NASA, SpaceX Coordinate Crucial Astronaut Recovery Exercise

Teams from NASA and SpaceX, rehearse crew extraction in Port Canaveral
NASA astronaut Doug Hurley, along with teams from NASA and SpaceX, rehearse crew extraction from SpaceX’s Crew Dragon, which will be used to carry humans to the International Space Station, on Aug. 13, 2019 at the Trident Basin in Cape Canaveral, Florida. Photo Credit: NASA/Bill Ingalls

Teams from NASA and SpaceX practiced removing astronauts from a Crew Dragon spacecraft on Tuesday, Aug. 13, at Port Canaveral in Florida, preparing for when humans return to Earth from a mission to the International Space Station as part of NASA’s Commercial Crew Program.

The joint simulation involved a mock-up of the spacecraft and Go Searcher, one of the SpaceX ships that will recover the spacecraft and astronauts after splashing down in the Atlantic Ocean. NASA astronauts Doug Hurley and Bob Behnken, who will fly to and from the space station aboard Crew Dragon for the SpaceX Demo-2 mission, participated in the exercise.

Teams from NASA and SpaceX, rehearse crew extraction from SpaceX’s Crew Dragon in Port Canaveral
Using SpaceX’s Go Searcher ship and a mock-up of the Crew Dragon, NASA and SpaceX teams worked through the steps necessary to get NASA astronauts Doug Hurley, left, and Bob Behnken out of the Dragon and back to dry land. Photo credit: NASA/Bill Ingalls

“Integrated tests like today’s are a crucial element in preparing for human spaceflight missions,” Hurley said. “This opportunity allowed us to work with the recovery team and ensure the plans are solid for the Demo-2 mission.”

The event marked the first time a fully integrated NASA and SpaceX team worked together on the ship to go through an end-to-end practice run of how the teams will recover and extract the astronauts when they return from the space station in Crew Dragon. Hurley and Behnken were taken out of the spacecraft, given a mock medical evaluation and then transported to the Cape Canaveral Air Force Station Skid Strip, or airport.

“We’re making sure that the team integrates together — that’s a key to any successful mission,” said Ted Mosteller, the NASA recovery director in charge of the agency’s team for the Commercial Crew Program. “We worked on successfully doing what we need to do to take care of the crew once they return to Earth.”

Teams from NASA and SpaceX, rehearse crew extraction from SpaceX’s Crew Dragon in Port Canaveral
NASA astronauts Doug Hurley, left, and Bob Behnken work with NASA and SpaceX teams during an astronaut recovery exercise in Port Canaveral, Florida. Photo Credit: NASA/Bill Ingalls

The purpose of the exercise, Mosteller pointed out, was to ensure participants knew their roles and responsibilities — and where they were supposed to be staged on the 150-foot vessel. He was extremely pleased with the results.

“It feels really good; it has been a lot of hard work to get us to this point,” Mosteller said. “There was a lot of collaboration, and it was a very positive experience for the integrated team.”

For Hurley and Behnken, it’s another milestone on the path to their historic flight.

“We are both looking forward to the Demo-2 flight and having the opportunity to return to the International Space Station,” Behnken said. “Each of these exercises puts us one step closer to fulfilling NASA’s mission of returning astronauts to the International Space Station from U.S. soil.”

As commercial crew providers Boeing and SpaceX begin to make regular flights to the space station, NASA will continue to advance its mission to go beyond low-Earth orbit and establish a human presence on the Moon with the ultimate goal of sending astronauts to Mars.

SpaceX Demo-2 Astronauts Walkthrough Launch Day Operations

SpaceX recently held a training event at its facility in Hawthorne, California for prelaunch operations with NASA astronauts Bob Behnken and Doug Hurley and ground operators for the company’s Demo-2 mission to the International Space Station as part of NASA’s Commercial Crew Program. The training provided an opportunity for the integrated team to dry run all of the activities, procedures and communication that will be exercised on launch day when a Crew Dragon spacecraft launches on a Falcon 9 rocket from Launch Complex 39A in Florida.

The astronauts performed suit-up procedures alongside the SpaceX ground closeout team and suit engineers using the same ground support equipment, such as the seats and suit leak check boxes, that will be used on launch day. Following crew suit-up, the teams performed a simulated launch countdown with the astronauts inside a Crew Dragon simulator and performed several emergency egress, or exit, scenarios.

The training exercise is one of several that NASA astronauts have participated in with our commercial crew partners, Boeing and SpaceX, in preparation for crew flight tests. NASA’s Commercial Crew Program continues to place astronaut safety at the forefront of preparations for human spaceflight.

 

 

 

Astronauts and Ground Teams Put Emergency Escape Procedures to the Test

An emergency medical technician cares for an astronaut with simulated injuries during a joint emergency escape and triage exercise led by NASA, along with Boeing and United Launch Alliance, at Space Launch Complex 41 at Cape Canaveral Air Force Station in Florida on July 24, 2019. The simulation is part of a series in preparation for upcoming crew flights to the International Space Station as part of NASA’s Commercial Crew Program. Photo credit: NASA/Ben Smegelsky

NASA led a joint emergency escape and triage simulation with Boeing and United Launch Alliance (ULA) on July 24 at Space Launch Complex 41 on Cape Canaveral Air Force Station (CCAFS) in Florida in preparation for upcoming crew flights to the International Space Station. The exercise ranged from astronauts and support teams quickly escaping the launch pad to emergency personnel practicing rescue and life support procedures focused on the safety of the launch site teams.

Medical and fire-rescue personnel park ambulances and set up a decontamination and triage area for the joint emergency escape and triage simulation.

In the event of an emergency on launch day, astronauts and support teams would need to exit the launch pad as quickly as possible. The exercise was designed to validate the escape procedures from the crew access tower – the nearly 200-foot-tall structure astronauts will ascend to the same level as the spacecraft on top of the rocket – to a pre-staged medical location a safe distance away from the launch pad. The second half of the rehearsal included the rescue teams that would conduct initial triage for the crew and ground team.

NASA astronauts Josh Cassada, currently in training for the second flight with crew aboard Boeing’s CST-100 Starliner spacecraft, and Eric Boe, along with astronaut candidate Jasmin Moghbeli, served as flight crew for the simulation.

During the exercise, the astronauts and support teams put on portable respirators and made their way to the emergency egress system – a commercial, off-the-shelf zip line modified and constructed as a safety measure for human spaceflight – for escape. The emergency system is on the same level of the crew access tower as the crew access arm, the bridge astronauts walk across to enter the Starliner. The launch teams, secured in seats, descended the tower to the pad perimeter below.

Wearing portable respirators, astronauts and personnel with simulated injuries exit an armored vehicle during the simulation.

Next, using mine-resistant ambush-protected vehicles, known as MRAPs, the crew members drove just under a mile north to a helipad, where flight surgeons and the emergency medical services teams waited with ambulances and a decontamination vehicle. Astronauts evacuating from a pad emergency may come into contact with hazardous substances, such as fuel from the rocket or spacecraft, and must be decontaminated to allow medical personnel to safely treat them. In a true emergency, anyone injured would then be transported via helicopter to area hospitals.

Personnel from Kennedy Space Center emergency medical services, pad rescue teams and environmental health, along with CCAFS fire and rescue and the U.S. Air Force 45th Space Wing worked in tandem with NASA, Boeing and ULA to whisk the astronauts to safety – and, in the process, test necessary procedures and equipment, while providing new team members valuable experience.

The simulation is one of several NASA has conducted with our commercial crew partners, Boeing and SpaceX, in preparation to launch astronauts from American soil. NASA’s Commercial Crew Program continues to place astronaut safety at the forefront of preparations for human spaceflight.

Flight Test Dates Under Review

SpaceX's Crew Dragon and Boeing's Starliner will transport astronauts to the International Space Station.

NASA’s Commercial Crew Program and private industry partners, Boeing and SpaceX, are working to return human spaceflight launches to the International Space Station from U.S. soil on American rockets and spacecraft.

NASA and our partners want to fly astronauts as quickly as we can without compromising the safety of our astronauts and always will give safety precedence over schedule. However, our schedules matter. The NASA Administrator has directed all programs in the Human Exploration and Operations Directorate to reexamine flight dates once new leadership is in place to deliver realistic schedule plans.

This is a pivotal time for NASA and our partners. The final phase of our development and testing is critical to the safety of our astronauts and the success of our mission – regular, reliable and cost-effective human transportation to and from the International Space Station on commercially-owned and operated American space systems.

We are testing, learning and incorporating changes to improve the design and operation of these next-generation human space transportation systems. As a result, our providers have improved the safety of these systems, and the effect of these changes have impacted schedules.

NASA, SpaceX Earn Emmy Nomination for Demo-1 Mission Coverage

NASA and SpaceX were nominated for an Emmy! Teams from the agency’s Commercial Crew Program are among six finalists in the Outstanding Interactive Program category for their coverage of SpaceX’s Demo-1 mission in March 2019.

The nomination recognizes the teams’ tremendous efforts in sharing with the world Crew Dragon’s historic journey to the International Space Station. The mission marked the first time a commercially operated spacecraft docked with the space station, and brought the United States a critical step closer to launching astronauts in American spacecraft on American rockets from American soil.

The uncrewed SpaceX Crew Dragon spacecraft s pictured with its nose cone open revealing its docking mechanism while approaching the International Space Station's Harmony module on March 3, 2019.
The uncrewed SpaceX Crew Dragon spacecraft is pictured with its nose cone open revealing its docking mechanism while approaching the International Space Station’s Harmony module on March 3, 2019. Image credit: NASA

NASA and SpaceX spent years preparing a collaborative approach to mission coverage, which featured multiple live broadcasts from agency and company facilities across the country during each phase of the mission, continuing through Crew Dragon’s stunning return to Earth. Throughout NASA’s coverage, the agency engaged social media users around the world and at local social media influencer gatherings at the agency’s Kennedy Space Center in Florida.

The Emmy Awards ceremony will be held Sunday, Sept. 22, 2019.

SpaceX Provides Update on Crew Dragon Static Fire Investigation

SpaceX held a joint teleconference with NASA on Monday, July 15, to update media on the company’s investigation into its Crew Dragon static fire mishap on Saturday, April 20. SpaceX’s full statement on the investigation and the current findings can be found at: https://go.nasa.gov/2GeGLyH

 

SpaceX’s Cargo Dragon to Deliver New Space Station Docking Adapter for Commercial Crew Spacecraft

The International Docking Adapter 3, a critical component for future crewed missions to the International Space Station, is carefully packed away in the unpressurized "trunk" section of the SpaceX Dragon spacecraft at the SpaceX facility on Cape Canaveral Air Force Station in Florida on June 19.
The International Docking Adapter 3, a critical component for future crewed missions to the International Space Station, is carefully packed away in the unpressurized “trunk” section of the SpaceX Dragon spacecraft at the SpaceX facility on Cape Canaveral Air Force Station in Florida on June 19. Photo credit: NASA/Isaac Watson

A new International Docking Adapter, called IDA-3, is scheduled to arrive at the International Space Station this July aboard SpaceX’s 18th cargo resupply mission to the microgravity laboratory. When installed on the space station, the one-of-a-kind outpost will have two common ports enabling expanded opportunities for visiting vehicles, including new spacecraft designed to carry humans for NASA’s Commercial Crew Program.

The docking adapters are the physical connections spacecraft like Boeing’s CST-100 Starliner, SpaceX’s Crew Dragon and future, yet-to-be designed international spacecraft will use to autonomously attach to station. The adapters are important because the plans are readily available for spacecraft builders and standardize a host of docking requirements.

The International Docking Adapter 3, a critical component for future crewed missions to the International Space Station, is carefully packed away in the unpressurized “trunk” section of the SpaceX Dragon spacecraft at the SpaceX facility on Cape Canaveral Air Force Station in Florida on June 19.
The International Docking Adapter 3, a critical component for future crewed missions to the International Space Station, is carefully packed away in the unpressurized “trunk” section of the SpaceX Dragon spacecraft at the SpaceX facility on Cape Canaveral Air Force Station in Florida on June 19. Photo credit: NASA/Cory Huston

Currently stowed in the trunk of SpaceX’s Dragon cargo spacecraft, the IDA-3 was assembled at NASA’s Kennedy Space Center in Florida, and comprises of a number of sensors that spacecraft will communicate with and connect to through use of onboard computers and navigation systems.  Docking requires no crew assistance and can be completed much more quickly than the berthing process often used for cargo spacecraft today, which may involve astronauts aboard the station manually capturing spacecraft using a robotic arm then maneuvering the craft to attach to a common hatch mechanism.

IDA-3 is one of the primary payloads on the SpaceX resupply mission and is identical to the International Docking Adapter-2, IDA-2, installed in the summer of 2016. IDA-2 was used by SpaceX during the company’s first uncrewed flight test, called Demo-1, for commercial crew. Both docking adapters were built by Boeing.

Once at the space station, flight controllers will use the station’s Canadarm2 robotic arm to remove the IDA-3 from Dragon’s trunk and place it over a Pressurized Mating Adapter (PMA-3) on the station’s Harmony module, or Node 2. Later this summer, two Expedition 60 crew members will perform a spacewalk to permanently install the IDA-3 to PMA-3.

The SpaceX CRS-18 mission is scheduled to launch at 7:35 p.m. EDT on Sunday, July 21, from Space Launch Complex 40 at Cape Canaveral Air Force Station. After its arrival, the Dragon cargo spacecraft will remain at the space station for about a month.

NASA, SpaceX Simulate Astronauts Docking to Station on Crew Dragon Spacecraft

NASA and SpaceX practiced Crew Dragon rendezvous and docking to the International Space Station during a virtual dress rehearsal on June 26
The uncrewed SpaceX Crew Dragon spacecraft is the first Commercial Crew vehicle to visit the International Space Station. Here it is pictured with its nose cone open revealing its docking mechanism while approaching the station’s Harmony module. Photo credit: NASA

NASA and SpaceX practiced Crew Dragon rendezvous and docking to the International Space Station during a virtual dress rehearsal on June 26 for the company’s first crew flight test, known as Demo-2, to the microgravity laboratory.

NASA and SpaceX practiced Crew Dragon rendezvous and docking to the International Space Station during a virtual dress rehearsal on June 26
The Demo-2 flight test will be the Crew Dragon’s chance to demonstrate a complete mission with astronauts, from launch to landing, and will put SpaceX on its way to earning certification from NASA’s Commercial Crew Program. Photo credit: NASA

The activity is part of a series of integrated simulations bringing together NASA and SpaceX flight control teams to complete multiple practice runs for each dynamic phase of a mission from launch to splashdown. These simulations provide the teams plenty of practice to ensure they safely and successfully perform the planned operations of the actual spaceflight, with opportunities to fine-tune their procedures and gain experience on how to solve problems should they arise.

Astronauts Bob Behnken and Doug Hurley are assigned to take the first flight on SpaceX’s Demo-2 mission, and the two have been working closely with SpaceX throughout the design and construction of the spacecraft, offering up the experience they gained on previous spaceflights. Joint simulations bring them together with the teams that will support them from the ground to practice for the mission — including handling any challenges that might arise during flight.

NASA and SpaceX practiced Crew Dragon rendezvous and docking to the International Space Station during a virtual dress rehearsal on June 26
In March, SpaceX’s Demo-1 mission proved the Crew Dragon and its Falcon 9 rocket worked as designed. Photo credit: NASA

The Demo-2 flight test will be the Crew Dragon’s chance to demonstrate a complete mission with astronauts, from launch to landing, and will put SpaceX on its way to earning certification from NASA’s Commercial Crew Program. Once the spacecraft is certified, SpaceX can begin regular flights to the space station with long-duration crews aboard.

In March, SpaceX’s Demo-1 mission proved the Crew Dragon and its Falcon 9 rocket worked as designed. The mission tested a new launch configuration, checked maneuverability demonstrations in free flight and ensured the crew’s ability to transfer power and data between the spacecraft and the space station. With those boxes all successfully checked, the Crew Dragon became the first commercial spacecraft built to carry humans to dock with the space station. Its subsequent safe reentry and splashdown in the Atlantic Ocean was an important step toward proving the spacecraft is ready to carry humans onboard.

Starliner Parachute System Finishes Two Tests in One Week

NASA and Boeing completed two different tests of the CST-100 Starliner parachute system this week at two different locations in the desert of the western United States. The tests were part of a series of parachute tests providing valuable data needed to prove the system is safe to carry astronauts to and from the International Space Station as part of NASA’s Commercial Crew Program.

A full-scale CST-100 Starliner test article, known as a boiler plate, lands safely June 24 at the U.S. Army’s White Sands Missile Range in New Mexico. Photo credit: Boeing

The first test, conducted June 24 at the U.S. Army’s White Sands Missile Range in New Mexico, used a full-scale Starliner test article, known as a boiler plate, designed to simulate the actual spacecraft. This test featured a double failure scenario meaning one of the parachute system’s two drogue parachutes and one of the three main parachutes were both intentionally disabled to test how the remaining parachutes handled the additional loads during deployment and descent.

The next test occurred June 26 using a dart-shaped test device meant to function as a Starliner weight simulant. The device was released from a C-17 aircraft above the U.S. Army’s Yuma Proving Ground in Arizona.  This was a “high Q” test, meaning the parachutes were intentionally inflated at higher pressures than they are expected to see during missions.

Parachutes deploy over the U.S Army’s Proving Ground on June 26 in a Boeing CST-100 Starliner parachute system test. Photo credit: U.S. Army

In both instances, the Starliner test articles landed safely, and the joint NASA and Boeing teams currently are reviewing the new data.

Boeing is targeting an uncrewed Orbital Flight Test to the space station this summer, which will test the full end-to-end capabilities of the system from launch to landing. The uncrewed test will be follow by its Crew Flight Test to the space station. Starliner will launch atop a United Launch Alliance Atlas V rocket from Space Launch Complex 41 at Cape Canaveral Air Force Station in Florida.

As commercial crew providers Boeing and SpaceX begin to make regular flights to the space station, NASA will continue to advance its mission to go beyond low-Earth orbit and establish a human presence on the Moon with the ultimate goal of sending astronauts to Mars.

The Atlas V to Launch Starliner Crew Missions to Station Arrives at Launch Site

The ULA Atlas V booster for Boeing's Crew Flight Test is backed into the Atlas Spaceflight Operations Center at CCAFS on June 5. 2019.
The United Launch Alliance (ULA) Atlas V booster that will be used for Boeing’s Crew Flight Test (CFT) is backed into the Atlas Spaceflight Operations Center (ASOC) at Cape Canaveral Air Force Station in Florida on June 5, 2019. The ULA Atlas V rocket will launch Starliner and its crew to the International Space Station for NASA’s Commercial Crew Program. Inside the ASOC, the booster will await the start of operations for its missions. The CFT will demonstrate Starliner and Atlas V’s ability to safely carry crew to and from the orbiting laboratory. Photo credit: NASA/Frank Michaux
The United Launch Alliance (ULA) Atlas V booster that will be used for Boeing’s Crew Flight Test (CFT) is moved out of the Mariner cargo ship at the Army Wharf at Cape Canaveral Air Force Station in Florida on June 5, 2019.
The United Launch Alliance (ULA) Atlas V booster that will be used for Boeing’s Crew Flight Test (CFT) is moved out of the Mariner cargo ship at the Army Wharf at Cape Canaveral Air Force Station in Florida on June 5, 2019. Photo Credit: NASA/Frank Michaux

The United Launch Alliance (ULA) Atlas V rocket that will launch Boeing’s CST-100 Starliner spacecraft on its Crew Flight Test (CFT) to the International Space Station for NASA’s Commercial Crew Program arrived on Saturday at Cape Canaveral Force Station in Florida.

The booster stage and the Dual Engine Centaur upper stage of the Atlas V rocket, designated AV-082, arrived on ULA’s Mariner cargo ship from the company’s facility in Decatur, Alabama.

The Atlas V rocket now located in the company’s Atlas Spaceflight Operations Center at Cape Canaveral will undergo receiving checks and await the start of operations for its mission. The CFT mission will take NASA astronauts Mike Fincke and Nicole Mann, and Boeing astronaut Chris Ferguson to the station to demonstrate Starliner and Atlas V’s ability to safely carry crew to and from the orbiting laboratory.

The United Launch Alliance (ULA) Atlas V booster that will be used for Boeing’s Crew Flight Test (CFT) is transported to the Atlas Spaceflight Operations Center (ASOC) at Cape Canaveral Air Force Station in Florida on June 5, 2019.
The United Launch Alliance (ULA) Atlas V booster that will be used for Boeing’s Crew Flight Test (CFT) is transported to the Atlas Spaceflight Operations Center (ASOC) at Cape Canaveral Air Force Station in Florida on June 5, 2019. Photo credit: NASA/Frank Michaux

CFT will be the second Starliner flight following the uncrewed Orbital Flight Test (OFT) that is targeted to launch to the station in August. The rocket for OFT, called AV-080, was brought to the Cape last year.

Both flights are key elements of NASA’s Commercial Crew Program that will return the nation’s capability to launch astronauts into orbit on American rockets and spacecraft from U.S. soil. Regular commercial transportation using Boeing’s Starliner and SpaceX’s Crew Dragon spacecraft to and from the space station will enable the addition of another crew member, expanded station use, and additional research time aboard the orbiting laboratory. This time will help address the challenges of moving humanity toward the Moon and Mars as we learn how to keep astronauts healthy during long-duration space travel and demonstrate technologies for human and robotic exploration beyond low-Earth orbit, to the Moon and Mars.