MLP is rising up at Kennedy Space Center

At NASA’s Kennedy Space Center in Florida, a crane positions a sixth tower segment onto five segments already secured to a new mobile launcher, or ML, being constructed to support the Constellation Program. When completed, the tower will be approximately 345 feet tall and have multiple platforms for personnel access. The construction is under way at the mobile launcher park site area north of Kennedy’s Vehicle Assembly Building. The launcher will provide a base to launch the Ares I rocket, designed to transport the Orion crew exploration vehicle, its crew and cargo to low Earth orbit. Its base is being made lighter than space shuttle mobile launcher platforms so the crawler-transporter can pick up the heavier load of the tower and taller rocket. For information on the Ares I, visit https://www.nasa.gov/ares

 

Managers reevaluating Ares I-Y flight test

Constellation program managers agreed to reevaluate the proposed Ares I-Y flight test during an Oct. 30 Control Board and plan to take the decision up the ladder to management at NASA Headquarters soon. The decision could result in the removal of the Ares I-Y flight from the manifest in order to better align test flights with evolving program objectives.

 

As part of the program’s ongoing review of its ground and flight test strategy, managers evaluated the flight test plan and decided that the Ares I-Y flight fell too late in the vehicle development phase to provide useful information and lacks key elements to make it a true validation of the flight vehicle’s systems.

 

Originally, the I-Y test was defined as an incremental “placeholder” and planned for 2012.  It was to be a suborbital flight to test a five-segment booster, a flight production upper stage — without a J-2X engine — a functional command module and launch abort system and a simulated encapsulated service module.

 

By fall 2008, program managers were already looking at changing direction for the Ares I-Y test to improve the overall program’s chances of flying a full test vehicle by 2014. Now, with the Constellation Program nearing its preliminary design review and with maturing vehicles and systems, managers agree the I-Y test objectives can be achieved through other tests already in the manifest.

 

For example, the ascent abort test for Orion’s Launch Abort System can be incorporated into abort tests planned at White Sands Missile Range in 2012 and 2013 and on the first Orion flight in 2014. The ascent test will document the performance of the LAS in the event control of the launch vehicle is lost after first stage separation.

 

Removing the Ares I-Y flight test eliminates a unique vehicle configuration that must be designed and managed separately from the objective designs of Ares and Orion. It allows the team to focus on achieving a first launch of a thoroughly verified system and represents a tightening of the program as a function of its maturation that will ultimately save money needed for other tests.

 

“It simply does not fit where we are headed,” said Jeff Hanley, Constellation Program manager and chairman of the Control Board. “The test vehicle was intended to meet evolving needs but the current configuration is too different from what the program requires to certify the Ares/Orion vehicle systems.”

 

The current Constellation manifest shows the Ares I-Y flight test scheduled in March 2014, just a year out from the proposed first crewed flight Orion 2, planned in 2015.

 

Managers are also considering other options including a flight test that would fly in 2012 or 2013 that would have revised flight test objectives to better support vehicle development.

Is a spacewalk still a spacewalk if it's undersea?

The answer is yes if you consider that three NASA astronauts are practicing future off-planet spacewalks undersea this week off the Florida coast.

 

The three astronauts, joined by a Constellation Program engineer and a team of diving “buddies,” are performing engineering evaluations for next spring’s NEEMO 14 mission.

 

The NASA Extreme Environment Mission Operations 14 (NEEMO 14) was slipped from October to allow the National Oceanic and Atmospheric Administration (NOAA) to complete a safety review of its Aquarius underwater laboratory.

 

Aquarius, located three miles off Key Largo in the Florida Keys National Marine Sanctuary, is the world’s only permanent underwater habitat and laboratory

 

The team of NASA divers and astronauts spent last week doing preliminary work at a Key Largo, Fla., base.  This week the team will perform some engineering evaluations on a low-fidelity, full scale mock-up of the Altair lunar lander positioned next to NOAA’s lab. 

 

The engineering tests include 1/6 g operational evaluations of unloading a mock-up of the Lunar Electric Rover off the lander platform, rover hatch size evaluations, and incapacitated crew rescue operations.

 

Veteran space shuttle pilot Eric Boe is leading the NASA team. Joining Boe are veteran astronauts and aquanauts Mike Gernhardt and Richard Arnold, along with Lunar Electric Rover deputy project manager Andrew Abercromby.

 

The rover and lander mockups rival the size of the vehicles NASA is designing for future planetary exploration. The lander mockup is wider than a school bus is long and almost three times as high, measuring 45 feet wide and 28 feet high, including a six-foot high crane. The rover mockup is slightly larger than a full-size SUV, standing eight feet tall and 14 feet long.

 

Boe completed his first space flight as pilot on STS-126 in November 2008 and is assigned to pilot the STS-133 mission targeted for September 2010. Gernhardt is a veteran of four space shuttle flights, four spacewalks and two NEEMO missions. Arnold completed two spacewalks during his first spaceflight, the STS-119 mission in March and he was part of the NEEMO 13 mission in August 2007.

 

Andrew Abercromby serves as the deputy project manager and a biomedical engineer for the Lunar Electric Rover project and deputy lead for the Exploration Analogs and Mission Development project. As part of the Human Research Program, he is a project engineer for the Extravehicular Activity Physiology, Systems and Performance project for Wyle Integrated Science and Engineering Group in Houston.  He has extensive experience in planning and executing field test operations including NEEMO and NASA’s Haughton Mars Project, Desert RATS, and the Pavilion Lake Research Project.

  

NEEMO missions are a cooperative project among NASA, NOAA and University of North Carolina at Wilmington the university.

 

 

 

 

Cruising to the Moon

How long does it take humans to travel to the moon? Currently, Constellation is planning for the trans-lunar coast to take no longer than 4 days, or 96 hours. Apollo’s design requirement was for the coast time to range between 60 hours and 100 hours. The actual missions (Apollo 10-17) varied from 72 hours to 83 hours.

So why would it take longer on the future missions? It may not actually. At this point, Constellation is in the requirements definition and preliminary design phase for the lunar exploration portion of the program therefore requirements are set for the most stressing – maximum and minimum – types of conditions.

The trans-lunar cruise duration is a function of the energy or change in velocity (delta-V) applied at the trans-lunar injection, or TLI, burn. The energy requirements for the TLI burn will vary depending on where the planned landing site is located on the moon and when the mission is launched, among other factors. So, if a mission is launched on a more favorable opportunity, less energy will be required for the TLI burn and the trip would be quicker.

Since Constellation is planning for worst-case conditions at this point, the transfer time in the current plan minimizes the amount of propellant, and therefore the mass, required for trans-lunar injection. When Constellation flies actual missions to the moon, there will likely be the same flexibility as Apollo to shorten the duration of the flight toward the moon if it is desirable to do so.

Artist’s concept of NASA’s Orion crew exploration vehicle and Altair Lunar Lander while the Earth departure stage performs the trans-lunar injection burn (JSC2009-E-031248).

Orion On the Move: Florida to Texas

An Orion mockup has hit the road again for another round of testing. The full-scale vehicle is taking part in a series of tests known as PORT (Post-landing Orion Recovery Tests) to study the environment for astronauts and recovery crews after an Orion ocean splashdown. We invite you to come out and check out America’s next crew exploration vehicle during several stops on its Florida to Texas trek:

 

— Challenger, Center, Tallahassee, Fla., Mon., Aug. 10, noon to 3 p.m. EDT

— Naval Aviation Museum, Pensacola, Fla., Tues., Aug. 11, 9 a.m. to 3 p.m. CDT

— StenniSphere, NASA’s Stennis Space Center, Miss., Wed., Aug. 12, 10 a.m. to 2:30 p.m. CDT.

— Museum of Natural Science, Jackson, Miss., Aug. 13, 8 a.m. to 1 p.m. CDT

— NASA’s Johnson Space Center, Houston, Texas, Aug. 14, 3 p.m. CDT through Aug. 17, approximately 9 a.m. CDT

 

Check out a photo from the last test and get a preview of what you can see this week (minus the water).

Orion at Port Canaveral, Fla.

 

You can read more in the news release: https://www.nasa.gov/home/hqnews/2009/aug/HQ_09_183_Orion_on_the_Move.html

 

You can also follow Orion on twitter: www.twitter.com/Orioncrewmodule

A Process of Assessment

There have been recent reports containing a leaked preliminary internal Air Force assessment document regarding potential abort scenarios for the Ares I rocket and the effect on an Orion crew exploration vehicle.  The assessment, as preliminary, addressed a certain class of abort scenarios.  This class of aborts involves destruction of the first stage because of either a case over-pressure or because of a range safety initiated destruct command.  The majority of aborts do not fall into this category because of the abort criteria and flight rules the program is implementing.  The analysis is not an official Air Force position, but a starting point for working specific issues associated with the complexities of aborts. 

An ongoing exchange of information and analysis is part of the formal process for the 45th Space Wing to evaluate a new vehicle’s request to use the Eastern Range and establish an operations agreement. NASA and the Air Force work together through routine technical interchange meetings to share data and analysis on launch vehicles and payloads. This is typical of how the two organizations have worked together in the past to evaluate Apollo, space shuttle, and nuclear payload missions such as New Horizons as they were in development. A joint team, comprised of experts from both NASA and the Air Force, meets routinely to collaborate on issues related to range safety, and works to provide answers to all outstanding questions and concerns.

The program will continue to work closely with the 45th Space Wing to mature the analyses as the development of the vehicle continues, with the top priority being the ability to protect the crew and public. ‪Ares/Orion were conceived and are being designed as the safest launch vehicles in history. The findings in this preliminary Air Force analysis have provided insight into the abort environment, and each issue and concern will be answered as NASA shares more in-depth studies and analysis with the Air Force and continues to refine its models and data. Constellation is a developing program and NASA will continue to work with the Air Force as the two agencies collaborate to assure both crew and public safety.‪

Ares I-X: Let the Stacking Begin…

Stacking is set to begin for the Ares I-X vehicle on Wednesday, July 8 in the Vehicle Assembly Building at Kennedy Space Center. It’s been a long time since the workers in the VAB have seen a new vehicle. In fact, it’s been 25 years since a new vehicle was stacked.

Following nearly three years of work by thousands of dedicated team members, the Ares I-X vehicle is ready for stacking on the Mobile Launch Platform, or MLP, in the Vehicle Assembly Building at Kennedy Space Center. 

Over the last week, the management team has met for reviews. Today (July 7), a “go” was given for the stacking operations. All of the modification work has been completed in VAB High Bay 3, as well as the Mobile Launch Platform, in preparation for the new Ares I-X vehicle.

Tomorrow, the Ares I-X aft assembly, composed of the aft skirt and aft motor segment, will be rolled from the Rotation Processing and Surge Facility to the VAB and lifted by overhead crane and placed on the MLP. (Be sure to check out the KSC gallery for photo updates.)

Over the next month, the stacking operations will continue with the additional motor segments, simulated upper stage segments and the vehicle will be completed when the simulated crew module and launch abort system is added to the top. (There will be a time-lapse camera. NASA will be posting video and images.)

We will keep you posted on this blog, on our Facebook page and Twitter.

Let the stacking begin!

 

Getting a good look at the terminator

The first images from NASA’s Lunar Reconnaissance Orbiter, or LRO, are in. The images were taken along the moon’s terminator — that’s the dividing line between day and night — giving scientists a good look at the topography. It’s exciting times for the LRO scientists and the folks at NASA’s Constellation program because the close-up camera shots will help determine safe landing sites for future explorers, locate potential resources, describe the moon’s radiation environment and demonstrate new technologies. It means NASA is another step closer to returning humans to the moon.

The satellite also has started to activate its six other instruments. The Lunar Exploration Neutron Detector will look for regions with enriched hydrogen that potentially could have water ice deposits. The Cosmic Ray Telescope for the Effects of Radiation is designed to measure the moon’s radiation environment. Both were activated on June 19 and are functioning normally.

 

Instruments expected to be activated during the next week and calibrated are the Lunar Orbiter Laser Altimeter, designed to build 3-D topographic maps of the moon’s landscape; the Diviner Lunar Radiometer Experiment, which will make temperature maps of the lunar surface; and the Miniature Radio Frequency, or Mini-RF, an experimental radar and radio transmitter that will search for subsurface ice and create detailed images of permanently-shaded craters.

 

The final instrument, the Lyman Alpha Mapping Project, will be activated after the other instruments have completed their calibrations, allowing more time for residual contaminants from the manufacture and launch of LRO to escape into the vacuum of space.

This instrument is an ultraviolet-light imager that will use starlight to search for surface ice. It will take pictures of the permanently-shaded areas in deep craters at the lunar poles.

 

Can’t wait to see and learn more.

 

All eyes on LRO

Constellation has its eyes on the Lunar Reconnaissance Orbiter and is anticipating some great images. The spacecraft entered lunar orbit on the morning of June 23 and after that orbit is refined engineers will power up and calibrate LRO’s instruments. In a couple months, LRO will begin mapping the lunar surface to find future landing sites and searching for resources that would make possible a permanent human presence on the moon.

 

While the Apollo missions demonstrated that that it was possible to send humans to the moon, they did so for very short times – only three days, and at great risks. The LRO mission is paving the way for extended human habitation on the lunar surface and striving to reduce the risks to the astronauts travelling there.

 

LRO’s very high resolution cameras and laser altimeter will examine more than 50 potential landing and outpost sites on the lunar surface in enough detail to resolve an object the size of a beach ball. This will provide information to engineers currently designing the Altair lunar lander and allow them to build safe and effective landing systems, and will give mission planners the information they need to select safe landing sites.

 

Plus, the logistics resupply of a lunar outpost will be a challenge far exceeding that of the International Space Station. It will be necessary for lunar astronauts to learn to “live off the land” by utilizing the resources available on the moon. These may include water in permanently shadowed regions of the lunar poles, which could be invaluable for both consumables for the astronauts and propellant for their spacecraft. LRO instruments will map these regions of shadow and determine whether and where these resources are located. In addition, LRO will map the resources of the entire moon’s surface looking for deposits of other valuable resources, such as oxygen, locked in the lunar soil.

 

The availability of energy also will be the determining factor on how effective humans will be in accomplishing lunar science and exploration objectives. Because the moon’s axis is not tilted like the Earth’s, there are regions of the lunar poles that receive almost continuous sunlight, rather than the 28-day cycle of light and dark found in most regions. This will allow solar power systems to provide electricity to a lunar outpost with much greater efficiency. The LRO cameras will accurately determine these regions of perpetual sunlight by observing them over an entire year. 

 

See the LRO web site for additional info: http://lro.gsfc.nasa.gov/

Comprehensive Constellation Status Report Presented to the Augustine Panel

The Norm  Augustine led U.S. Human Space Flight Plans Committee heard from Doug Cooke and Jeff Hanley  yesterday during the panel’s first public meeting held at the Carnegie Institute in Washington. 

The full presentation, which includes a comprehensive status report on Constellation can be found at:

https://www.nasa.gov/exploration/library/hsfr_exploration.html

Jeff Hanley briefed that NASA is on track to maintain the March 2015 goal for the first crewed Orion/Ares flight to the International Space Station.  He emphasized how Constellation is making use of existing NASA and contractor facilities and capabilities but in a leaner, smaller more sustainable manner to not just provide crew transport to space station, but to develop future human spaceflight systems that move beyond low Earth orbit, to the moon and beyond.  

Technical progress to date is impressive.  Scan through the Augustine panel briefing charts and you can see the labor of over 10,000 civil servant and contractor employees hard at work designing, building and testing hardware.   Click and scan through an interactive tool posted to the Constellation website this week and you can see the Ares and Ares I-X, Orion, Altair vehicle designs come to life, linking design drawings to video footage of actual hardware and tests.

https://www.nasa.gov/externalflash/constellation_projects/