The Pegasus team is designing a rocket with the goal of demonstrating the feasibility of controlled recovery from high-powered flight from over 10,000 ft through the use of a parafoil. The team is currently working on the design of an L3 rocket to be launched on March 19, 2016 as well as an L1 to be launched on February 6, 2016, the purpose of which is to test the ejection of the parafoil from the airframe.

Pegasus (ARES-2)
Pegasus Flag.png
Launch 1 - L1
Launch date February 20, 2016
Launch site LUNAR
Launch 2 - L2
Launch date Pending
Launch site Pending
Launch 3 - L3
Launch date Pending
Launch site Pending
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Team Summary

Ian Gomez (Project Manager), Marie Johnson (Team lead), Austin Pineault (Structural Development and Mechanical Systems Integration), Andrew Milich (Avionics, Deployment, and Programming), John Dean (Avionics, Deployment, and Programming), Hannah Williams (Structural Development and Parafoil), Nate Simon (Parafoil and Aerodynamics).

Launch Vehicle and Payload Summary

The purpose of the Pegasus rocket is to demonstrate the feasibility of using a parafoil recovery system to create a controlled, directed recovery for a high-powered rocket from over 10,000 ft.

The payload of this rocket is the active recovery system and its backup. The payload will be a parafoil deployed at apogee and controlled by two servos throughout descent.

Vehicle Criteria

Mission Statement

The Pegasus Rocket team is seeking to develop an efficient and reliable recovery system for high-powered rockets that utilizes a parafoil instead of a parachute.

Mission Success Criteria

The mission will be considered successful if the recovered rocket would be able to pass a L3 certification inspection. This means that if the rocket experiences excessive damage to the point that it could not be re-flown that day with a reloaded motor, then the recovery system will have failed. Another criteria is that the rocket will have landed within a 300ft radius of its original target landing space.

Constraints

  1. Tripoli height ceiling of 16,800 ft
  2. Rocket construction to be made using a “minimum of metallic parts” excepting those necessary for airframe integrity
  3. Motor impulse to not exceed 10,240 N-s
  4. Redundant avionics, wiring, and safe arm systems
  5. Automated program for descent path
  6. Manual back up control system for descent path
  7. Back up recovery system consisting of main parachute
  8. Vertical descent speed of 20 ft/s maximum upon landing
  9. Budget

System Overview

Moments after reaching apogee, a parafoil will deployed from the nosecone of the Firestorm rocket. Structural and control lines of the parafoil will be secured on the exterior of the rocket. Using stepper motors and an XBee, the rocket will be monitored and controlled during descent. This includes real-time data monitoring of position, velocity, vertical speed, and system status as well as options to steer or flare the system. Initially, this will be limited to simple guidance motions such as left or right turns, or flare using both control surfaces simultaneously.

Propulsion System

The Cesaroni M1450 was chosen because it is commercially available, reloadable, complies with the Tripoli and California restrictions, keeps our rocket sub Mach-1, and should achieve a maximum height to a safe margin below the maximum ceiling. Thus even if our mass budget increases, there will still be ample altitude to test the parafoil system.

The M1450 has an average thrust of 1500 N, a total impulse of 10000 N-s, a specific impulse of 210 s, and a burn time of 6.9 s.

Flight Characteristics

With current mass budget considerations, the M1450 motor is projected to boost the rocket to a peak of roughly Mach 0.78 and an apogee of roughly 11000 ft after 27 s.

 
Altitude and Mach variation throughout the flight

On liftoff, the acceleration of the rocket is projected to be roughly 10 g, increasing to a sustained 11.5 g. A maximum drag force of roughly 85 N is expected. Max-Q is expected to occur roughly 4 s into the flight.

 
Acceleration and drag forces on the rocket during the motor firing

A nominal static stability ranging between 1.5 and 2.3 calibers is expected in the current configuration.

 
Mass decrease and change in static stability during the motor firing

Structural Design

The complete launch vehicle can be broken-down into three primary sections: nose cone, forward airframe, and aft airframe.

Nose Cone

A fiberglass nose cone will be used. A custom lay-up of fiberglass will be used to control the exact aerodynamic profile and meet the diameter requirements of the rocket.

Forward Airframe

The forward airframe will be 6“ in diameter and 44” in length. It will house, from front to rear, the primary recovery system (parafoil), backup recovery system (parachute payload), and avionics bay.

 
Structural overview for parafoil storage in forward airframe

Each of these components will be separated by bulkheads; the foreward bulkhead is designed to protect the backup recovery system from the parafoil’s expulsion and will be mobile (supported on the aft side by blocks along the inner wall of the airframe) to allow backup system to exit the rocket, while the aft bulkhead is designed to protect the avionics and therefore will be stationary.

Aft Airframe

The aft airframe will be 6“ in diameter and 48” in length, and will house the motor retainer and fins, as well as have aft attachment points for the coupler.

Fins

There are going to be three fins for this rocket. We are going to be using a trapezoidal design with a root length of 12“ and a tip of 6”. They are to have a span of roughly 12“, a leading sweep of 60, and a trailing sweep of 20. This design choice was made to keep the CP within the ”rule of thumb" 1-2 diameter distance between the CP and CG that generates correct stability. However, there is a concern with how the trailing ends of the fins, which extend beyond the aft end of the rocket, will incur damage upon landing.

This possibility of damage is to be mitigated by the material choice for the fins. Aluminum is currently the best choice, for resistance to deformation upon landing, malleability and ease of machining, as well as being relatively lightweight.

Materials

There will be a variety of materials used for the Pegasus rocket. For the airframes we are currently considering to either use polycarbonate due to its structural qualities. However, we are also considering phenolic for the airframes. The nosecone will be made of fiberglass because it is lightweight and strong as well as relatively easy to shape into smooth and specific designs, such as an ogive nosecone. The fins are currently going to be made from aluminum unless a structural equivalent can be found from a non-metal material. Inner support and structures to hold the motors and avionics will be made from a mixture of wood and aluminum bulkheads, as well as some structural support from aluminum struts.

Avionics and Telemetry

Telemetry is accomplished using two XBee 9B 900MHZ 250MW long range radio transmitters. Under line of sight conditions, these are expected to achieve a maximum range of 28 miles. We equipped both with 900 MHZ, low impedance, RP-SMA duck antennas.

 
Avionics block diagram

Avionics Teensy Pinout

A Teensy 3.2 microncontroller served as the principal brains of the rocket due to considerable size and performance advantages compared to Arduino based platforms. Through software serial, it communicated directly with the XBee (and thus the ground station) while reading from the GPS and 10DOF sensors as well.

In-Flight Tracking

The in-flight tracking will use a XBee Pro module and an Adafruit GPS receiver with a ceramic antena.

 

For the in-flight communication and redundant tracking, the rocket will rely on live communication via XBee transmitters and the use of a small SPOT GPS for precise location of the rocket.

Power Sources and Budget

Due to high power density and low weight, we chose to use a Lithium Polymer battery. As stepper motors require relatively high amounts of voltage and current, we chose a two cell, 7.4 V LiPo. As the motor’s burn time is relatively short, a battery with low mAh was suitable for these applications. This battery is required to power the Teensy, XBee, stepper motors, and sensors used for guidance.

Parafoil System

Storage and Attachment

The parafoil is going to be stored directly behind the nosecone within the forward airframe. The majority of the attachment and support lines are going to be folded in with the parafoil with the four main lines leading out of the nosecone and down the outside of the airframe. These four lines are the two control and two load bearing lines respectively. Each of these four lines is to be inserted through its own slot in the foreward/aft airframes where it is attached to the inside of the rocket near the CG.

 
Bulkhead and backup separation design

Deployment

Deployment is going to be the result of a pyrodex ejection charge that pushes off the nosecone and a drogue chute. This drogue chute then pulls out the parafoil, allowing it to open in a more controlled manner which should reduce the possibility of lines getting tangled. This should also minimize the possibility of the parafoil becoming wrapped around the airframe due to axial spin.

Guidance

We developed a series of in-flight maneuvers used for our initial L1 launch. These can be selected at any time during descent in the Python or Processing ground stations. All allow the selection of a specific period of time and were tested during initial systems experiments.

  • Turn Left: Turning left requires opposite directional movement of the two stepper motors for a period of time. During this time, the steppers are first rotated in opposite directions an equal number of steps. For the remainder of the time, the stepper motors maintain position in the turning state. A short period before the time expires, they are returned to the initial state by rotating back the same number of steps.
  • Turn right: This is accomplished in the same manner as above.
  • Flare: Flaring requires a fairly similar maneuver. Instead of rotating opposite directions, the two stepper motors are both rotated in the same direction to increase lift and drag. This causes the parafoil to slow down and momentarily reduce the rate of descent.

Ground Station

The ARES-2 Ground Station will include two equivalently functional pieces of software for GUI or text based monitoring and control of the rocket. This includes, but is not limited to:

  • A Processing GUI with in-flight instruments, real-time mapping, and graphical renderings of system status (such as velocity, vertical speed, or heading).
  • A simple Python text-based monitoring application to continually log data and send basic commands (for example, ’turn right for 15 seconds’) to the rocket.
  • Other simple applications to monitor range or other basic parameters.

Landing

There are two landing procedures possible with this rocket. The first is by flaring the parafoil upon the approach of the ground, similar to how airplanes and skydivers land. This would be performed by using the “flaring” procedure described in the Guidance section. The second is by deploying the backup parachute. This option would be used if the ability to flare the parafoil is deemed ineffective by prior testing. The backup parachute would then be deployed at around 600ft. This height would give the parachute enough time to decrease the speed of the rocket to an acceptable landing speed of 20 ft/s.

Backup Recovery System

Backup Recovery Purpose

The backup Recovery system for the Pegasus rocket is also its payload. This system has a dual purpose: to become the main source of safe recovery upon a possible failure of the parafoil due to twisting, wrapping, and breakage, or as the second, and final, stage of recovery to drop the rocket down to its predesignated landing site. This last purpose may, or may not, become used as it is pending upon how well we are able to flare the ends of the parafoil in order to slow down the rocket and have a controlled touchdown.

Backup Recovery System Design

The backup recovery system is to consist of a main parachute and a shockcord attached to a hardpoint within the rocket airframes. The parachute is going to be located inside of the inner tube that provides the resting point for the movable bulkhead.

Upon the need for the backup recovery system, a pyrodex ejection charge located behind the parachute will be ignited from a command given by the altimeter. This charge will force out the parachute, pushing the movable bulkhead out of the forward airframe with it. Since the shockcord is going to be traveling a large distance within the rocket, the shockcord will have a tennis ball around it to mitigate possible zippering of the rocket.

 
Bulkhead and backup separation design

Manufacturing and Assembly

For all of the testing, kits and other pre-made parts are going to be bought and modified in house. For the final L3, CAD will be sent out to make parts, such as the fiberglass nosecone that we are unable to make in house. The airframe tubes are going to be purchased, however modifications to them, such as cutting and reinforcement, will be done in house. The fins may also be made in house pending time. The parafoil and other recovery parts are going to be purchased through reliable vendors.

Systems Integration and Testing

Major Vehicle Launch Dates

February 6th
Launch test for parafoil deployment at 2,000ft using scale version of L3 rocket
February 20th
2nd Major Launch test for avionics system and refining of parafoil deployment
March 19th
L3 Launch

Risk Management

Safety Hazards

For this rocket using a parafoil recovery system creates most of the possible risks of having an unsuccessful flight. Our first risk is the parafoil not deploying properly. This could mean not emerging from the rocket, becoming tangled upon exit of the airframe, and becoming tangled in mid-air while opening. To mitigate the first issue, non-emergence, we are performing pre-launch date small scale tests to practice our system and amount of propellant needed to fully expel the parafoil. The second issue of becoming tangled upon exit we will also be performing small scale tests on prior to the full L3 rocket. This test will be performed again using a static run on the L3 to make sure we scaled it up properly. The final issue of becoming tangled while opening will also be examined through the small scale L1-L2 tests and should be mitigated depending on how the parafoil is folded and fit into the rocket airframe. The parafoil is also going to be contained in a freebag that will be pulled out by the drogue chute. This combination should also help prevent the other issues upon exit. In the event that all of this fails, the payload for the rocket is a parachute that is rigged to an altimeter. Upon too quick of a descent (aka parafoil mal-deployment) the parachute will deploy prematurely to slow the descent of the rocket to a safe speed of 20 m/s.

The second point of risk is when the rocket is descending while being controlled by the parafoil and the step motors. There is always a possibility of having strong winds above 10,000ft and gusts could cause major control issues for both the stepper motors and for the coded flight plan. Some fail-safes are put into place such as having overly robust stepper motors so that under larger-than-predicted forces the stepper motors will not fail. Another safe-guard are pre-written statements that are associated with the parachute. These safe-guards include too quick of a descent rate (parafoil failure), prolonged ascension after the rocket has reached apogee (in case of thermals or wind gusts forcing the parafoil upwards).

Further safe-guards are the pre-launch weather requirements. Due to the nature of the recovery system and understanding that parafoils can become rather difficult to control above certain windspeeds, the Pegasus will not plan to launch when the ground windspeed exceeds 15mph. Under these types of conditions it is not unreasonable to assume that the windspeed above 10,000ft could be close to, if not greater than, 40mph; which is too high for the recovery system to be able to be properly controlled in a successful and reliable manner by the step motors.

Budget Risks

Our current total budget for Pegasus is $4000. Most of this will be going towards the purchases of our L3 components. Currently, our projected expenditures are below that budget limit. The largest budget “risk” would be testing expenses. It is easier to predict how much the L3 components are going to cost rather than the testing because extra tests might need to be run if we come upon unexpected problems, or are simply desirous of more testing before launching the L3. For this reason, we have allocated $690 as an overhead for testing costs and unforseen, but necessary, purchases. Due to the scale of the rocket and the cost of materials we are using, it is highly unlikely that the team will burn through the entire reserve fund.

Activity Plan

Timeline

January 23rd
Small scale ground ejection tests completed.
January 30th
Small scale rocket fully assembled
February 6th
Launch test for parafoil deployment at 2,000ft using scale version of L3 rocket
February 13th
APRS transmitter, GPS ground station and XBee controller built
February 20th
2nd Major Launch test for avionics system and refining of parafoil deployment
March 5th
Optional extra launch test if necessary to continue refining systems
March 12th
Finish assembly of L3 rocket
March 19th
L3 Launch

Budget

The overall Budget that the Pegasus team has is $4000. Currently our expenditure for our L3 rocket specifically, as predicted and as already purchased, stands at $3310. An extra $400 is expected to be spent on L1-L2 testing. The current budget break-down is as follows:

Motor $710
Structural Components
Airframe $200
Nosecone $120
Fins $80
Recovery System
Parafoil $1200
Drogue $66
Backup Recovery System
Parachute $324
Recovery Accessories $120
Avionics $490
Reserve + Testing Expenses $690