1. Rockets Tuesday: Rocketry Wednesday: Meet in my room 601: hydrogen demo and Quiz over rocketry. Thursday: Satellites and Orbital Mechanics Friday: Satellites, Orbital Mechanics and Tsiolkovsky Quiz

2. What are the seven obstacles? Vacuum of space Heat Reentry Orbital mechanics Debris Restrooms Getting off the ground

3. Three Countries that have put people in orbit are… Russia (USSR) China United States

4. Rockets Overview What type of energy does a motor use? How is that different from a rocket engine? What principle does a rocket engine use?

5. Rocket Propulsion Newton’s 3 rd Law?

6. How do we overcome this problem?? Measured in Newton’s. WHY?

7. Lets try a practice problem… An elephant weighs 1 ton, how much thrust is necessary to hold its weight at a constant level but not send it into orbit?

8. Is it really that easy? In order to be launched however, the thrust must be greater than your weight. In other words you must have extra thrust. That extra thrust make you ACCELERATE upwards. In other words, “the greater the thrust the faster your rocket will accelerate.”

9. So which Newton’s law are we talking about now? 2 nd Law: f = ma When mass increases, acceleration decrease.

10. Another problem you say… Sure Another problem you say… Sure On a frictionless surface you want to measure acceleration of a rocket moving horizontally. (we don’t want to fight gravity just yet). If the rocket produces 50lbs of thrust and weighs 10 kgs, what is the acceleration?

11. Lets add gravity into the mix. This time the same rocket is launched upward. What is the acceleration?

12. The book’s example

13. So what must be done to change the thrust? More balls Bigger ball More acceleration

14. So what is the funny problem that rockets have? The fuel, that they use to create thrust weighs something. (like adding an extra space suit to the rocket) but more of course.

15. Just some statistics… How many main sections of the shuttle are there? How much does the shuttle weigh at launch? What is the shuttle’s main engine fuel? For how many minutes did the Space Shuttle’s two solid boosters burn at launch? 3 4.4 million Liquid oxygen and hydrogen 2

16. Lets compare and contrast the two types of rockets… Solid FuelLiquid Fuel

17. Now its time for the fun part… The fundamentals of rocketry rest on Newton’s laws. Thrust = (propellant mass flow) x (exhaust velocity) T= mC Propellant mass flow = how much “fire” come out. Exhaust velocity = It represents the force with respect to the amount of propellant used per unit time

18. Lets explore exhaust velocity… It is a way to describe the efficiency of rocket and jet engines Measured in ISP = number of seconds a lb of propellant can deliver a lb of thrust. C= g (ISP) C = Exhaust velocity g= gravity ISP= impulse

19. In order for all this to matter… velocity = to get where you want to go. This is the fundamental currency of astronauts. Measure in units of speed. The ROCKET EQUATION shows how big a velocity the system can generate.

20. The ROCKET EQUATION (M + P) / M = e V/C e= 2.71828 (M + P) = M= DRY mass at lift off, P= Propellent M = DRY mass in orbit V/C = shows the velocity change a rocket can generate.

21. Because of the exponent there small changes make big differences. Increase in V or decrease in C can be bad. It is desired to have a have V down and C up.

22. Since the mass of tanks, engines and most other vehicles increase in proportion to the propellent load, it can be described as 1 factor. ◦DRY MASS FRACTION = F ◦Takes into account system design and lightness of the materials used in construction. F x Propellent mass = dry mass ** this is not counting payload***

23. For example: If F = 0.1 and it is carrying 90 tons of propellant what would the dry mass of the ship? What if the mass ratio of the system had to be 10 to perform a certain V? Then there would only be allowed a 1 ton payload. However, if the F increases to.12 the dry mass of the vehicle would be 10.8 and there would be no lift off!! 9 tons

24. How do we fix this? We chop the V into stages and then drop the dry mass of that stage.