Difference between revisions of "L1 Certification"

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Revision as of 04:05, 11 February 2016

Cameron Ramos before his L1 certification flight

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

Background Information

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

Jargon

Impulse and its Specificity

Impulse (or total impulse) is defined as equal to force multiplied by time - it is a measure of how powerful motors are, and can easily give you your change in velocity, Impulse / Mass, assuming no drag or gravity losses. (There will always be drag and gravity losses.) Total impulse can be thought of as the area under the thrust curve.

Thrust curves of motors with the same total impulse

In the above graph, each of those three motors have the same total impulse (area under the curve), but with very different thrust profiles. The letter designation for each motor (e.g. in E15, H125, or M1250) are a measure of total impulse and each successive letter represents double the total impulse.

It turns out that impulse alone is not a good measure for rocket fuel performance; it is technically possible to use wood and air as rocket fuels, and to get an insanely large impulse by making the engine really big. That will never get you to space. Instead, rockets really care about a number called the specific impulse, defined as impulse divided by the mass of the propellant and the gravitational constant. This gives a far better picture of what constitutes a good rocket fuel, although there are definitely other considerations.

Motor Systems (DMS and RMS)

A DMS with its packaging

DMS stands for Disposable Motor System. These motors are one time use only, and are very easy to work with.

RMS stands for Reloadable Motor System. These types of motors are harder to work with, since they require the maintenance of a motor casing and proficiency in loading, cleaning, and reloading the casing. After purchasing the relatively expensive casing, one must learn how to assemble it with motor reloads. If not assembled properly, your rocket will most likely not make it through the flight. However, once you become good at assembling and using RMS, it is cheaper to merely have to purchase propellant each time you launch instead of an entirely new DMS motor.

Motor Retention (Positive or Otherwise) and Adaptors

There is one direction we care about when discussing motor retention, the y direction (axially). Simply put, the job of a motor retainer is to keep your motor from falling out of your rocket or allowing it to shoot through the nosecone upon ignition, resulting in a cato. Depending on the company, motor retainers have a couple different ways they work. For the slimline retainers used in the SSI Firestorm kit, the motor retainers use retaining rings. These rings are removable and are located on the lip of the the retainer. The purpose of the rings are to keep the motor from sliding out of the bottom while a lip on the body of the retainer prevents the motor from launching through the rocket's nosecone. For any 38mm motor being used in the 58mm Firestorm airframe, a motor adaptor is going to be used which has identical retaining rings, except smaller in diameter, to the motor retainer.


You can purchase/make motor adaptors which allow you to have a motor of a diameter that is smaller than the diameter of your rocket. For example: If one wanted to launch an L1 with a 54mm H motor but his or her rocket had an ID of 98mm, that person would purchase/make a motor adapter to keep the motor stable and restrained. Motor adapters consist of a tube that has the same ID as the motor's OD and uses centering rings to keep the motor centered between the airframe walls. If you are planning on using various diameter motors for the same airframe it might be a wise choice to invest in a motor retention system that allows the user to buy various components designed to work with different sized motors.

Some Quick Terminology Positive = not falling out the bottom.

Stability

CG and CP for stable flight

Center of Gravity

An objects center of gravity is its (rigorously and mathematically defined) middle point. The force of gravity can be simulated to act here, and the object will tend to rotate about this point, making it crucial to finding rocket stability.

The relation of CG to your L1 rocket is its relation to the center of pressure (CP). For stable flight your CG needs to be towards the nosecone of your CP. If you determine that your CG is too close to your CP and need to move it forward because you can't change the position of your CP, a common method is to add some mass weight to your nosecone.

Center of Pressure

The center of pressure is the location at which we can model the aerodynamic effects as acting. In other words, the drag on the rocket acts at this point. If the center of pressure is below the center of gravity, then the downwards force of drag will keep the rocket upright, while a center of pressure above the center of gravity will flip the rocket. A CP and CG at the same point will create a neutrally stable rocket, meaning that any incidental forces could theoretically spin it. This makes the distance between the CP and CG critically important for determining whether flight will be safe and successful.

The main tool we have to change the center of pressure is the size of the rocket's fins - larger fins will bring the center of pressure lower down on the rocket, increasing its stability.

To calculate center of pressure, you can use the Barrowman equations (link to a slighty confusing example) or the cardboard cutout method.

Another way to determine the CP of your rocket is to use a program like OpenRocket or RockSim. Both of these programs take all the information you input about your rocket and input into the Barrowman equations for you.

Calibers

A caliber is a unit of measurement defined as the diameter of the airframe. Calibers are used to measure the distance between the CP and CG - it doesn't make sense to solely measure based on distance, as a 3" difference on a 2" OD, 24" long rocket is very different from a 2" difference on a 10' long, 6" OD one.

Calibers measure the length between CP and CG allowing for a much more fair comparison between different rocket sizes. It would be correct to say, the CG is 2 calibers away from the CP.

As a rule of thumb, having your CP 1.5-2 calibers in front of your CG is considered good, while numbers outside of that range tend to be either under-or-over-stable.

Motor Specs

Solid rocket motors have a fairly standardized labeling system. On the casing (or reload) itself there is a three-part code which denotes what the total impulse range is, the average thrust, and the delay grain length. All these numbers are in standard metric units.

The letter designation represents the total impulse. Each letter category represents double the total impulse of the previous letter category.

Letter designations increase total impulse exponentially

Motor classification table:

alt text


Motor Designation Breakdown

To better understand how to read a motor label lets take an example:

Aerotech H550ST-14A

Here is the spec sheet for this motor[1]. This is the motor that SSI uses for its L1 certification launches.

  • H: the letter designating the impulse range. For an H this is from 160 Ns - 320 Ns.
  • 550: denotes that the motor's average thrust is 550 N.
  • ST: denotes what type of propellant is in the casing. In this case, ST stands for "Super Thunder". Aerotech has various names for their different types of propellants, however, often these names are only denoting the color of the flame rather than the chemical compounds that it is made of.
  • 14: denotes that the motor will fire its ejection charge 14 s after burnout unless it is adjusted, as indicated by the A. Motor delay times can be adjusted with a motor delay tool (otherwise known as a proprietary screwdriver, here is a link to buy one[2]).

Recovery

Motor delay charge

Recovery is the second stage of a simple non-complex rocket, aka basic L1. Although it would seem like the largest percentage of failure would happen during ascent, 75% of failed rockets are a result of a faulty recovery system. Common points of failure for an L1 are: the parachute did not deploy out of the airframe, the parachute deployed too soon before or too far after apogee, line tangling, and too quick of a descent. All of these aspects are things that you should consider when compiling your recovery system.

For L1 all a rocketeer needs is single stage deployment. Simply put, only a main parachute is required to bring the rocket safely back to the ground. Because it is single stage, the parachute should be ejected as close to apogee as possible to prevent unnecessary damage to the rocket. Apogee is the highest point of a rocket trajectory, where the vertical velocity is momentarily zero and the rocket transitions from ascent to descent. This is the point at which the rocket is moving slowest and thus is the most ideal for deployment of a parachute.

For typical L1 rockets, after the motor burns through its main propellant, it burns through a delay grain. This is a slow-burning section at the end of the motor which acts as a timer. Once it has burned through the delay grain, the flame front ignites an ejection charge loaded in the charge well at the front of the motor. This ejection charge, typically black powder, pressurizes the body tube of the rocket and forces the nose cone out, along with the parachute. To test whether your nose cone has the proper fit (tight enough to stay on during flight but loose enough to eject for recovery), hold the back end of your completed, and unloaded, rocket to your mouth and blow hard with a good seal. The nose cone and parachute should both pop out. If you are incapable of doing this, another test can be done by vigorously shaking the rocket by holding the nosecone. The nosecone should separate from the rocket by doing this.

Simulations

Example of the OpenRocket infterface

It is always important to know what your rocket will do (assuming that things go according to plan), and we use a program called OpenRocket to find the flight profile of our rockets. The program is free, and can be found here[3]

OpenRocket is quite easy to learn, and is quite accurate for sub-Mach rockets (those that fly faster should use RasAero to model drag forces.) OpenRocket includes ascent, including a massive database of thrust curves, as well as a simulated descent using the parachutes included in the rocket. If used properly, it can output data from height of apogee to time of flight to drift distance, all of which are incredibly useful while designing your rocket. (Hint: the center of pressure calculation is extremely important.)

One other program of note is called FinSim, which can model possible vibrations within fins. If unchecked, these vibrations can grow and shear the fins off, likely dooming the rocket. The program is required for transonic and supersonic flights, and can be found here[4]

Safety Codes

NFPA 1127 and FAA 101

Note: Might be better to just give summaries of each relevant section and only post links to full documents. Someone please fix.

The National Fire Protection Association has multiple documents spanning different types of rocketry. Section 1122 governs model rockets and 1127 governs high powered rockets. We are most interested in 1127.

NFPA 1127 sets the rules and regulations for high power rocketry, including the motor classification system, rules for Range Safety Officers, and guidelines for the safe construction, use, and storage of rocket materials. Critically, it also includes the formal definition of High Power Rocketry, and it is this definition that is referenced in ITAR.

The Federal Aviation Administration Regulations also has a relevant section to the high powered rocketry community. FAA 101 Subpart C, Amateur Rockets. Here are the extremely relevant sections.

§101.22 Definitions.

The following definitions apply to this subpart:

(a) Class 1—Model Rocket means an amateur rocket that:
(1) Uses no more than 125 grams (4.4 ounces) of propellant;
(2) Uses a slow-burning propellant;
(3) Is made of paper, wood, or breakable plastic;
(4) Contains no substantial metal parts; and
(5) Weighs no more than 1,500 grams (53 ounces), including the propellant.
(b) Class 2—High-Power Rocket means an amateur rocket other than a model rocket that is propelled by a motor or motors having a combined total impulse of 40,960 Newton-seconds (9,208 pound-seconds) or less.
(c) Class 3—Advanced High-Power Rocket means an amateur rocket other than a model rocket or high-power rocket.
§101.23 General operating limitations.
(a) You must operate an amateur rocket in such a manner that it:
(1) Is launched on a suborbital trajectory;
(2) When launched, must not cross into the territory of a foreign country unless an agreement is in place between the United States and the country of concern;
(3) Is unmanned; and
(4) Does not create a hazard to persons, property, or other aircraft.
(b) The FAA may specify additional operating limitations necessary to ensure that air traffic is not adversely affected, and public safety is not jeopardized.
§101.25 Operating limitations for Class 2-High Power Rockets and Class 3-Advanced High Power Rockets.

When operating Class 2-High Power Rockets or Class 3-Advanced High Power Rockets, you must comply with the General Operating Limitations of §101.23. In addition, you must not operate Class 2-High Power Rockets or Class 3-Advanced High Power Rockets—

(a) At any altitude where clouds or obscuring phenomena of more than five-tenths coverage prevails;
(b) At any altitude where the horizontal visibility is less than five miles;
(c) Into any cloud;
(d) Between sunset and sunrise without prior authorization from the FAA;
(e) Within 9.26 kilometers (5 nautical miles) of any airport boundary without prior authorization from the FAA;
(f) In controlled airspace without prior authorization from the FAA;
(g) Unless you observe the greater of the following separation distances from any person or property that is not associated with the operations:
(1) Not less than one-quarter the maximum expected altitude;
(2) 457 meters (1,500 ft.);
(h) Unless a person at least eighteen years old is present, is charged with ensuring the safety of the operation, and has final approval authority for initiating high-power rocket flight; and
(i) Unless reasonable precautions are provided to report and control a fire caused by rocket activities.
§101.29 Information requirements.
(a) Class 2—High-Power Rockets. When a Class 2—High-Power Rocket requires a certificate of waiver or authorization, the person planning the operation must provide the information below on each type of rocket to the FAA at least 45 days before the proposed operation. The FAA may request additional information if necessary to ensure the proposed operations can be safely conducted. The information shall include for each type of Class 2 rocket expected to be flown:
(1) Estimated number of rockets,
(2) Type of propulsion (liquid or solid), fuel(s) and oxidizer(s),
(3) Description of the launcher(s) planned to be used, including any airborne platform(s),
(4) Description of recovery system,
(5) Highest altitude, above ground level, expected to be reached,
(6) Launch site latitude, longitude, and elevation, and
(7) Any additional safety procedures that will be followed.

TRA and NAR Codes

Useful documents:

For reference, here is a summary of NAR's safety code. For an non-edited version of NAR's code, check out the links above.

  • Certification. I will only fly high power rockets or possess high power rocket motors that are within the scope of my user certification and required licensing.
  • Materials. I will use only lightweight materials such as paper, wood, rubber, plastic, fiberglass, or when necessary ductile metal, for the construction of my rocket.
  • Motors. I will use only certified, commercially made rocket motors.
  • Ignition System. I will launch my rockets with an electrical launch system, and with electrical motor igniters that are installed in the motor only after my rocket is at the launch pad or in a designated prepping area. The electronics will have an off and on switch. They will turned off until my rocket is in the launching position.
  • Misfires. If my rocket does not launch when I press the button of my electrical launch system, I will remove the launcher’s safety interlock or disconnect its battery, and will wait 60 seconds after the last launch attempt before allowing anyone to approach the rocket.
  • Launch Safety. I will use a 5-second countdown before launch. I will ensure that a means is available to warn participants and spectators in the event of a problem. I will ensure that no person is closer to the launch pad than allowed by the accompanying Minimum Distance Table. I will check the stability of my rocket before flight and will not fly it if it cannot be determined to be stable.
  • Launcher. I will launch my rocket from a stable device that provides rigid guidance until the rocket has attained a speed that ensures a stable flight, and that is pointed to within 20 degrees of vertical. I will use a blast deflector to prevent the motor’s exhaust from hitting the ground.
  • Size. My rocket will not contain any combination of motors that total more than 40,960 N-sec of total impulse. My rocket will not weigh more at liftoff than one-third of the certified average thrust of the high power rocket motor(s) intended to be ignited at launch.
  • Flight Safety. I will not launch my rocket at targets, into clouds, near airplanes, nor on trajectories that take it directly over the heads of spectators or beyond the boundaries of the launch site, and will not put any flammable or explosive payload in my rocket. I will not launch my rockets if wind speeds exceed 20 miles per hour. I will comply with Federal Aviation Administration airspace regulations when flying, and will ensure that my rocket will not exceed any applicable altitude limit in effect at that launch site.
  • Launch Site. I will launch my rocket outdoors, in an open area where trees, power lines, occupied buildings, and persons not involved in the launch do not present a hazard, and that is at least as large on its smallest dimension as one-half of the maximum altitude to which rockets are allowed to be flown at that site or 1500 feet, whichever is greater.
  • Recovery System. I will use a recovery system such as a parachute in my rocket so that all parts of my rocket return safely and undamaged and can be flown again, and I will use only flame-resistant or fireproof recovery system wadding in my rocket.
  • Recovery Safety. I will not attempt to recover my rocket from power lines, tall trees, or other dangerous places, fly it under conditions where it is likely to recover in spectator areas or outside the launch site, nor attempt to catch it as it approaches the ground.

L1 Requirements

Sources of information: TRA L1 certification info and NAR L1 certification info.

The following is a combination of the NAR and TRA requirements and rules.

You must be at least 18 years old to be certified for Level 1. Although it is good practice to already be a member of NAR and/or TRA before certifying, in practice it is not enforced. Motors must be certified and non-experimental.

Your certifier (for NAR) needs to be either two people with the level you are attempting for, or one person with the level above the one you are attempting for. They must witness the flight.

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).TRA does not allow staged and/or Clustered rockets for certification flights while NAR states you must use at least one HPR motor on your certification rocket. 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. Single use motors are permitted.

Electronics

Electronics are not required for level 1 certification flights.

Pre-flight Inspection

The model will be subjected to a safety inspection prior to flight. The safety inspection form is on the back of the NAR High Power Certification Application. During the safety inspection the modeler will be expected to provide oral answers to technical questions related to the safety and construction of their model. The questions may include (but not limited to) identification of the model’s center of gravity and center of pressure, methods used to determine model stability, and interpretation of the rocket motor’s designation. The certification team will initial (or check) the blocks indicating that model safety, motor certification, and the existence of a FAA waiver (if required) in effect were verified prior to flight.

Certification Flight

Level 1 Certification flight may take place at any insured launch. The certifying member (i.e. Prefect, TRA Director, NAR certifiers 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. If successful, the certifiers will sign the correct sheet to indicate that the certification attempt was successfully completed.

Post-Post-Flight

The certification sheets are returned to NAR or TRA Headquarters. No fees are required. The certification sheet must be returned by the certified individual or the event sponsors to NAR or TRA Headquarters to allow updating the NAR or TRA database. NAR sends an updated membership card showing the certification level upon receipt of the certification paperwork.

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

Tripoli Central California

Tripoli hosts launches on the third Saturday of each month. Details, calendar, updates, and directions, as well as other pertinent information, can be found on their website here[5]. Be aware that Tripoli has slightly different policies and forms from NAR, as well as requiring a separate Tripoli membership in order to launch. However, certification levels from either are accepted at the other, i.e. if you are certified L1 through Tripoli, you can get your L2 certification at NAR, as long as you are a registered member of both.

Livermore Unit of the National Association of Rocketry

LUNAR hosts launches on the first Saturday of each month - details can be found here[6]

Launch Day Procedures

Who You Will Meet

Range Safety Officer (RSO)

The RSO is responsible for pre-flight inspection and approval of hobby rocket vehicles within a specified motor impulse range. They give the final word on whether your rocket will launch. Jump to Range Safety Check to read about what you need to prepare for inspection or read this document [7] if you're interested in the nuts and bolts of what an RSO does.

Launch Control Officer (LCO)

The LCO is responsible for control of the range and the actual launching of the rocket vehicles themselves.

What You Need To Bring

Rocket Fuel

  • Epoxy
  • Tools to apply epoxy (i.e. popsicle sticks and paper plates)
  • Power Drill and Impact Driver
  • Correct drill bits and heads
  • Dremel
  • Igniters
  • Bolts (what kind?)
  • Screwdrivers
  • Adjustable spanner
  • Masking and duct tape
  • Sandpaper (120 grit)
  • Measuring tape
  • Calipers

If doing L2 also bring these things along:

  • Wire strippers
  • Small needlenose pliers
  • Black powder
  • Extra igniters and ematches
  • Soldering iron
  • Power supply
  • Rosin solder
  • Altimeters
  • Altimeter USB cables
  • Batteries
  • Multimeter
  • Precision Screwdriver
  • Laptop

People Fuel

Rebecca Wong at a November launch at TCC
  • Cases of water
  • Cooler for drinks
  • Snacks (bring your own food)
  • Cash for launch fees and purchasing miscellaneous parts
  • Nice cameras
  • Inverters and power strips for power from car
  • Sharpies and pens
  • Pre-filled out documentation
  • First aid kits
  • Tent
  • Chairs
  • Folding tables
  • Trash bags
  • Table cloth

Appropriate Clothing

These requirements obviously change per season, but the running theme is that you will be exposed to the elements all day.

  • Sunglasses
  • Hats
  • Scarves
  • Pants
  • Walking boots or sneakers
  • Rain boots (for walking in muddy farmland)
  • Jacket

Vendors

Bay Area Rocketry is a local supplier of rocket parts and motors, and will often travel to launches, allowing us to pick up our motors at the site. Since SSI does not store motors on campus, this is a very nice perk.

Apogee Rockets is a website selling everything from guides to motors to fiberglass tubing, and are a very good starting point for any rocket-related parts.

Giant Leap Rocketry has a large selection of components, and tends to stock parts for larger rockets. They also sell the Firestorm 54 kit, which we have used extensively.

Public Missiles sells very large components - think rockets with diameters >6in.

Range Layout

Depending on which launch site you go to, this will be different. However, there are some basic themes.

The main areas of a launching range are the launch pad and control tent, and the parking area. Most high powered rocketry ranges have at least one launch pad that is set up 100ft away from the control tent, a distance specified by the NFPA, section 1127, as the "Minimum Personnel Distance" for any non-complex motor under 1,280 Ns (J motor). However, quite a few ranges also have a second pad, 300ft away, to be able to launch an L motor rocket, or any complex motor combinations up to J motors.

The control tent is where you check in your rocket with the RSO, and get your pad assignment from the LCO. This is also where you can take your L2 exam, if you have not done so already, and also where you bring your rocket back to get your certification.

Packing Your Parachute

When packing your parachute it should not fit too tightly within your airframe. You can test this yourself by giving a quick pull on the shock cord attached to the parachute. For the L1s, and most of the L2s, the parachutes are small enough that you should be able to have the entire parachute pop out of the airframe by doing this. If you find yourself having trouble either inserting your parachute into your airframe, removing it, or simply have no idea where to start there are a couple of styles of folding that may help.


Half Fold: This style is recommended if you have a relatively skinny airframe and are not concerned about airframe space.

Triple Fold: This style of folding results in a slightly thicker packed 'chute but it has a shorter length than the half fold.

Diagrams*

Here is a video.*


Some other techniques you may want to try:

  • folding your lines in with your 'chute rather than wrapping them around the 'chute
  • taping the folded lines with a bit of masking tape to act as a way of creating a "slider" to help slow the opening of the parachute. This essentially creates a faux dual deploy to help reduce recovery drift.


Don't forget to wrap the bottom end of your parachute in a heat resistant cloth like Nomex or Kevlar to prevent the ejection charge from burning holes into your parachute.

Re-do the parachute tied to the screw on metal loop 12 inches below the nose cone. Unscrew the loop, remove the cords and loop the parachute in a simple knot around the loop by passing the parachute through the loops of the cord lines.

Lay the parachute on the ground and arrange it so where all the cords come off the parachute are in the same spot. Accordian fold the parachute like a shirt. It should end with a width of about the diameter of the rocket.

Make a z-fold the long way on the parachute, if it looks like it will be too long for the chute protector, make 2 or 3 z-folds. Lay the cord lines along the chute the long ways and then fold the chute over once along the line of the cords. The cords should not go down the entire way, pull them out through the fold about half an inch from the bottom. Now wrap the cord lines around the chute, taking care to not cross the lines with each other.

Once that is done, take the chute protector and burrito wrap it around the chute. Make sure the slit that the shock cord goes through is at the spot furthest away from where the fire will be.

Fire + Parachute = Very Bad

The parachute+kevlar should act as a plug in the airframe. If the motor ejection does not push the parachute and kevlar out of the airframe, the pressure will push the nose cone out, which will pull the parachute and kevlar out. Both cases are fine.

This folding technique is courtesy of Stue, who learned it from a guy that makes parachutes for the military. We will assume that if it is good enough for the military, it is good enough for us.

Shock cord should be 5 body lengths, rather than 3 body lengths.

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.

Filling Out Your Flight Card

You must fill out a flight card before launching any rockets on launch day. You must know and indicate:

NAR Flight Card
  • Your name
  • Model's name as well as whether it is a kit, plan, or original
  • What type of recovery is on-board (i.e. parachute, helicopter, streamer, etc.)
  • How many stages and engines are on-board
  • What the payload is
  • What type of rod is needed
  • The motor specs: manufacturer, type, impulse, how many, total impulse if multiple

Range Safety Check

Before you get cleared for launch, the RSO will inspect your rocket structures, motor certification, and dynamic properties. You should be prepared to answer any and all questions the RSO may have about your rocket. Remember -- the RSO has the final say on whether your rocket gets to launch or not, so it is in your best interest to prepare beforehand all the necessary paperwork, calculations, safety procedures, and proper assembly and convince the RSO you know what you are doing and your launch is unlikely to fail. A full documentation of what the RSO does (or doesn't) do can be found under Range Safety Officer.

Administrative

  • Is the flier over 18 years of age? If you are not over 18, you legally cannot launch mid or high power rockets. Sorry.
  • Is the flier certified to the power level being flown? Not really an issue for L1's since you have no certification (yet) and will not be attempting to use any motors that require a certification, but if you are flying a motor that requires a high power certification later on, you must bring your NAR/TRA membership card indicating your current membership and certification level.
  • Will the flight of the model rocket vehicle “bust” the launch site's FAA waiver? This is very important. You must be able to anticipate the altitude your rocket will fly to and be prepared to show simulation data if asked for it. For a single motor, you may be denied a launch if you expect to reach within 15% of the waiver height (15,000' for LUNAR and 16,800' for TCC). This won't be an issue for L1's, but you will certainly be asked what your rocket's expected apogee is, and you better be prepared to answer with an accurate model to back your number.
  • Will the rocket penetrate cloud cover? In accordance with Federal Aviation Regulations (FAR) (the FAA regulations pertaining to who can or can't use airspace), high power rockets cannot be launched into cloud cover greater than 50% or visibility less than 5 miles.

Motors

  • Is the motor certified? NAR, TRA, and NFPA Safety Codes require that only certified motors be used. Motors are certified by undergoing testing as set forth by the NFPA. TRA and NAR have a reciprocity agreement so that motors that are certified with one organization are upheld by the other. Main takeaway: make sure your motor is certified (it will be) and would be good to know which organization did the certification (easily looked up online).
  • What is the motor type, average thrust, and rocket weight? Is the delay time approximate for rocket? Motors may be single-use or reloadable, and can be solid, liquid, or hybrids. SSI currently only uses solid motors. Your L1 motor will likely be a single-use motor as these are less prone to errors in assembly that can occur with reloadable casings. The rule of thumb regarding motor selection is a 5-to-1 thrust-to-weight ratio. The motor delay should be set appropriately for the rocket configuration and weather conditions. Motors with longer delays have lower weight recommendations so be sure to run simulations and have a good idea of what delay you need on launch day.
  • Is the igniter a low-current igniter? DO NOT USE LOW-CURRENT IGNITERS FOR YOUR MOTOR IGNITION. I repeat. DO NOT USE LOW-CURRENT IGNITERS FOR YOUR MOTOR IGNITION. Low-current igniters, as their name suggest, ignite with very little current -- so little in fact that the continuity test can set them off. This means that if you do not follow this very important warning, you could end up in a situation where you put your rocket on the rails, connect up the leads, go to press the button for continuity and BAMMMMM YOUR ROCKET GOES FLYING OFF IN FRONT OF YOUR FACE. DO NOT USE LOW-CURRENT IGNITERS FOR YOUR MOTOR IGNITION AKA NO Electric Matches. E-matches are ok for ejection charges in avionics bays (for L2s+), but they should NOT be used for motor ignition.
  • Does your rocket motor have the ejection charge installed? This involves pouring a small amount of ejection charge into the top of your motor and putting a cap on it. Do not forget to do this. People have forgotten before (apparently) so don't let that be you, otherwise you'll find your rocket will go up quickly, and then proceed to come down very quickly. And dangerously. And you won't get certified. So don't forget.
  • Is sufficient wadding/Kevlar installed? Wadding, sometimes referred to as dog barf, is fire-retardant, blown-cellulose insulation (used in home insulation) that protects your rocket/shock cord/parachute protector from getting blown to smithereens by your ejection charge. The Kevlar pads in the Firestorm kits serve an equivalent purpose of protector your parachutes from getting fried. Be sure the Kevlar pad fully wraps around the area of your parachute that is facing the ejection charge. Use your head on this one -- what good is a Kevlar covering, if it isn't covering the part of your parachute that is going to get blasted with BP/Pyrodex?
  • What kind of motor retention system is installed? Motors can be retained with either a friction fit (not recommended) or a positive retention system such as motor clips or retaining rings (what you'll be using for Firestorms). Examine the motor retainer and retaining rings carefully and make sure the smaller ring is sitting inside the groove of the retainer, not just pressed into the retainer anywhere. Give your motor a good pull (the RSO may do this also) and make sure the motor cannot fall out in anyway.
  • What prevents the motor from flying-through the rocket? Give your motor a good push (the RSO may do this also) and make sure neither the motor nor the motor tube move inside the airframe.

Rocket Construction & Inspection

  • Is the rocket stable? Is the CG in front of the CP? Be able to identify both. You can find the CG of the rocket with the motor installed by finding its balancing point. Mark this point on the outside of your rocket. Use a simulation program to determine where your CP is and mark this on the outside also. The CG must be at least 1 caliber in front of the CP.
  • Is the nose cone fitted correctly? Check the fit of your nose cone by yourself first. Does the nose cone separate from the rocket under its own weight? It shouldn't. Add a little bit of tape around the shoulder. The right fit is such that the nose cone will not detach if you simply pick up your rocket by the nose cone, but not so tight that you need to exert excessive effort to remove it. A few strong shakes should do the trick. Also check that paint is not inside the body tube or on the shoulder, which can cause the issues with sliding the nose cone off -- sand things down carefully as needed.
  • Launch lugs and/or rail guides properly installed, positioned, and aligned? Verify your rail guides are attached securely and are in good condition (no cracks, deformations, etc). Check for any paint build up that could interfere with the launch rails -- sand as needed.
  • Are the fins in good condition and mounted parallel to the roll axis? Verify you epoxied your fins on straight. Wiggle the fins at the tip. Do your fins move or flex a lot? They shouldn't. Examine the fins for any cracks or warpage.
  • Is an appropriately-sized recovery system installed and attached? Verify that your shock cord is not frayed, burnt, or cut and that all knots are secure and will not slip out. Pull on the shock cord several times to check it is secured to your airframe properly. Check all your quick links and any other hardware are tightened completely and will not separate under load. Check that your parachute is in good condition and is not loose, burnt, or cut. Double check your Kevlar wrapping.
  • Are there vent holes? Vent holes are used to vent the rocket's internal pressure and avoid premature separation. You should have two vent holes, one in the aft section of your rocket and one in the forward, near the nose cone.

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.

Checklist of What to Know

If you do not know the answer to any part of this, look it up. Either in the above sections, or on the internet.

- How to answer questions about the bolts attaching the coupler

- How high will your rocket go? Use your own measurements of the rocket and plug them into openRocket. Don't use other peoples calculations.

- How fast will your rocket go? Same as above.

- Where is your CP?

- Where is the CG?

- How fast the rocket is going off the launch pad?

- Model of motor?

- Impulse of motor?

- Thrust of motor?

- Burn time of motor?

- Stability margin?

- What epoxy was used in construction? Ans - 30 min epoxy for the tube fins and JB Weld for hardpoint and motor retainer.

Quick G Calculation

Quick way to calculate g’s on liftoff: Take the average thrust of motor in N, divide by 5 to get lbs, divide by the weight of your rocket, you want to aim for around 5 - 6 g’s.

The H550 motor puts us at an initial launch acceleration of 30g’s, approximately 90 ft/s off the launch rod, so anything inside the tube will shake uncontrollably and possibly break. It will also cause the parachutes and other stuff in the rocket to be shoved down the tube. Be careful about how you attach the coupler as screws can catch the parachute and make it fail. Ask Ian on how to explain this to the safety officer!

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.

Clean Up

Make sure to wash off all the metal components of your rocket so they do not corrode from left over motor fuel.