SpaceX Adopts Lessons Learned From Multiple Booster Landings – Test Fires Recovered 1st Stage: Videos

SpaceX completed the first full duration test firing of a landed first stage booster on July 28, 2016 on a test stand at their rocket development facility in McGregor, Texas. Credit: SpaceX
SpaceX completed the first full duration test firing of a landed first booster on July 28, 2016 on a test stand at their rocket development facility in McGregor, Texas.
SpaceX completed the first full duration test firing of a landed first stage booster on July 28, 2016 on a test stand at their rocket development facility in McGregor, Texas. Credit: SpaceX

KENNEDY SPACE CENTER, FL – SpaceX founder Elon Musk’s daring dream of rocket recycling and reusability is getting closer and closer to reality with each passing day. After a breathtaking series of experimental flight tests aimed at safely landing the firms spent Falcon 9 first stages on land and at sea over the past half year the bold effort achieved another major milestone by just completing the first full duration test firing of one of those landed boosters.

On Thursday, July 28, SpaceX engineers successful conducted a full duration static engine test firing of the 156-foot-tall (47-meter) recovered Falcon 9 first stage booster while held down on a test stand at the company’s rocket development test facility in McGregor, Texas. The engines fired up for about two and a half minutes.

The SpaceX team has been perfecting the landing techniques by adopting lessons learned after each landing campaign attempt.

What are the lessons learned so far from the first stage landings and especially the hard landings? Are there any changes being made to the booster structure? How well did the landing burn scenario perform?

During SpaceX’s recent CRS-9 launch campaign media briefings at NASA’s Kennedy Space Center on July 18, I asked SpaceX VP Hans Koenigsmann for some insight.

“We learned a lot … from the landings,” Hans Koenigsmann, SpaceX vice president of Flight Reliability, told Universe Today during the recent media briefings for the SpaceX CRS-9 space station cargo resupply launch on July 18.

“There are no structural changes first of all.”

“The key thing is to protect the engines,” Koenigsmann elaborated, while they are in flight and “during reentry”.

The SpaceX Falcon 9 first stage is outfitted with four landing legs at the base and four grid fins at the top to conduct the landing attempts.

“In general I think the landing concept with the legs, and the number of burns and the way we perform those seems to work OK,” Koenigsmann told Universe Today.

After separating from the second stage at hypersonic speeds of up to some 4000 mph, the first stage engines are reignited to reverse course and do a boost backburn back to the landing site and slow the rocket down for a soft landing, via supersonic retropulsion.

Proper engine performance is critical to enabling a successful touchdown.

“The key thing is to protect the engines – and make sure that they start up well [in space during reentry],” Koenigsmann explained. “And in particular the hot trajectory, so to speak, like the ones that comes in after a fast payload, like the geo-transfer payload basically.”

“Those engines need to be protected so that they start up in the proper way. That’s something that we learned.”

Elon Musk’s goal is to radically slash the cost of launching rockets and access to space via rocket reuse – in a way that will one day lead to his vision of a ‘City on Mars.’

SpaceX hopes to refly a once flown booster later this year, sometime in the Fall, using the ocean landed Falcon from NASA’s CRS-8 space station mission launched in April, says Koenigsmann.

But the company first has to prove that the used vehicle can survive the extreme and unforgiving stresses of the violent spaceflight environment before they can relaunch it.

The July 28 test firing is part of that long life endurance testing and involved igniting all nine used first stage Merlin 1D engines housed at the base of a used landed rocket.

The Falcon 9 first stage generates over 1.71 million pounds of thrust when all nine Merlin engines fire up on the test stand for a duration of up to three minutes – the same as for an actual launch.

Watch the engine test in this SpaceX video:

Video Caption: Falcon 9 first stage from May 2016 JCSAT mission was test fired, full duration, at SpaceX’s McGregor, Texas rocket development facility on July 28, 2016. Credit: SpaceX

The used 15 story Falcon booster had successfully carried out an intact soft landing on an ocean going platform after launching a Japanese commercial telecommunications satellite only two months ago on May 6 of this year.

Just 10 minutes after launching the JCSAT-14 telecom satellite to a Geostationary Transfer Orbit (GTO), the used first stage relit a first stage Merlin 1D engine.

It conducted a series of three recovery burns to maneuver the rocket to a designated landing spot at sea or on land and rapidly decelerate it from supersonic speeds for a propulsive soft landing, intact and upright using a quartet of landing legs that deploy in the final moments before a slow speed touchdown.

However, although the landing was upright and intact, this particular landing was also classed as a ‘hard landing’ because the booster landed at a higher velocity and Merlin 1D first stage engines did sustain heavy damage as seen in up close photos and acknowledged by Musk.

“Most recent rocket took max damage, due to v high entry velocity. Will be our life leader for ground tests to confirm others are good,” Musk tweeted at the time.

Nevertheless it all worked out spectacularly and this was the first one to be recovered from the much more demanding, high velocity trajectory delivering a satellite to GTO.

Indeed prior to liftoff, Musk had openly doubted a successful landing outcome, since this first stage was flying faster and at a higher altitude at the time of separation from the second stage and thus was much more difficult to slow down and maneuver back to the ocean based platform compared to ISS missions, for example.

So although this one cannot be reflown, it still serves another great purpose for engineers seeking to determining the longevity of the booster and its various components – as now audaciously demonstrated by the July 28 engine test stand firing.

“We learned a lot even on the missions where things go wrong with the landing, everything goes well on the main mission of course,” said Koenigsmann.

Altogether SpaceX has successfully soft landed and recovered five of their first stage Falcon 9 boosters intact and upright since the history making first ever land landing took place just seven months ago in December 2015 at Cape Canaveral Air Force Station in Florida.

The most recent launch and landing occurred last week on July 18, 2016 during the dramatic midnight blastoff of the SpaceX CRS-9 commercial cargo resupply mission to the International Space Station (ISS) under contract for NASA.

See the stupendous events unfold in up close photos and videos herein.

SpaceX Falcon 9 launches and lands over Port Canaveral in this streak shot showing  rockets midnight liftoff from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida at 12:45 a.m. EDT on July 18, 2016 carrying Dragon CRS-9 craft to the International Space Station (ISS) with almost 5,000 pounds of cargo and docking port. View from atop Exploration Tower in Port Canaveral. Credit: Ken Kremer/kenkremer.com
SpaceX Falcon 9 launches and lands over Port Canaveral in this streak shot showing rockets midnight liftoff from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida at 12:45 a.m. EDT on July 18, 2016 carrying Dragon CRS-9 craft to the International Space Station (ISS) with almost 5,000 pounds of cargo and docking port. View from atop Exploration Tower in Port Canaveral. Credit: Ken Kremer/kenkremer.com

Following each Falcon 9 launch and landing attempt, SpaceX engineers assess the voluminous and priceless data gathered, analyze the outcome and adopt the lessons learned.

Moments before dramatic touchdown of SpaceX Falcon 9 1st stage at Landing Zone-1 (LX-1) accompanied by sonic booms after launching Dragon CRS-9 supply ship to orbit from Cape Canaveral Air Force Station, Florida at 12:45 a.m., bound for the International Space Station (ISS).   Credit: Ken Kremer/kenkremer.com
Moments before dramatic touchdown of SpaceX Falcon 9 1st stage at Landing Zone-1 (LX-1) accompanied by sonic booms after launching Dragon CRS-9 supply ship to orbit from Cape Canaveral Air Force Station, Florida at 12:45 a.m., bound for the International Space Station (ISS). Credit: Ken Kremer/kenkremer.com

CRS-9 marks only the second time SpaceX has attempted a land landing of the 15 story tall first stage booster back at Cape Canaveral Air Force Station – at the location called Landing Zone 1 (LZ 1).

Watch this exquisitely detailed up close video showing the CRS-9 first stage landing at LZ 1, as shot by space colleague Jeff Seibert from the ITL causeway at CCAFS- which dramatically concluded with multiple shockingly loud sonic booms rocketing across the Space Coast and far beyond and waking hordes of sleepers:

Video caption: This was the second terrestrial landing of a SpaceX Falcon 9 booster on July 18, 2016. It had just launched the CRS9 Dragon mission towards the ISS. The landing took place at LZ1, formerly known as Pad 13, located on CCAFS and caused a triple sonic boom heard 50 miles away. Credit: Jeff Seibert

The history making first ever ground landing successfully took place at Landing Zone 1 (LZ 1) on Dec. 22, 2015 as part of the ORBCOMM-2 mission. Landing Zone 1 is built on the former site of Space Launch Complex 13, a U.S. Air Force rocket and missile testing range.

SpaceX also successfully recovered first stages three times in a row at sea this year on an ocean going drone ship barge using the company’s OCISLY Autonomous Spaceport Drone Ship (ASDS) on April 8, May 6 and May 27.

OCISLY is generally stationed approximately 400 miles (650 kilometers) off shore and east of Cape Canaveral, Florida in the Atlantic Ocean. The barge arrives back in port at Port Canaveral several days after the landing, depending on many factors like weather, port permission and the state of the rocket.

However while trying to extend the touchdown streak to 4 in a row during the latest drone ship landing attempt following the June 15 Eutelsat telecom launch to GTO, the booster basically crashed because it descended too quickly due to insufficient thrust from the Merlin descent engines.

The rocket apparently ran out of liquid oxygen fuel in the final moments before touchdown, hit hard, tipped over and pancaked onto the deck.

“Looks like early liquid oxygen depletion caused engine shutdown just above the deck,” Musk explained via twitter at the time.

“Looks like thrust was low on 1 of 3 landing engines. High g landings v sensitive to all engines operating at max.”

Flattened SpaceX Falcon 9 first stage arrived into Port Canaveral, FL atop a droneship late Saturday, June 18 after hard landing and tipping over following successful June 15, 2016  commercial payload launch.  Credit: Julian Leek
Flattened SpaceX Falcon 9 first stage arrived into Port Canaveral, FL atop a droneship late Saturday, June 18 after hard landing and tipping over following successful June 15, 2016 commercial payload launch. Credit: Julian Leek

“We learned a lot even on the mission where things go wrong with the landing,” Koenigsmann explained. “Everything goes well on the main mission of course.”

“That’s actually something where you have successful deploy and the landing doesn’t quite work- and yet its the landing that gets all the attention.”

“But even on those landings we learned a lot. In particular on the last landing [from Eutelsat launch] we learned a lot.”

“We believe we found a way to operationally protect these engines and to make it safer for them to start up – and to come up to full thrust and stay at full thrust.”

What exactly does “protecting the engines” mean “in flight?”

“Yes I mean protecting the engines during reentry,” Koenigsmann told me.

“That’s when the engines get hot. We enter with the engines facing the flow. So its basically the engines directly exposed to the hot flow. And that’s when you need to protect the engines and the gases and liquids that are in the engines. To make sure that nothing boils off and does funny things.”

“So all in all these series of drone ship landings has been extremely successful, even when we didn’t recover all the first stages [fully intact].”

SpaceX Falcon 9 booster moving along the Port Canaveral channel atop droneship platform with cruise ship in background nears ground docking facility on June 2, 2016 following Thaicom-8 launch on May 27, 2016.  Credit: Ken Kremer/kenkremer.com
SpaceX Falcon 9 booster moving along the Port Canaveral channel atop droneship platform with cruise ship in background nears ground docking facility on June 2, 2016 following Thaicom-8 launch on May 27, 2016. Credit: Ken Kremer/kenkremer.com

Watch for Ken’s continuing SpaceX and CRS-9 mission coverage where he reported onsite direct from the Kennedy Space Center and Cape Canaveral Air Force Station, Florida.

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

Watch my launch pad video of the CRS-9 launch:

Video caption: SpaceX Falcon 9 lifts off with Dragon CRS-9 resupply ship bound for the International Space Station on July 18, 2016 at 12:45 a.m. EDT from Space Launch Complex 40 at Cape Canaveral Air Force Station, Fl, as seen in this up close video from Mobius remote camera positioned at pad. Credit: Ken Kremer/kenkremer.com

Watch this CRS-9 launch and landing video compilation from space colleague Mike Wagner:

Video caption: SpaceX CRS-9 Launch and Landing compilation on 7/18/2016. Local papers reported 911 calls for a loud explosion up to 75 miles away. This sonic boom seemed louder than the first landing at the Cape in Dec. 2015. Credit: USLaunchReport

Prelaunch view of SpaceX Falcon 9 awaiting launch on May 27, 2016 from Cape Canaveral Air Force Station, Fl.  Credit: Lane Hermann
Prelaunch view of SpaceX Falcon 9 awaiting launch on May 27, 2016 from Cape Canaveral Air Force Station, Fl. Credit: Lane Hermann
First stage booster with landing legs removed from SpaceX JCSAT-14 launch was transported horizontally to SpaceX hangar at pad 39A at the Kennedy Space Center, Florida on May 16, 2016. Credit: Julian Leek
First stage booster with landing legs removed from SpaceX JCSAT-14 launch was transported horizontally to SpaceX hangar at pad 39A at the Kennedy Space Center, Florida on May 16, 2016. Credit: Julian Leek
Proud fisherman displays ultra fresh ‘catch of the day’ as ultra rare species of SpaceX Falcon 9 rocket floats by simultaneously on barge in Port Canaveral, Fl, on June 2, 2016.  Credit: Ken Kremer/kenkremer.com
Proud fisherman displays ultra fresh ‘catch of the day’ as ultra rare species of SpaceX Falcon 9 rocket floats by simultaneously on barge in Port Canaveral, Fl, on June 2, 2016. Credit: Ken Kremer/kenkremer.com
Recovered SpaceX Falcon 9 basks in nighttime glow after arriving into Port Canaveral on June 2, 2016.  Credit: Ken Kremer/kenkremer.com
Recovered SpaceX Falcon 9 basks in nighttime glow after arriving into Port Canaveral on June 2, 2016. Credit: Ken Kremer/kenkremer.com

Crackling Roar of Atlas Rocket Carries Clandestine NRO Surveillance Satellite Aloft From Cape

A United Launch Alliance (ULA) Atlas V rocket carrying the NROL-61 surveillance satellite for the National Reconnaissance Office (NRO) lifts off from Space Launch Complex-41 on July 28, 2016 at 8:37 a.m. EDT from Cape Canaveral Air Force Station, FL. Credit: Ken Kremer/kenkremer.com
A United Launch Alliance (ULA) Atlas V rocket carrying the NROL-61 surveillance satellite for the National Reconnaissance Office (NRO) lifts off from Space Launch Complex-41 on July 28, 2016 at 8:37 a.m. EDT. Credit: Ken Kremer/kenkremer.com
A United Launch Alliance (ULA) Atlas V rocket carrying the NROL-61 surveillance satellite for the National Reconnaissance Office (NRO) lifts off from Space Launch Complex-41 on July 28, 2016 at 8:37 a.m. EDT from Cape Canaveral Air Force Station, FL. Credit: Ken Kremer/kenkremer.com

CAPE CANAVERAL AIR FORCE STATION, FL — Riding atop the crackling roar of an Atlas V rocket, a clandestine surveillance satellite for our nation’s spy masters was carried aloft by a powerful booster from the Florida space coast to an undisclosed orbit at breakfast time today, Thursday, July 28.

The United Launch Alliance (ULA) Atlas V rocket carrying the NROL-61 surveillance satellite for the National Reconnaissance Office (NRO) lifted off from Space Launch Complex-41 right at the appointed time of 8:37 a.m. EDT this morning with approximately 1.5 million pounds of thrust.

The top secret NROL-61 satellite bolted on top and inside the 4 meter diameter nose cone was launched in support of US national defense and is vital to US national security.

“Thank you to the entire mission team for years of hard work and collaboration on today’s successful launch of NROL-61. We are proud the U.S. Air Force and NRO Office of Space Launch have entrusted ULA with delivering this critical asset for our nation’s security,” said Laura Maginnis, ULA vice president of Custom Services, in a statement.

“Our continued one launch at a time focus and exceptional teamwork make launches like today’s successful.”

A United Launch Alliance (ULA) Atlas V rocket carrying the NROL-61 surveillance satellite for the National Reconnaissance Office (NRO) lifts off from Space Launch Complex-41 on July 28, 2016 at 8:37 a.m. EDT. Credit: Ken Kremer/kenkremer.com
A United Launch Alliance (ULA) Atlas V rocket carrying the NROL-61 surveillance satellite for the National Reconnaissance Office (NRO) lifts off from Space Launch Complex-41 on July 28, 2016 at 8:37 a.m. EDT from Cape Canaveral Air Force Station, FL. Credit: Ken Kremer/kenkremer.com

The launch was webcast live by ULA and featured video recorded call in questions about spaceflight from the general public – especially children!

The rocket roared off pad 41 atop an ever expanding plume of smoke and ash into a brilliant and cloudless blue sky under absolutely ideal weather conditions with clear lines of sight enjoyed by hordes of spectators gathered here from near and far, and lining the space coast beaches and surrounding viewing areas.

Many local area hotels were packed with space enthusiasts hoping for a space spectacular at this unusually convenient launch time – and they were not disappointed!!

Because the Atlas rocket was equipped with a pair of powerful solid rocket boosters to augment its liftoff thrust, the smoke plume was visible for as long as we could see it.

ULA Atlas V rocket lifts off with NROL-61 spy satellite for the NRO from pad 41 on July 28, 2016 at 8:37 a.m. EDT. Credit: Julian Leek
ULA Atlas V rocket lifts off with NROL-61 spy satellite for the NRO from pad 41 on July 28, 2016 at 8:37 a.m. EDT. Credit: Julian Leek

The rocket soon arced over, racing southeasterly to orbit and towards the African continent.

Virtually everything about the clandestine payload, its mission, purpose and goals are classified top secret on a mission of vital importance to America’s national security and defense needs.

The NRO is the government agency that runs a vast fleet of powerful orbital assets hosting a multitude of the most advanced, wide ranging and top secret capabilities.

The most recent NRO payload, known as NROL 37, was just launched by ULA last month on their Delta IV Heavy – the most powerful rocket in the world on June 11 – read my story here.

The venerable ULA Atlas V rocket sports a 100% record of launch success and its unusual for technical issues to hold up a launch. The ever changeable Florida weather is another matter entirely.

The NROL-61 mission counts as ULA’s sixth launch of 2016 and the 109th overall since the company was founded in 2006.

The 20 story tall Atlas V launched in its 421 configuration – the same as what will be used for manned launches with the crewed Boeing ‘Starliner’ space taxi carrying astronaut crews to the International Space Station.
This was the sixth Atlas V to launch in the 421 configuration.

The Atlas 421 vehicle includes a 4-meter diameter Extra Extended Payload Fairing (XEPF) payload fairing and two solid rocket boosters that augment the first stage. The Atlas booster for this mission was powered by the RD AMROSS RD-180 engine and the Centaur upper stage was powered by the Aerojet Rocketdyne RL10C-1 engine.

The RD-180 burns RP-1 (Rocket Propellant-1 or highly purified kerosene) and liquid oxygen and delivers 860,200 lb of thrust at sea level.

The strap on solids deliver approximately 500,000 pounds of thrust.

The solids were jettisoned about 2 minutes after liftoff.

Virtually everything about the clandestine payload, its mission, purpose and goals are classified top secret.

The NRO is the government agency that runs a vast fleet of powerful orbital assets hosting a multitude of the most advanced, wide ranging and top secret capabilities.

The possible roles for the reconnaissance payload include signals intelligence, eavesdropping, imaging and spectroscopic observations, early missile warnings and much more.

The NRO was formed in response to the Soviet launch of Sputnik and secretly created on September 6, 1961.

“The purpose is overseeing all satellite and overflight reconnaissance projects whether overt or covert. The existence of the organization is no longer classified today, but we’re still pressing to perform the functions necessary to keep American citizens safe,” according to the official NRO website.

Atlas V rocket streaks to orbit on smoke and ash carrying NROL-61 spy satellite for the NRO  after launch on July 28, 2016 at 8:37 a.m. EDT from Cape Canaveral Air Force Station, FL.  Credit: Ken Kremer/kenkremer.com
Atlas V rocket streaks to orbit on smoke and ash carrying NROL-61 spy satellite for the NRO after launch on July 28, 2016 at 8:37 a.m. EDT from Cape Canaveral Air Force Station, FL. Credit: Ken Kremer/kenkremer.com

Watch for Ken’s continuing on site reports direct from Cape Canaveral Air Force Station, the Kennedy Space Center and the ULA Atlas launch pad.

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

………….

Learn more about SLS and Orion crew vehicle, SpaceX CRS-9 rocket launch, ISS, ULA Atlas and Delta rockets, Juno at Jupiter, Orbital ATK Antares & Cygnus, Boeing, Space Taxis, Mars rovers, NASA missions and more at Ken’s upcoming outreach events:

July 27-28: “ULA Atlas V NRO Spysat launch July 28, SpaceX launch to ISS on CRS-9, SLS, Orion, Juno at Jupiter, ULA Delta 4 Heavy NRO spy satellite, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, evenings

Atlas V rocket streaks to orbit carrying NROL-61 spy satellite for the NRO  on July 28, 2016 at 8:37 a.m. EDT as seen from Satellite Beach, FL.  Credit: Jillian Laudick
Atlas V rocket streaks to orbit carrying NROL-61 spy satellite for the NRO on July 28, 2016 at 8:37 a.m. EDT as seen from Satellite Beach, FL. Credit: Jillian Laudick

Mission artwork for Atlas V NROL-61 mission for the National Reconnaissance Office (NRO) is painted on nose cone of Atlas V rocket and depicts a green lizard, Spike, riding an Atlas V  launch vehicle.  Credit: Ken Kremer/kenkremer.com
Mission artwork for Atlas V NROL-61 mission for the National Reconnaissance Office (NRO) is painted on nose cone of Atlas V rocket and depicts a green lizard, Spike, riding an Atlas V launch vehicle. Credit: Ken Kremer/kenkremer.com

A ULA Atlas V rocket carrying the NROL-61 satellite is poised for blastoff from the pad at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on July 28, 2016.   Credit: Ken Kremer/kenkremer.com
A ULA Atlas V rocket carrying the NROL-61 satellite is poised for blastoff from the pad at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on July 28, 2016. Credit: Ken Kremer/kenkremer.com

Top Secret NRO SpySat Set for Brilliant Breakfast Blastoff July 28 – Watch Live

A ULA Atlas V rocket carrying the NROL-61 satellite is poised for blastoff from the pad at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on July 28, 2016. Credit: Ken Kremer/kenkremer.com
A ULA Atlas V rocket carrying the NROL-61 satellite is poised for blastoff from the pad at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on July 28, 2016.   Credit: Ken Kremer/kenkremer.com
A ULA Atlas V rocket carrying the NROL-61 satellite is poised for blastoff from the pad at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on July 28, 2016. Credit: Ken Kremer/kenkremer.com

CAPE CANAVERAL AIR FORCE STATION, FL — The nation’s newest surveillance satellite is all set for a brilliant breakfast blastoff on Thursday July 28 atop a powerful Atlas V rocket from the Florida Space Coast – and both the booster and weather are in excellent shape at this time!

The goal is carry the top secret NROL-61 mission for the National Reconnaissance Office (NRO) to an undisclosed orbit which in support of US national defense and vital to US national security.

The NROL-61 mission is set to lift off on a United Launch Alliance (ULA) Atlas V rocket on Thursday morning July 28 from Space Launch Comple-41 at Cape Canaveral Air Force Station in Florida.

In an uncommon move, ULA and the military have announced the launch time is 8:37 a.m. EDT.

Virtually everything about the clandestine payload, its mission, purpose and goals are classified top secret.

The NRO is the government agency that runs a vast fleet of powerful orbital assets hosting a multitude of the most advanced, wide ranging and top secret capabilities.

The most recent NRO payload, known as NROL 37, was just launched by ULA last month on their Delta IV Heavy – the most powerful rocket in the world on June 11 – read my story here.

The excitement is building with the launch just a day away and visitors are checking into local area hotels hoping for a magnificent show from the venerable Atlas rocket with a perfect record of launch performance.

ULA managers completed the Launch Readiness Review and everything “is on track for launch.”

So you can now plan your day and watch Thursday’s launch live via a ULA broadcast which starts 20 minutes prior to the given launch time at 8:17 a.m. EDT.

Webcast links: http://bit.ly/nrol61

Or: www.youtube.com/unitedlaunchalliance

Better yet if you are free and mobile you can watch this truly impressive feat with your own eyes by making your way to the many excellent viewing locations surrounding Cape Canaveral in every direction.

Here’s the rather cool ULA mission art with a webcast link.

ULA Webcast info for launch of Atlas V NROL-61 mission for the National Reconnaissance Office (NRO) on July 28, 2016.  Credit: ULA/NRO
ULA Webcast info for launch of Atlas V NROL-61 mission for the National Reconnaissance Office (NRO) on July 28, 2016. Credit: ULA/NRO

The NROL-61 patch depicts a green lizard, Spike, riding an Atlas V launch vehicle from the Cape Canaveral AFS. Spike was chosen as the mission mascot.

Mission artwork for Atlas V NROL-61 mission for the National Reconnaissance Office (NRO) is painted on nose cone of Atlas V rocket and depicts a green lizard, Spike, riding an Atlas V  launch vehicle.  Credit: Ken Kremer/kenkremer.com
Mission artwork for Atlas V NROL-61 mission for the National Reconnaissance Office (NRO) is painted on nose cone of Atlas V rocket and depicts a green lizard, Spike, riding an Atlas V launch vehicle. Credit: Ken Kremer/kenkremer.com

The Florida weather outlook is looking quite promising at this time rather favorable. Air Force meteorologists are predicting an 80 percent chance of ‘GO’ with favorable weather conditions for Thursdays breakfast time blastoff.

The primary weather concern is for Cumulus Clouds.

In the event of a scrub delay for any reason, a backup launch opportunity exists on Friday, July 29. The weather odds are the same at 80% GO!

The rocket should put on a spectacular sky show since it is equipped with a pair of powerful solid rocket boosters spewing fire and an expanding plume of smoke and ash as is soars to orbit!

The Atlas rocket and payload were rolled put to launch pad 41 as planned Tuesday morning, July 26 – for a distance of about 1800 feet from the Vertical Integration Facility (VIF) where the rocket and payload were assembled, out to the pad.

It is now visibly erect at the pad from a number of viewing locations including Titusville and Playalinda Beach – positioned in between four lightning masts for protection from lightening.

Here’s a detailed mission profile video describing the launch events:

The NROL-61 mission counts as ULA’s sixth launch of 2016 and the 109th overall since the company was founded in 2006.

A ULA Atlas V rocket carrying the NROL-61 satellite is poised for blastoff from the pad at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on July 28, 2016.   Credit: Ken Kremer/kenkremer.com
A ULA Atlas V rocket carrying the NROL-61 satellite is poised for blastoff from the pad at Space Launch Complex-41 at Cape Canaveral Air Force Station in Florida on July 28, 2016. Credit: Ken Kremer/kenkremer.com

The 20 story tall Atlas V will launch in its 421 configuration – the same as what will be used for manned launches with the crewed Boeing ‘Starliner’ space taxi carrying astronaut crews to the International Space Station.

This will be the sixth Atlas V to launch in the 421 configuration.

The Atlas 421 vehicle includes a 4-meter diameter payload fairing and two solid rocket boosters that augment the first stage. The Atlas booster for this mission was powered by the RD AMROSS RD-180 engine and the Centaur upper stage was powered by the Aerojet Rocketdyne RL10C-1 engine.

The RD-180 burns RP-1 (Rocket Propellant-1 or highly purified kerosene) and liquid oxygen and delivers 860,200 lb of thrust at sea level.

The strap on solids deliver approximately 500,000 pounds of thrust.

The solids will be jettisoned about 2 minutes after liftoff

The possible roles for the reconnaissance payload include signals intelligence, eavesdropping, imaging and spectroscopic observations, early missile warnings and much more.

The NRO was formed in response to the Soviet launch of Sputnik and secretly created on September 6, 1961.

“The purpose is overseeing all satellite and overflight reconnaissance projects whether overt or covert. The existence of the organization is no longer classified today, but we’re still pressing to perform the functions necessary to keep American citizens safe,” according to the official NRO website.

Watch for Ken’s continuing on site reports direct from Cape Canaveral Air Force Station, the Kennedy Space Center and the ULA Atlas launch pad.

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

………….

Learn more about SLS and Orion crew vehicle, SpaceX CRS-9 rocket launch, ISS, ULA Atlas and Delta rockets, Juno at Jupiter, Orbital ATK Antares & Cygnus, Boeing, Space Taxis, Mars rovers, NASA missions and more at Ken’s upcoming outreach events:

July 27-28: “ULA Atlas V NRO Spysat launch July 28, SpaceX launch to ISS on CRS-9, SLS, Orion, Juno at Jupiter, ULA Delta 4 Heavy NRO spy satellite, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, evenings

NASA Welds Together 1st SLS Hydrogen Test Tank for America’s Moon/Mars Rocket – Flight Unit in Progress

The first liquid hydrogen tank, also called the qualification test article, for NASA's new Space Launch System (SLS) heavy lift rocket lies horizontally beside the Vertical Assembly Center robotic weld machine on July 22, 2016 after final welding was just completed at NASA’s Michoud Assembly Facility in New Orleans. Credit: Ken Kremer/kenkremer.com
The first liquid hydrogen tank, also called the qualification test article, on NASA's new Space Launch System (SLS) heavy lift rocket lies horizontally beside the Vertical Assembly Center robotic weld machine on July 22, 2016 after final welding was just completed at NASA’s Michoud Assembly Facility in New Orleans.  Credit: Ken Kremer/kenkremer.com
The first liquid hydrogen tank, also called the qualification test article, for NASA’s new Space Launch System (SLS) heavy lift rocket lies horizontally beside the Vertical Assembly Center robotic weld machine on July 22, 2016 after final welding was just completed at NASA’s Michoud Assembly Facility in New Orleans. Credit: Ken Kremer/kenkremer.com

MICHOUD ASSEMBLY FACILITY, NEW ORLEANS, LA – NASA has just finished welding together the very first fuel tank for America’s humongous Space Launch System (SLS) deep space rocket currently under development – and Universe Today had an exclusive up close look at the liquid hydrogen (LH2) test tank shortly after its birth as well as the first flight tank, during a tour of NASA’s New Orleans rocket manufacturing facility on Friday, July 22, shortly after completion of the milestone assembly operation.

“We have just finished welding the first liquid hydrogen qualification tank article …. and are in the middle of production welding of the first liquid hydrogen flight hardware tank [for SLS-1] in the big Vertical Assembly Center welder!” explained Patrick Whipps, NASA SLS Stages Element Manager, in an exclusive hardware tour and interview with Universe Today on July 22, 2016 at NASA’s Michoud Assembly Facility (MAF) in New Orleans.

“We are literally putting the SLS rocket hardware together here at last. All five elements to put the SLS stages together [at Michoud].”

This first fully welded SLS liquid hydrogen tank is known as a ‘qualification test article’ and it was assembled using basically the same components and processing procedures as an actual flight tank, says Whipps.

“We just completed the liquid hydrogen qualification tank article and lifted it out of the welding machine and put it into some cradles. We will put it into a newly designed straddle carrier article next week to transport it around safely and reliably for further work.”

And welding of the liquid hydrogen flight tank is moving along well.

“We will be complete with all SLS core stage flight tank welding in the VAC by the end of September,” added Jackie Nesselroad, SLS Boeing manager at Michoud. “It’s coming up very quickly!”

“The welding of the forward dome to barrel 1 on the liquid hydrogen flight tank is complete. And we are doing phased array ultrasonic testing right now!”

SLS is the most powerful booster the world has even seen and one day soon will propel NASA astronauts in the agency’s Orion crew capsule on exciting missions of exploration to deep space destinations including the Moon, Asteroids and Mars – venturing further out than humans ever have before!

The LH2 ‘qualification test article’ was welded together using the world’s largest welder – known as the Vertical Assembly Center, or VAC, at Michoud.

And it’s a giant! – measuring approximately 130-feet in length and 27.6 feet (8.4 m) in diameter.

See my exclusive up close photos herein documenting the newly completed tank as the first media to visit the first SLS tank. I saw the big tank shortly after it was carefully lifted out of the welder and placed horizontally on a storage cradle on Michoud’s factory floor.

The newly assembled first liquid hydrogen tank, also called the qualification test article, for NASA's new Space Launch System (SLS) heavy lift rocket lies horizontally beside the Vertical Assembly Center robotic weld machine (blue) on July 22, 2016. It was lifted out of the welder (top) after final welding was just completed at NASA’s Michoud Assembly Facility in New Orleans.  Credit: Ken Kremer/kenkremer.com
The newly assembled first liquid hydrogen tank, also called the qualification test article, for NASA’s new Space Launch System (SLS) heavy lift rocket lies horizontally beside the Vertical Assembly Center robotic weld machine (blue) on July 22, 2016. It was lifted out of the welder (top) after final welding was just completed at NASA’s Michoud Assembly Facility in New Orleans. Credit: Ken Kremer/kenkremer.com

Finishing its assembly after years of meticulous planning and hard work paves the path to enabling the maiden test launch of the SLS heavy lifter in the fall of 2018 from the Kennedy Space Center (KSC) in Florida.

The qual test article is the immediate precursor to the actual first LH2 flight tank now being welded.

“We will finish welding the liquid hydrogen and liquid oxygen flight tanks by September,” Whipps told Universe Today.

Up close view of the dome of the newly assembled first ever liquid hydrogen test tank for NASA's new Space Launch System (SLS) heavy lift rocket on July 22, 2016  after it was welded together at NASA’s Michoud Assembly Facility in New Orleans.  Sensors will be attached to both ends for upcoming structural loads and proof testing.  Credit: Ken Kremer/kenkremer.com
Up close view of the dome of the newly assembled first ever liquid hydrogen test tank for NASA’s new Space Launch System (SLS) heavy lift rocket on July 22, 2016 after it was welded together at NASA’s Michoud Assembly Facility in New Orleans. Sensors will be attached to both ends for upcoming structural loads and proof testing. Credit: Ken Kremer/kenkremer.com

Technicians assembled the LH2 tank by feeding the individual metallic components into NASA’s gigantic “Welding Wonder” machine – as its affectionately known – at Michoud, thus creating a rigid 13 story tall structure.

The welding work was just completed this past week on the massive silver colored structure. It was removed from the VAC welder and placed horizontally on a cradle.

I watched along as the team was also already hard at work fabricating SLS’s first liquid hydrogen flight article tank in the VAC, right beside the qualification tank resting on the floor.

Welding of the other big fuel tank, the liquid oxygen (LOX) qualification and flight article tanks will follow quickly inside the impressive ‘Welding Wonder’ machine, Nesselroad explained.

The LH2 and LOX tanks sit on top of one another inside the SLS outer skin.

The SLS core stage – or first stage – is mostly comprised of the liquid hydrogen and liquid oxygen cryogenic fuel storage tanks which store the rocket propellants at super chilled temperatures. Boeing is the prime contractor for the SLS core stage.

To prove that the new welding machines would work as designed, NASA opted “for a 3 stage assembly philosophy,” Whipps explained.

Engineers first “welded confidence articles for each of the tank sections” to prove out the welding techniques “and establish a learning curve for the team and test out the software and new weld tools. We learned a lot from the weld confidence articles!”

“On the heels of that followed the qualification weld articles” for tank loads testing.

“The qualification articles are as ‘flight-like’ as we can get them! With the expectation that there are still some tweaks coming.”

“And finally that leads into our flight hardware production welding and manufacturing the actual flight unit tanks for launches.”

“All the confidence articles and the LH2 qualification article are complete!”

What’s the next step for the LH2 tank?

The test article tank will be outfitted with special sensors and simulators attached to each end to record reams of important engineering data, thereby extending it to about 185 feet in length.

Thereafter it will loaded onto the Pegasus barge and shipped to NASA’s Marshall Space Flight Center in Huntsville, Alabama, for structural loads testing on one of two new test stands currently under construction for the tanks. The tests are done to prove that the tanks can withstand the extreme stresses of spaceflight and safely carry our astronauts to space.

“We are manufacturing the simulators for each of the SLS elements now for destructive tests – for shipment to Marshall. It will test all the stress modes, and finally to failure to see the process margins.”

NASA’s Space Launch System (SLS) blasts off from launch pad 39B at the Kennedy Space Center in this artist rendering showing a view of the liftoff of the Block 1 70-metric-ton (77-ton) crew vehicle configuration.   Credit: NASA/MSFC
NASA’s Space Launch System (SLS) blasts off from launch pad 39B at the Kennedy Space Center in this artist rendering showing a view of the liftoff of the Block 1 70-metric-ton (77-ton) crew vehicle configuration. Credit: NASA/MSFC

The SLS core stage builds on heritage from NASA’s Space Shuttle Program and is based on the shuttle’s External Tank (ET). All 135 ET flight units were built at Michoud during the thirty year long shuttle program by Lockheed Martin.

“We saved billions of dollars and years of development effort vs. starting from a clean sheet of paper design, by taking aspects of the shuttle … and created an External Tank type generic structure – with the forward avionics on top and the complex engine section with 4 engines (vs. 3 for shuttle) on the bottom,” Whipps elaborated.

“This is truly an engineering marvel like the External Tank was – with its strength that it had and carrying the weight that it did. If you made our ET the equivalent of a Coke can, our thickness was about 1/5 of a coke can.”

“It’s a tremendous engineering job. But the ullage pressures in the LOX and LH2 tanks are significantly more and the systems running down the side of the SLS tank are much more sophisticated. Its all significantly more complex with the feed lines than what we did for the ET. But we brought forward the aspects and designs that let us save time and money and we knew were effective and reliable.”

The Vertical Weld Center tool used to fabricate barrel segments for the SLS liquid hydrogen and oxygen core stage tanks via vertical friction stir welding operations at NASA’s Michoud Assembly Facility in New Orleans.  Credit: Ken Kremer/kenkremer.com
The Vertical Weld Center tool used to fabricate barrel segments for the SLS liquid hydrogen and oxygen core stage tanks via vertical friction stir welding operations at NASA’s Michoud Assembly Facility in New Orleans. Credit: Ken Kremer/kenkremer.com

The SLS core stage is comprised of five major structures: the forward skirt, the liquid oxygen tank (LOX), the intertank, the liquid hydrogen tank (LH2) and the engine section.

The LH2 and LOX tanks feed the cryogenic propellants into the first stage engine propulsion section which is powered by a quartet of RS-25 engines – modified space shuttle main engines (SSMEs) – and a pair of enhanced five segment solid rocket boosters (SRBs) also derived from the shuttles four segment boosters.

The tanks are assembled by joining previously manufactured dome, ring and barrel components together in the Vertical Assembly Center by a process known as friction stir welding. The rings connect and provide stiffness between the domes and barrels.

The LH2 tank is the largest major part of the SLS core stage. It holds 537,000 gallons of super chilled liquid hydrogen. It is comprised of 5 barrels, 2 domes, and 2 rings.

The LOX tank holds 196,000 pounds of liquid oxygen. It is assembled from 2 barrels, 2 domes, and 2 rings and measures over 50 feet long.

The material of construction of the tanks has changed compared to the ET.

“The tanks are constructed of a material called the Aluminum 2219 alloy,” said Whipps. “It’s a ubiquosly used aerospace alloy with some copper but no lithium, unlike the shuttle superlightweight ET tanks that used Aluminum 2195. The 2219 has been a success story for the welding. This alloy is heavier but does not affect our payload potential.”

“The intertanks are the only non welded structure. They are bolted together and we are manufacturing them also. It’s much heavier and thicker.”

Overall, the SLS core stage towers over 212 feet (64.6 meters) tall and sports a diameter of 27.6 feet (8.4 m).

NASA’s Vehicle Assembly Center is the world’s largest robotic weld tool. The domes and barrels are assembled from smaller panels and piece parts using other dedicated robotic welding machines at Michoud.

The total weight of the whole core stage empty is 188,000 pounds and 2.3 million pounds when fully loaded with propellant. The empty ET weighed some 55,000 pounds.

Considering that the entire Shuttle ET was 154-feet long, the 130-foot long LH2 tank alone isn’t much smaller and gives perspective on just how big it really is as the largest rocket fuel tank ever built.

“So far all the parts of the SLS rocket are coming along well.”

“The Michoud SLS workforce totals about 1000 to 1500 people between NASA and the contractors.”

Every fuel tank welded together from now on after this series of confidence and qualification LOX and LH2 tanks will be actual flight article tanks for SLS launches.

“There are no plans to weld another qualification tank after this,” Nesselroad confirmed to me.

What’s ahead for the SLS-2 core stage?

“We start building the second SLS flight tanks in October of this year – 2016!” Nesselroad stated.

The world’s largest welder was specifically designed to manufacture the core stage of the world’s most powerful rocket – NASA’s SLS.

The Vertical Assembly Center welder was officially opened for business at NASA’s Michoud Assembly Facility in New Orleans on Friday, Sept. 12, 2014.

NASA Administrator Charles Bolden was personally on hand for the ribbon-cutting ceremony at the base of the huge VAC welder.

The state-of-the-art welding giant stands 170 feet tall and 78 feet wide. It complements the world-class welding toolkit being used to assemble various pieces of the SLS core stage including the domes, rings and barrels that have been previously manufactured.

The Gore Weld Tool (foreground) and  Circumferential Dome Weld Tool (background) Center tool used to fabricate dome segments for the SLS liquid hydrogen and oxygen core stage tanks via vertical friction stir welding operations at NASA’s Michoud Assembly Facility in New Orleans.  Credit: Ken Kremer/kenkremer.com
The Gore Weld Tool (foreground) and Circumferential Dome Weld Tool (background) used to fabricate dome segments for the SLS liquid hydrogen and oxygen core stage tanks via vertical friction stir welding operations at NASA’s Michoud Assembly Facility in New Orleans. Credit: Ken Kremer/kenkremer.com

The maiden test flight of the SLS/Orion is targeted for no later than November 2018 and will be configured in its initial 70-metric-ton (77-ton) Block 1 configuration with a liftoff thrust of 8.4 million pounds – more powerful than NASA’s Saturn V moon landing rocket.

Although the SLS-1 flight in 2018 will be uncrewed, NASA plans to launch astronauts on the SLS-2/EM-2 mission slated for the 2021 to 2023 timeframe.

The exact launch dates fully depend on the budget NASA receives from Congress and who is elected President in the November 2016 election – and whether they maintain or modify NASA’s objectives.

“If we can keep our focus and keep delivering, and deliver to the schedules, the budgets and the promise of what we’ve got, I think we’ve got a very capable vision that actually moves the nation very far forward in moving human presence into space,” said William Gerstenmaier, associate administrator for the Human Exploration and Operations Mission Directorate at NASA Headquarters in Washington, during the post QM-2 SRB test media briefing in Utah last month.

“This is a very capable system. It’s not built for just one or two flights. It is actually built for multiple decades of use that will enable us to eventually allow humans to go to Mars in the 2030s.”

Orion crew module pressure vessel for NASA’s Exploration Mission-1 (EM-1) is unveiled for the first time on Feb. 3, 2016 after arrival at the agency’s Kennedy Space Center (KSC) in Florida. It is secured for processing in a test stand called the birdcage in the high bay inside the Neil Armstrong Operations and Checkout (O&C) Building at KSC. Launch to the Moon is slated in 2018 atop the SLS rocket.  Credit: Ken Kremer/kenkremer.com
Orion crew module pressure vessel for NASA’s Exploration Mission-1 (EM-1) is unveiled for the first time on Feb. 3, 2016 after arrival at the agency’s Kennedy Space Center (KSC) in Florida. It is secured for processing in a test stand called the birdcage in the high bay inside the Neil Armstrong Operations and Checkout (O&C) Building at KSC. Launch to the Moon is slated in 2018 atop the SLS rocket. Credit: Ken Kremer/kenkremer.com

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

………….

Learn more about SLS and Orion crew vehicle, SpaceX CRS-9 rocket launch, ISS, ULA Atlas and Delta rockets, Juno at Jupiter, Orbital ATK Antares & Cygnus, Boeing, Space Taxis, Mars rovers, NASA missions and more at Ken’s upcoming outreach events:

July 27-28: “ULA Atlas V NRO Spysat launch July 28, SpaceX launch to ISS on CRS-9, SLS, Orion, Juno at Jupiter, ULA Delta 4 Heavy NRO spy satellite, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, evenings

Graphic shows all the dome, barrel, ring and engine components used to assemble the five major structures of the core stage of NASA’s Space Launch System (SLS) in Block 1 configuration. Credits: NASA/MSFC
Graphic shows all the dome, barrel, ring and engine components used to assemble the five major structures of the core stage of NASA’s Space Launch System (SLS) in Block 1 configuration. Credits: NASA/MSFC
At NASA’s Michoud Assembly Facility in New Orleans, Patrick Whipps/NASA SLS Stages Element Manager and Ken Kremer/Universe Today discuss details of SLS manufacture by the Circumferential Dome Weld Tool used to fabricate dome segments for the SLS liquid hydrogen and oxygen core stage tanks.   Credit: Ken Kremer/kenkremer.com
At NASA’s Michoud Assembly Facility in New Orleans, Patrick Whipps/NASA SLS Stages Element Manager and Ken Kremer/Universe Today discuss details of SLS manufacture by the Circumferential Dome Weld Tool used to fabricate dome segments for the SLS liquid hydrogen and oxygen core stage tanks. Credit: Ken Kremer/kenkremer.com
Graphic shows Block I configuration of NASA’s Space Launch System (SLS). Credits: NASA/MSFC
Graphic shows Block I configuration of NASA’s Space Launch System (SLS). Credits: NASA/MSFC

Flawless Capture and Berthing of SpaceX Dragon Supply Ship at ISS

The SpaceX Dragon is captured in the grips of the Canadarm2 robotic arm. Credit: NASA TV
The SpaceX Dragon is captured in the grips of the Canadarm2 robotic arm. Credit: NASA TV
The SpaceX Dragon is captured in the grips of the Canadarm2 robotic arm. Credit: NASA TV

KENNEDY SPACE CENTER, FL – Following a flawless post midnight blastoff two mornings ago, a pair of NASA astronauts executed a flawless capture of the newest SpaceX Dragon supply ship at the International Space Station early this morning, July 20, carrying 2.5 tons of priceless research equipment and gear for the resident astronauts and cosmonauts.

As the orbiting outpost was traveling 252 statute miles over the Great Lakes, NASA’s veteran Expedition 48 Commander Jeff Williams and newly arrived NASA Flight Engineer Kate Rubins used the station’s 57.7-foot (17.6-meter) Canadian-built robotic arm to reach out and capture the Dragon CRS-9 spacecraft at 6:56 a.m. EDT.

“Good capture confirmed after a two day rendezvous,” said Houston Mission Control at NASA’s Johnson Space Center, as Dragon was approximately 30 feet (10 meters) away from the station.

“We’ve captured us a Dragon,” radioed Williams.

“Congratulations to the entire team that put this thing together, launched it, and successfully rendezvoused it to the International Space Station. We look forward to the work that it brings.”

The SpaceX Dragon is seen attached to the International Space Station’s Harmony module just before orbital sunrise. Credit: NASA TV
The SpaceX Dragon is seen attached to the International Space Station’s Harmony module just before orbital sunrise. Credit: NASA TV

The events unfolded live on a NASA TV webcast for all to follow along.

Furthermore, today’s dramatic Dragon arrival coincides with a renowned day in the annuls of space history. Today coincides with the 40th anniversary of humanity’s first successful touchdown on the surface of Mars by NASA’s Viking 1 lander on July 20, 1976. It paved the way for many future missions.

And Neil Armstrong and Buzz Aldrin were the first humans to land on another celestial body – the Moon – on July 20, 1969 during NASA’s Apollo 11 lunar landing mission.

Williams was working from a robotics work station in the station’s domed cupola. Rubins was Williams backup. She just arrived at the station on July 9 for a minimum 4 month stay, after launching to orbit on a Russian Soyuz on July 6 with two additional crew mates.

Ground controllers then used the robotic arm to maneuver the Dragon cargo spacecraft closer to its berthing port on the Earth facing side of the Harmony module, located at the front of the station.

Some three hours after the successful grappling, Dragon was joined to the station and bolted into place for initial berthing on the Harmony module at 10:03 a.m. EDT as the station flew about 252 statute miles over the California and Oregon border.

Controllers then activated four gangs of four bolts in the common berthing mechanism (CBM) to complete the second stage capture of the latching and berthing of Dragon to the station with a total of 16 bolts to ensure a snug connection, safety and no pressure leaks.

Crew members Williams and Rubins along with Japanese astronaut Takuya Onishi are now working to install power and data cables from the station to Dragon. They plan to open the hatch tomorrow after pressurizing the vestibule in the forward bulkhead between the station and Dragon.

Dragon reached the station after a carefully choreographed orbital chase and series of multiple thruster firings to propel the cargo ship from its preliminary post launch orbit up to the massive million pound science outpost with six resident crew members from the US, Russia and Japan.

Among the 5000 pounds of equipment on board is the first of two identical docking adapters essential for enabling station dockings next year by NASA’s new commercial astronaut taxis. This mission is all about supporting NASA’s ‘Journey to Mars’ by humans in the 2030s.

Liftoff of the SpaceX Falcon 9 rocket in its upgraded, full thrust version and the Dragon CRS-9 resupply ship took place barely 48 hours ago at 12:45 a.m. EDT Monday, July 18, from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida.

SpaceX Falcon 9 launches and lands over Port Canaveral in this streak shot showing  rockets midnight liftoff from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida at 12:45 a.m. EDT on July 18, 2016 carrying Dragon CRS-9 craft to the International Space Station (ISS) with almost 5,000 pounds of cargo and docking port. View from atop Exploration Tower in Port Canaveral. Credit: Ken Kremer/kenkremer.com
SpaceX Falcon 9 launches and lands over Port Canaveral in this streak shot showing rockets midnight liftoff from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida at 12:45 a.m. EDT on July 18, 2016 carrying Dragon CRS-9 craft to the International Space Station (ISS) with almost 5,000 pounds of cargo and docking port. View from atop Exploration Tower in Port Canaveral. Credit: Ken Kremer/kenkremer.com

Dragon reached its preliminary orbit about 10 minutes after launch and then deployed a pair of solar arrays.

SpaceX also successfully executed a spellbinding ground landing of the Falcon 9 first stage back at Cape Canaveral Air Force Station’s Landing Zone 1, located a few miles south of launch pad 40.

The dramatic ground landing of the 156 foot tall Falcon 9 first stage at LZ -1 took place about 9 minutes after liftoff. It marks only the second time a spent orbit class booster has touched down intact and upright on land.

Moments before dramatic touchdown of SpaceX Falcon 9 1st stage at Landing Zone-1 (LX-1) accompanied by sonic booms after launching Dragon CRS-9 supply ship to orbit from Cape Canaveral Air Force Station, Florida at 12:45 a.m., bound for the International Space Station (ISS).   Credit: Ken Kremer/kenkremer.com
Moments before dramatic touchdown of SpaceX Falcon 9 1st stage at Landing Zone-1 (LX-1) accompanied by sonic booms after launching Dragon CRS-9 supply ship to orbit from Cape Canaveral Air Force Station, Florida at 12:45 a.m., bound for the International Space Station (ISS). Credit: Ken Kremer/kenkremer.com

Among the wealth of over 3900 pounds (1790 kg) of research investigations loaded on board Dragon is an off the shelf instrument designed to perform the first-ever DNA sequencing in space and the first international docking adapter (IDA) that is absolutely essential for docking of the SpaceX and Boeing built human spaceflight taxis that will ferry our astronauts to the International Space Station (ISS) in some 18 months.

Other science experiments on board include OsteoOmics to test if magnetic levitation can accurately simulate microgravity to study different types of bone cells and contribute to treatments for diseases like osteoporosis, a Phase Change Heat Exchanger to test temperature control technology in space, the Heart Cells experiments that will culture heart cells on the station to study how microgravity changes the human heart, new and more efficient three-dimensional solar cells, and new marine vessel tracking hardware known as the Automatic Identification System (AIS) that will aid in locating and identifying commercial ships across the globe.

The ring shaped IDA-2 unit is stowed in the Dragon’s unpressurized truck section. It weighs 1029 lbs (467 kg), measures about 42 inches tall and sports an inside diameter of 63 inches in diameter – so astronauts and cargo can easily float through. The outer diameter measures about 94 inches.

“Outfitted with a host of sensors and systems, the adapter is built so spacecraft systems can automatically perform all the steps of rendezvous and dock with the station without input from the astronauts. Manual backup systems will be in place on the spacecraft to allow the crew to take over steering duties, if needed,” says NASA.

View of International Docking Adapter 2 (IDA-2) being processed inside the Space Station Processing Facility (SSPF) at NASA Kennedy Space Center for eventual launch to the ISS in the trunk of a SpaceX Dragon on the CRS-9 mission. It will be connected to the station to provide a port for Commercial Crew spacecraft carrying astronauts to dock to the orbiting laboratory as soon as 2017.  The identical IDA-1 was destroyed during SpaceX CRS-7 launch failure on June 28, 2015.  Credit: Ken Kremer/kenkremer.com
View of International Docking Adapter 2 (IDA-2) being processed inside the Space Station Processing Facility (SSPF) at NASA Kennedy Space Center for eventual launch to the ISS in the trunk of a SpaceX Dragon on the CRS-9 mission. It will be connected to the station to provide a port for Commercial Crew spacecraft carrying astronauts to dock to the orbiting laboratory as soon as 2017. The identical IDA-1 was destroyed during SpaceX CRS-7 launch failure on June 28, 2015. Credit: Ken Kremer/kenkremer.com

“It’s a passive system which means it doesn’t take any action by the crew to allow docking to happen and I think that’s really the key,” said David Clemen Boeing’s director of Development/Modifications for the space station.

“Spacecraft flying to the station will use the sensors on the IDA to track to and help the spacecraft’s navigation system steer the spacecraft to a safe docking without astronaut involvement.”

CRS-9 counts as the company’s ninth scheduled flight to deliver supplies, science experiments and technology demonstrations to the International Space Station (ISS).

The CRS-9 mission is for the crews of Expeditions 48 and 49 to support dozens of the approximately 250 science and research investigations in progress under NASA’s Commercial Resupply Services (CRS) contract.

Up close view of SpaceX Dragon CRS-9 resupply ship and solar panels atop Falcon 9 rocket at pad 40 prior to blastoff to ISS on July 18, 2016 from Cape Canaveral Air Force Station, Florida.   Credit: Ken Kremer/kenkremer.com
Up close view of SpaceX Dragon CRS-9 resupply ship and solar panels atop Falcon 9 rocket at pad 40 prior to blastoff to ISS on July 18, 2016 from Cape Canaveral Air Force Station, Florida. Credit: Ken Kremer/kenkremer.com

Dragon will remain at the station until its scheduled departure on Aug. 29 when it will return critical science research back to Earth via a parachute assisted splashdown in the Pacific Ocean off the California coast.

Watch for Ken’s continuing CRS-9 mission coverage where he reported onsite direct from the Kennedy Space Center and Cape Canaveral Air Force Station, Florida.

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

SpaceX Nails Mesmerizing Midnight Launch and Land Landing of Falcon 9 Carrying Critical ISS Science and Docking Port

A team of engineers from the University of Glasgow and the Ukraine have created an engine that could cut costs by "eating itself". Credit: Ken Kremer/kenkremer.com
SpaceX Falcon 9 launches and lands over Port Canaveral in this streak shot showing  rockets midnight liftoff from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida at 12:45 a.m. EDT carrying Dragon CRS-9 craft to the International Space Station (ISS) with almost 5,000 pounds of cargo and docking port. View from atop Exploration Tower in Port Canaveral. Credit: Ken Kremer/kenkremer.com
SpaceX Falcon 9 launches and lands over Port Canaveral in this streak shot showing rockets midnight liftoff from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida at 12:45 a.m. EDT on July 18, 2016 carrying Dragon CRS-9 craft to the International Space Station (ISS) with almost 5,000 pounds of cargo and docking port. View from atop Exploration Tower in Port Canaveral. Credit: Ken Kremer/kenkremer.com

KENNEDY SPACE CENTER, FL – In a breathtaking feat mesmerizing hordes of thrilled spectators, SpaceX nailed today’s (July 18) back to back post midnight launch and landing of the firms Falcon 9 first stage tasked to carry a cargo Dragon loaded with over two tons of critical science, supplies and a crew docking port to the space station for NASA.

Liftoff of the SpaceX Falcon 9 rocket in its upgraded, full thrust version and the Dragon CRS-9 resupply ship took place right on time at 12:45 a.m. EDT Monday, July 18, from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida.

SpaceX simultaneously successfully delivered over 5000 pounds (2200 kg) of research supplies to orbit for NASA in a commercial cargo Dragon ship, as the primary mission goal – and soft landed the approximately 60,000 pound Falcon 9 first stage on land, as the experimental secondary mission goal.

“The Falcon 9 first stage we landed is in excellent shape,” Hans Koenigsmann, SpaceX vice president of Flight Reliability, told Universe Today at the 2 a.m. EDT post launch and landing media briefing early this morning.

See my launch and landing streak shot and photos herein, including deployment of the four landing legs in the final seconds before propulsive touchdown.

The twin accomplishments will have far reaching implications for the exploration and exploitation of space for all humanity.

“Each commercial resupply flight to the space station is a significant event. Everything, from the science to the spare hardware and crew supplies, is vital for sustaining our mission,” said Kirk Shireman, NASA’s International Space Station Program manager.

“With equipment to enable novel experiments never attempted before in space, and an international docking adapter vital to the future of U.S. commercial crew spacecraft, we’re thrilled this Dragon has successfully taken flight.”

The CRS-9 mission is to support the resident six-person crew of men and women currently working on the station from the US, Russia and Japan.

The propulsive soft landing of the 156 foot tall Falcon 9 first stage of the Falcon 9 rocket on land at Cape Canaveral Air Force Station’s Landing Zone 1, located a few miles south of launch pad 40.

The dramatic ground landing at LZ -1 took place about 9 minutes after liftoff.

Moments before dramatic touchdown of SpaceX Falcon 9 1st stage at Landing Zone-1 (LX-1) accompanied by sonic booms after launching Dragon CRS-9 supply ship to orbit from Cape Canaveral Air Force Station, Florida at 12:45 a.m., bound for the International Space Station (ISS).   Credit: Ken Kremer/kenkremer.com
Moments before dramatic touchdown of SpaceX Falcon 9 1st stage at Landing Zone-1 (LX-1) accompanied by sonic booms after launching Dragon CRS-9 supply ship to orbit from Cape Canaveral Air Force Station, Florida at 12:45 a.m., bound for the International Space Station (ISS). Credit: Ken Kremer/kenkremer.com

The first and second stages separated about two and a half minutes after liftoff and were easily visible to any eyewitness watching – backdropped by the sunshine states dark skies.

As the second stage soared to orbit, the first stage reignited a first stage engine for a series of burns targeting a return to the Cape.

We spotted the first engine firing about two mintues before landing, as it descended directly overhead of myself and everyone in the Cape Canaveral region.

For a few moments it looked like it was headed right towards us, but then steered away as planned with engines blazing to slow the boosters descent to make a gentle landing at LZ-1.

Finally the Falcon landed, obscured by a big vapor cloud and sonic booms roaring around the space coast – and waking many local residents. Several folks told me they were suddenly woken by the shocking booms reverberating inside their homes.

Some area residents even called 911 not knowing the true nature of the noises.

Streak shot of launch and landing of SpaceX Falcon CRS-9 mission from Cape Canaveral Air Force Station, Florida to the ISS on July 18, 2016 at 12:45 a.m. EDT. View from Satellite Beach, FL.  Credit: John Krauss/johnkraussphotos.com
Streak shot of launch and landing of SpaceX Falcon CRS-9 mission from Cape Canaveral Air Force Station, Florida to the ISS on July 18, 2016 at 12:45 a.m. EDT. View from Satellite Beach, FL. Credit: John Krauss/johnkraussphotos.com

Among the wealth of over 3900 pounds (1790 kg) of research investigations loaded on board Dragon is an off the shelf instrument designed to perform the first-ever DNA sequencing in space, and the first international docking adapter (IDA) that is absolutely essential for docking of the SpaceX and Boeing built human spaceflight taxis that will ferry our astronauts to the International Space Station (ISS) in some 18 months.

Blastoff of SpaceX Falcon 9 on Dragon CRS-9 resupply mission to the  International Space Station (ISS) at 12:45 a.m. EDT on July 18, 2016.   Credit: Ken Kremer/kenkremer.com
Blastoff of SpaceX Falcon 9 on Dragon CRS-9 resupply mission to the International Space Station (ISS) at 12:45 a.m. EDT on July 18, 2016. Credit: Ken Kremer/kenkremer.com

CRS-9 counts as the company’s ninth scheduled flight to deliver supplies, science experiments and technology demonstrations to the International Space Station (ISS).

The CRS-9 mission is for the crews of Expeditions 48 and 49 to support dozens of the approximately 250 science and research investigations in progress under NASA’s Commercial Resupply Services (CRS) contract.

Dragon reached its preliminary orbit about 10 minutes after launch. Then it deployed a pair of solar arrays and began a carefully choreographed series of thruster firings to reach the space station.

If all goes well, Dragon is scheduled to arrive at the orbiting outpost on Wednesday, July 20, after a 2 day orbital chase.

NASA astronaut Jeff Williams will then reach out with the station’s 57.7-foot-long Canadian-built robotic arm to grapple and capture the private Dragon cargo ship working from a robotics work station in the station’s cupola. NASA astronaut Kate Rubins will serve as Williams backup. She just arrived at the station last week on July 9 for a minimum 4 month stay, after launching to orbit on a Russian Soyuz on July 6 with two additional crew mates.

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. The crew expects to open the hatch a day later after pressurizing the vestibule in the forward bulkhead between the station and Dragon.

Live coverage of the rendezvous and capture July 20 will begin at 5:30 a.m. on NASA TV, with installation coverage set to begin at 9:45 a.m.

CRS-9 marks only the second time SpaceX has attempted a land landing of the 15 story tall first stage booster.

The history making first time successfully took place at Landing Zone 1 (LZ 1) on Dec. 22, 2015 as part of the ORBCOMM-2 mission. Landing Zone 1 is built on the former site of Space Launch Complex 13, a U.S. Air Force rocket and missile testing range.

SpaceX also successfully recovered first stages three times in a row at sea this year on an ocean going drone ship barge using the company’s OCISLY Autonomous Spaceport Drone Ship (ASDS) on April 8, May 6 and May 27.

Altogether SpaceX has successfully landed and recovered 5 first stage booster intact and upright.

The International Docking Adapter-2 was tested in the Space Station Processing Facility prior to being loaded for launch into space on the SpaceX CRS-9 mission set for July 18, 2016 from Cape Canaveral, Fl.  Credits: NASA
The International Docking Adapter-2 was tested in the Space Station Processing Facility prior to being loaded for launch into space on the SpaceX CRS-9 mission [set for July 18, 2016 from Cape Canaveral, Fl. Credits: NASA

Watch for Ken’s onsite CRS-9 mission reports direct from the Kennedy Space Center and Cape Canaveral Air Force Station, Florida.

Here’s my launch pad video of the blastoff:

Video caption: SpaceX Falcon 9 lifts off with Dragon CRS-9 resupply ship bound for the International Space Station on July 18, 2016 at 12:45 a.m. EDT from Space Launch Complex 40 at Cape Canaveral Air Force Station, Fl, as seen in this up close video from Mobius remote camera positioned at the pad. Credit: Ken Kremer/kenkremer.com

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

………….

Learn more about Juno at Jupiter, SpaceX CRS-9 rocket launch, ISS, ULA Atlas and Delta rockets, Orbital ATK Cygnus, Boeing, Space Taxis, Mars rovers, Orion, SLS, Antares, NASA missions and more at Ken’s upcoming outreach events:

July 18, 26-28: “SpaceX launches to ISS on CRS-9, Juno at Jupiter, ULA Delta 4 Heavy and Atlas V spy satellite launches, SLS, Orion, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, evenings

An illustration of how the IDA will look when attached to the International Space Station. Credits: NASA
An illustration of how the IDA will look when attached to the International Space Station.
Credits: NASA
Up close view of SpaceX Dragon CRS-9 resupply ship and solar panels atop Falcon 9 rocket at pad 40 prior to blastoff to the ISS on July 18, 2016 from Cape Canaveral Air Force Station, Florida.   Credit: Ken Kremer/kenkremer.com
Up close view of SpaceX Dragon CRS-9 resupply ship and solar panels atop Falcon 9 rocket at pad 40 prior to blastoff to the ISS on July 18, 2016 from Cape Canaveral Air Force Station, Florida. Credit: Ken Kremer/kenkremer.com

SpaceX Midnight Launch Carrying Crucial Docking Port and Science to ISS Set for July 18, Plus Loud Land Landing – Watch Live

SpaceX conducts Falcon 9 Dragon CRS-9 mission static fire test ahead of planned 18 July 2016 liftoff from Cape Canaveral Air Force Station in Florida at 12:45 a.m. EDT. View from atop Launch Complex 39B at the Kennedy Space Center. Credit: Ken Kremer/kenkremer.com
SpaceX conducts Falcon 9 Dragon CRS-9 mission static fire test ahead of planned 18 July 2016 liftoff from Cape Canaveral Air Force Station in Florida on 18 July 2016 at 12:45 a.m. EDT.  Credit: Ken Kremer/kenkremer.com
SpaceX conducts Falcon 9 Dragon CRS-9 mission static fire test ahead of planned 18 July 2016 liftoff from Cape Canaveral Air Force Station in Florida at 12:45 a.m. EDT. View from atop Launch Complex 39B at the Kennedy Space Center. Credit: Ken Kremer/kenkremer.com

KENNEDY SPACE CENTER, FL – The outlook is outstanding for a dramatic midnight blastoff of the next SpaceX commercial cargo Dragon jam packed with some 5000 pounds of critical payloads and research supplies for NASA and heading to the space station on Monday, July 18 – that also simultaneously features an experimental land landing that promises to rock loudly across the Florida space coast and one day slash launch costs.

Dragon is carrying a crucial crew docking port absolutely essential for conducting future human space missions to the orbiting outpost as well as a host of wide ranging science experiments essential for NASA exploiting the space environment for research in low earth orbit and deep space exploration.

Liftoff of the SpaceX Falcon 9 rocket in its upgraded, full thrust version and the Dragon CRS-9 resupply ship is targeted for 12:45 a.m. EDT Monday, July 18, from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida.

The International Docking Adapter-2 was tested in the Space Station Processing Facility prior to being loaded for launch into space on the SpaceX CRS-9 mission set for July 18, 2016 from Cape Canaveral, Fl.  Credits: NASA
The International Docking Adapter-2 was tested in the Space Station Processing Facility prior to being loaded for launch into space on the SpaceX CRS-9 mission set for July 18, 2016 from Cape Canaveral, Fl. Credits: NASA

The CRS-9 mission is to support the resident six-person crew of men and women currently working on the station from the US, Russia and Japan.

Spectators are filling local area hotels in anticipation of a spectacular double whammy sky show comprising a thunderous nighttime launch streaking to orbit – followed minutes later by a brilliant rocket flash and night landing back at the Cape of the Falcon first stage that will send sonic booms roaring all around the coast and surrounding inland areas.

SpaceX has confirmed they are attempting the secondary mission of landing the 156 foot tall first stage of the Falcon 9 rocket on land at Cape Canaveral Air Force Station’s Landing Zone 1, located a few miles south of launch pad 40.

The weather and technical outlook for the 229 foot-tall (70 meter) Falcon 9 looks fantastic at this time, a day before liftoff.

The official weather forecast from Air Force meteorologists with the 45th Space Wing calls for a 90 percent chance of “GO” with extremely favorable conditions at launch time for liftoff of this upgraded, SpaceX Falcon 9.

The only concerns are for Cumulus clouds building up and a chance of precipitation.

And for added stargazers delight the night sky features a full moon.

The SpaceX/Dragon CRS-9 launch coverage will be broadcast on NASA TV beginning at 11:30 p.m. EDT Sunday, July 17, with additional commentary on the NASA launch blog.

SpaceX will also feature their own live webcast beginning approximately 20 minutes before launch at 12:25 a.m. EDT Monday, July 18

You can watch the launch live at NASA TV at – http://www.nasa.gov/nasatv

You can watch the launch live at SpaceX Webcast at – spacex.com/webcast

The launch window is instantaneous, meaning that any delays due to weather or technical issues will results in a minimum 2 day postponement.

If the launch does not occur Monday, a backup launch opportunity exists on 12 a.m. Wednesday, July 20, just seconds after midnight, with NASA TV coverage starting at 10:45 p.m. EDT Tuesday, July 19.

View of International Docking Adapter 2 (IDA-2) being processed inside the Space Station Processing Facility (SSPF) at NASA Kennedy Space Center for eventual launch to the ISS in the trunk of a SpaceX Dragon on the CRS-9 mission. It will be connected to the station to provide a port for Commercial Crew spacecraft carrying astronauts to dock to the orbiting laboratory as soon as 2017.  The identical IDA-1 was destroyed during SpaceX CRS-7 launch failure on June 28, 2015.  Credit: Ken Kremer/kenkremer.com
View of International Docking Adapter 2 (IDA-2) being processed inside the Space Station Processing Facility (SSPF) at NASA Kennedy Space Center for eventual launch to the ISS in the trunk of a SpaceX Dragon on the CRS-9 mission. It will be connected to the station to provide a port for Commercial Crew spacecraft carrying astronauts to dock to the orbiting laboratory as soon as 2017. The identical IDA-1 was destroyed during SpaceX CRS-7 launch failure on June 28, 2015. Credit: Ken Kremer/kenkremer.com

CRS-9 marks only the second time SpaceX has attempted a land landing of the 15 story tall first stage booster.

The history making first time took place at Landing Zone 1 (LZ 1) on Dec. 22, 2015 as part of the ORBCOMM-2 mission. Landing Zone 1 is built on the former site of Space Launch Complex 13, a U.S. Air Force rocket and missile testing range.

SpaceX also successfully recovered first stages three times in a row at sea this year on an ocean going drone ship barge using the company’s OCISLY Autonomous Spaceport Drone Ship (ASDS) on April 8, May 6 and May 27.

SpaceX issued a statement describing how local area residents could hear sonic booms – similar to those heard during landings of NASA’s space shuttles.

“There is the possibility that residents of northern and central Brevard County, Fla. may hear one or more sonic booms during landing. A sonic boom is a brief thunder-like noise a person on the ground hears when an aircraft or other vehicle flies overhead faster than the speed of sound,” said SpaceX.

Who could be affected?

“Residents of the communities of Cape Canaveral, Cocoa, Cocoa Beach, Courtenay, Merritt Island, Mims, Port Canaveral, Port St. John, Rockledge, Scottsmoor, Sharpes, and Titusville in Brevard County, Fla. are most likely to hear a sonic boom, although what residents experience will depend on weather conditions and other factors.”

The sights and sound are certain to be thrilling- so catch it if you can!

CRS-9 counts as the company’s ninth scheduled flight to deliver supplies, science experiments and technology demonstrations to the International Space Station (ISS).

The CRS-9 mission is for the crews of Expeditions 48 and 49 to support dozens of the approximately 250 science and research investigations in progress under NASA’s Commercial Resupply Services (CRS) contract.

SpaceX engineers conducted their standard static fire hold down test of the first stages Merlin 1D engines with the rocket erect at pad 40, this morning Saturday, July 16.

The customary test lasts a few seconds and was conducted with the Dragon bolted on top at about 9:30 a.m. I saw the test while visiting atop neighboring Launch Complex 39B at the Kennedy Space Center – see photo.

“All looks good,” reported Hans Koenigsmann, SpaceX vice president of Flight Reliability, at a media briefing this afternoon.

“We expect a GO for launch.”

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.

If all goes well, Dragon will arrive at the orbiting outpost on Wednesday, July 20, after a 2 day orbital chase.

NASA astronaut Jeff Williams will then reach out with the station’s 57.7-foot-long Canadian-built robotic arm to grapple and capture the private Dragon cargo ship working from a robotics work station in the station’s cupola. NASA astronaut Kate Rubins will serve as Williams backup. She just arrived at the station last week on July 9 for a minimum 4 month stay, after launching to orbit on a Russian Soyuz on July 6 with two additional crew mates.

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. The crew expects to open the hatch a day later after pressurizing the vestibule in the forward bulkhead between the station and Dragon.

Live coverage of the rendezvous and capture July 20 will begin at 5:30 a.m. on NASA TV, with installation coverage set to begin at 9:45 a.m.

An illustration of how the IDA will look when attached to the International Space Station. Credits: NASA
An illustration of how the IDA will look when attached to the International Space Station.
Credits: NASA

Perhaps the most critical payload relating to the future of humans in space is the 1,020-pound international docking adapter known as IDA-2 or International Docking Adapter-2.

Here’s an early morning video view of Falcon 9 on the pad today.

Video Caption: Early morning shots of CRS-9 ready for flight on Monday July 18 at 12:45 AM. Credit: USLaunchReport

Watch for Ken’s onsite CRS-9 mission reports direct from the Kennedy Space Center and Cape Canaveral Air Force Station, Florida.

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

………….

Learn more about Juno at Jupiter, SpaceX CRS-9 rocket launch, ISS, ULA Atlas and Delta rockets, Orbital ATK Cygnus, Boeing, Space Taxis, Mars rovers, Orion, SLS, Antares, NASA missions and more at Ken’s upcoming outreach events:

July 15-18: “SpaceX launches to ISS on CRS-9, Juno at Jupiter, ULA Delta 4 Heavy spy satellite, SLS, Orion, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, evenings

Former astronaut Bob Cabana, director of NASA's Kennedy Space Center in Florida, surveys the IDA-2 inside the Space Station Processing Facility.  Credits: NASA
Former astronaut Bob Cabana, director of NASA’s Kennedy Space Center in Florida, surveys the IDA-2 inside the Space Station Processing Facility. Credits: NASA
SpaceX Dragon CRS-9 mission logo. Credit: SpaceX
SpaceX Dragon CRS-9 mission logo. Credit: SpaceX

Juno Transmits 1st Orbital Imagery after Swooping Arrival Over Jovian Cloud Tops and Powering Up

This color view from NASA's Juno spacecraft is made from some of the first images taken by JunoCam after the spacecraft entered orbit around Jupiter on July 4, 2016. Credits: NASA/JPL-Caltech/SwRI/MSSS
This color view from NASA's Juno spacecraft is made from some of the first images taken by JunoCam after the spacecraft entered orbit around Jupiter on July 4, 2016.  Credits: NASA/JPL-Caltech/SwRI/MSSS
This color view from NASA’s Juno spacecraft is made from some of the first images taken by JunoCam after the spacecraft entered orbit around Jupiter on July 4, 2016. Credits: NASA/JPL-Caltech/SwRI/MSSS

NASA’s newly arrived Jovian orbiter Juno has transmitted its first imagery since reaching orbit last week on July 4 after swooping over Jupiter’s cloud tops and powering back up its package of state-of-the-art science instruments for unprecedented research into determining the origin of our solar systems biggest planet.

The breathtaking image clearly shows the well known banded cloud tops in Jupiter’s atmosphere as well as the famous Great Red Spot and three of the humongous planet’s four largest moons — Io, Europa and Ganymede.

The ‘Galilean’ moons are annotated from left to right in the lead image.

Juno’s visible-light camera named JunoCam was turned on six days after Juno fired its main engine to slow down and be captured into orbit around Jupiter – the ‘King of the Planets’ following a nearly five year long interplanetary voyage from Earth.

The image was taken when Juno was 2.7 million miles (4.3 million kilometers) distant from Jupiter on July 10, at 10:30 a.m. PDT (1:30 p.m. EDT, 5:30 UTC), and traveling on the outbound leg of its initial 53.5-day capture orbit.

Juno came within only about 3000 miles of the cloud tops and passed through Jupiter’s extremely intense and hazardous radiation belts during orbital arrival over the north pole.

Illustration of NASA's Juno spacecraft firing its main engine to slow down and go into orbit around Jupiter. Lockheed Martin built the Juno spacecraft for NASA's Jet Propulsion Laboratory.  Credit: NASA/Lockheed Martin
Illustration of NASA’s Juno spacecraft firing its main engine to slow down and go into orbit around Jupiter. Lockheed Martin built the Juno spacecraft for NASA’s Jet Propulsion Laboratory. Credit: NASA/Lockheed Martin

The newly released JunoCam image is visible proof that Juno survived the do-or-die orbital fireworks on America’s Independence Day that placed the baskeball-court sized probe into orbit around Jupiter – and is in excellent health to carry out its groundbreaking mission to elucidate Jupiter’s ‘Genesis.’

“This scene from JunoCam indicates it survived its first pass through Jupiter’s extreme radiation environment without any degradation and is ready to take on Jupiter,” said Scott Bolton, principal investigator from the Southwest Research Institute in San Antonio, in a statement.

“We can’t wait to see the first view of Jupiter’s poles.”

Within two days of the nerve wracking and fully automated 35-minute-long Jupiter Orbital Insertion (JOI) maneuver, the Juno engineering team begun powering up five of the probes science instruments on July 6.

Animation of Juno 14-day orbits starting in late 2016.  Credits: NASA/JPL-Caltech
Animation of Juno 14-day orbits starting in late 2016. Credits: NASA/JPL-Caltech

All nonessential instruments and systems had been powered down in the final days of Juno’s approach to Jupiter to ensure the maximum chances for success of the critical JOI engine firing.

“We had to turn all our beautiful instruments off to help ensure a successful Jupiter orbit insertion on July 4,” said Bolton.

“But next time around we will have our eyes and ears open. You can expect us to release some information about our findings around September 1.”

Juno resumed high data rate communications with Earth on July 5, the day after achieving orbit.

We can expect to see more JunoCam images taken during this first orbital path around the massive planet.

But the first high resolution images are still weeks away and will not be available until late August on the inbound leg when the spacecraft returns and swoops barely above the clouds.

“JunoCam will continue to take images as we go around in this first orbit,” said Candy Hansen, Juno co-investigator from the Planetary Science Institute, Tucson, Arizona, in a statement.

“The first high-resolution images of the planet will be taken on August 27 when Juno makes its next close pass to Jupiter.”

All of JunoCams images will be released to the public.

During a 20 month long science mission – entailing 37 orbits lasting 14 days each – the probe will plunge to within about 2,600 miles (4,100 kilometers) of the turbulent cloud tops.

It will collect unparalleled new data that will unveil the hidden inner secrets of Jupiter’s origin and evolution as it peers “beneath the obscuring cloud cover of Jupiter and study its auroras to learn more about the planet’s origins, structure, atmosphere and magnetosphere.”

The solar powered Juno spacecraft approached Jupiter over its north pole, affording an unprecedented perspective on the Jovian system – “which looks like a mini solar system” – as it flew through the giant planets intense radiation belts in ‘autopilot’ mode.

Juno is the first solar powered probe to explore Jupiter or any outer planet.

In the final weeks of the approach JunoCam captured dramatic views of Jupiter and all four of the Galilean Moons moons — Io, Europa, Ganymede and Callisto.

At the post JOI briefing on July 5, these were combined into a spectacular JunoCam time-lapse movie released by Bolton and NASA.

Watch and be mesmerized -“for humanity, our first real glimpse of celestial harmonic motion” says Bolton.

Video caption: NASA’s Juno spacecraft captured a unique time-lapse movie of the Galilean satellites in motion about Jupiter. The movie begins on June 12th with Juno 10 million miles from Jupiter, and ends on June 29th, 3 million miles distant. The innermost moon is volcanic Io; next in line is the ice-crusted ocean world Europa, followed by massive Ganymede, and finally, heavily cratered Callisto. Galileo observed these moons to change position with respect to Jupiter over the course of a few nights. From this observation he realized that the moons were orbiting mighty Jupiter, a truth that forever changed humanity’s understanding of our place in the cosmos. Earth was not the center of the Universe. For the first time in history, we look upon these moons as they orbit Jupiter and share in Galileo’s revelation. This is the motion of nature’s harmony. Credits: NASA/JPL-Caltech/MSSS

The $1.1 Billion Juno was launched on Aug. 5, 2011 from Cape Canaveral, Florida atop the most powerful version of the Atlas V rocket augmented by 5 solid rocket boosters and built by United Launch Alliance (ULA). That same Atlas V 551 version just launched MUOS-5 for the US Navy on June 24.

The Juno spacecraft was built by prime contractor Lockheed Martin in Denver.

The mission will end in February 2018 with an intentional death dive into the atmosphere to prevent any possibility of a collision with Europa, one of Jupiter’s moons that is a potential abode for life.

The last NASA spacecraft to orbit Jupiter was Galileo in 1995. It explored the Jovian system until 2003.

From Earth’s perspective, Jupiter was in conjunction with Earth’s Moon shortly after JOI during the first week in July.

Personally its thrilling to realize that an emissary from Earth is once again orbiting Jupiter after a 13 year long hiatus as seen in the authors image below – coincidentally taken the same day as JunoCam’s first image from orbit.

Juno, Jupiter and the Moon as seen from I-95 over Dunn, NC on July 10, 2016. Credit: Ken Kremer/kenkremer.com
Juno, Jupiter and the Moon as seen from I-95 over Dunn, NC on July 10, 2016. Credit: Ken Kremer/kenkremer.com

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

………….

Learn more about Juno at Jupiter, SpaceX CRS-9 rocket launch, ISS, ULA Atlas and Delta rockets, Orbital ATK Cygnus, Boeing, Space Taxis, Mars rovers, Orion, SLS, Antares, NASA missions and more at Ken’s upcoming outreach events:

July 15-18: “SpaceX launches to ISS on CRS-9, Juno at Jupiter, ULA Delta 4 Heavy spy satellite, SLS, Orion, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, evenings

NASA's Juno probe captured the image data for this composite picture during its Earth flyby on Oct. 9 over Argentina,  South America and the southern Atlantic Ocean. Raw imagery was reconstructed and aligned by Ken Kremer and Marco Di Lorenzo, and false-color blue has been added to the view taken by a near-infrared filter that is typically used to detect methane. Credit: NASA/JPL/SwRI/MSSS/Ken Kremer/Marco Di Lorenzo
NASA’s Juno probe captured the image data for this composite picture during its Earth flyby on Oct. 9 over Argentina, South America and the southern Atlantic Ocean. Raw imagery was reconstructed and aligned by Ken Kremer and Marco Di Lorenzo, and false-color blue has been added to the view taken by a near-infrared filter that is typically used to detect methane. Credit: NASA/JPL/SwRI/MSSS/Ken Kremer/Marco Di Lorenzo

Flawless Shakedown Mission from Modified Soyuz Delivers Multinational Crew to Space Station

Three newly arrived crew of Expedition 48 in Soyuz MS-01 open the hatch and enter the International Space Station after docking on July 9, 2016. Credit: NASA TV
Three newly arrived crew of Expedition 48 in Soyuz MS-01 open the hatch and enter the International Space Station after docking on July 9, 2016.  Credit: NASA TV
Three newly arrived crew of Expedition 48 in Soyuz MS-01 open the hatch and enter the International Space Station after docking on July 9, 2016. Credit: NASA TV

A flawless shakedown mission from Russia’s newly modified Soyuz capsule successfully delivered a new multinational crew to the Space Station early Saturday, July 9 after a two day orbital chase.

The upgraded Soyuz MS-01 spacecraft launching on its maiden flight successfully docked to the International Space Station at 12:06 a.m. EDT Saturday, July 9, while soaring 254 statute miles over the South Pacific.

“Docking confirmed,” said a commentator from Russian mission control at Korolev outside Moscow. “Contact and capture complete.”

The Soyuz was ferrying the new multinational trio of astronauts and cosmonauts comprising Kate Rubins of NASA, Soyuz Commander Anatoly Ivanishin of the Russian space agency Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency on the Expedition 48/49 mission.

The three person crew of two men and one woman had launched flawlessly into picture perfect skies two days earlier from the Baikonur Cosmodrome in Kazakhstan at 9:36 p.m. EDT Wednesday, July 6 (7:36 a.m. Baikonur time, July 7), in the brand new version of the Russian Soyuz capsule that has been significantly upgraded and modified.

NASA’s Kate Rubins was strapped into the right seat, Ivanishin in the center and Onishi on the left.

The Soyuz MS-01 spacecraft, carrying three Expedition 48-49 crew members, launches from the Baikonur Cosmodrome in Kazakhstan at 9:36 p.m. EDT Wednesday, July 6, 2016 (7:36 a.m. Baikonur time, July 7).  Credits: NASA/Bill Ingalls
The Soyuz MS-01 spacecraft, carrying three Expedition 48-49 crew members, launches from the Baikonur Cosmodrome in Kazakhstan at 9:36 p.m. EDT Wednesday, July 6, 2016 (7:36 a.m. Baikonur time, July 7). Credits: NASA/Bill Ingalls

It was a textbook approach on the shakedown mission that culminated in a flawless docking at the Earth-facing Russian Rassvet module on the Russian side of the massive orbiting outpost.

NASA TV carried the whole operation live with beautiful color video imagery streaming from the ISS showing the Soyuz approach and black and white video streaming from the Soyuz.

The Soyuz MS-01 spacecraft is viewed from the International Space Station as it approaches the Rassvet module docking port. Credit: NASA TV
The Soyuz MS-01 spacecraft is viewed from the International Space Station as it approaches the Rassvet module docking port. Credit: NASA TV

The Soyuz performed magnificently. All of the upgraded and modified systems checked out perfectly on this maiden flight of the new version of Russias venerable Soyuz, said NASA commentator Rob Navias.

“All new systems functioning perfectly,” said Navias. “This has been a perfect shakedown mission for the new Soyuz crew docking at the ISS.”

The Soyuz had slowed to an approach velocity of just 0.1 m/s at docking with the forward docking probe extended.

The approach was fully automated under Russian mission control as Ivanishin carefully monitored all spacecraft systems with steady update calls back to ground control.

The fully automated approached utilized the upgraded KURS NA automated rendezvous radar system.

During final approach, the Soyuz conducted a fly around maneuver starting at a distance of 400 meters. It moved 57 degress around the station while closing in to about 250 meters.

After station keeping for about 2 minutes while ground controllers conducted a final evaluation and no issues were detected, Russian mission control at last gave the GO for final approach and the GO command for docking was given.

The Soyuz made contact and completed a perfect docking at Rassvet. The hook and latches were then closed in for a tight grasp onto the station.

The crews then conducted a series of leak and pressurization checks.

After everything checked out, the hatches were finally opened about two and a half hours later at 2:26 a.m. EDT.

The new crew members of Expedition 48 officially floated aboard the International Space Station at about 2:50 a.m. EDT, July 9 with the hatches opened between their Soyuz MS-01 and the space station and after a live video transmission link had been established to show the festivities.

The new six-member Expedition 48 crew join each other for well wishes and congratulations from family, friends and mission officials. In front, from left, are the new crew members Kate Rubins, Anatoly Ivanishin and Takuya Onishi. In the back row are Flight Engineers Oleg Skripochka and Alexey Ovchinin and Commander Jeff Williams. Credit: NASA TV
The new six-member Expedition 48 crew join each other for well wishes and congratulations from family, friends and mission officials. In front, from left, are the new crew members Kate Rubins, Anatoly Ivanishin and Takuya Onishi. In the back row are Flight Engineers Oleg Skripochka and Alexey Ovchinin and Commander Jeff Williams. Credit: NASA TV

They were welcomed aboard with hugs and joined the Expedition 48 Commander Jeff Williams of NASA and Flight Engineers Oleg Skripochka and Alexey Ovchinin of Roscosmos.

With the arrival of Rubins, Ivanishin and Onishi, the stations resident crew is beefed up to its normal six person crew complement.

They soon held the traditional video telecon for well wishes and congratulations from family, friends and mission officials.

The new trio will spend at least four months at the orbiting lab complex conducting more than 250 science investigations in fields such as biology, Earth science, human research, physical sciences, and technology development.

Rubins is on her rookie space mission. She holds a bachelor’s degree in molecular biology and a doctorate in cancer biology which will be a big focus of her space station research activities.

The new trio will join Expedition 48 Commander Jeff Williams of NASA and Flight Engineers Oleg Skripochka and Alexey Ovchinin of Roscosmos.

“The approximately 250 research investigations and technology demonstrations – not possible on Earth – will advance scientific knowledge of Earth, space, physical, and biological sciences. Science conducted on the space station continues to yield benefits for humanity and will enable future long-duration human and robotic exploration into deep space, including the agency’s Journey to Mars,” says NASA.
The newly upgraded Soyuz offers increased reliability and enhanced performance.

Many changes were instituted including enhanced structural performance to minimize chances of micrometeoroid penetration. Engineers also added a fifth battery for more power and storage capacity. The solar arrays are also about one square meter larger and the efficiency of the solar cells increased about 2 percent.

Also a more modern command and telemetry system to interact with a new series of new Russian communications satellites that will offer greatly increased the coverage by ground control. This was previously only about 20 minutes per orbit while over Russian ground stations and will now increase up to 45 to 90% of orbital coverage via the Russian comsat system.

A phased array antenna was also added with increased UHF radio capability in the Soyuz descent module that now also include a GPS system to improve search and rescue possibilities.

The newly upgraded KURS rendezvous radar system will weigh less, use less power and overall will be less complicated. For example it doesn’t have to be moved out of the way before docking. Weighs less and uses less power.

New approach and attitude control thrusters were installed. The new configuration uses 28 thrusters with a redundant thruster for each one – thus two fully redundant manifolds of 28 thrusters each.
All of these modification were tested out on the last two progress vehicles.

Multiple unmanned cargo ships carrying tons of essential supplies and science experiments are also scheduled to arrive from Russia, the US and Japan over the next few months.

A SpaceX Dragon is scheduled to launch as soon as July 18 and an Orbital ATK Cygnus should follow in August.
The SpaceX Dragon CRS-9 mission is slated to deliver the station’s first International docking adapter (IDA) to accommodate the future arrival of U.S. commercial crew spacecraft, including the Boeing built Starliner and SpaceX built Crew Dragon.

A Japanese HTV cargo craft will carry lithium ion batteries to replace the nickel-hydrogen batteries currently used on station to store electrical energy generated by the station’s huge rotating solar arrays.

Two Russian Progress craft with many tons of supplies are also scheduled to arrive.

The Soyuz MS-01 spacecraft launches from the Baikonur Cosmodrome with Expedition 48-49 crewmembers Kate Rubins of NASA, Anatoly Ivanishin of Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) onboard, Thursday, July 7, 2016 , Kazakh time (July 6 Eastern time), Baikonur, Kazakhstan.  Photo Credit: NASA/Bill Ingalls
The Soyuz MS-01 spacecraft launches from the Baikonur Cosmodrome with Expedition 48-49 crewmembers Kate Rubins of NASA, Anatoly Ivanishin of Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) onboard, Thursday, July 7, 2016 , Kazakh time (July 6 Eastern time), Baikonur, Kazakhstan. Photo Credit: NASA/Bill Ingalls

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer

International Trio from US, Russia and Japan Launches to Space Station on Newly Upgraded Soyuz

The Soyuz MS-01 spacecraft launches from the Baikonur Cosmodrome with Expedition 48-49 crewmembers Kate Rubins of NASA, Anatoly Ivanishin of Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) onboard, Thursday, July 7, 2016 , Kazakh time (July 6 Eastern time), Baikonur, Kazakhstan. Photo Credit: NASA/Bill Ingalls
The Soyuz MS-01 spacecraft launches from the Baikonur Cosmodrome with Expedition 48-49 crewmembers Kate Rubins of NASA, Anatoly Ivanishin of Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) onboard, Thursday, July 7, 2016 , Kazakh time (July 6 Eastern time), Baikonur, Kazakhstan. Rubins, Ivanishin, and Onishi will spend approximately four months on the orbital complex, returning to Earth in October. Photo Credit: NASA/Bill Ingalls
The Soyuz MS-01 spacecraft launches from the Baikonur Cosmodrome with Expedition 48-49 crewmembers Kate Rubins of NASA, Anatoly Ivanishin of Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) onboard, Thursday, July 7, 2016 , Kazakh time (July 6 Eastern time), Baikonur, Kazakhstan. Photo Credit: NASA/Bill Ingalls

An international trio of astronauts and cosmonauts representing the United States, Russia and Japan blasted off in the early morning Kazakh hours today, July 7, for a new mission of science and discovery on the International Space Station (ISS).

The three person crew of two men and one woman launched flawlessly into picture perfect skies from the Baikonur Cosmodrome in Kazakhstan at 9:36 p.m. EDT Wednesday, July 6 (7:36 a.m. Baikonur time, July 7), and in a brand new version of the Russian Soyuz capsule that has been significantly upgraded and modified.

The launch of the Soyuz MS-01 spacecraft was carried live on NASA TV starting approximately an hour before the usual on time liftoff from Baikonur. The three stage Soyuz booster generates 930,000 pounds of liftoff thrust.

The trio comprises Kate Rubins of NASA, Soyuz Commander Anatoly Ivanishin of the Russian space agency Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency on the Expedition 48/49 mission.

They safely reached orbit at about 9:46 p.m. after the eight minute climb delivered them to the preliminary orbit of 143 x 118 mi. The Soyuz separated from the third stage and the solar arrays deployed as planned. NASA’s Kate Rubins was strapped into the left seat, Ivanishin in the center and Onishi on the right.

And precisely because it’s a heavily modified Soyuz, they will take the slow road to the ISS.

The crew will spend the next two days and 34 Earth orbits inside in order to fully check out and test the upgraded Soyuz spacecraft systems.

That’s in contrast to missions in recent years that took a vastly sped up 4 orbit 6 hour route to the space station.

International Space Station Expedition 48/49 astronaut Kate Rubins of NASA, Russian cosmonaut Anatoly Ivanishin and Japan Aerospace Exploration Agency (JAXA) astronaut Takuya Onishi.  Credits: NASA
International Space Station Expedition 48/49 astronaut Kate Rubins of NASA, Russian cosmonaut Anatoly Ivanishin and Japan Aerospace Exploration Agency (JAXA) astronaut Takuya Onishi. Credits: NASA

Three carefully choreographed orbital adjustment burns will raise the orbit and propel the crew to the ISS over the next 2 days.

They expect to rendezvous and dock at the space station’s Russian Rassvet module at 12:12 a.m. EDT Saturday, July 9. After conducting leak and safety check they expect to open the hatch to the ISS at about 2:50 a.m. Saturday, July 9.
You can watch all the hatch opening action live on NASA TV with coverage starting at 2:30 a.m.

They will spend about four months at the orbiting lab complex conducting more than 250 science investigations in fields such as biology, Earth science, human research, physical sciences, and technology development.

The Soyuz MS-01 spacecraft launches from the Baikonur Cosmodrome with Expedition 48-49 crewmembers Kate Rubins of NASA, Anatoly Ivanishin of Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) onboard, Thursday, July 7, 2016 , Kazakh time (July 6 Eastern time), Baikonur, Kazakhstan. Rubins, Ivanishin, and Onishi will spend approximately four months on the orbital complex, returning to Earth in October. Photo Credit: (NASA/Bill Ingalls)
The Soyuz MS-01 spacecraft launches from the Baikonur Cosmodrome with Expedition 48-49 crewmembers Kate Rubins of NASA, Anatoly Ivanishin of Roscosmos and Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) onboard, Thursday, July 7, 2016 , Kazakh time (July 6 Eastern time), Baikonur, Kazakhstan. Rubins, Ivanishin, and Onishi will spend approximately four months on the orbital complex, returning to Earth in October. Photo Credit: (NASA/Bill Ingalls)

With the arrival of Rubins, Ivanishin and Onishi, the station is beefed up to its normal six person crew complement.

Rubins is on her rookie space mission. She holds a bachelor’s degree in molecular biology and a doctorate in cancer biology which will be a big focus of her space station research activities.

The new trio will join Expedition 48 Commander Jeff Williams of NASA and Flight Engineers Oleg Skripochka and Alexey Ovchinin of Roscosmos.

The Expedition 48 crew members will spend four months contributing to more than 250 experiments in fields such as biology, Earth science, human research, physical sciences and technology development.

“The approximately 250 research investigations and technology demonstrations – not possible on Earth – will advance scientific knowledge of Earth, space, physical, and biological sciences. Science conducted on the space station continues to yield benefits for humanity and will enable future long-duration human and robotic exploration into deep space, including the agency’s Journey to Mars,” says NASA.

The Soyuz MS-01 spacecraft service structure is put into place after the rocket rolled out by train to the launch pad at the Baikonur Cosmodrome, Kazakhstan, Monday, July 4, 2016. NASA astronaut Kate Rubins, cosmonaut Anatoly Ivanishin of the Russian space agency Roscosmos, and astronaut Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) will launch from the Baikonur Cosmodrome in Kazakhstan the morning of July 7, Kazakh time (July 6 Eastern time.) All three will spend approximately four months on the orbital complex, returning to Earth in October. Photo Credit: (NASA/Bill Ingalls)
The Soyuz MS-01 spacecraft service structure is put into place after the rocket rolled out by train to the launch pad at the Baikonur Cosmodrome, Kazakhstan, Monday, July 4, 2016. NASA astronaut Kate Rubins, cosmonaut Anatoly Ivanishin of the Russian space agency Roscosmos, and astronaut Takuya Onishi of the Japan Aerospace Exploration Agency (JAXA) will launch from the Baikonur Cosmodrome in Kazakhstan the morning of July 7, Kazakh time (July 6 Eastern time.) All three will spend approximately four months on the orbital complex, returning to Earth in October. Photo Credit: (NASA/Bill Ingalls)

The newly upgraded Soyuz offers increased reliability and enhanced performance. Many changes were instituted including enhanced structural performance to minimize chances of meteorite penetration. Engineers also added a fifth battery for more power and storage capacity. The solar arrays are also about one square meter larger and the efficiency of the solar cells increased about 2 percent.

Also a more modern command and telemetry system to interact with a new series of new Russian communications satellites that will offer greatly increased the coverage by ground control from only about 20 minutes per orbit up to from 45 to 90% of orbital coverage.

A phased array antenna was also added with increased UHF radio capability in the Soyuz descent module that now also include a GPS system to improve search and rescue possibilities.

The newly upgraded KURS rendezvous radar system will weigh less, use less power and overall will be less complicated. For example it doesn’t have to be moved out of the way before docking. Weighs less and uses less power.

New approach and attitude control thrusters were installed. The new configuration uses 28 thrusters with a redundant thruster for each one – thus two fully redundant manifolds of 28 thrusters each.

All of these modification were tested out on the last two progress vehicles.

Multiple unmanned cargo ships carrying tons of essential supplies and science experiments are also scheduled to arrive from Russia, the US and Japan over the next few months.

A SpaceX Dragon could launch as soon as July 18 and an Orbital ATK Cygnus could follow in August.

The Dragon CRS-9 mission is slated to deliver the station’s first International docking adapter (IDA) to accommodate the future arrival of U.S. commercial crew spacecraft, including the Boeing built Starliner and SpaceX built Crew Dragon.

A Japanese HTV cargo craft will carry lithium ion batteries to replace the nickel-hydrogen batteries currently used on station to store electrical energy generated by the station’s huge rotating solar arrays.

Two Russian Progress craft with many tons of supplies are also scheduled to arrive.

Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.

Ken Kremer