Ares I-X

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Ares I-X
Ares I-X before launch
Ares I-X launch
LaunchOctober 28, 2009, 15:30 (2009-10-28UTC15:30Z) UTC
OperatorNASA
PadKennedy LC-39B
OutcomeSuccess
Apogeec. 28 miles (45 km)
Launch duration6 minutes
Components
First stage4-segment SRB with a fifth segment mass simulator
Second stageUpper stage simulator (USS)
Ares I-X insignia

Ares I-X was the first-stage prototype and design concept demonstrator of

LC-39B until Artemis 1
13 years later.

The Ares I-X vehicle used in the

Orion crew exploration vehicles. Along with the Ares V launch system and the Altair lunar lander, Ares I and Orion were part of NASA's Constellation program, which was developing spacecraft for U.S. human spaceflight after the Space Shuttle retirement
.

Test objectives

Two minutes after launch, the Ares I-X's expended Solid Rocket Booster (SRB) first stage was detached from the unpowered Upper Stage Simulator (USS); both landed in the Atlantic Ocean at different locations, as planned.

Ares I-X was the only test flight of a launch vehicle like the Ares I. The test flight objectives included:[4]

  • Demonstrating control of a dynamically similar vehicle using control algorithms similar to those used for Ares I.
  • Performing an in-flight separation/staging event between an Ares I-similar First Stage and a representative Upper Stage.
  • Demonstrating assembly and recovery of an Ares I-like First Stage at Kennedy Space Center (KSC).
  • Demonstrating First Stage separation sequencing, and measuring First Stage
    atmospheric entry
    dynamics, and parachute performance.
  • Characterizing the magnitude of integrated vehicle roll torque throughout First Stage flight.

The flight also had several secondary objectives, including:[5]

  • Quantifying the effectiveness of the first-stage booster deceleration motors.
  • Characterizing induced environments and loads on the vehicle during ascent.
  • Demonstrating a procedure for determining the vehicle's position to orient the flight control system.
  • Characterize induced loads on the Flight Test Vehicle while on the launch pad.
  • Assess potential Ares I access locations in the VAB and on the Pad.
  • Assess First Stage electrical umbilical performance.

The Ares I-X flight profile closely approximated the flight conditions that the Ares I would expect to experience through Mach 4.5, at an altitude of about 130,000 feet (40,000 m) and through a maximum dynamic pressure (“Max Q”) of approximately 800 pounds per square foot (38 kPa).[6]: 3 

The Ares I-X flight profile resembled the uncrewed Saturn I flights of the 1960s, which tested the Saturn propulsion concept.[6]: 2 

By flying the vehicle through first-stage separation, the test flight also verified the performance and dynamics of the Ares I solid rocket booster in a “single stick” arrangement, which is different from the solid rocket booster's then-current “double-booster” configuration alongside the external tank on the space shuttle.[7]

Description

Rollout of Ares I-X at Kennedy Space Center Launch Complex 39 secured by four bolts on a mobile launcher platform.

The Ares I-X vehicle consisted of a functional four-segment solid rocket booster (SRB) stage, a fifth segment mass simulator, an upper-stage simulator (USS), which was similar in shape and heavier than the actual upper stage, as well as a simulated Orion crew module (CM) and launch abort system (LAS). Since the actual upper-stage hardware could not be produced in time for the flight test, the upper-stage mass simulator allowed the booster to fly approximately the same trajectory through the first stage of flight. The USS and the CM/LAS mass simulators launched by the Ares I-X were not recovered and fell into the Atlantic Ocean. The first stage, including the fifth segment mass simulator, was recovered to retrieve flight data recorders and reusable equipment.[8]

First stage

The four-segment solid rocket motor and aft skirt for Ares I-X was drawn directly from the Space Shuttle inventory. The motor was manufactured by

Indianapolis, Indiana. The first-stage element was managed by Marshall Space Flight Center in Huntsville, Alabama.[9]
Modifications to the solid rocket booster include:

For the Ares I-X flight test, the frustum and forward skirt extension were made of aluminum. The forward skirt and fifth segment simulator were made of steel.[11]

Upper-stage simulator

The upper stage simulator

The upper-stage simulator (USS) was manufactured by NASA personnel at Glenn Research Center in Cleveland.[9] Because of transportation limitations (bridge heights on highways and rivers), the simulator was built out of eleven steel segments 9.5 feet (2.9 m) tall by 18 feet (5.5 m) wide. The USS simulated the shape, mass, and center of gravity characteristics of Ares I from the interstage to the top of the service module of the Orion Crew exploration vehicle. The centers of mass for the liquid hydrogen and liquid oxygen tanks were simulated through the use of steel ballast plates.[6]: 7 

The USS included a variety of temperature, vibration, thermal, and acoustic sensors to collect the primary data needed to meet the mission objectives. It also housed the Fault Tolerant Inertial Navigation Unit (FTINU), which controlled the vehicle's flight and primary avionics functions. For stability, the FTINU was mounted on the underside of the lower ballast plates. Ground operations personnel accessed the FTINU through a crew hatch on the side of the interstage segment, which also housed the roll control system. Each USS segment included a ladder and ring-shaped platform to allow access to the sensors and cabling for the developmental flight instrumentation. The stairs and platforms were necessary because Launch Complex 39B is not tall enough to provide crew access to the upper parts of Ares I-X.[12]

Roll control system

The roll control system (artist's impression of launch)

The active roll control system (RoCS) was needed because the flight test vehicle had a tendency to roll around its axis of forward motion. The RoCS for Ares I-X consisted of two modules containing engines originally used on now-decommissioned

Peacekeeper missiles. The RoCS performed two primary functions:[6]
: 8 

  • Rolling the vehicle 90 degrees after liftoff to emulate the Ares I roll attitude at launch.
  • Maintaining a constant roll attitude during ascent up to stage separation.

The RoCS modules, placed on opposite sides of the outer skin of the Upper Stage Simulator, used hypergolic monomethyl hydrazine (MMH) and nitrogen tetroxide (NTO) for propellants and each included two nozzles, which fired tangential to the skin and at right angles to the roll axis in order to provide a controlling roll torque. The propellants were loaded into the modules at Kennedy Space Center's Hypergol Maintenance Facility (HMF) and transported on the ground for installation into the USS in the Vehicle Assembly Building (VAB) prior to rollout to Launch Complex 39B.

The RoCS modules were designed and constructed to fit into the Interstage segment of the USS by Teledyne Brown Engineering in Huntsville, Alabama.[9][13] The engines were hot-fire tested at White Sands Test Facility in 2007 and 2008 to verify that they could perform the pulsing duty cycle required by Ares I-X.[9]

Crew Module / Launch Abort System Simulator (CM/LAS Simulator)

At the top of the Ares I-X flight test vehicle was a combined Orion crew module and launch abort system simulator, resembling the structural and aerodynamic characteristics of Ares I. The full-scale crew module (CM) is approximately 16 feet (4.9 m) in diameter and 7 feet (2.1 m) tall, while the launch abort system (LAS) is 46 feet (14 m) long.

The CM/LAS simulator was built with high fidelity to ensure that its hardware components accurately reflect the shape and physical properties of the models used in computer analyses and wind tunnel tests. This precision enables NASA to compare CM/LAS flight performance with preflight predictions with high confidence. The CM/LAS simulator also helps verify analysis tools and techniques needed to further develop Ares I.[citation needed]

Ares I-X flight data were collected with sensors throughout the vehicle, including approximately 150 sensors in the CM/LAS simulator that recorded thermal, aerodynamic, acoustic, vibration and other data. Data were transmitted to the ground via telemetry and also stored in the First Stage Avionics Module (FSAM), located in the empty fifth segment.

Aerodynamic data collected from sensors in the CM/LAS contribute to measurements of vehicle acceleration and angle of attack.[6]: 9  How the tip of the rocket slices through the atmosphere is important because that determines the flow of air over the entire vehicle.

The CM/LAS splashed down in the ocean along with the upper-stage simulator (USS) after the

boost phase
of the mission.

This simulator was designed and built by a government-industry team at Langley Research Center in Virginia. It was flown to Kennedy Space Center by C-5 transport and was the last piece of hardware stacked onto the rocket in the Vehicle Assembly Building.[9][14]

Avionics

Avionics

Ares I-X used avionics hardware from the Atlas V

thrust vector control system. The ATVC was the only new avionics box for the flight. All other components were existing or off-the-shelf
units. Ares I-X also employed 720 thermal, acceleration, acoustic, and vibration sensors as part of its developmental flight instrumentation (DFI) to collect the data necessary for the mission. Some of this data was transmitted real-time via telemetry while the rest was stored in electronics boxes located in the First Stage Avionics Module (FSAM), located inside the hollow first-stage fifth segment.

The ground-based portion of the mission's avionics included a

ground control, command, and communications (GC3) unit, which was installed on Mobile Launcher Platform-1
(MLP-1) for launch at Launch Complex 39B at Kennedy Space Center. The GC3 unit enabled the flight control system to interface with computers on the ground. The flight test vehicle flew autonomously and was controlled by the FTINU, located on the underside of the lower ballast plates of the upper-stage simulator (USS).

The avionics were developed by

Denver, Colorado, a subcontractor to Jacobs Engineering of Huntsville, Alabama, and is managed by Marshall Space Flight Center in Huntsville, Alabama.[9]

Commemorative payload

Three shoebox-size packages were affixed inside the fifth segment simulator of the first stage to carry:

Processing

Ground operations

Ares I-X at the Launch Pad

Ground operations include activities such as vehicle stacking, integration, rollout, and liftoff, while ground systems include vehicle interfaces and lightning protection. Several new procedures and hardware items were developed for Ares I-X, including:

  • A new, taller lightning protection system for Launch Complex 39B, which is taller than the existing tower used for Space Shuttle operations.
  • A Shuttle-era VAB Firing Room 1 was completely remodeled and updated with new computer hardware to support Constellation and dedicated as the Young-Crippen Firing Room named after astronauts John Young and Bob Crippen in September 2009
  • A new Mobile Launch (ML) gantry was constructed using universal connectors to allow commercial vehicles to launch using ML. ML was used in the test flight.
  • Several systems on the Crawler Transporter were updated
  • A platform inside the Vehicle Assembly Building was removed to allow the Ares I-X vehicle to fit and roll out.[citation needed]
  • A new vehicle stabilization system (VSS), which kept the vehicle from swaying on the launch pad after rollout. The VSS uses off-the-shelf hydraulic shock absorbers from the Monroe division of Tenneco, Inc.
  • ground crew
    cool.
  • The ECS interfaces to the rocket are “T-0” units, meaning they disconnected from the launch vehicle automatically when the countdown reached zero.[6]: 4 

Ground operations and ground systems were handled by United Space Alliance and NASA personnel at Kennedy Space Center.

Systems engineering and integration

The Ares I-X Systems Engineering & Integration (SE&I) Office, managed by the NASA Langley Research Center, was responsible for integrating the vehicle's parts into a complete rocket and making sure they work together as a system to meet flight test objectives. SE&I was responsible for ensuring all components functioned collectively to satisfy primary and secondary mission objectives. Detailed management of system interfaces, mission level requirements, validation plans, and flight instrumentation management were key SE&I contributions. SE&I provided the structural, thermal and aerodynamic analyses for the overall system to allow the components to be designed and built. SE&I also managed the mass of the vehicle and developed the trajectory and the guidance, navigation, and control algorithms used for vehicle flight.

To complete these tasks, wind tunnel testing and computational fluid dynamics (CFD) were used to investigate forces acting on the vehicle in various phases of flight, including lift-off, ascent, stage separation and descent. Once the basic design was understood SE&I provided structural analyses for the system to assure the rocket would behave properly once it was integrated.

Schedule development, management and control was provided by ATK Schedule Analysts permanently located at the NASA Langley Research Center working through the TEAMS contract agreement between ATK and NASA Langley.[citation needed]

Flight test

October 27, 2009 (Launch attempt 1)

Ares I-X launches from LC-39B, 15:30 UTC, October 28, 2009. The dramatic yaw maneuver to clear the launch tower is evident in the photo.

Ares I-X had been scheduled for launch on October 27, 2009, the 48th anniversary of the first

RSO's ability to issue the self-destruction command. Launch Director Ed Mango repeatedly delayed resumption of the countdown from the planned hold point at T-00:04:00.[18][19] Ultimately, constraints of the 4-hour launch window, coupled with high clouds and other last-minute concerns, caused the mission to be scrubbed for the day at 15:20 UTC on October 27, 2009. Launch was rescheduled for a four-hour window opening at 12:00 UTC on October 28, 2009.[18][20]

October 28, 2009 (Launch)

Ares I-X launch video
Mission managers watch the launch.

Ares I-X launched on October 28, 2009, at 11:30 EDT (15:30 UTC) from

LC-39B, successfully completing a brief test flight. The vehicle's first stage ignited at T-0 seconds and Ares I-X lifted off from Launch Complex 39B.[21]
The first stage separated from the upper-stage simulator and parachuted into the Atlantic Ocean roughly 150 miles (240 km) downrange of the launch site. The maximum altitude of the rocket was not immediately known, but had been expected to be 28 miles (45 km).

The launch accomplished all primary test objectives,[22] and many lessons were learned in preparing and launching a new vehicle from Kennedy Space Center.[23]

Thrust oscillation

Prior to the flight there had been some concern among NASA scientists and among Ares critics and skeptics that the thrust oscillation would prove too violent for human astronauts to safely ride an Ares rocket.

NASA Watch revealed that the first-stage solid rocket booster of the Ares I could create high vibrations during the first few minutes of ascent. The vibrations are caused by sudden acceleration pulses due to thrust oscillations inside the first stage. NASA admitted that this potential problem was very real, rating it four out of five on a risk scale. NASA was very confident it could solve the problem, referring to a long history of successful problem solving.[24] NASA officials had known about the problem since fall 2007, stating in a press release that they had wanted to solve it by March 2008.[24][25] According to NASA, analysis of the data and telemetry from the Ares I-X flight showed that vibrations from thrust oscillation were within the normal range for a Space Shuttle flight.[26]

Pad damage

Approximately two hours after launch of Ares I-X, safing crews entering pad LC-39B reported a small cloud of residual

Payload Changeout Room and the Fixed Service Structure. Both leaks were capped without injury to personnel.[27]

Due to the Pad Avoidance Maneuver performed by Ares I-X, shortly after liftoff, the Fixed Service Structure at LC-39B received significantly more direct rocket exhaust than occurs during a normal Space Shuttle launch. The resulting damage was reported as "substantial," with both pad elevators rendered inoperable, all communication lines between the pad and launch control destroyed and all outdoor megaphones melted. The vehicle-facing portions of the Fixed Service Structure appear to have suffered extreme heat damage and scorching, as do the hinge columns supporting the Rotating Service Structure.[28] This damage was anticipated as NASA intended to remove the FSS and launch future Ares flights from a "clean pad".

Parachute malfunction

During the flight, a

pyrotechnic charge on the reefer, which holds the chute together, was set off early while still inside the parachute, causing the parachute to overload and fail on deployment. The added stress on the second parachute caused it to overload and partially fail as well. The two remaining parachutes guided the booster to a rough landing, but it luckily sustained minimal damage.[29] The parachute lanyard design was changed as well to prevent repeat incidents.[29]

According to NASA, partial parachute failures were common in Space Shuttle Solid Rocket Boosters, from which the Ares I-X is derived. Eleven partial parachute failures occurred on Space Shuttle SRBs, including on STS-128.[26]

First-stage damage

A portion of the large dent in the first-stage lower segment, as photographed by divers from the recovery vessel MV Freedom Star.

The first stage was found floating upright, as is typical of expended Space Shuttle Solid Rocket Boosters. However, recovery divers noted buckling of the lower portion.[30][31] Reports also note an apparent fracture of the booster's forward segment casing and a fractured bracket that held an actuator, part of the SRM's nozzle vectoring system.[31] A NASA memo states that engineers believe that the lower segment buckled when the first stage landed at a much higher speed than designed as a result of one of three main parachutes failing to deploy, as well as the failure of a second main parachute to remain deployed.[28] It is unclear, at this point, what caused the apparent casing fracture and broken bracket, and NASA has not commented on this damage.

Upper Stage Simulator flat spin

The unpowered Upper Stage Simulator (USS), which was not meant to be retrieved, impacted further out into the Atlantic Ocean.

counterclockwise spin almost immediately after staging. After initial concerns that the motion might have been caused by a collision between the USS and the first stage,[33] further analysis showed that no actual recontact happened and that the tumble had been one of the possible behaviours predicted by pre-flight simulations.[34]

The USS was not a precise match to the characteristics of a real Ares I upper stage, and was not intended to test the upper stage's independent performance. The fact that the upper stage was not powered, and separated at a lower altitude than the real upper stage would on the final Ares I, contributed to the spin.[26]

References

Public Domain This article incorporates public domain material from websites or documents of the

National Aeronautics and Space Administration
.

  1. hdl:2060/20110014643
    .
  2. hdl:2060/20110014362
    .
  3. ^ Harwood, William (October 20, 2009). "Ares I-X rocket hauled to launch pad for critical test flight | The Space Shot – CNET News". News.cnet.com. Retrieved March 1, 2011.
  4. ^ Operational Lessons Learned from the Ares I-X Flight Test (PDF), NASA, retrieved August 6, 2022.
  5. ^ "Constellation Program: Ares I-X Flight Test Vehicle" (PDF). NASA. May 2009. Retrieved April 2, 2023.
  6. ^ a b c d e f Davis, Stephan R. Ares I-X Flight Test—The Future Begins Here (PDF) (Report). NASA NTRS. Retrieved December 10, 2022.
  7. ^ "NASA – NASA's Ares I-X Rocket". Nasa.gov.
  8. ^ Davis, Stephan R.; Askin, Bruce R. (July 25, 2010). Ares I-X: First Flight of a New Generation (PDF). 46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. Nashville, Tennessee: NASA. pp. 4–5. Archived (PDF) from the original on May 22, 2022. Retrieved May 23, 2023.
  9. ^ a b c d e f g "Arex Flight Test Vehicle Integration Map" (PDF). NASA.
  10. ^ "The Flame Trench | Florida Today's Space Team Blog". floridatoday.com. February 23, 2009. Archived from the original on February 26, 2009. Retrieved March 15, 2009.
  11. ^ "Ares I-X Press Kit" (PDF). NASA. October 2009. Archived from the original (PDF) on January 6, 2010.
  12. ^ "Ares I-X Upper Stage Simulator at NASA Glenn revealed | Metro - cleveland.com". Blog.cleveland.com. March 13, 2008.
  13. ^ "Teledyne Brown Ships Ares I-X Hardware | SpaceRef – Your Space Reference". SpaceRef. Archived from the original on September 10, 2012.
  14. ^ "NASA a Step Closer to First Flight Test of Next Crew Launch Vehicle". Reuters. January 22, 2009. Archived from the original on May 22, 2009.
  15. ^ Robert Z. Pearlman (October 26, 2009). "NASA's Ares I-X to fly on historic hardware with commemorative payload". collectSPACE.com.
  16. ^ "NASA scrubs launch of Ares I-X rocket". CNN. October 27, 2009.
  17. ^ "In a critical step before launch, technicians remove a protective cover from the Ares I-X nose sensors". NASA. Archived from the original on June 8, 2011. Retrieved October 29, 2009.
  18. ^ a b Philman, Amber (October 27, 2009). "NASA's Ares I-X Launch Rescheduled for Wednesday" (Press release). NASA.
  19. ^ Kanigan, Dan (October 27, 2009). "Flight Rules and Triboelectrification (What the Heck is That?)". NASA Ares I blog. Archived from the original on October 30, 2009.
  20. ^ "NASA – Ares 1-X Flight Test Launch Blog". Nasa.gov. October 26, 2009.
  21. hdl:2060/20110014618
    .
  22. ^ Chris Bergin (October 31, 2009), Pad 39B suffers substantial damage from Ares I-X launch – Parachute update, NASA Spaceflight.com, retrieved February 1, 2012
  23. ^ Stephan R. Davis, Operational Lessons Learned from the Ares I-X Flight Test (PDF), American Institute of Aeronautics and Astronautics, retrieved February 1, 2012
  24. ^ a b Carreau, Mark (January 19, 2008). "Severe vibration problem plagues moon rocket design". Houston Chronicle. Retrieved August 5, 2009.
  25. NASA Watch
    . Retrieved August 5, 2009.
  26. ^ a b c NASA (November 10, 2009). "Video of Ares I-X First Stage splashdown". Space.com.
  27. Floridatoday.com. Archived from the original
    on November 2, 2009. Retrieved October 30, 2009.
  28. ^ a b Bergin, Chris (October 31, 2009). "Pad 39B suffers substantial damage from Ares I-X launch – Parachute update". NASASpaceFlight.com.
  29. ^ a b Jennifer Stanfield (April 5, 2010). "The Root of the Problem: What Caused the Ares I-X Parachute to Fail?". nasa.gov.
  30. ^ Harwood, William (October 29, 2009). "NASA assessing parachutes and dented Ares 1-X booster". Spaceflightnow.com.
  31. ^
    Floridatoday.com. Archived from the original
    on November 1, 2009. Retrieved October 30, 2009.
  32. ^ Dunn, Marcia (October 27, 2009). "NASA's new moon rocket makes first test flight". Associated Press. Archived from the original on January 2, 2013.
  33. NASAspaceflight.com
    . October 28, 2009.
  34. ^ Clark, Stephen (October 30, 2009). "Parachute failure causes damage to Ares 1-X booster". Spaceflightnow.com.

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