HP) |
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100 |
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120 |
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140 |
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160 |
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180 |
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190 |
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200 |
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220 |
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240 |
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260 |
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E. Draw/sketch (or plot in an Excel diagram) your Power Required curve against the speed scale from the table data in A. above. (Note: This step is again solely for your visualization and to give you the chance to graphically solve the next questions in analogy to the textbook and examples. See sketch above.)
F. Find the Max Range Airspeed [kts] for your aircraft. Remember from the textbook discussion pp. 125 through 127 that Maximum Range Airspeed for a reciprocating/propeller driven aircraft occurs where a line through the origin is tangent to the power required curve (see textbook Fig. 8.9 and sketch above). However, as per the textbook discussion, it is also the (L/D)max point, which we know from our previous work on drag happens where total drag is at a minimum (therefore, you can also reference the total drag column in your table and find the airspeed associated with the minimum total drag value).
G. Find the Max Endurance Airspeed [kts] in a similar fashion. (Tip: The minimum point in the curve will also be visible as minimum value in the Pr column of your table.)
H. Let’s assume that the aircraft weight is reduced by 10% due to fuel burn (i.e. similar to the gross weight reduction in Exercise 4, problem B).
I) Aircraft Weight [lbs] for 90% of Maximum Gross Weight (i.e. the 10% reduced weight from above). Simply apply the factor 0.9 to your aircraft Maximum Gross Weight from number 2. above:
II) Find the new Max Range Airspeed [kts] for the reduced weight. Remember (from your textbook reading and Exercise 4, B.) that the weight change influence on speed was expressed by Eq. 4.2 in the textbook.
Landing Performance
For this last part of this week’s assignment you will continue with your reciprocating engine (i.e. prop) powered aircraft and its reduced weight. Let’s first collect some of the data that we already know:
3. Stall Speed for 90% of Maximum Gross Weight (i.e. the stall speed for 10% decreased weight from above, which we already calculated in Exercise 4, problem B.):
I. Find the Approach Speed [kts] for your 90% max gross weight aircraft trying to land at a standard sea level airport. Approach speed is usually some safety margin above stall speed -.let’s assume for our case a factor of 1.2, i.e. multiply your stall speed from number 3. with a factor of 1.2 to find the approach speed:
J. Determine the drag [lbs] on the aircraft during landing roll.
I) For simplification, start by using the total drag value [lbs] for stall speed (for the full weight aircraft) from your module 4 table:
II) Adjust the total drag (from I) above) for the new weight (from H. I) above) by using the textbook Equation 7.1 relationship: D2/D1 = W2/W1
III) Find the average drag [lbs] on the aircraft during landing roll. A commonly used simplification for the dynamics at play is to use 70% of the total drag at touchdown as the average value. Therefore, find 70% of your II) result above.
K. Find the frictional forces during landing roll. The Total Friction is comprised of Braking Friction at the main wheels and Rolling Friction at the nose/tail wheel. For this example, let’s assume that, in average, there is 75% of aircraft weight on the main wheels and 25% on the nose/tail wheel over the course of the landing roll. The Average Friction Force is then the product of respective friction coefficient and effective weight at the wheel/wheels (see p. 209 textbook):
F = (*N
I) If the rolling friction coefficient is 0.02, what is the Rolling Friction [lbs] on the nose/tail wheel? (Remember that only 25% of total weight are on that wheel and that the weight was reduced by 10% from maximum gross weight – see H I)):
II) If the main wheel brakes are applied for an optimum 10% wheel slippage (as discussed on textbook pp. 209/210), what is the Braking Friction [lbs] on the main wheels during landing roll on a dry concrete runway? Use textbook figure 13.9 to determine the friction coefficient. (Remember that the weight on the main wheels is only 75% of total aircraft weight).
III) Find the total Average Friction [lbs] during landing by building the sum of I) and II):
L. Find the Average Deceleration [ft/s2] during landing roll. Use the same rectilinear relationships as in module 1, applying the decelerating forces of friction and drag from J. III) & K. III) above. Assume that residual thrust is zero. (Keep again in mind that for application of Newton’s second law, mass is not the same as weight. Your result should be a negative acceleration value since the aircraft decelerates in this case.):
M. Find the Landing Distance [ft] (Remember that we start from a V0 at approach speed and want to slow the aircraft to a complete stop, applying the negative acceleration that we found in L. Also, remember to convert approach speed from I. above into a consistent unit of ft/s.):
N. If your aircraft was to land at a higher than sea level airport (e.g. at Aspen, Co) what factors would change and how would it affect your previous calculations, especially your landing distance. Explain principles and relationships at work and support your answer with applicable formula/equations from the textbook. You can include example calculations to support your answer:
V
Pr
maxR
maxE
This document was developed for online learning in ASCI 309.
File name: Ex_5_Aircraft Performance
Updated: 07/19/2015
assignment 6.docx
Directions
For this assignment, research the Internet for information on the UA 232 DC-10 accident that occurred on July 19, 1989 in Sioux City, Iowa and the DHL Airbus-300 shoot-down incident that occurred on November 22, 2003 in Baghdad. Then write a one or two paragraph analysis (approximately 100 to 150 words) comparing and contrasting these two cases. There are many articles on the Internet related to these cases. Please do not include any direct quotes in your analysis. Use your own words. Be sure to cite and reference all of your sources as applicable.
assignment 7.doc
1
Exercise 7: Maneuvering & High Speed Flight
For this week’s assignment you will research a historic or current fighter type aircraft of your choice (options for historic fighter jets include, but are not limited to: Me262, P-59, MiG-15, F-86, Hawker Hunter, Saab 29, F-8, Mirage III, MiG-21, MiG-23, Su-7, Electric Lightning, Electric Canberra, F-104, F-105, F-4, F-5, A-6, A-7, Saab Draken, Super Etendard, MiG-25, Saab Viggen, F-14, and many more).
As previously mentioned and in contrast to formal research for other work in your academic program at ERAU, Wikipedia may be used as a starting point for this assignment. However, DO NOT USE PROPRIETARY OR CLASSIFIED INFORMATION even if you happen to have access in your line of work.
Notice also that NASA has some great additional information at: http://www.hq.nasa.gov/pao/History/SP-468/contents.htm.
1. Selected Aircraft:
2. Aircraft Gross Weight [lbs]:
3. Aircraft Wing Area [ft2]:
4. Positive Limit Load Factor (LLF - i.e. the max positive G) for your aircraft:
5. Negative LLF (i.e. the max negative G) for your aircraft:
6. Maximum Speed [kts] of your aircraft. If given as Mach number, convert by using Eq. 17.2 relationships with a sea level speed of sound of 661 kts.
For simplification, assume the CLmax for your aircraft was 1.5 (unless you can find a different CLmax in your research).
A. Find the Stall Speed [kts] at 1G under sea level standard conditions for your aircraft (similar to all of our previous stall speed work, simply apply the lift equation in its stall speed form from page 44 to the above data):
B. Find the corresponding Stall Speeds for 2G, 3G, 4G, and so on for your selected aircraft (up to the positive load limit from 4. above), using the relationship of Eq. 14.5. You can use the table below to track your results.
C. Add the corresponding Stall Speeds for -1G, -2G, and so on for your selected aircraft (up to the negative load limit from 5. above) to your table. Assume that your fighter wing has symmetrical airfoil characteristics, i.e. that the negative maximum CL value is equal but opposite to the positive one. (Feel free to use specific airfoil data for your aircraft, but please make sure to use the correct maximum positive and negative Lift Coefficients in the correct places, i.e. CLmax in the positive part and highest negative CL in the negative part of the table and curve, and indicate your changes to the given example.)
Explanation: Making the assumption of symmetry simplifies your work, since the stall curve in the negative part of the V-G diagram becomes a mirror image of the positive side. Notice also that the simplified form of Eq. 14.5 won’t work with negative values; however, if using the G-dependent stall equation in the middle of page 222, it becomes obvious that negative signs cancel out between the negative G and the negative CLmax, and Stall Speeds can actually be calculated in the same way as for positive G, reducing your workload on the negative side to only one calculation of the stall speed at the negative LLF, if not a whole number.)
D. Track your results in the V-G diagram below by properly labeling speeds at intercept points. Add also horizontal lines for positive and negative load limits on top and bottom and a vertical line on the right for the upper speed limit of your aircraft at sea level from 6. above. (Essentially you are re-constructing the V-G diagram by appropriately labeling it for your aircraft. Notice that the shape of the diagram and the G-dependent curve relationship is essentially universal and just the applicable speeds will change from aircraft to aircraft. Make sure to reference book Fig. 14.8 for comparison.)
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E. Find the Ultimate Load Factor (ULF) based on your aircraft’s Positive Limiting Load Factor (LLF). (For the relationship between LLF and ULF, see book discussion p. 226 and Fig. 14.9):
F. Find the Positive Ultimate Limit Load [lbs] based on the ULF in E. above and the Gross Weight from 2.?
G. Explain how limit load factors change with changes in aircraft weight. Support your answer with formula work and/or calculation example.
H. What is the Maneuvering Speed [kts] for your aircraft?
I. At the Maneuvering Speed and associated load factor, find the Turn Radius ‘r’ [ft] and the Rate of Turn (ROT) [deg/s].
I) Use Eq. 14.3 to find bank angle ‘(’ for that load factor (i.e. G). (Remember to check that your calculator is in the proper trigonometric mode when building the arccos).
II) With bank angle from I) above and maneuvering speed from H., use Eq. 14.15 to find turn radius ‘r’.
III) With bank angle from I) above and maneuvering speed from H., use Eq. 14.16 to find ROT. (Make sure to use the formula that already utilizes speed in kts and gives results in degree per second).
J. For your selected aircraft, describe the different features that are incorporated into the design to allow high-speed and/or supersonic flight. Explain how those design features enhance the high-speed performance, and name additional features not incorporated in your aircraft, but available to designers of supersonic aircraft.
K. Using Fig. 14.10 from Flight Theory and Aerodynamics, find the Bank Angle for a standard rate (3 deg/s) turn at your aircraft’s maneuvering speed. (This last assignment is again designed to review some of the diagram reading skills required for your final exam; therefor, please make sure to fully understand how to extract the correct information and review book, lecture, and/or tutorials as necessary. You can use the below diagram copy to visualize your solution path by adding the appropriate lines, either via electronic means, e.g. insert line feature in Word or Acrobat, or through printout, drawing, and scanning methods.)
From: Dole, C. E. & Lewis, J. E. (2000). Flight Theory and Aerodynamics. New York, NY: John Wiley & Sons Inc.
-2
-4
0
1
2
3
4
5`
6
7
8
9
10
-1
-3
-5
EAS (kts):
LOAD FACTOR G
This document was developed for online learning in ASCI 309.
File name: Ex_5_Aircraft Performance
Updated: 08/01/2015
Example of assignment 7.docx
GIVEN:
W= 25,000lb
Stall Speed @1G Level Flight = 125 KEAS= Vs1
S= 314.5 ft2
CLmax = 1.5
Sea Level Standard Day (σ = 1.0)
Utility Certification (+4.4G to -2.0G)
Find stall speed (KEAS) at 4.0 G (Vs2)
From the Lecture Notes and Dole & Lewis-page 222
or
Equation 14.5 Vs2 = Vs1 = 125 KEAS = 250 KEAS
Find Va (Maneuvering Speed) (KEAS)
Equation 14.9 Va = Vs = 125 KEAS = 262 KEAS
Find Stall speed (KEAS), level flight at 0.5 G
Equation 14.5 Va = Vs = 125 KEAS = 88.4 KEAS
Find Stall speed (KEAS) , level flight 60 deg bank angle
Equation 14.6 Vs2 = Vs1 = 125 = 176.8 KEAS
Find turn radius (r) and Rate of Turn (ROT) at 250KEAS and 70 deg bank angle level turn
or approximated graphically using Figure 14.10
(Note: The figure has two scales for Bank Angle. One you use for Rate of Turn (ROT) and the other you use for Radius of Turn (r).The example lines are for 70 degrees bank angle
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