Remote camera photo from “Of Course I Still Love You” droneship of SpaceX Falcon 9 first stage landing following launch of Dragon cargo ship to ISS on CRS-8 mission. Credit: SpaceX
SpaceX has released a slew of up close photos showing the sensational “super smooth” touchdown last week of a Falcon 9 booster on a tiny droneship at sea located several hundred miles (km) off the East coast of Florida.
“This time it really went super smooth,” Hans Koenigsmann, SpaceX VP of Flight Reliability, told Universe Today at the NorthEast Astronomy and Space Forum (NEAF) held in Suffern, NY. “The rest is history almost.”
The dramatic propulsive descent and soft landing of the SpaceX Falcon 9 first stage took place last Friday, April 8 about 9 minutes after blasting off from Cape Canaveral Air Force Station at 4:43 p.m. EDT on the Dragon CRS-8 resupply mission for NASA to the International Space Station (ISS).
The breathtaking new photos show the boosters central Merlin 1D engine refiring to propulsively slow the first stage descent with all four landing legs unfurled and locked in place at the bottom and all four grid fins deployed at the top.
Why did it all go so well, comparing this landing to the prior attempts? Basically the return trajectory was less challenging due to the nature of the NASA payload and launch trajectory.
“We were more confident about this droneship landing,” Koenigsmann said at NEAF.
“I knew the trajectory we had [for CRS-8] was more benign, although not super benign. But certainly benigner than for what we had before on the SES-9 mission, the previous one. The [droneship] landing trajectory we had for the previous one on SES-9 was really challenging.”
“This one was relatively benign. It was really maybe as benign as for the Orbcomm launch [in December 2015] where we had the land landing.”
Timelapse sequence shows dramatic landing of SpaceX Falcon 9 first stage on “Of Course I Still Love You” droneship as captured by remote camera on 8 April 2016. Credit: SpaceX
The diminutive ocean landing platform measures only about 170 ft × 300 ft (52 m × 91 m). SpaceX formally dubs it an ‘Autonomous Spaceport Drone Ship’ or ASDS.
The ocean going ship is named “Of Course I Still Love You” after a starship from a novel written by Iain M. Banks.
It was stationed some 200 miles off shore of Cape Canaveral, Florida surrounded by the vastness of the Atlantic Ocean.
Remote camera photo from “Of Course I Still Love You” droneship of Falcon 9 first stage landing following launch of Dragon cargo ship to ISS on CRS-8 mission on 8 April 2016. Credit: SpaceX
“The CRS-8 launch was one of the easiest ones we ever had.”
The revolutionary rocket recovery event counts as the first successful droneship landing of a rocket in history and is paving the way towards eventual rocket recycling aimed at dramatically slashing the cost of access to space.
The final moments of the 15 story tall boosters approach and hover landing was captured up close in stunning high resolution imagery recorded by multiple remote cameras set up right on the ocean going platform by SpaceX photographer Ben Cooper.
Landing the booster on land rather than at sea was actually an option this time around. But SpaceX managers wanted to try and nail a platform at sea landing to learn more and validate their calculations and projections.
“As Elon Musk said at the post-landing press conference of Friday, we could have actually come back to land- to land this one on land,” Koenigsmann elaborated.
“But we decided to land on the drone ship first to make sure that on the droneship we had worked everything out!”
“And that’s exactly what happened. So I felt this was only going out a little bit on the limb,” but not too much.”
Remote camera photo from “Of Course I Still Love You” droneship of Falcon 9 first stage landing following launch of Dragon cargo ship to ISS on CRS-8 mission on 8 April 2016. Credit: SpaceX
Before the CRS-8 launch, Koenigsmann had rated the chances of a successful landing recovery rather high.
Three previous attempts by SpaceX to land on a droneship at sea were partially successful, as the stage made a pinpoint flyback to the tiny droneship, but it either hit too hard or tipped over in the final moments when a landing leg failed to fully deploy or lock in place.
“Everything went perfect with the launch,” Koengismann said. “We just still have to do the post launch data review.”
“I am really glad this went well.”
Droneship touchdown of SpaceX Falcon 9 first stage on “Of Course I Still Love You” as captured by remote camera on 8 April 2016. Credit: SpaceX
This recovered Falcon 9 booster finally arrived back into Port Canaveral, Florida four days later in the early morning hours of Tuesday, April 12 at about 1:30 a.m. EDT.
Recovered SpaceX Falcon 9 rocket moved by crane from drone ship to an upright storage cradle on land at Port Canaveral, Florida on April 12, 2016. Credit: Julian Leek
The primary goal of the Falcon 9 launch on April 8 was carrying the SpaceX Dragon CRS-8 cargo freighter to low Earth orbit on a commercial resupply delivery mission for NASA to the International Space Station (ISS).
Dragon arrived at the station on Sunday, April 10, loaded with 3 tons of supplies, science experiments and the BEAM experimental expandable module.
Landing on the barge was a secondary goal of SpaceX and not part of the primary mission for NASA.
Watch this launch video from my video camera placed at the pad:
Video Caption: Spectacular blastoff of SpaceX Falcon 9 rocket carrying Dragon CRS-8 cargo freighter bound for the International Space Station (ISS) from Space Launch Complex 40 on Cape Canaveral Air Force Station, FL at 4:43 p.m. EST on April 8, 2016. Up close movie captured by Mobius remote video camera placed at launch pad. Credit: Ken Kremer/kenkremer.com
The recovered booster will be cleaned and defueled, says SpaceX spokesman John Taylor.
SpaceX engineers will conduct a series of 12 test firings to ensure all is well operationally and that the booster can be re-launched.
SpaceX hopes to refly the recovered booster in a few months, perhaps as early as this summer.
Droneship touchdown of SpaceX Falcon 9 first stage on “Of Course I Still Love You” as captured by remote camera on 8 April 2016. Credit: SpaceX
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
Learn more about SpaceX, NASA Mars rovers, Orion, SLS, ISS, Orbital ATK, ULA, Boeing, Space Taxis, NASA missions and more at Ken’s upcoming outreach events:
Apr 17: “NASA and the Road to Mars Human Spaceflight programs”- 1:30 PM at Washington Crossing State Park, Nature Center, Titusville, NJ – http://www.state.nj.us/dep/parksandforests/parks/washcros.html
SpaceX Falcon 9 booster successfully lands on droneship after blastoff on Dragon CRS-8 mission to ISS for NASA on April 8, 2016. Credit: SpaceXHans Koenigsmann, SpaceX VP of Flight Reliability at NorthEast Astronomy and Space Forum, NY, discusses SpaceX Falcon 9 and Dragon launches. Credit: Ken Kremer/kenkremer.com
Bigelow Aerospace and United Launch Alliance (ULA) announced they are joining forces to develop and launch the world’s first commercial space habitat to Low Earth Orbit (LEO) by 2020 – potentially as a huge and revolutionary new addition to the International Space Station (ISS).
The expandable habitat will be based on the Bigelow Aerospace B330 module and would be carried to orbit on the most powerful version of ULA’s venerable Atlas V rocket.
Robert Bigelow, founder and president of Bigelow Aerospace, and Tory Bruno, ULA president and CEO announced the partnership on the fully commercial space habitat during a joint media briefing held at the 32nd Space Symposium in Colorado Springs, Colorado on April 11.
“We could not be more pleased than to partner with Bigelow Aerospace and reserve a launch slot on our manifest for this revolutionary mission,” said Tory Bruno, ULA president and CEO.
The B330 boasts an interior volume of 330 cubic meters (12,000 cu ft). It measures 57 feet (17.3 m) in length, weighs 20 tons and offers a design life span of 20 years.
If NASA agrees to attach the B330 to the ISS, the stations habitable volume would grow by a whopping 30% in one giant step.
“The alliance represents the first-ever commercial partnership between a launch provider and a habitat provider,” according to ULA.
The advantage of expandable habitats is that they offer a much better volume to weight ratio compared to standard rigid structures, such as all of the current ISS pressurized modules.
The station based B330 concept is named XBASE or Expandable Bigelow Advanced Station Enhancement.
Schematic of the Bigelow Aerospace B330 expandable module tucked inside the fairing of a ULA Atlas V 552 rocket. Credit: ULA
The additional volume would enable a significant increase in the orbiting outposts ability to support research and development operations and manufacturing processes for NASA and commercial users.
Bigelow further views the B330 and follow on modules as a potential destination for space tourism and a beneficial component for human missions to the Moon and Mars.
“We are exploring options for the location of the initial B330 including discussions with NASA on the possibility of attaching it to the International Space Station (ISS),” said Robert Bigelow, founder and president of Bigelow Aerospace.
“In that configuration, the B330 will enlarge the station’s volume by 30% and function as a multipurpose testbed in support of NASA’s exploration goals as well as provide significant commercial opportunities. The working name for this module is XBASE or Expandable Bigelow Advanced Station Enhancement.”
Bigelow said his firm plans to build two B330 modules by 2020.
The B330 would be tucked inside the cavernous payload fairing of the Atlas V which would launch in the 552 configuration with 5 meter diameter fairing with 5 solid rocket booster attached to the first stage and a dual engine Centaur second stage.
Launch of Bigelow B330 expandable habitat module tucked inside ULA Atlas V payload fairing. Credit: ULA
“When looking for a vehicle to launch our large, unique spacecraft, ULA provides a heritage of solid mission success, schedule certainty and a cost effective solution,” says Bigelow.
The SpaceX falcon 9 fairing is not big enough to house the B330.
“SpaceX, they do not have the capability with the fairing size that is necessary to accommodate the B330. So that is not even a choice,” Bigelow stated.
The B330 partnership announcement follows hot on the heels of last weeks successful launch of Bigelow’s experimental BEAM expandable module on a SpaceX Falcon 9 rocket on a mission to the ISS on April 8.
The Bigelow Expandable Activity Module (BEAM) is an experimental expandable capsule that attaches to the space station. Credits: Bigelow Aerospace, LLC
BEAM is tucked inside the rear truck section of the SpaceX Dragon now berthed at the station. It will soon be attached to a side port on the Harmony module.
“This innovative and game-changing advance will dramatically increase opportunities for space research in fields like materials, medicine and biology,” said Bruno.
“It enables destinations in space for countries, corporations and even individuals far beyond what is available today, effectively democratizing space. We can’t begin to imagine the future potential of affordable real estate in space.”
The B330 could also function as a free flyer but would work best at the station, Bigelow noted at the briefing.
Both of the commercial space taxis being developed under NASA’s commercial crew program (CCP) could dock at the B330; the Boeing Starliner and the SpaceX crew Dragon, Bigelow stated.
Multiple B330 modules could also be joined together in orbit to form a free flying commercial space station.
File photo of Atlas V rocket in with 5 meter diameter payload fairing and 5 solid rocket boosters following rollout to Space Launch Complex 41 at Cape Canaveral Air Force Station, FL. Credit: Ken Kremer – kenkremer.com
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
Learn more about SpaceX, ULA, commercial space, NASA Mars rovers, Orion, SLS, ISS, Orbital ATK, Boeing, Space Taxis, NASA missions and more at Ken’s upcoming outreach events:
Apr 17: “NASA and the Road to Mars Human Spaceflight programs”- 1:30 PM at Washington Crossing State Park, Nature Center, Titusville, NJ – http://www.state.nj.us/dep/parksandforests/parks/washcros.html
Recovered SpaceX Falcon 9 rocket arrives back in port overnight at Port Canaveral, Florida on April 12, 2016 following successful launch and landing on April 8 from Cape Canaveral Air Force Station. Credit: Julian Leek
The SpaceX Falcon 9 that triumphantly accomplished history’s first upright landing of the spent first stage of a rocket on a barge at sea – after launching a critical cargo payload to orbit for NASA – sailed back into port at Cape Canaveral overnight in the wee hours of this morning, April 12, standing tall.
The recovered 15 story tall Falcon 9 booster arrived back into Port Canaveral, Florida at about 130 a.m. early today, towed atop the ocean going platform that SpaceX dubs an ‘Autonomous Spaceport Drone Ship’ or ASDS.
The ship is named “Of Course I Still Love You” after a starship from a novel written by Iain M. Banks. The landing platform measures only about 170 ft × 300 ft (52 m × 91 m).
A small crowd of excited onlookers and space photographers savored and cheered the incredible moment that is surely changing the face and future of space exploration and travel.
The two stage SpaceX Falcon 9 rocket boasting over 1.5 million pounds of thrust originally launched on Friday, April 8 at 4:43 p.m. EDT from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida.
The primary goal of the Falcon 9 launch was carrying the SpaceX Dragon CRS-8 cargo freighter to low Earth orbit on a commercial resupply delivery mission for NASA to the International Space Station (ISS).
Before the launch, SpaceX managers rated the chances of a successful landing recovery rather high.
Three previous attempts by SpaceX to land on a barge at sea were partially successful, as the stage made a pinpoint flyback to the tiny ship but either hit too hard or tipped over in the final moments when a landing leg failed to fully deploy or lock in place.
“We were very optimistic of the chances of a successful landing on this mission,” Hans Koenigsmann told Universe Today in an exclusive post landing interview at the NorthEast Astronomy and Space Forum (NEAF) held in Suffern, NY.
Recovered SpaceX Falcon 9 rocket arrives back in port overnight at Port Canaveral, Florida on April 12, 2016 following successful launch and landing on April 8 from Cape Canaveral Air Force Station. Credit: Julian Leek
Coincidentally, today marks two major anniversaries in the history of space flight; the 55th anniversary of the launch of Russia’s Yuri Gagarin, the first man in space on Vostok-1 on April 12, 1961; and the 35th anniversary of the launch of shuttle Columbia on America’s first space shuttle mission (STS-1) on April 12, 1981 with John Young and Bob Crippen.
The vision of SpaceX’s billionaire founder and CEO Elon Musk is to dramatically slash the cost of access to space by recovering the firms rockets and recycling them for reuse – so that launching rockets will one day be nearly as routine and cost effective as flying on an airplane.
The stage will now be painstakingly inspected, tested and refurbished.
The essential next step after recovery is recycling. Musk said he hopes to re-launch the booster this year.
At liftoff, Dragon was loaded with over 3.5 tons of research experiments and essential supplies for the six man crew living aboard the orbiting science complex.
Watch this launch video from my video camera placed at the pad:
Video Caption: Spectacular blastoff of SpaceX Falcon 9 rocket carrying Dragon CRS-8 cargo freighter bound for the International Space Station (ISS) from Space Launch Complex 40 on Cape Canaveral Air Force Station, FL at 4:43 p.m. EST on April 8, 2016. Up close movie captured by Mobius remote video camera placed at launch pad. Credit: Ken Kremer/kenkremer.com
The Dragon CRS-8 cargo ship successfully arrived at the station on Sunday, April 10 and was joined to the million pound station at the Earth-facing port of the Harmony module.
The secondary objective was to try and land the Falcon 9 first stage on the ASDS done ship located some 200 miles off shore in the Atlantic Ocean.
The action-packed and propulsive landing took place some 10 minutes after liftoff.
In the final moments of the descent to the drone ship, one of the first stage Merlin 1D engines was reignited to slow the boosters descent speed as the quartet of side-mounted landing legs at the boosters base were unfurled, deployed and locked into place.
The entire launch and landing sequence was webcast live on NASA TV and by SpaceX.
The recovered booster atop the “Of Course I Still Love You” barge was towed back to port by the Elsbeth III tug.
“Home sweet home”, said my friend and veteran space photographer Julian Leek, who witnessed the boosters arrival back in port overnight.
“It was really a sight to see. Pilots and tugs did a well coordinated job to bring her in.”
After daylight dawned, a crane lifted the recovered booster into a storage cradle where it will remain upright for a few days. Then it will be lowered and placed horizontally for transport a few miles north to a SpaceX processing hanger back at pad 39A at the Kennedy Space Center.
Recovered SpaceX Falcon 9 rocket moved by crane from drone ship to an upright storage cradle on land at Port Canaveral, Florida on April 12, 2016. Credit: Julian Leek
The booster will be cleaned and defueled, SpaceX spokesman John Taylor told the media.
SpaceX engineers will conduct a series of 12 test firings to ensure all is well operationally and that the booster can be re-launched.
Recovered SpaceX Falcon 9 rocket arrives back in port overnight at Port Canaveral, Florida on April 12, 2016 following successful launch and landing on April 8 from Cape Canaveral Air Force Station. Credit: SpaceX
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
Learn more about SpaceX, NASA Mars rovers, Orion, SLS, ISS, Orbital ATK, ULA, Boeing, Space Taxis, NASA missions and more at Ken’s upcoming outreach events:
Apr 12: Hosting Dr. Jim Green, NASA, Director Planetary Science, for a Planetary sciences talk about “Ceres, Pluto and Planet X” at Princeton University; 7:30 PM, Amateur Astronomers Assoc of Princeton, Peyton Hall, Princeton, NJ – http://www.princetonastronomy.org/
Apr 17: “NASA and the Road to Mars Human Spaceflight programs”- 1:30 PM at Washington Crossing State Park, Nature Center, Titusville, NJ – http://www.state.nj.us/dep/parksandforests/parks/washcros.html
The U.S. SpaceX Dragon cargo craft arrived at the ISS following a carefully choreographed orbital chase inaugurated by a spectacular launch atop an upgraded SpaceX Falcon 9 rocket from Cape Canaveral Air Force Station, Florida, on Friday, April 8.
As the massive Earth orbiting outpost was soaring some 250 miles (400 kilometers) over the Pacific Ocean west of Hawaii, British astronaut Tim Peake of ESA (European Space Agency), with the able assistance of NASA’s Jeff Williams, successfully captured the SpaceX Dragon CRS-8 resupply ship with the station’s Canadian-built robotic arm.
Peake painstakingly maneuvered and deftly grappled Dragon with the snares at the terminus of the 57 foot long (19 meter long) Canadarm2 at 7:23 a.m. EDT for installation on the million pound orbital lab complex.
“Looks like we’ve caught a Dragon,” Peake radioed back to Mission Control. The orbital operational was webcast live on NASA TV.
“Awesome capture by crewmate Tim Peake,” said fellow NASA crewmate Tim Kopra who snapped a series of breathtaking images of the approach and capture.
Final Approach for @SpaceXDragon before an awesome capture by crewmate @Astro_TimPeake! Credit: NASA/Tim Kopra/@astro_tim
Ground controllers at Mission Control in Houston then issued commands to carefully guide the robotic arm holding the Dragon freighter to the Earth-facing port on the bottom side of the Harmony module for its month long stay at the space station.
The ship was finally bolted into place at 9:57 a.m. EDT as the station flew 250 miles (400 km) over southern Algeria.
Watch this NASA video compiling all the highlights of the arrival and mating of the SpaceX Dragon on April 10, 2016 carrying the BEAM habitat module and 3.5 tons of science and supplies. Credit: NASA
Expedition 47 crew members Jeff Williams and Tim Kopra of NASA, Tim Peake of ESA (European Space Agency) and cosmonauts Yuri Malenchenko, Alexey Ovchinin and Oleg Skripochka of Roscosmos are currently living aboard the orbiting laboratory.
In a historic first, the arrival of the SpaceX Dragon cargo spacecraft marks the first time that two American cargo ships are simultaneously docked to the ISS. The Orbital ATK Cygnus CRS-6 cargo freighter only just arrived on March 26 and is now installed at a neighboring docking port on the Unity module.
The SpaceX Dragon is seen shortly after it was mated to the Harmony module. The Cygnus cargo craft with its circular solar arrays and the Soyuz TMA-19M spacecraft (bottom right) are also seen in this view. Credit: NASA TV
Cygnus was launched to the ISS atop a ULA Atlas V barely two weeks earlier on March 22 – as I reported on and witnessed from the Kennedy Space Center press site.
“With the arrival of Dragon, the space station ties the record for most vehicles on station at one time – six,” say NASA officials.
The Dragon spacecraft is delivering almost 7,000 pounds of cargo, including the Bigelow Expandable Activity Module (BEAM), to the orbital laboratory which was carried to orbit inside the Dragon’s unpressurized truck section.
BEAM is a prototype inflatable habitat that the crew will soon pluck from the Dragon’s truck with the robotic arm for installation on a side port of the Harmony module.
The Bigelow Expandable Activity Module (BEAM) is an experimental expandable capsule that attaches to the space station. Credits: Bigelow Aerospace, LLC
CRS-8 counts as the company’s eighth flight to deliver supplies, science experiments and technology demonstrations to the ISS for the crews of Expeditions 47 and 48 to support dozens of the approximately 250 science and research investigations in progress.
Friday’s launch marks the first for a Dragon since the catastrophic failure of the SpaceX Falcon 9 last June.
Dragon will remain at the station until it returns for Earth on May 11 for a parachute assisted splash down in the Pacific Ocean off the west coast of Baja California. It will be packed with almost 3,500 pounds off cargo and numerous science samples, including those biological samples collected by 1 year ISS crew member Scott Kelly, for return to investigators, hardware and spacewalking tools, some additional broken hardware for repair and some items of trash for disposal.
Video caption: 5 camera views of the SpaceX Falcon 9 launch of the CRS-8 mission to the ISS on 04/08/2016. Credit: Jeff Seibert/AmericaSpace
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
Learn more about SpaceX, NASA Mars rovers, Orion, SLS, ISS, Orbital ATK, ULA, Boeing, Space Taxis, NASA missions and more at Ken’s upcoming outreach events:
Apr 12: Hosting Dr. Jim Green, NASA, Director Planetary Science, for a Planetary sciences talk about “Ceres, Pluto and Planet X” at Princeton University; 7:30 PM, Amateur Astronomers Assoc of Princeton, Peyton Hall, Princeton, NJ – http://www.princetonastronomy.org/
Apr 17: “NASA and the Road to Mars Human Spaceflight programs”- 1:30 PM at Washington Crossing State Park, Nature Center, Titusville, NJ – http://www.state.nj.us/dep/parksandforests/parks/washcros.html
SpaceX Falcon 9 rocket with a Dragon cargo spacecraft launches on April 8, 2015 from Space Launch Complex 40 at Cape Canaveral Air Force Station on the CRS-8 mission to the International Space Station. Credit: Julian Leek
All around, today, April 8, was a great day for the future of space exploration. SpaceX successfully restarted their critical cargo flights for NASA to stock the International Space Station (ISS) with essential supplies and groundbreaking science experiments, while the innovative firm also successfully landed the first stage of their Falcon 9 rocket on a barge at sea.
The triumphant ‘Return to Flight’ launch of the upgraded SpaceX Falcon 9 with the Dragon CRS-8 cargo freighter was the primary goal of Friday’s launch and validated the hardware fixes put in place following the catastrophic failure of the previous Dragon CRS-7 cargo ship two minutes after liftoff on June 28, 2015 due to a faulty strut in the boosters second stage.
Landing the booster safely on a drone ship at sea was the secondary goal of the flight but is critical towards achieving the vision of rocket recovery and reusability at the heart of SpaceX Founder Elon Musk’s dream of slashing the cost of access to space and one day establishing a ‘City on Mars.”
The weather was fantastic in the sunshine state as the two stage SpaceX Falcon 9 rocket boasting over 1.3 million pounds of thrust launched on time Friday at 4:43 p.m. EDT from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida.
SpaceX Falcon 9 rocket with a Dragon spacecraft launches on April 8, 2015 from Space Launch Complex 40 at Cape Canaveral Air Force Station on the CRS-8 mission to the International Space Station. Credits: NASA
The Dragon spacecraft is delivering almost 7,000 pounds of cargo, including the Bigelow Expandable Activity Module (BEAM), to the orbital laboratory.
Friday’s launch marks the first for a Dragon since the catastrophic failure of the SpaceX Falcon 9 last June.
CRS-8 counts as the company’s eighth flight to deliver supplies, science experiments and technology demonstrations to the ISS for the crews of Expeditions 47 and 48 to support dozens of the approximately 250 science and research investigations in progress.
Packed aboard the Dragon’s unpressurized trunk section is the experimental Bigelow Expandable Activity Module (BEAM) – an experimental expandable capsule that the crew will attach to the space station. The 3115 pound (1413 kg) BEAM will test the use of an expandable space habitat in microgravity. BEAM will expand to roughly 13-feet-long and 10.5 feet in diameter after it is installed.
Among the new experiments arriving to the station will be Veggie-3 to grow Chinese lettuce in microgravity as a followup to Zinnias recently grown, an investigation to study muscle atrophy and bone loss in space, using microgravity to seek insight into the interactions of particle flows at the nanoscale level and use protein crystal growth in microgravity to help in the design of new drugs to fight disease, as well as reflight of 25 student experiments from Student Spaceflight Experiments Program (SSEP) Odyssey II payload that were lost during the CRS-7 launch failure.
“The cargo will allow investigators to use microgravity conditions to test the viability of expandable space habitats, assess the impact of antibodies on muscle wasting, use protein crystal growth to aid the design of new disease-fighting drugs and investigate how microbes could affect the health of the crew and their equipment over a long duration mission,” said NASA Deputy Administrator Dava Newman.
SpaceX Falcon 9 rocket with a Dragon spacecraft streak to orbit after launch on April 8, 2015 from Space Launch Complex 40 at Cape Canaveral Air Force Station on the CRS-8 mission to the International Space Station. Credit: Julian Leek
Dragon reached its preliminary orbit about 10 minutes after launch and deployed its solar arrays as targeted and as seen on the live webcast. It now begins a carefully choreographed series of thruster firings to reach the space station.
After a 2 day orbital chase Dragon is set to arrive at the orbiting outpost on Sunday, April 10.
NASA astronaut Jeff Williams and ESA (European Space Agency) astronaut Tim Peake will then reach out with the station’s Canadian-built robotic arm to grapple and capture the Dragon spacecraft.
Ground commands will be sent from Houston to the station’s arm to install Dragon on the Earth-facing bottom side of the Harmony module for its stay at the space station. Live coverage of the rendezvous and capture will begin at 5:30 a.m. on NASA TV, with installation set to begin at 9:30 a.m.
In a historic first, the launch of a SpaceX Dragon cargo spacecraft sets the stage for the first time that two American cargo ships will be simultaneously attached to the ISS. The Orbital ATK Cygnus cargo freighter launched just launched on March 22 and arrived on March 26 at a neighboring docking port on the Unity module.
Dragon will remain at the station until it returns for Earth on May 11 for a parachute assisted splash down in the Pacific Ocean off the west coast of Baja California. It will be packed with almost 3,500 pounds off cargo and numerous science samples, including those biological samples collected by 1 year ISS crew member Scott Kelly, for return to investigators, hardware and spacewalking tools, some additional broken hardware for repair and some items of trash for disposal.
SpaceX Falcon 9 rocket with a Dragon spacecraft streaks to orbit after launch on April 8, 2015 from Space Launch Complex 40 at Cape Canaveral Air Force Station on the CRS-8 mission to the International Space Station. As seen from the Quality Inn Kennedy Space Center, Titusville, Fl. Credit: Ashley Crouch
SpaceX CRS-8 is the eighth of up to 20 missions to the ISS that SpaceX will fly for NASA under the Commercial Resupply Services (CRS) contract.
SpaceX Falcon 9 rocket with a Dragon cargo spacecraft launches on April 8, 2015 from Space Launch Complex 40 at Cape Canaveral Air Force Station on the CRS-8 mission to the International Space Station. Credit: Julian Leek
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
Learn more about SpaceX, NASA Mars rovers, Orion, SLS, ISS, Orbital ATK, ULA, Boeing, Space Taxis, NASA missions and more at Ken’s upcoming outreach events:
Apr 9/10: “NASA and the Road to Mars Human Spaceflight programs” and “Curiosity explores Mars” at NEAF (NorthEast Astronomy and Space Forum), 9 AM to 5 PM, Suffern, NY, Rockland Community College and Rockland Astronomy Club – http://rocklandastronomy.com/neaf.html
Apr 12: Hosting Dr. Jim Green, NASA, Director Planetary Science, for a Planetary sciences talk about “Ceres, Pluto and Planet X” at Princeton University; 7:30 PM, Amateur Astronomers Assoc of Princeton, Peyton Hall, Princeton, NJ – http://www.princetonastronomy.org/
Apr 17: “NASA and the Road to Mars Human Spaceflight programs”- 1:30 PM at Washington Crossing State Park, Nature Center, Titusville, NJ – http://www.state.nj.us/dep/parksandforests/parks/washcros.html
A Falcon 9 rocket with a Dragon spacecraft stand at Space Launch Complex 40 at Cape Canaveral Air Force Station before the CRS-8 mission to deliver experiments and supplies to the International Space Station. Credits: SpaceX
The SpaceX Dragon is set for its ‘Return to Flight’ mission on Friday, April 8, packed with nearly 7000 pounds (3100 kg) of critical cargo and research experiments bound for the six-man crew working aboard the International Space Station.
Blastoff of the commercial SpaceX Falcon 9 carrying the Dragon CRS-8 resupply ship is slated for 4:43 p.m. EDT from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida.
The weather outlook looks great with a forecast of 90 percent “GO” and extremely favorable conditions at launch time of the upgraded, full thrust version of the SpaceX Falcon 9. The only concern is for winds.
The SpaceX/Dragon CRS-8 launch coverage will be broadcast on NASA TV beginning at 3:30 p.m. EDT with additional commentary on the NASA launch blog.
SpaceX also features a live webcast approximately 20 minutes before launch beginning at 4:23 p.m. EDT.
The launch window is instantaneous, meaning that any delays due to weather or technical issues will results in a minimum 1 day postponement.
A backup launch opportunity exists on Saturday, April 9, at 4:20 p.m. with NASA TV coverage starting at 3:15 p.m.
SpaceX most recently launched the upgraded Falcon 9 from the Cape on March 4, 2016 as I reported from onsite here.
Friday’s launch marks the first for a Dragon since the catastrophic failure of a SpaceX Falcon 9 rocket in flight last year on June 28, 2015 on the CRS-7 resupply mission.
CRS-8 counts as the company’s eighth flight to deliver supplies, science experiments and technology demonstrations to the ISS for the crews of Expeditions 47 and 48 to support dozens of the approximately 250 science and research investigations in progress.
Also packed aboard in the Dragon’s unpressurized trunk section is experimental Bigelow Expandable Activity Module (BEAM) – an experimental expandable capsule that the crew will attach to the space station. The 3115 pound (1413 kg) BEAM will test the use of an expandable space habitat in microgravity. BEAM will expand to roughly 13-feet-long and 10.5 feet in diameter after it is installed.
As a secondary objective, SpaceX will attempt to recover the Falcon 9 first stage by propulsively landing it on an ocean-going droneship barge stationed offshore in the Atlantic Ocean.
The Bigelow Expandable Activity Module (BEAM) is an experimental expandable capsule that attaches to the space station. Credits: Bigelow Aerospace, LLC
Expedition 47 crew members Jeff Williams and Tim Kopra of NASA, Tim Peake of ESA (European Space Agency) and cosmonauts Yuri Malenchenko, Alexey Ovchinin and Oleg Skripochka of Roscosmos are currently living aboard the orbiting laboratory.
Dragon will reach its preliminary orbit about 10 minutes after launch. Then it will deploy its solar arrays and begin a carefully choreographed series of thruster firings to reach the space station.
After a 2 day orbital chase Dragon is set to arrive at the orbiting outpost on Sunday, April 10.
NASA astronaut Jeff Williams and ESA (European Space Agency) astronaut Tim Peake will then reach out with the station’s Canadian-built robotic arm to grapple and capture the Dragon spacecraft.
Ground commands will be sent from Houston to the station’s arm to install Dragon on the Earth-facing bottom side of the Harmony module for its stay at the space station. Live coverage of the rendezvous and capture will begin at 5:30 a.m. on NASA TV, with installation set to begin at 9:30 a.m.
In a historic first, the launch of a SpaceX Dragon cargo spacecraft sets the stage for the first time that two American cargo ships will be simultaneously attached to the ISS. The Orbital ATK Cygnus cargo freighter launched just launched on March 22 and arrived on March 26 at a neighboring docking port on the Unity module.
The Bigelow Expandable Activity Module (BEAM), developed for NASA by Bigelow Aerospace, is lifted into SpaceX’s Dragon spacecraft for transport to the International Space Station when the spacecraft launches at 4:43 p.m. Friday, April 8, from Space Launch Complex 40 at Cape Canaveral Air Force Station (CCAFS) in Florida. Credits: SpaceX
Among the new experiments arriving to the station will be Veggie-3 to grow Chinese lettuce in microgravity as a followup to Zinnias recently grown, an investigation to study muscle atrophy and bone loss in space, using microgravity to seek insight into the interactions of particle flows at the nanoscale level and use protein crystal growth in microgravity to help in the design of new drugs to fight disease, as well as reflight of 25 student experiments from Student Spaceflight Experiments Program (SSEP) Odyssey II payload that were lost during the CRS-7 launch failure.
Dragon will remain at the station until it returns to Earth on May 11 for a parachute assisted splash down in the Pacific Ocean off the coast of Baja California. It will be packed with numerous science samples, including those collected by 1 year crew member Scott Kelly, for return to investigators, some broken hardware for repair and some items of trash for disposal.
SpaceX CRS-8 is the eighth of up to 20 missions to the ISS that SpaceX will fly for NASA under the Commercial Resupply Services (CRS) contract.
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
Learn more about SpaceX, NASA Mars rovers, Orion, SLS, ISS, Orbital ATK, ULA, Boeing, Space Taxis, NASA missions and more at Ken’s upcoming outreach events:
Apr 9/10: “NASA and the Road to Mars Human Spaceflight programs” and “Curiosity explores Mars” at NEAF (NorthEast Astronomy and Space Forum), 9 AM to 5 PM, Suffern, NY, Rockland Community College and Rockland Astronomy Club – http://rocklandastronomy.com/neaf.html
Apr 12: Hosting Dr. Jim Green, NASA, Director Planetary Science, for a Planetary sciences talk about “Ceres, Pluto and Planet X” at Princeton University; 7:30 PM, Amateur Astronomers Assoc of Princeton, Peyton Hall, Princeton, NJ – http://www.princetonastronomy.org/
Apr 17: “NASA and the Road to Mars Human Spaceflight programs”- 1:30 PM at Washington Crossing State Park, Nature Center, Titusville, NJ – http://www.state.nj.us/dep/parksandforests/parks/washcros.html
Patch for the SpaceX CRS-8 mission to the ISS. Credit: SpaceXSpaceX Falcon 9 rocket exploded shortly after liftoff from Cape Canaveral Air Force Station, Florida on June 28, 2015. Credit: Ken Kremer/kenkremer.comIgnition and liftoff of SpaceX Falcon 9 as umbilical’s fly away from rocket carrying SES-9 satellite to orbit from Cape Canaveral Air Force Station, FL on March 4, 2016. As seen from remote camera set near rocket on launch pad 40. Credit: Ken Kremer/kenkremer.com
SpaceX Dragon 2 crew vehicle, powered by eight SuperDraco engines, conducts propulsive hover test at the company’s rocket development facility in McGregor, Texas. Credit: SpaceX
On the road to restoring US Human spaceflight from US soil, SpaceX conducted a pair of key tests involving a propulsive hover test and parachute drop test for their Crew Dragon vehicle which is slated to begin human missions in 2017.
SpaceX released a short video showing the Dragon 2 vehicle executing a “picture-perfect propulsive hover test” on a test stand at the firms rocket development facility in McGregor, Texas.
The video published last week shows the Dragon 2 simultaneously firing all eight of its side mounted SuperDraco engines, during a five second test carried out on Nov. 22, 2015.
Using the SuperDragos will eventually enable pinpoint propulsive soft landings like a helicopter in place of parachute assisted landings in the ocean or on the ground.
The video clip seen below includes both full speed and slow motion versions of the test, showing the vehicle rising and descending slowly on the test stand.
Video caption: SpaceX Dragon 2 crew vehicle, powered by eight SuperDraco engines, conducts propulsive hover test firing at rocket development facility in McGregor, Texas.
The eight SuperDraco thrusters are mounted in sets 90 degrees apart around the perimeter of the vehicle in pairs called “jet packs.”
The SuperDracos generate a combined total of 33,000 lbs of thrust.
SpaceX is developing the Crew Dragon under the Commercial Crew Program (CCP) awarded by NASA to transport crews of four or more astronauts to the International Space Station.
“This test was the second of a two-part milestone under NASA’s Commercial Crew Program,” said SpaceX officials. “The first test—a short firing of the engines intended to verify a healthy propulsion system—was completed November 22, and the longer burn two-days later demonstrated vehicle control while hovering.”
The first unmanned and manned orbital test flights of the crew Dragon are expected sometime in 2017. A crew of two NASA astronauts should fly on the first crewed test before the end of 2017.
Parachute drop test for SpaceX crew Dragon involving four red-and-white parachutes unfurled from a mass simulator high above the desert near Coolidge, Arizona. Credit NASA/SpaceX
Initially, the Crew Dragon will land via parachutes in the ocean before advancing to use of pinpoint propulsive landing.
Thus SpaceX recently conducted a parachute drop test involving deployment of four red-and-white parachutes unfurling high above the desert near Coolidge, Arizona using a mass simulator in place of the capsule.
Video Caption: SpaceX performed a successful test of its parachute system for the Crew Dragon spacecraft near Coolidge, Arizona, as part of its final development and certification work with NASA’s Commercial Crew Program. Using a weight simulant in the place of a boilerplate spacecraft, four main parachutes were rigged to deploy just as they would when the Crew Dragon returns to Earth with astronauts aboard. Credit: NASA/SpaceX
“The mass simulator and parachutes were released thousands of feet above the ground from a C-130 cargo aircraft. This test evaluated the four main parachutes, but did not include the drogue chutes that a full landing system would utilize,” said NASA.
Since the CCP program finally received full funding from Congress in the recently passed Fiscal Year 2016 NASA budget, the program is currently on track to achieve the orbital test flight milestones.
Boeing and SpaceX were awarded contracts by NASA Administrator Charles Bolden in September 2014 worth $6.8 Billion to complete the development and manufacture of the privately developed Starliner CST-100 and Crew Dragon astronaut transporters under the agency’s Commercial Crew Transportation Capability (CCtCap) program and NASA’s Launch America initiative.
The Crew Dragon will launch atop a SpaceX Falcon 9 rocket from launch Complex 39A at the Kennedy Space Center. The historic launch pad has been leased by SpaceX from NASA and is being refurbished for launches of the Falcon 9 and Falcon Heavy.
SpaceX Crew Dragon will blast off atop a Falcon 9 rocket from Launch Pad 39A at NASA’s Kennedy Space Center in Florida for missions to the International Space Station. Pad 39A is undergoing modifications by SpaceX to adapt it to the needs of the company’s Falcon 9 and Falcon Heavy rockets, which are slated to lift off from the historic pad in the near future. A horizontal integration facility (right) has been constructed near the perimeter of the pad where rockets will be processed for launch prior of rolling out to the top of the pad structure for liftoff. Credit: Ken Kremer/Kenkremer.com
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
First enhanced Orbital ATK Cygnus commercial cargo ship is fully assembled and being processed for blastoff to the ISS on Dec. 3, 2015 on a ULA Atlas V rocket. This view shows the Cygnus, named the SS Deke Slayton II, and twin payload enclosure fairings inside the Kennedy Space Center clean room. Credit: Ken Kremer/kenkremer.com
KENNEDY SPACE CENTER, FL – The largest and most advanced version of the privately developed Cygnus cargo freighter ever built by Orbital ATK is fueled, loaded and ready to go to orbit – signifying a critical turning point towards resuming American commercial cargo launches to the space station for NASA that are critical to keep it functioning.
The enhanced and fully assembled commercial Cygnus was unveiled to the media, including Universe Today, during an exclusive tour inside the clean room facility on Friday, Nov. 13, where it is undergoing final prelaunch processing at the Kennedy Space Center (KSC).
The first tier of seven tiers for Crew Access Tower is moved from its construction yard to Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on Sept 9, 2015. The tower will provide access at the pad for astronauts and ground support teams to the Boeing CST-100 Starliner launching atop a United Launch Alliance Atlas V rocket. Photo credit: NASA/Dmitrios Gerondidakis Story/photos updated[/caption]
“Everything is on schedule,” Howard Biegler, ULA’s Human Launch Services Lead, told Universe Today during an exclusive interview. “The new 200-foot-tall tower structure goes up rather quickly at launch pad 41.”
The access tower essentially functions as the astronauts walkway to the stars.
“We start stacking the crew access tower [CAT] after the MUOS-4 launch and prior to the next launch after that of Morelos-3,” Beigler said in a wide ranging interview describing the intricately planned pad modifications and tower construction at the Atlas V Space Launch Complex 41 facility at Cape Canaveral.
Depending on the always tricky weather at the Cape, more than half the tower should be “installed prior to MORELOS-3’s launch on Oct. 2. The balance of the CAT will take form after the launch.”
The first tier of the new Crew Access Tower for the Boeing CST-100 Starliner arrives at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on Sept 9, 2015. The tower will provide access at the pad for astronauts and ground support teams to the Boeing CST-100 Starliner launching atop a United Launch Alliance Atlas V rocket. Photo credit: NASA/Dmitrios Gerondidakis
The crew access tower is a critical space infrastructure element and absolutely essential for getting Americans back to space on American rockets for the first time since NASA’s shuttles were retired in 2011. That action forced our total dependence on the Russian Soyuz capsule for astronaut ridesto the space station.
Boeing was awarded a $4.2 Billion contract in September 2014 by NASA Administrator Charles Bolden to complete development and manufacture of the CST-100 space taxi under the agency’s Commercial Crew Transportation Capability (CCtCap) program and NASA’s Launch America initiative. SpaceX also received a NASA award worth $2.6 Billion to build the Crew Dragon spacecraft for launch atop the firms man-rated Falcon 9 rocket.
Starliner is a key part of NASA’s overarching strategy to send Humans on a “Journey to Mars” in the 2030s.
The tower is of modular design for ease of assembly at the always busy Atlas launch pad.
“The crew tower is comprised of seven major tiers, or segments,” Beigler explained. “The building of the tiers went right on schedule. Each tier is about 20 feet square and 28 feet tall.”
Five of the seven tiers will be installed ahead of the next Atlas launch in early October, depending on the weather which has been difficult at the Cape.
“Our plan is to get 5 tiers and a temporary roof installed prior to MORELOS-3’s launch on October 2.”
“We have been hit hard with weather and are hopeful we can gain some schedule through the weekend. The balance of the CAT will take form after the 10/2 launch with the 7th tier planned to go up on 10/13 and roof on 10/15,” Biegler explained.
The first tier of the new Crew Access Tower for the Boeing CST-100 Starliner is installed at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida where United Launch Alliance Atlas V rockets will lift Boeing Starliners into orbit. Photo credit: NASA/Dmitrios Gerondidakis
The newly named ‘Starliner’ space taxi will launch atop a newly human-rated Atlas V booster as soon as mid-2017, say NASA, ULA and Boeing officials.
But before astronauts can even climb aboard Starliner atop the Atlas rocket, ULA and Boeing first had to design, build and install a brand new tower providing access to the capsule for the crews and technicians.
Pad 41 is currently a “clean pad” with no gantry and no walkway to ‘Starliner’ because the Atlas V has only been used for unmanned missions to date.
The CST-100 ‘Starliner’ is at the forefront of ushering in the new commercial era of space flight and will completely revolutionize how we access, explore and exploit space for the benefit of all mankind.
This is the first new Crew Access Tower to be built at the Cape in decades, going back to NASA’s heyday and the Apollo moon landing era.
The tier segments were assembled about four miles down the road at the Atlas Space Operations Center on Cape Canaveral – so as not to disrupt the chock full manifest of Atlas rockets launching on a breakneck schedule for the NASA, military and commercial customers who ultimately pay the bills to keep ULA afloat and launch groundbreaking science probes and the most critical national security payloads vital to national defense.
“Each segment was outfitted with additional steel work, as well as electrical, plumbing and the staircase. Then they will be transported 3.9 miles out to the pad, one at a time on a gold hoffer and then we start erecting.”
The first two tiers were just transported out to pad 41. Installation and stacking of one tier on top of another starts in a few days.
Artist’s concept of Boeing’s CST-100 space taxi atop a human rated ULA Atlas-V rocket showing new crew access tower and arm at Space Launch Complex 41, Cape Canaveral Air Force Station, Fl. Credit: ULA/Boeing
“We are very pleased with the progress so far,” Biegler told me. “Everything is on schedule and has gone remarkably well so far. No safety or workmanship issues. It’s all gone very well.”
“The first tier is obviously the most critical [and will take a bit longer than the others to insure that everything is being done correctly]. It has to be aligned precisely over the anchor bolts on the foundation at the pad. Then it gets bolted in place.”
“After that they can be installed every couple of days, maybe every three days or so. The pieces of the tower will go up quickly.”
Artist’s concept of Boeing’s CST-100 space taxi atop a human rated ULA Atlas-V rocket showing new crew access tower and arm. Credit: ULA/BoeingThe steel tiers and tower are being built by Hensel Phelps under contract to ULA.
“Construction by the Hensel Phelps team started in January 2015,” Biegler said.
Erecting the entire tower is the next step. After stacking the tiers is fully completed later this year then comes structure, testing and calibration work over the next year.
“After tower buildup comes extensive work to outfit the tower with over 400 pieces of outboard steel that have to be installed. That takes much longer,” Biegler said.
“Designed with modern data systems, communications and power networks integrated and protected from blast and vibration, plus an elevator, the Crew Access Tower has been built with several features only a fully suited astronaut could appreciate, such as wider walkways, snag-free railings and corners that are easy to navigate without running into someone,” according to NASA officials.
Just like the shuttle, “the tower will also be equipped with slide wire baskets for emergency evacuation to a staged blast-resistant vehicle.”
“At the very top is the area that protects the access arm and provides the exit location for the emergency egress system. It will all be stick built from steel out at the pad,” Biegler elaborated.
The access arm with the walkway that astronauts will traverse to the Starliner capsule is also under construction. It is about 180 feet above ground.
Astronauts will ride an elevator up the tower to the access arm, and walk through it to the white room at the end to board the Starliner capsule.
“The arm along with the white room and torque tube are being fabricated in Florida. It will all be delivered to the pad sometime around next June [2016],” Biegler stated.
“We built a test stand tower for the access arm at our Oak Hill facility to facilitate the installation process. We mount the arm and the hydraulic drive system and then run it through its paces prior to its delivery to the pad.”
“The access arm – including the torque tube out to the end – is just over 40 feet in length.”
“We will integrate it off line because we don’t have a lot of time to troubleshoot out at the pad. So we will hook up all its drive systems and electronics on the test structure stand.”
“Then we will spend about 3 months testing it and verifying that everything is right. We’ll use laser lining to know it all precisely where the arm is. So that when we bring it out to the pad we will know where it is to within fractions of an inch. Obviously there will be some minor adjustments up and down.”
“That way in the end we will know that everything in the arm and the hydraulic drive system are working within our design specs.”
When the arm is finally installed on the crew access tower it will be complete, with the white room and environmental seal already attached.
“It will stow under the crew access tower, which is located west and north of the launch vehicle. The arm will swing out about 120 degrees to the crew module to gain access and was strategically picked to best fit the features and foundation at the existing pad structure.”
Tower construction takes place in between Atlas launches and pauses in the days prior to launches. For example the construction team will stand down briefly just ahead of the next Atlas V launch currently slated for Oct. 2 with the Mexican governments Morelos-3 communications satellite.
The Crew Access Tower is now being erected at Pad 41 following MUOS-4 blastoff here. MUOS-4 US Navy communications satellite and Atlas V rocket at pad 41 at Cape Canaveral Air Force Station, FL for launch on Sept. 2, 2015 at 5:59 a.m. EDT. Credit: Ken Kremer/kenkremer.com
Starliners’ actual launch date totally depends on whether the US Congress provides full funding for NASA’s commercial crew program (CCP).
Thus far the Congress has totally failed at providing the requested CCP budget to adequately fund the program – already causing a 2 year delay of the first flight from 2015 to 2017.
Boeing is making great progress on manufacturing the first CST-100 Starliner.
Barely a week ago, Boeing staged the official ‘Grand Opening’ ceremony for the craft’s manufacturing facility held at the Kennedy Space Center on Friday, Sept 4. 2015 – attended by Universe Today as I reported here.
ULA has also already started assembly of the first two Atlas V rockets designated for Starliner at their rocket factory in Decatur, Alabama.
Read my earlier exclusive, in depth one-on-one interviews with Chris Ferguson – America’s last shuttle commander, who now leads Boeings’ CST-100 program; here and here.
First view of the Boeing CST-100 ‘Starliner’ crewed space taxi at the Sept. 4, 2015 Grand Opening ceremony held in the totally refurbished C3PF manufacturing facility at NASA’s Kennedy Space Center. These are the upper and lower segments of the first Starliner crew module known as the Structural Test Article (STA) being built at Boeing’s Commercial Crew and Cargo Processing Facility (C3PF) at KSC. Credit: Ken Kremer /kenkremer.com
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
SpaceX released new images today of the sleek interior of “Crew Dragon,” SpaceX’s spacecraft designed to carry humans to the International Space Station, and possibly other future destinations. If things go as hoped, the first commercial crew flights under the Commercial Crew Transportation Capability (CCtCap) program contract could take place in 2017.
UPDATE: SpaceX added a new video of the Crew Dragon in orbit, which you can see below, in addition to a video that provides views of the interior.
The futuristic interior is “designed to be an enjoyable ride,” says SpaceX. Four windows provide passengers with views of Earth, the Moon, and the wider Solar System right from their seats. The seats — which don’t look especially plush — are made from high-grade carbon fiber and Alcantara cloth.
SpaceX provided just snapshots of parts of the interior, and so its hard to get a feel for what the entire crew cabin will be like and how roomy it might be.
But with the white and black interior and the clean lines, the imagery is reminiscent of the interior of the spacecraft in “2001: A Space Odyssey.” See below for the non-HAL 9000 computer screen, and well as more images and a video scanning the interior:
Exterior of the Crew Dragon capsule. Credit: SpaceX.
NASA named four astronauts earlier this year who will fly on the first U.S. commercial spaceflights on either SpaceX or Boeing crew transportation vehicles. The agreement between NASA and the commercial companies is that at least one member of the two person crews for the initial flights will be a NASA astronaut – who will be “on board to verify the fully-integrated rocket and spacecraft system can launch, maneuver in orbit, and dock to the space station, as well as validate all systems perform as expected, and land safely,” according to a NASA statement.
The second crew member would likely be a company test pilot, but the details remain to be worked out.
There’s not been indication as of yet if the explosion of the SpaceX Falcon 9 rocket and Dragon cargo ship loaded with supplies for the International Space Station (ISS) on June 28, 2015 will have an impact on when the first crewed Dragon flights will take place. The explosion happened about 148 seconds after an initially successful launch. It was later determined an in-flight failure of a critical support strut inside the second stage liquid oxygen tank holding a high pressure helium tank in the Falcon 9 rocket was the likely cause of the accident.
Crew Dragon features an advanced emergency escape system to swiftly carry astronauts to safety if something were to go wrong. Credit: SpaceX.
SpaceX said the escape system provides a safe way to carry astronauts to safety if there is a problem and the crew would experience about the same G-forces as a ride at Disneyland.
Crew Dragon’s displays will provide real-time information on the state of the spacecraft’s capabilities – anything from Dragon’s position in space, to possible destinations, to the environment on board. Credit: SpaceX.Crew Dragon has an Environmental Control and Life Support System (ECLSS) that provides a comfortable and safe environment for crew members. During their trip, astronauts on board can set the spacecraft’s interior temperature to between 65 and 80 degrees Fahrenheit. Credit: SpaceX.Crew Dragon will be a fully autonomous spacecraft that can also be monitored & controlled by on board astronauts and SpaceX mission control in Hawthorne, California. Credit: SpaceX.
