ESA’s Big Cargo Ship Departs from the Space Station

The view when ATV-3 approached the ISS in 2012. Credit: NASA.

After a three-day delay, the European Space Agency’s “Edoardo Amaldi” Automated Transfer Vehicle (ATV-3) undocked from the aft port of the International Space Station’s Zvezda service module at 21:44 UTC (5:44 p.m. EDT) on Friday.

Tuesday’s initial attempt to undock the European cargo ship was called off due to a communications error between the Zvezda module’s proximity communications equipment and computers on the ATV. Russian flight controllers resolved the problem, but then an additional delay occurred because of the possibility of two pieces of space debris coming close to the ISS, and the ATV would have been used to perform an avoidance maneuver; however, it was later deemed the debris posed no threat.

Image of the ATV-3 when it reached the International Space Station on March 28, 2012. Credit: NASA TV

Expedition 33 Flight Engineers Yuri Malenchenko and Aki Hoshide, who together closed up the hatches to ATV-3 Monday, monitored its automated departure from a control panel inside Zvezda. Meanwhile, Commander Suni Williams photographed the departing space freighter to document the condition of its docking assembly.

ATV-3, now filled with trash and unneeded items, backed away to a safe distance from the orbiting complex after undocking. Once it reaches distance about 4,500 miles in front of the station, the European cargo craft will fire its engines twice on Tuesday, Oct. 2, to send it into the Earth’s atmosphere for a planned destructive re-entry that evening. As the ATV-3 plunges back to the Earth, the Re-Entry Breakup Recorder that Hoshide installed inside the vehicle will collect and transmit engineering data to enhance the efficiency of spacecraft designs and minimize the hazards to people and property on the ground even in the case of an uncontrolled re-entry for future cargo ships.

“Edoardo Amaldi,” named for the 20th-century Italian physicist regarded as one of the fathers of European spaceflight, delivered 7.2 tons of food, fuel and supplies to the orbiting complex after docking to the station March 28. The fourth ATV, named “Albert Einstein,” is slated to launch in April 2013. More than 32 feet long — about the size of a traditional London double-decker bus – the ATV is the largest and heaviest vehicle that provides cargo resupply for the station.

Space Debris Threat May Require Avoidance Maneuver for Space Station

The International Space Station. Credit: NASA

UPDATE (9/27/2012, 13:00 UTC) NASA now says that with additional tracking, they have determined the two pieces of space debris do not pose a threat to the ISS, and a debris avoidance maneuver scheduled for Thursday morning was cancelled by the flight control team at Mission Control. The ATV undocking time on Friday is still being decided at the time of this posting. See additional info at NASA’s website. (End of update)

International Space Station officials are keeping a watchful eye on two different pieces of space junk that may require the ISS to steer away from potential impact threats. Debris from the Russian COSMOS satellite and a fragment of a rocket from India may come close enough to the space station to require a debris avoidance maneuver. If needed, the maneuver would be done using the ESA’s Automated Transfer Vehicle (ATV) “Edoardo Amadi.” The ATV was supposed to undock last night, but a communications glitch forced engineers to call off the departure.

Both pieces of debris are edging just inside the so-called “red zone” of miss distance to the station with a time of closest approach calculated to occur Thursday at 14:42 UTC (10:42 a.m. Eastern time.) It is not known how large the object is.

An approach of debris is considered close only when it enters an imaginary “pizza box” shaped region around the station, measuring 1.5 x 50 x 50 kilometers (about a mile deep by 30 miles across by 30 miles long) with the vehicle in the center.

NASA says the three-person Expedition 33 crew is in no danger and continues its work on scientific research and routine maintenance. The current crew includes NASA astronaut Sunita Williams, Japanese astronaut Akihiko Hoshide and Russian cosmonaut Yuri Malenchenko.

If the maneuver is required – and NASA said it could be called off any time — it would occur at 12:12 UTC (8:12 a.m. EDT) Thursday, using the engines on the ATV, which remains docked to the aft port of the Zvezda Service Module. It usually takes about 30 hours to plan for and verify the need for an avoidance maneuver.

Debris avoidance maneuvers are conducted when the probability of collision is greater than 1 in 100,000, if it will not result in significant impact to mission objectives. If it is greater than 1 in 10,000, a maneuver will be conducted unless it will result in additional risk to the crew.

Only three times during the nearly 12 years of continual human presence on the ISS has a collision threat been so great that the crew has taken shelter in the Soyuz vehicles. (Those events occured on March 12, 2009, June 28, 2011 and March 24, 2012.) During those events, the station was not impacted. While the ISS likely receives small micrometeoroid hits frequently (based on experiments left outside the ISS and visual inspections of the station’s hull) no large debris impacts have occurred that have caused depressurization or other problems on the ISS.

Tuesday’s initial attempt to undock the ATV was called off due to a communications error between the Zvezda module’s proximity communications equipment and computers on the ATV. Russian engineers told mission managers that they fully understand the nature of the error and are prepared to proceed to a second undocking attempt, which has been postponed to Friday at the earliest, due to the potential space debris threat.

Once it is undocked, the ATV will move to a safe distance away from the station for a pair of engine firings that will send the cargo ship back into the Earth’s atmosphere to burn up over the Pacific Ocean.

The ATV still has extra fuel on board, and so the decision was made that if need, that available resource would be used.

Here’s the info on NASA’s criteria for performing debris avoidance maneuvers.

Source: NASA

*this article has been updated

Next SpaceX Launch to ISS Set for October 7

SpaceX’s Falcon 9 rocket with a Dragon spacecraft is rolled out to the company’s launch pad in Cape Canaveral, Florida.
Credit: SpaceX

There will be more Dragons in space! The SpaceX Dragon’s next launch to the International Space Station has been scheduled for Sunday, October 7, 2012, NASA and SpaceX announced today. This will be the first of 12 contracted flights by SpaceX to resupply the space station and marks the second trip by a Dragon to the station, following a successful demonstration mission in May.

NASA said they have confirmed the status and readiness of the Falcon 9 rocket and its Dragon cargo spacecraft for the SpaceX CRS-1 mission, as well as the space station’s readiness to receive Dragon.

Dragon will be filled with about 450 kg (1,000 pounds) of supplies. This includes materials to support the 166 investigations planned for the station’s Expedition 33 crew, including 63 new science investigations. The Dragon will return about 330 kg (734 lbs) of scientific materials, including results from human research, biotechnology, materials and educational experiments, as well as about 230 kg (504 lbs) of space station hardware.

Materials being launched on Dragon will support experiments in plant cell biology, human biotechnology and various materials technology demonstrations, among others. One experiment, called Micro 6, will examine the effects of microgravity on the opportunistic yeast Candida albicans, which is present on all humans. Another experiment, called Resist Tubule, will evaluate how microgravity affects the growth of cell walls in a plant called Arabidopsis. About 50 percent of the energy expended by terrestrial-bound plants is dedicated to structural support to overcome gravity. Understanding how the genes that control this energy expenditure operate in microgravity could have implications for future genetically modified plants and food supply. Both Micro 6 and Resist Tubule will return with the Dragon at the end of its mission.

Expedition 33 Commander Sunita Williams of NASA and Aki Hoshide of the Japan Aerospace Exploration Agency will use the CanadArm2 to grapple the Dragon following its rendezvous with the station on Wednesday, Oct. 10. They will attach the Dragon to the Earth-facing port of the station’s Harmony module for a few weeks while crew members unload cargo and load experiment samples for return to Earth.

Dragon is scheduled to return in late October, and splash down via parachute in the Pacific Ocean off the coast of southern California.

Endeavour Departs Kennedy Forever for California Home

Image caption: Endeavour departs Kennedy Space Center forever on Sept 19 on last flight of NASA’s Space Shuttle Program. Credit: Ken Kremer

Under cloudy skies at first light, Space Shuttle Endeavour departed NASA’s Kennedy Space Center in Florida early Wednesday morning, Sept. 19, at about 7:22 a.m. EDT marking the final flight of NASA’s storied shuttle program.

The 100 ton Endeavour was secured atop NASA’s specially modified 747 Shuttle Carrier Aircraft for the cross-country ferry flight to California and Los Angeles International Airport.

The farewell flight went off without a hitch following two days of weather related delays. The shuttle & 747 Shuttle Carrier Aircraft (SCA) Jumbo Jet were in tip top shape.

Image caption: Endeavour’s Final Takeoff atop modified Boeing 747 from the Kennedy Space Center on Sept. 19 to California home. Credit: Ken Kremer – www.kenkremer.com

Hordes of local spectators and excited tourists from several continents caught a magnificent last glimpse of the piggybacked pair as they flew two looping north-south farewells over the Florida Space Coast making a low pass over nearby beaches, Patrick Air Force Base, Cape Canaveral Air Force Station, Kennedy Space Center Visitor Complex, and the shuttle landing runway at Kennedy before leaving the area to a mix of emotions both happy and sad.

Then all of a sudden after some 25 minutes, the dynamic duo disappeared without warning into the hazy clouds, flying on a north east heading and across the Florida panhandle.

After making low-level passes over NASA’s Stennis Space Center in southwest Mississippi and the Michoud Assembly Facility in New Orleans, Endeavour touched down at the Johnson Space Center at about 10:40 a.m. at Houston’s Ellington Field for a curtailed overnight stay.

Image caption: Endeavour departs Kennedy Space Center on Sept 19 on last flight accompanied by T-38 training jet. Credit: Ken Kremer

21 years after rolling out from the Palmdale assembly facility in California where she was constructed, Endeavour landed at Edwards Air Force Base at 3:50 p.m. EDT today, Sept. 20.

Early Friday morning (Sept. 21), Endeavour and the SCA will take flight on a victory lap initially heading north for low level passes over Sacramento and the San Francisco Bay area including the Golden Gate bridge – akin to the April 2012 flight of Enterprise over NYC. Then the pair will turn south and pass over NASA’s Ames Research Center, Vandenberg Air Force Base and NASA’s Jet Propulsion Laboratory before heading into the Los Angeles area and landing at Los Angeles International Airport.

In October, Endeavour will be towed over 2 days through the streets of Inglewood and Los Angelos to begin a new mission inspiring future explorers at her permanent new home at the California Science Center.

Endeavour was NASA’s youngest orbiter and flew 25 missions and traveled 122,883,151 miles during 299 days in space.

NASA’s trio of shuttle orbiters were forcibly retired in July 2011 following the successful STS-135 mission to the International Space Station.

Ken Kremer

Image caption: Endeavour prepares for final takeoff from the Shuttle Landing Facility at KSC. Credit: Brent Houston

Image caption: STS-130 astronaut Kay Hire greets space enthusiasts at the shuttle landing strip during the flyaway of Endeavour. Credit: Klaus Krueger

Ken Kremer with Space Shuttle Endeavour and the 747 Shuttle Carrier Aircraft (SCA) at the Shuttle Landing Facility at the Kennedy Space Center for final flyaway departure in September 2012 reporting for Universe Today. Credit: Brent Houston

Expedition 32 Lands Safely in Kazakhstan

Welcome home to Gennady Padalka, Joe Acaba and Sergei Revin! The trio landed safely in Kazakhstan at 02:54 UTC on Monday, September 17 (8:53 a.m. Kazakhstan time Monday, 10:53 p.m. EDT Sunday, September 16). Expedition 32 officially ended when Soyuz TMA-04M the trio undocked at 23:09 UTC Sunday from the Poisk module. The had been on the International Space Station since May 17, spending a total of 123 days on the orbital laboratory.

The Soyuz TMA-04M spacecraft is seen as it lands with the Expedition 32 crew. Credit: NASA/Carla Cioffi

Expedition 33 is now underway as Commander Suni Williams and Flight Engineers Aki Hoshide and Yuri Malenchenko continue their stay until Nov. 12

Padalka ceremonially handed the controls of the station over to Williams on Saturday afternoon. He previously commanded two International Space Station missions including Expeditions 9 and 19. His first spaceflight was aboard the Russian Mir space station in 1998 bringing his total spaceflight experience to 711 days.

Here’s the undocking video:

Williams is serving her second mission in space, her first being Expedition 14 as flight engineer. She has conducted six spacewalks, four during Expedition 14 and two on Expedition 32, for a total of 44 hours and two minutes.

A new crew is set to join Expedition 33 when Flight Engineers Kevin Ford, Oleg Novitskiy and Evgeny Tarelkin launch Oct. 15 aboard the Soyuz TMA-06M spacecraft for an Oct. 17 docking to Poisk. Ford will command Expedition 34 when Williams, Hoshide and Malenchenko complete their mission.

More landing images can be seen at NASA’s Flickr page.

Shuttle Endeavour mated to Jumbo Jet for Final Flight

Image caption: Endeavour mated to Boeing 747 in the Mate-Demate device at the Kennedy Space Center Shuttle Landing Facility on Sept. 14 for Final Ferry Flight to California on Sep. 17. Credit: Ken Kremer

Space Shuttle Endeavour was joined to the 747 Jumbo carrier jet that will carry her majestically on Sept 17 on her final flight to the California Science Center – her permanent new home at the in Los Angeles. Enjoy my photos from onsite at the Kennedy Space Center in Florida.

On Friday (Sept. 14), Endeavour was towed a few miles in the predawn darkness from the Vehicle Assembly Building (VAB ) to the Shuttle Landing Facility (SLF) and the specially modified 747 known as the Shuttle Carrier Aircraft, or SCA.

In a day long process, Endeavour departed the VAB at 5:04 a.m. and was hauled into the gantry-like Mate-Demate device, hoisted and then lowered onto the awaiting 747 Jumbo Jet. The pair were joined at about 2:41 p.m.

Image caption: Endeavour towed past waiting Boeing 747 Shuttle Carrier Aircraft (SCA) at the Kennedy Space Center Shuttle Landing Facility on Sept. 14 for Final Ferry Flight to California on Sep. 17. Credit: Ken Kremer

Final work to hard mate NASA’s youngest orbiter to the SCA Jumbo Jet known as NASA 905 is due to be completed by Sunday.

The 747 crew will fly perform multiple, crowd pleasing low flyovers of the Florida space coast region, the KSC Visitor complex and the beaches – giving every spectator a thrilling front row seat to this exciting but bittersweet moment in space history as the shuttle takes flight for the very final time.

Image caption: Endeavour towed out of the Vehicle Assembly Building on the way to the Kennedy Space Center Shuttle Landing Facility on Sept. 14 for Final Ferry Flight to California on Sep. 17. Venus shines to the left. Credit: Ken Kremer – www.kenkremer.com

Everyone involved felt a strong mix of emotions from pride in the tremendous accomplishments of NASA’s Space Shuttle Program to the sad and bittersweet feeling that comes with the retirement of all 3 orbiters barely one third of the way into their design lifetime. All three shuttles could easily have flown tens of millions more miles but for lack of money and political support from Washington D.C.

Image caption: Endeavour mated on top of NASA SCA at Shuttle Landing Facility on Sept. 14 for Final Ferry Flight to California on Sep. 17. Credit: Ken Kremer

Altogether Endeavour flew 25 missions and traveled 122,883,151 miles during 299 days in space.

Ken Kremer

Image caption: Endeavour gently lowered on top of NASA SCA with Ken Kremer on hand at the Kennedy Space Center Shuttle Landing Facility on Sept. 14 for Final Ferry Flight to California on Sep. 17. Credit: Ken Kremer

Editor’s note: Visit John O’Connor’s NASATech website for panoramic views of Endeavour’s mating:
http://nasatech.net/EndeavourMDM3_120914/

http://nasatech.net/EndeavourMDM4_120914/

http://nasatech.net/EndeavourMDM5_120914/

On the Hunt for High-Speed Sprites

Air glow (along with a lightning sprite) is visible in this image from the International Space Station. Credit: NASA

A bright red sprite appears above a lightning flash in a photo captured from the ISS

Back on April 30, Expedition 31 astronauts aboard the ISS captured this photo of a red sprite hovering above a bright flash of lightning over Myanmar. Elusive atmospheric phenomena, sprites are extremely brief bursts of electromagnetic activity that are associated with powerful lightning discharges, but exactly how and why they form isn’t yet known — although recent research (along with some incredible high-speed video) is shedding new light on sprites.

Although the appearance of bright high-altitude flashes above thunderstorms have been reported by pilots for nearly a century, it wasn’t until 1989 that a sprite was captured on camera — and the first color image of one wasn’t taken until 1994.

So-named because of their elusive nature, sprites appear as several clusters of red tendrils above a lighting flash followed by a breakup into smaller streaks, often extending as high as 55 miles (90 km) into the atmosphere. The brightest region of a sprite is typically seen at altitudes of 40-45 miles (65-75 km).

Because they occur above storms, only last for a thousandth of a second and emit light in the red portion of the visible spectrum (to which our eyes are the least sensitive) studying sprites has been notoriously difficult for atmospheric scientists. Space Station residents may get great views but they have lots of other things to do in the course of their day besides sprite hunting! Luckily, a team of scientists were able to capture some unprecedented videos of sprites from airplanes in the summer of 2011, using high-speed cameras and help from Japan’s NHK television.

Chasing storms over Denver via plane for two weeks, researchers were able to locate “hot zones” of sprites and capture them on camera from two planes flying 12 miles apart. Combining their videos with ground-based measurements they were able to create 3-dimensional maps of the formation and evolution of individual sprites.

Based on the latest research, it’s suggested that sprites form as a result of a positive electrical charge within a lightning strike that reaches the ground, which leaves the top of the cloud negatively charged — a one-in-ten chance that then makes conditions above the cloud “just right” for a sprite to form higher in the atmosphere.

“Seeing these are spectacular,” said Hans C. Stenbaek-Nielsen, a geophysicist at the University of Alaska in Fairbanks, Alaska, where much sprite research has been conducted. “But we need the movies, because not only are they so fast that you could blink and miss them, but they emit most of their light in red, where the human eye is relatively blind.”

An example of how energy can be exchanged between lower and higher regions of Earth’s atmosphere, it’s been suggested that sprites could also be found on other planets as well, and may provide insight into the exotic chemistries of alien atmospheres.

Read more on NASA Heliophysics here.

Main image: Image Science & Analysis Laboratory, NASA Johnson Space Center. Inset image: the first color image of a sprite  (NASA/UAF.) Video: NHK.

Shields Up! ISS Spacewalkers Install New Micrometeorite Shields

International Space Station Commander Gennady Padalka and Flight Engineer Yuri Malenchenko completed the first spacewalk of the Expedition 32 mission on Monday, Aug. 20, and successfully completed several tasks, including the installation of micrometeoroid debris shields on the exterior of the Zvezda service module and the deployment of a small science satellite.

Graphic showing the Debris Panel Installation Sites. Credit: NASA

The primary task during the five-hour, 51-minute EVA was to move the Strela-2 cargo boom from the Pirs docking compartment to the Zarya module. The move was another step in preparing Pirs for its eventual undocking and disposal, which will make room for the docking of the new Russian multipurpose laboratory module to the Zvezda nadir port.

This was the 163rd in support of station assembly and maintenance.

A second Expedition 32 spacewalk, scheduled for Aug. 30, will be conducted by NASA Flight Engineer Sunita Williams and Japan Aerospace Exploration Agency Flight Engineer Akihiko Hoshide. This will be the first U.S.-based spacewalk in over a year, since July 2011. During the planned 6.5-hour EVA, the astronauts will replace a faulty power relay unit on the station’s truss, rig power cables for the arrival late next year of a Russian laboratory module, replace a failing robotic arm camera and install a thermal cover on a docking port.

New Stunning ISS Time-lapse: Earth Illuminated

“If you could see the Earth illuminated when you were in a place as dark as night, it would look to you more spendid than the Moon.”

— Galileo Galilei.

400 years ago, Galileo could only imagine what the view of Earth would be like from space. Today, we have people on board the International Space Station who see that view every day. This new beautiful time-lapse shows aurora, lightning, our Milky Way Galaxy, city lights and other sights as seen from orbit.

Below is a great still image from this video, an amazing look through the ISS’s Cupola as Earth whizzes by:

Image caption: A view out the Cupola of the ISS. Credit: NASA

For more time-lapse videos and imagery, visit NASA’s Gateway to Astronaut Photography of Earth website.

Progress Resupply Ship Takes Fast-Track to ISS, Arriving 6 Hours After Launch

After a flawless launch, an unmanned Russian Progress resupply ship used a new expedited technique to reach the International Space Station in hours instead of days. Progress 48 was loaded with almost three tons of food, fuel and supplies for the six crew members, and it docked successfully to the Pirs docking compartment on August 1, just six hours after the launch from the Baikonur Cosmodrome in Kazakhstan at 19:35 UTC (3:35 p.m. EDT, 1:35 a.m. Aug. 2 Baikonur time). The fast trip and rendezvous was designed to test a method for conducting additional firings of the Progress engines early in its mission to expedite the time required for a Russian vehicle to reach the complex.

Russian officials say the technique could be applied to manned Soyuz vehicles in the future to improve crew comfort and extend the life of the Soyuz return vehicle.

Russian cosmonaut Gennady Padalka has been quoted as saying it is every cosmonaut’s dream to only have a 6-hour flight in the cramped Soyuz!

Russian engineers and managers are still assessing the new technique, but by all appearances the quick trip seemed to be a great success. This Progress vehicle will stay at the ISS until December.

During the docking, NASA also tested a new technique of attitude control for the ISS which will save fuel, requiring 10 times less fuel to put the station in the proper orientation relative to Earth for the unpiloted cargo vehicle’s arrival.

According to Pooja Jesrani, lead attitude determination and control officer (ADCO) for this expedition at the Mission Control Center in Houston, the new maneuver is called the optimal propellant maneuver, or OPM. OPM is an improvement on the standard zero propellant maneuver, or ZPM, also developed by Draper Laboratory. The OPM takes into account the need to make the orientation, or attitude, changes to the space station faster than the ZPM. This speed avoids thermal concerns on the exterior of the station’s modules.

“Maneuvers such as the OPM will increase the International Space Station’s efficiency by using less propellant,” Jesrani said. “Additionally, the reduction in thruster firings during an OPM results in the station enduring lower structural loads. These benefits, among others, will help increase the longevity of the station.”

The maneuvers to and from the docking attitude are expected to save more than 90 percent of the fuel typically used when a Russian cargo spacecraft docks with the orbiting outpost.

Source: NASA