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In order to understand high power rocketry enough to launch and successfully recover an L1 rocket, you must read, live, and understand the following information.

Background Information

NASA's online Beginner's Guide To Rockets will get you started on many of the basic principles govenrning rocketry. If you manage to make your way through all of these, you will understand the vernacular often used in rocketry.

L1 Requirements

TRA

Level 1 Certification allows flyers to fly High Power Rockets with a total installed impulse up to 640 newton-seconds.

Airframe

The rocket must be built by the flyer. The rocket shall have a display on the exterior identifying the calculated center of pressure. The rocket must be of "conventional rocket design". "Odd Rockets" including flying pyramids, saucers and flying spools will not be allowed for any certification flight. The rocket may be either a kit or scratch built. Scratch built rockets may contain commercially built components.

Recovery

Standard parachute recovery is required. Non-parachute recovery methods (e.g. tumble, helicopter, gliding, etc) are not permitted for certification flights. If the rocket is using dual deployment, the first recovery event may be via a drogue-less or streamer as long as the main or second event uses a standard parachute.

Motor

The certification flight must be with a single certified H or I motor (tested total impulse between 160.01 and 640.00 n-sec). Staged and/or Clustered rockets may not be used for certification flights. The flyer shall be observed by the certifying member or their designated representative during the assembly (if a reload or hybrid) and preparation of the motor.

Electronics

Electronics are not required for level 1 certification flights.

Certification Flight

Level 1 Certification flight may take place at any insured launch. The certifying member (i.e. Prefect, TRA Director, or TAP Member) must be present and witness the certification flight. The certifying member must witness the rocket ascend in a stable manner and descend in stabilized manner controlled by the recovery system.

Post-Flight Inspection

The rocket must be presented to the certifying member for inspection. If the rocket cannot be recovered, but can be inspected in place (power lines, tree, etc...) this is acceptable. The certifying member shall inspect the rocket for excessive damage. Excessive damage shall be considered damage to the point that if the flyer were handed another motor, the rocket could not be put on the pad and flown again safely. Damage caused by wind dragging will not cause a disqualification.

Non-certification

Any of the following will result in non-certification for a certification flight: Motor Cato Excessive Damage No recovery system deployment or tangled recovery system deployment Rocket drifting outside the specified launch range Components coming down not attached to the recovery system. Any other violation of TRA safety code associated with this particular flight. Any other legitimate reason the certifying member deems merits non-certification

Launch Locations

Map

Time launch begins

etc

Launch Day Procedures

Who You Will Meet

RSO

Mike

Cliff

Stu

What You Need To Bring

People Fuel - water food money etc

Car Fuel - petrol

Appropriate Clothing

Vendors

BAR

Range Layout

Big, cars on the side, site in the middle

Packing Your Parachute

It should not be too tight. Etc.

Here is a video.

Here is how a NAR member does it. (Cliff)

Look at these great diagrams.

Prepping Your Motor

If using a single use motor or Disposable Motor System, make sure to check that the delay on the ejection charge is correct using a simulation software (i.e. OpenRocket). If needed adjust the length of the delay grain. Then place the correct quantity of ejection propellant in the correct location. Cap it.

Here is a great video to watch.

Range Safety Check

Is your paperwork in order?

Motors

Is the motor certified, what is the motor type and average thrust? Is the delay time is approximate for rocket?

Will the rocket penetrate cloud cover?

Does your rocket motor have the ejection charge installed?

Is sufficient wadding/Kevlar installed?

What kind of motor retention system is installed?

What prevents the motor from flying-through the rocket?

Rocket Construction

Stability? Is the CG in front of the CP? Be able to identify both.

Is the nose cone fitted correctly?

Launch lugs and/or rail guides properly installed, positioned, and aligned?

Fins atttached securely and in a manner that will not cause an unsafe flight?

Is an appropriately-sized recovery system installed and attached?

Are there vent holes?

Launch Pad Procedure

The rocket should slide freely on the rail. The pad angle should be within 20 degrees of the vertical axis (normal to the surface of the earth). Flight critical electronics (if there are any) should be armed before putting in igniters. Any radio control equipment should also be nominally operating before arming the igniters.

How to install an igniter

Place in the nozzle of rocket, and tape the igniter to the rocket so it does not slide out. Make sure not to short the leads of the igniters.

Here is a great video to watch.

Success and Failure

Following the launch, the rocket will be inspected; should the airframe be deemed suitable for flight given a new motor, it will have passed L1 certification. Failed deployment, motor cato, drifting beyond a particular range (see launch officer), or the violation of other safety codes will result in a failure. L1 certification, however, is an excellent introduction to the basic operations of rockets and recovery! See Pegasus for a description of an L1 rocket used as a testbed for an L3 concept.

Final Steps

Mailing It In

You must mail in your certification form to have the rocketry association acknowledge your achievement. These are the addresses of NAR and TRA.