Commercial Space Archives

May 29, 2016June 22, 2016 by Ken Kremer

Reborn Antares Raised at Virginia Launch Pad for Crucial May 31 Engine Test

First stage of Orbital ATK Antares rocket outfitted with new RD-181 engines stands erect at Launch Pad-0A on NASA Wallops Flight Facility on May 24, 2016 in preparation for the upcoming May 31 hot fire engine test. Credit: Ken Kremer/kenkremer.com

WALLOPS ISLAND, VA – The soon to be reborn Orbital ATK Antares commercial rocket sporting new first stage engines has been raised at its repaired launch pad on Virginia’s scenic eastern shore for a long awaited test firing of the powerplants. The static test firing is now slated to take place in less than 3 days on Tuesday evening, May 31.

The now revamped launch vehicle – dubbed Antares 230 – has been ‘re-engined’ and upgraded with a pair of modern and more powerful first stage engines – the Russian-built RD-181 fueled by LOX/kerosene.

The engine test will be conducted using only the first stage of Antares at the Mid-Atlantic Regional Spaceport’s Pad-0A at NASA’s Wallops Flight Facility.

The raised rocket with the first stage capped at the top is visible right now at the Wallops pad – as seen in my new photos taken this week.

NASA announced that the static test firing is slated for no earlier than May 31 during a test window that runs from 5 p.m. to 8:15 p.m. EDT. As a contingency, the Wallops range has been reserved for backup test dates that run through June 5 just in case issues crop up.

NASA will not be carrying a live webcast of the test. Rather they will note the completion of the test on the Wallops’ Facebook and Twitter sites.

Orbital ATK’s Antares first stage with the new RD-181 engines stands erect at Virginia Space’s Mid-Atlantic Regional Spaceport Pad-0A on NASA Wallops Flight Facility on May 24, 2016 in preparation for the upcoming stage test on May 31. Credit: Ken Kremer/kenkremer.com

The test firing will be visible from various public viewing locations in the local Wallops area. However the NASA Wallops Visitor center will not be open.

NASA will not be carrying a live webcast of the test. Rather they will note the completion of the test on the Wallops’ Facebook and Twitter sites.

Bird takes flight over Orbital ATK Antares set to sail skyward again in summer 2016 from NASA Wallops Flight Facility, VA. Credit: Ken Kremer/kenkremer.com

The test firing will be visible from various public viewing locations in the local Wallops area. However the NASA Wallops Visitor center will not be open.

The test involves firing up Antares dual first stage RD-181 engines at full 100% power (thrust) for a scheduled duration of approximately 30 seconds. Hold down restraints will keep the rocket firmly anchored at the pad during the test.

The new RD-181 engines are installed on the Orbital ATK Antares first stage core ready to support a full power hot fire test at the NASA Wallops Island launch pad in March 2016. New thrust adapter structures, actuators, and propellant feed lines are incorporated between the engines and core stage. Credit: Ken Kremer/kenkremer.com — The new RD-181 engines are installed on the Orbital ATK Antares first stage core ready to support a full power hot fire test at the NASA Wallops Island launch pad in May 2016. New thrust adapter structures, actuators, and propellant feed lines are incorporated between the engines and core stage. Credit: Ken Kremer/kenkremer.com

To prepare for the static hot fire test, Orbital ATK technicians rolled the vehicle on a dedicated multi-wheeled transporter erector launcher from the rockets processing hangar inside the Horizontal Integration Facility at NASA’s Wallops Flight Facility to Virginia Space’s Mid-Atlantic Regional Spaceport Pad-0A about a mile away.

A successful outcome is absolutely crucial for permitting Antares to carry out its ‘Return to Flight’ launch dubbed OA-5 and set for sometime this summer.

“The hot fire will demonstrate the readiness of the rocket’s first stage and the launch pad fueling systems to support upcoming flights,” said NASA officials.

Antares launches ground to a halt following a devastating launch failure 19 months ago which destroyed the rocket and its payload of space station science and supplies for NASA in a huge fireball.

The ‘Return to Flight’ blastoff – which could come as soon as July 2016 – will be the first for the private Antares rocket since that catastrophic launch failure on Oct. 28, 2014, just seconds after liftoff from Wallops. That flight was carrying Orbital ATK’s Cygnus cargo freighter on the critical Orb-3 resupply mission for NASA and the astronauts living and working on the International Space Station (ISS).

The launch mishap was traced to a failure in the AJ26 first stage engine turbopump and caused Antares launches to immediately grind to a halt.

The RD-181 replaces the AJ26. The flight engines are built by Energomash in Russia.

“They are a good drop in replacement for the AJ26. And they offer 13% higher thrust compared to the AJ26,” said Kurt Eberly, Orbital ATK Antares deputy program manager, in an interview with Universe Today.

As a result of switching to the new RD-181 engines, the first stage also had to be modified to incorporate new thrust adapter structures, actuators, and propellant feed lines between the engines and core stage structure.

“This stage test paradigm is a design verification test,” said Eberly.

“After the 30 second test is done we will shut it down and have a pile of data to look at,” Eberly told Universe Today.

“Hopefully it will confirm all our environments and all our models and give us the confidence so we can proceed with the return to flight.”

Technicians have been processing the rocket at the pad to ready it for the test. They also conducted a wet dress rehearsal (WDR) and loaded the propellants like during an actual launch campaign.

The full up engine test follows the WDR.

“After the WDR we will do the stage test,” Eberly explained.

“It is a 30 second test. We will fire up both engines and hit all 3 power levels that we plan to use in flight.”

“We will use the thrust vector controls. So we will move the nozzles and sweep them through sinusoidal sweeps at different frequencies and excite various resonances and look for any adverse interaction between fluid modes and structural modes.”

The test uses the first stage core planned to launch the OA-7 mission from Wallops late this year.

After the engine test is completed, the stage will be rolled back to the HIF and a new stage fully integrated with the Cygnus cargo freighter will be rolled out to the pad for the OA-5 ‘Return to Flight’ mission as soon as July.

“Orbital ATK is building, testing and flying the Antares rocket and Cygnus cargo spacecraft under NASA’s Commercial Resupply Services contract. NASA initiatives like the cargo resupply contracts are helping develop a robust U.S. commercial space transportation industry with the goal of achieving safe, reliable and cost-effective transportation to and from the International Space Station and low-Earth orbit,” according to NASA.

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

Ken Kremer

Antares soars to space on Jan. 9, 2014 from NASA Wallops on Virginia coast on the Orb-1 mission to the ISS. Photo taken by remote camera at launch pad. Credit: Ken Kremer - kenkremer.com — Antares soars to space on Jan. 9, 2014 from NASA Wallops on Virginia coast on the Orb-1 mission to the ISS. Photo taken by remote camera at launch pad. Credit: Ken Kremer – kenkremer.com

May 28, 2016May 28, 2016 by Ken Kremer

SpaceX Falcon 9 Thunders to Space with Thai Comsat – Scores Double Headed Win with 3rd Straight Booster Landing

Upgraded SpaceX Falcon 9 blasts off with Thaicom-8 communications satellite on May 27, 2016 from Space Launch Complex 40 at Cape Canaveral Air Force Station, FL. 1st stage booster landed safely at sea minutes later. Credit: Ken Kremer/kenkremer.com

CAPE CANAVERAL AIR FORCE STATION, FL. – Atop a billowing plume of fire and smoke a SpaceX Falcon 9 rocket soared to space this afternoon, Friday, May 27, as the crackling thunder of the engines roared across the Florida space coast and the company scored a stunning double headed launch and landing success.

The 229 foot-tall (70 meter) Falcon 9 successfully delivered a 7000 pound commercial Thai telecommunications satellite to a Geostationary Transfer Orbit (GTO) and the first stage booster successfully soft landed on a platform at sea some nine minutes later.

Thus SpaceX is now an unfathomable 3 for 3 in the last three first stage landing attempts – both at sea and on land.

Even more remarkable is the string of two straight successes in landings via the high energy reentries as a consequence of launching the commercial payloads to GTO.

The Falcons screams were the loudest and most thrilling I’ve ever heard from a SpaceX launch as the two stage rocket lifted off on time at 5:39 p.m. EDT from Space Launch Complex-40 at Cape Canaveral Air Force Station, FL.

“Satellite deployed to 91,000 km apogee,” tweeted SpaceX CEO and founder Elon Musk.

“All looks good.”

The spectacular looking launch into mostly sunny Florida skies followed a days delay forced by a technical glitch in the second stage.

SpaceX engineers had to lower the Falcon 9 to the horizontal position and hurriedly fix the second engine actuator that gave concerning readings during Thursday’s original launch attempt and scrubbed the liftoff – and do so in time to safely carry out a launch attempt late this afternoon.

Hundreds of millions of dollars were at stake on this commercial flight slated to deliver the Thaicom-8 comsat to a Geostationary Transfer Orbit (GTO) for Thaicom PLC, a leading satellite operator in Asia.

The first and second stages separated as planned about 2 minutes and 39 seconds after liftoff.

The nosecone, or payload fairing deployed into two halves at about T plus 3 minutes and 37 seconds.

Up close view of payload fairing of SpaceX Falcon 9 rocket delivering Thaicom-8 communications satellite on May 27, 2016 from Space Launch Complex 40 at Cape Canaveral Air Force Station, FL. Credit: Ken Kremer/kenkremer.com

The second stage with Thaicom-8 continued to orbit. A pair of burns carried Thaicom-8 to orbit and the satellite was deployed at T plus 31 minutes and 56 seconds.

The rocket arced over as it accelerated eastwards towards Africa.

The nine first stage Marlin 1D engines on the 229 foot tall Falcon 9 rocket generate approximately 1.5 million pounds of thrust.

Thaicom-8 was built by aerospace competitor Orbital ATK, based in Dulles, VA. It will support Thailand’s growing broadcast industry and will provide broadcast and data services to customers in South Asia, Southeast Asia and Africa.

Thaicom-8 communications satellite built by Orbital ATK will launch on SpaceX Falcon 9 on May 26, 2016. The satellite has delivered to the launch site in Cape Canaveral, Florida in late April 2016. Credit: Orbital ATK

The Falcon 9 launch is the 5th this year for SpaceX.

Meanwhile, the first stage began a series of propulsive burns of a Merlin 1 D engine to target a drone ship platform at sea.

SpaceX said the barge was positioned some 620 km off the Florida coast in the Atlantic Ocean.

After the primary goal of delivering Thaicom-8 to GTO, the secondary test objective of SpaceX was to land the Falcon 9 rockets first stage on the ocean going barge.

The Autonomous Spaceport Drone Ship (ASDS) platform is named “Of Course I Still Love You.”

SpaceX Falcon 9 aloft with Thaicom-8 communications satellite after afternoon liftoff from Space Launch Complex 40 at Cape Canaveral Air Force Station, FL on May 27, 2016. Credit: Ken Kremer/kenkremer.com

However with this mission’s GTO destination, the first stage was subject to extreme velocities and re-entry heating and a successful landing would be difficult.

Altogether, SpaceX has now recovered 4 first stage boosters – 3 by sea and 1 by land.

The quartet of landings count as stunning successes towards SpaceX founder and CEO Elon Musk’s vision of rocket reusability and radically slashing the cost of sending rockets to space by recovering the boosters and eventually reflying them with new payloads from paying customers.

SpaceX hopes to cut launch costs by one third initially, and much much more down the road.

Watch for Ken’s on site reports direct from Cape Canaveral and the SpaceX launch pad.

SpaceX Falcon 9 arcs over eastwards with Thaicom-8 communications satellite after liftoff from Space Launch Complex 40 at Cape Canaveral Air Force Station, FL on May 27, 2016. Credit: Ken Kremer/kenkremer.com

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

Ken Kremer

THAICOM 8 spacecraft as seen during deployment into a nominal supersynch transfer orbit. Credit: SpaceX

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

May 28: “SpaceX, ULA, SLS, Orion, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, afternoon/evening

Falcon 9 first stage landed on the droneship in the Atlantic Ocean after launch of Thaicom-8 on May 27, 2016. Credit: SpaceX

May 27, 2016 by Evan Gough

Blue Origin Will Shoot Itself In The Foot On Purpose

New Shepard's crew capsule is seen descending with its parachutes deployed. The capsule's landing is cushioned by firing rockets after the parachutes have done their job. Image: Blue Origin

Blue Origin, the builder of the New Shepard re-usable rocket, has announced plans for the fourth flight of the rocket. With a recent successful launch and landing in their pocket, the company is anticipating another similar result. But this time, something will be done differently.

This time around, New Shepard will be launched and landed normally, but the crew capsule will be tested with an intentionally failed parachute. Blue Origin is promising an “exciting demonstration,” and in an email said they will be “demonstrating our ability to safely handle that failure scenario.”

Though no date has yet been set for this gimped-parachute demonstration, we are looking forward to it.

In previous tests, the crew capsule performed maneuvers that characterized its aerodynamics and reduced what are called ‘model uncertainties.’ Greater predictability is what these test flights are designed to achieve. Obviously, too many question marks are not good.

As Jeff Bezos, head of Blue Origin, said in an email, “One of the fundamental tenets of Blue Origin is that the safest vehicle is one that is robust and well understood. Each successive mission affords us the opportunity to learn and improve our vehicles and their modeling.”

The company also shared news of the construction of additional test cells at its facility in West Texas. These cells were announced in October, and now one of the cells has been commissioned. This cell “supports the development of the pre-burner start and ignition sequence timing” according to Bezos.

A new test cell has been commissioned at the Blue Origin facility in Texas. Image: Blue Origin

Bezos also touted the benefits of privately-funded endeavours, saying “…one of the many benefits of a privately funded engine development is that we can make and implement decisions quickly. We made the decision to build these two new test cells as a team in a 10 minute discussion.” He added, “Less than three weeks later we were pouring concrete and now we have an operating pressure fed test cell 7 months later.”

It’s clear that privately-funded initiatives can have more flexibility than governmental initiatives. They don’t face the same budgetary wrangling that organizations like NASA do. But, they don’t command the same resources that NASA does.

Companies like Blue Origin an SpaceX are very innovative and are leading the way in reusable rockets. If Blue Origin can make the crew capsule survivable in a failed parachute scenario, as the next test aims to do, then commercial space flight will benefit. Private trips to space, which are one of Blue Origin’s goal, will also become more and more attainable.

The New Shepard launching from its facility in West Texas. Image: Blue Origin

May 27, 2016May 27, 2016 by Ken Kremer

Technical Glitch Postpones SpaceX Thaicom Launch/Landing to Friday May 27 – Watch Live Webcast

Upgraded SpaceX Falcon 9 awaits launch of Thaicom-8 communications satellite on May 27, 2016 from Space Launch Complex 40 at Cape Canaveral Air Force Station, FL, in this file photo. Credit: Ken Kremer/kenkremer.com

CAPE CANAVERAL AIR FORCE STATION, Fla. – Thursday’s (May 26) planned blastoff of an upgraded SpaceX Falcon 9 rocket on a lucrative commercial mission to deliver a Thai telecommunications satellite to orbit, was postponed in the final stages of the countdown after engineers discovered a technical glitch in the booster’s second stage.

Liftoff of the two stage Falcon 9 is now planned for Friday, May 27 at 5:39 p.m. EDT from Space Launch Complex-40 at Cape Canaveral Air Force Station in Florida.

Soon after liftoff, SpaceX will again execute a sea landing attempt of the first stage booster on a platform a sea following a tough reentry trajectory.

Since the launch window extends two hours, the SpaceX launch team took the time available to work the issue and tried as best they could to resolve it.

But in the end, and more than an hour into the available window, launch controllers decided it was best to stay safe and scrub for the day at about 6:40 p.m. EST and take the opportunity to thoroughly review all the data.

“Out of an abundance of caution, launch postponed until no earlier than tomorrow [May 27] for additional data review” SpaceX said via social media accounts.

Hundreds of millions of dollars are at stake on this commercial flight slated to deliver the Thaicom-8 comsat to a Geostationary Transfer Orbit (GTO) for Thaicom PLC, a leading satellite operator in Asia.

“Falcon 9 & THAICOM 8 spacecraft remain healthy,” SpaceX tweeted.

SpaceX founder and CEO Elon Mush said that the problem was traced to an engine actuator in the second stage wich is critical for delivering Thaicom-8 to its required geostationary orbit.

“There was a tiny glitch in the motion of an upper stage engine actuator,” SpaceX CEO Musk tweeted.

“Probably not a flight risk, but still worth investigating.”

You can watch the launch live on Friday via a special live webcast from SpaceX.

The SpaceX webcast will be available starting at about 20 minutes before liftoff, at approximately 5:19 p.m. EDT- at SpaceX.com/webcast
The two stage Falcon 9 rocket has a two-hour launch window that extends until Friday, May 27 at 7:39 p.m. EDT.

The Florida weather is much less favorable than yesterday. Air Force meteorologists are predicting only a 40 percent chance of favorable weather conditions at launch time Friday. The major concerns could be violations of the Thick Cloud Layer Rule, Cumulus Cloud Rule, and Liftoff Winds.

The backup launch opportunity is Saturday, May 28. The weather outlooks is somewhat better at a 50 percent chance of favorable conditions.

Watch this truly cool video showing the rocket rollout to pad 40, rocket erection and finally the short static fire test carried out on Tuesday May 24, 2016.

Video Caption: SpaceX – Thaicom 8 – Roll Out – Lift – Static Fire Test – 05-24-2016. Credit: USLaunchReport

The Falcon 9 launch is the 5th this year for SpaceX.

Tune in to the SpaceX webcast Thursday afternoon to catch all the exciting action !!

Watch for Ken’s on site reports direct from Cape Canaveral and the SpaceX launch pad.

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

Ken Kremer

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

May 27: “SpaceX, ULA, SLS, Orion, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, late evening

May 25, 2016May 26, 2016 by Ken Kremer

SpaceX Targets Thursday May 26 for Thai Comsat Launch and Tough Sea Landing – Watch Live

SpaceX Falcon 9 rocket stands poised for launch on May 26 at Cape Canaveral Air Force Station, FL, similar to this file photo. Credit: Ken Kremer/kenkremer

CAPE CANAVERAL AIR FORCE STATION, Fla. – Just three weeks after SpaceX’s last launch from their Florida launch base, the growing and influential aerospace firm is deep into commencing their next space spectacular – targeting this Thursday, May 26, for launch of a Thai comsat followed moments later by a sea landing attempt of the booster on a tough trajectory.

SpaceX is slated to launch the Thaicom-8 telecommunications satellite atop an upgraded version of the SpaceX Falcon 9 on Thursday at 5:40 p.m. EDT from Space Launch Complex-40 at Cape Canaveral Air Force Station in Florida.

SpaceX is rapidly picking up the pace of rocket launches for their wide ranging base of commercial, government and military customers that is continuously expanding and reaping contracts and profits for the Hawthorne, Calif. based company.

This commercial mission involves lofting Thaicom-8 to a Geostationary Transfer Orbit (GTO) for Thaicom PLC, a leading satellite operator in Asia.

This also counts as the second straight GTO launch and the second straight attempt to land a rocket on a sea based platform from the highly demanding GTO launch trajectory.

Will this mission make for 3 successful Falcon 9 1st stage booster landings in a row? Tune in and find out !!

Engineers have a two-hour window to launch the Falcon 9 and deliver Thaicom to orbit.

The Falcon 9 launch is the 5th this year for SpaceX.

You can watch the launch live via a special live webcast from SpaceX.

The SpaceX webcast will be available starting at about 20 minutes before liftoff, at approximately 5:20 a.m. EDT at SpaceX.com/webcast

The two stage Falcon 9 rocket has a two-hour launch window that extends until Thursday, May 26 at 7:40 p.m. EDT.

The path to liftoff was cleared late last night the company completed the customary pre-launch static fire test of the rocket’s first stage upgraded Merlin 1D engines for several seconds at pad 40.

The nine engines on the 229 foot tall Falcon 9 rocket generate approximately 1.5 million pounds of thrust.

Engineers monitored the test and after analyzing results declared the Falcon 9 was fit to launch Thursday afternoon.

The weather currently looks very good. Air Force meteorologists are predicting a 90 percent chance of favorable weather conditions at launch time Thursday morning with a minor concern for ground winds.

The backup launch opportunity is Friday, May 27. The weather outlooks is somewhat less promising at a 70 percent chance of favorable conditions.

After the Falcon 9 rocket delivers the satellite into its targeted geosynchronous transfer orbit it will enter a 30-day testing phase, says Orbital ATK.

Following in-orbit activation and after reaching its final orbital slot, Orbital ATK will then turn over control of the satellite to Thaicom to begin normal operations.

THAICOM 8’s orbital location will be positioned at 78.5 degrees east longitude and the satellite is designed to operate for more than 15 years.

Thaicom-8 is a Ku-band satellite that offers 24 active transponders that will deliver broadcast and data services to customers in Thailand, Southeast Asia, India and Africa.

Thaicom-8 has a mass of approximately 6,800 pounds (3,100 kilograms). It is based on Orbital ATK’s flight-proven GEOStar-2TM platform.

“We built and delivered this high-quality communications satellite for Thaicom PLC two months ahead of schedule, demonstrating our ability to manufacture reliable, affordable and innovative products that exceed expectations for our customer,” said Amer Khouri, Vice President of the Commercial Satellite Business at Orbital ATK.

“As one of Asia’s leading satellite operators, we are grateful for Thaicom’s continued confidence and look forward to more successful partnerships in the future.”

Thaicom-8 will join Thaicom-6 already in orbit. It was also designed, manufactured, integrated and tested by Orbital ATK. at the firm’s state-of-the-art satellite manufacturing facility in Dulles, Virginia.

Thaicom PLC commissioned Thaicom-8 in 2014, shortly after SpaceX launched the THAICOM 6 satellite into orbit in January 2014.

Thaicom-8 mission patch artwork. Credit: SpaceX

The secondary test objective of SpaceX is to land the Falcon 9 rockets first stage on an ocean going barge several hundred miles offshore in the Atlantic Ocean.

The Autonomous Spaceport Drone Ship (ASDS) barge is named “Of Course I Still Love You.”

However with this mission’s GTO destination, the first stage will be subject to extreme velocities and re-entry heating and a successful landing will be difficult.

Having said that and despite those hurdles, the last GTO mission landing attempt did succeed brilliantly following the May 6 JCSAT-14 launch.

Tune in to the SpaceX webcast Thursday afternoon to catch all the exciting action !!

Composite image of first stage booster 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: Jeff Seibert/AmericaSpace. Inset: Trio of SpaceX boosters inside pad 39A hangar. Credit: SpaceX. Composite: Ken Kremer

Watch for Ken’s on site reports direct from Cape Canaveral and the SpaceX launch pad.

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

Ken Kremer

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

May 25/26: “SpaceX, ULA, SLS, Orion, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, evenings

Jun 2 to 5: “ULA, NRO, SpaceX, SLS, Orion, Commercial crew, Curiosity explores Mars, Pluto and more,” Kennedy Space Center Quality Inn, Titusville, FL, evenings

May 25, 2016June 13, 2016 by Evan Gough

The Bigelow Expandable Module Is About To Blow Up

This computer rendering shows the Bigelow Expanded Activity Module in its fully expanded configuration. Image: NASA

Update:

The Bigelow Expandable Activity Module did not fully expand today, May 26th, as planned. Engineers are meeting to try to understand why the module didn’t fully expand. They are evaluating data from the expansion to determine what has happened. If the data says its okay to resume expansion, that could happen as early as tomorrow, May 27th.

A previously scheduled teleconference has been postponed, and NASA will update when a decision on expansion is made.

People who aren’t particularly enthusiastic about space science and space exploration often accuse those of us who are, of “living in a bubble.” There are so many seemingly intractable problems here on Earth, so they say, that it’s foolish to spend so much money and time on space exploration. But if all goes well with the Bigelow Expandable Activity Module (BEAM) at the ISS this week, astronauts may well end up living in a sort of bubble.

Expandable, inflatable habitats could bring about a quiet revolution in space exploration, and the BEAM is leading that revolution. Because it’s much more compact and much lighter than rigid steel and aluminum structures, the cost of building them and launching them into space is much lower. The benefits of lower costs for building them and launching them are obvious.

NASA first announced plans to test the BEAM back in 2013. They awarded a $17.8 million contract to Bigelow Aerospace to provide the expandable module, with the idea of testing it for a two-year period.

NASA Deputy Administrator Lori Garver and Bigelow Aerospace founder Robert Bigelow stand in front of the BEAM in January, 2013. Image: NASA/Bill Ingalls

When the contract was announced, NASA Deputy Administrator Lori Garver said, “The International Space Station is a unique laboratory that enables important discoveries that benefit humanity and vastly increase understanding of how humans can live and work in space for long periods. This partnership agreement for the use of expandable habitats represents a step forward in cutting-edge technology that can allow humans to thrive in space safely and affordably, and heralds important progress in U.S. commercial space innovation.”

Though no astronauts will be living in the module, it will be tested to see how it withstands the rigours of space. ISS astronauts will enter the module periodically, but for the most part, the module will be monitored remotely. Of particular interest to NASA is the module’s ability to withstand solar radiation, debris impact, and temperature extremes.

The BEAM was launched in April aboard a SpaceX Dragon Capsule, itself carried aloft by a SpaceX Falcon rocket. Personnel aboard the ISS used the station’s robotic arm to unpack the BEAM and attach it to the station. That procedure went well, and now the BEAM is ready for inflation.

This sped-up animation shows the ISS's robotic arm removing the uninflated BEAM from the Dragon capsule and attaching it to the station. Credit: NASA — This sped-up animation shows the ISS’s robotic arm removing the uninflated BEAM from the Dragon capsule and attaching it to the station. Credit: NASA

How exactly the BEAM will behave while it’s being inflated is uncertain. The procedure will be done slowly and methodically, with the team exercising great caution during inflation.

Once inflated, the BEAM will expand to almost five times its travelling size. While packed inside the Dragon capsule, the module is 8 ft. in diameter by 7 ft. in length. After inflation, it will measure 10 ft. in diameter and 13 ft. in length, and provide 16 cubic meters (565 cubic ft.) of habitable volume. That’s about as large as a bedroom.

After inflation, the BEAM will sit for about a week before any astronauts enter it. After that, the plan is to visit the module 2 or 3 times per year to check conditions inside. During those visits, astronauts will also get sensor data from equipment inside the BEAM.

Some, including Bigelow CEO Robert Bigelow, are hopeful that after the first six months or so, the timeline can be accelerated a little. If NASA approves it, the BEAM could be used for science experiments at that time.

As for Bigelow itself, they are already working on the B330, a much larger expandable habitat that promises even greater impact durability and radiation protection than the BEAM. Bigelow hopes that the B330 could be used on the surface of the Moon and Mars, as well as in orbit.

The BEAM will never attract the attention that rocket launches and Mars rovers do. But their impact on space exploration will be hard to deny. And when naysayers accuse us of living in a bubble, we can smile and say, “We’re working on it.”

May 16, 2016May 16, 2016 by Ken Kremer

Upgraded Antares Rolls Out to Virginia Launch Pad, High Stakes Engine Test Looms

Orbital ATK’s Antares first stage with the new engines is rolled from NASA Wallops Flight Facility’s Horizontal Integration Facility to Virginia Space’s Mid-Atlantic Regional Spaceport Pad-0A on May 12, 2016, in preparation for the upcoming stage test in the next few weeks. Credit: NASA's Wallops Flight Facility/Allison Stancil

An upgraded version of Orbital ATK’s commercially developed Antares rocket has at last rolled out to its launch pad on the Virginia shore – thus paving the path for a high stakes first stage engine test looming “in the next few weeks,” according to the aerospace firm.

“This stage test paradigm is a design verification test, said Kurt Eberly, Orbital ATK Antares deputy program manager, in an interview with Universe Today.

The rocket will be erected at the pad during the full power hot fire test which is scheduled to last approximately 30 seconds. Hold down restraints will keep the rocket firmly anchored at the pad.

“After the 30 second test is done we will shut it down and have a pile of data to look at,” Eberly told Universe Today.

“Hopefully it will confirm all our environments and all our models and give us the confidence so we can proceed with the return to flight.”

Indeed the significance of the hot fire engine test cannot be overstated because the entire future of Antares as a viable launch vehicle and resuming delivery of NASA cargo to the International Space Station (ISS) depends on a successful outcome of the crucial test firing – following a devastating launch failure 19 months ago.

Orbital ATK hopes to restart resupply missions to the crews living aboard the space station as soon as July – less than two months from today.

The now revamped launch vehicle dubbed Antares 230 has been re-engined and upgraded with a pair of modern new first stage engines, the Russian-built RD-181 fueled by LOX/kerosene.

To prepare for the upcoming stage test, workers carefully assembled and thoroughly tested an Antares first stage equipped with the new RD-181 engines.

On May 12, 2016, they moved the vehicle on a dedicated multi-wheeled transporter from the Horizontal Integration Facility at NASA’s Wallops Flight Facility to Virginia Space’s Mid-Atlantic Regional Spaceport Pad-0A about a mile away.

The team has about 3 weeks of check out work to complete before the live firing, including a wet dress rehearsal (WDR).

“The team will continue to work meticulously as they begin final integration and check outs on the pad and several readiness reviews prior to the test. The window for the stage test will be over multiple days to ensure technical and weather conditions are acceptable,” noted Orbital ATK in a statement.

The ‘Return to Flight’ blastoff – currently planned for as soon as July 2016 – will be the first for the private Antares rocket since a catastrophic launch failure on Oct. 28, 2014, just seconds after liftoff from Wallops. That flight was carrying Orbital ATK’s Cygnus cargo freighter on the critical Orb-3 resupply mission for NASA to the space station.

The launch mishap was traced to a failure in the AJ26 first stage engine turbopump and caused Antares launches to immediately grind to a halt.

Top Orbital ATK management soon decided to ditch the AJ26s, which were 40 year old refurbished engines, originally built during the Soviet era and originally known as the NK-33.

They sought a replacement and eventually decided to upgrade Antares by powering it with a pair of new Russian-made RD-181 main stage engines and modifying the first stage core structure to accommodate the new engines.

The RD-181 flight engines are built by Energomash in Russia.

“They are a good drop in replacement for the AJ26. And they offer 13% higher thrust compared to the AJ26,” Eberly noted.

Independent review teams have also been brought in to ensure that no stone is left unturned and everything is being done to achieve success.

Now it’s time for the real deal. After all the hard work Antares is now at the pad.

“We place it on the pad about 3 weeks prior to the engine test,” Eberly told me. “Then we and do a series of integrated checks, and electrical checks and pressure checks on the feed lines.”

“Then we will do a wet dress rehearsal where we will load the tanks with propellants. We will load the pressure bottles, pressurize the tanks and then count down just like we would for the real stage test. And right before we ignite the engines we will call a halt to the sequencer.”

“Then we will detank and pick through all that data and do a readiness review.”

If the WDR goes well, the full up engine test will follow.

“Then we will do the stage test,” Eberly explained.

“It is a 30 second test. We will fire up both engines and hit all 3 power levels that we plan to use in flight.”

Orbital Sciences Antares rocket and Launch Complex 0-A at the edge of Virginia’s shore at NASA Wallops are crucial to resupply the International Space Station (ISS). . Credit: Ken Kremer (kenkremer.com) — Orbital Sciences Antares rocket first stage stands erect at Launch Complex 0-A at the edge of Virginia’s shore at NASA Wallops, in this file photo. Credit: Ken Kremer/kenkremer.com

The vehicle and pad will be outfitted with lots of special instrumentation to gather as much test data as possible.

“We will have a lot of accelerometers and extra instrumentation and extra microphones on the test article and around the pad.

“After the 30 second test is done we will shut it down and have a pile of data to look at.”

“That will hopefully confirm all our environments and all our models and give us the confidence so we can proceed with the return to flight on the OA-5 mission.”

The test uses the first stage core planned to launch the OA-7 mission late this year.

After the engine test is completed, the stage will be rolled back to the HIF and a new stage fully integrated with the Cygnus will be rolled out to the pad for the OA-5 ‘Return to Flight’ mission as soon as July.

In the past 6 months, Orbital ATK has successfully resumed launches of their Cygnus cargo freighters to the ISS – as an interim measure until Antares is returned to flight status

They utilized the United Launch Alliance (ULA) Atlas V rocket to deliver two Cygnus resupply vessels to the ISS on the OA-4 flight in Dec. 2015 and OA-6 flight in March 2016.

A United Launch Alliance (ULA) Atlas V rocket carrying the OA-6 mission lifted off from Space Launch Complex 41 at 11:05 p.m. EDT on March 22, 2016 from Cape Canaveral Air Force Station, Fla. Credit: Ken Kremer/kenkremer.com

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

Ken Kremer

A Cygnus cargo spacecraft named the SS Rick Husband is being prepared inside the Payload Hazardous Servicing Facility at NASA's Kennedy Space Center for upcoming Orbital ATK CRS-6/OA-6 mission to deliver hardware and supplies to the International Space Station. The Cygnus is scheduled to lift off atop a United Launch Alliance Atlas V rocket on March 22, 2016. Credit: Ken Kremer/kenkremer.com — A Cygnus cargo spacecraft named the SS Rick Husband is being prepared inside the Payload Hazardous Servicing Facility at NASA’s Kennedy Space Center for upcoming Orbital ATK CRS-6/OA-6 mission to deliver hardware and supplies to the International Space Station. The Cygnus is scheduled to lift off atop a United Launch Alliance Atlas V rocket on March 22, 2016. Credit: Ken Kremer/kenkremer.com

May 11, 2016May 12, 2016 by Ken Kremer

SpaceX Dragon Returns to Earth After Splashdown with Critical NASA Science

A SpaceX Dragon cargo spacecraft splashed down in the Pacific Ocean at 2:51 p.m. EDT today, May 11, with more than 3,700 pounds of NASA cargo, science and technology demonstration samples from the International Space Station. Credit: SpaceX

A SpaceX cargo Dragon spacecraft loaded with nearly two tons of critical NASA science and technology experiments and equipment returned to Earth this afternoon, Wednesday, May 11, safely splashing down in the Pacific Ocean – and bringing about a successful conclusion to its mission to the International Space Station (ISS) that also brought aloft a new room for the resident crew.

Following a month long stay at the orbiting outpost, the unmanned Dragon was released from the grip of the stations Canadian-built robotic arm at 9:19 a.m. EDT by European Space Agency (ESA) astronaut Tim Peake.

After being detached from its berthing port at the Earth-facing port on the stations Harmony module by ground controllers, Peake commanded the snares at the terminus of the 57 foot long (19 meter long) Canadarm2 to open – as the station was soaring some 260 miles (418 kilometers) over the coast of Australia southwest of Adelaide.

Dragon backed away and soon departed after executing a series of three departure burns and maneuvers to move beyond the 656-foot (200-meter) “keep out sphere” around the station.

European Space Agency astronaut Tim Peake captured this photograph of the SpaceX Dragon cargo spacecraft as it undocked from the International Space Station on May 11, 2016. The spacecraft was released from the station’s robotic arm at 9:19 a.m. EDT. Following a series of departure burns and maneuvers Dragon returned to Earth for a splashdown in the Pacific Ocean at 2:51 p.m., about 261 miles southwest of Long Beach, California. Credit: NASA — European Space Agency astronaut Tim Peake captured this photograph of the SpaceX Dragon cargo spacecraft as it undocked from the International Space Station on May 11, 2016. Following a series of departure burns Dragon returned to Earth for a splashdown in the Pacific Ocean at 2:51 p.m., about 261 miles southwest of Long Beach, California. Credit: NASA

“The Dragon spacecraft has served us well, and it’s good to see it departing full of science, and we wish it a safe recovery back to planet Earth,” Peake said.

Dragon fired its braking thrusters to initiate reentry back into the Earth’s atmosphere, and survived the scorching 3000+ degree F temperatures for the plummet back home.

A few hours after departing the ISS, Dragon splashed down in the Pacific Ocean at 2:51 p.m. EDT today, descending under a trio of huge orange and white main parachutes about 261 miles southwest of Long Beach, California.

“Good splashdown of Dragon confirmed, carrying thousands of pounds of @NASA science and research cargo back from the @Space_Station,” SpaceX notified via Twitter.

It was loaded with more than 3,700 pounds of NASA cargo, science and technology demonstration samples including a final batch of human research samples from former NASA astronaut Scott Kelly’s historic one-year mission that concluded in March.

“Thanks @SpaceX for getting our science safely back to Earth! Very important research,” tweeted Kelly soon after the ocean splashdown.

Among the study samples returned are those involving Biochemical Profile, Cardio Ox, Fluid Shifts, Microbiome, Salivary Markers and the Twins Study.

The goal of Kelly’s one-year mission was to support NASA’s plans for a human ‘Journey to mars’ in the 2030s. Now back on the ground Kelly continues to support the studies as a human guinea pig providing additional samples to learn how the human body adjusts to weightlessness, isolation, radiation and the stress of long-duration spaceflight.

Among the other items returned was a faulty spacesuit worn by NASA astronaut Tim Kopra. It will be analyzed by engineers to try and determine why a small water bubble formed inside Kopra’s helmet during his spacewalk in January that forced it to end prematurely as a safety precaution.

Dragon was plucked from the ocean by SpaceX contracted recovery ships and is now on its way to port in Long Beach, California.

“Dragon recovery team on site after nominal splashdown in Pacific,” said SpaceX.

“Some cargo will be removed and returned to NASA, and then be prepared for shipment to SpaceX’s test facility in McGregor, Texas, for processing,” says NASA.

Currently Dragon is the only station resupply craft capable of returning significant quantities of cargo and science samples to Earth.

The Dragon CRS-8 cargo delivery mission began with a spectacular blastoff atop an upgraded version of the two stage SpaceX Falcon 9 rocket, boasting over 1.5 million pounds of thrust on Friday, April 8 at 4:43 p.m. EDT from Space Launch Complex 40 at Cape Canaveral Air Force Station in Florida.

The primary goal of the Falcon 9 launch was carrying the SpaceX Dragon CRS-8 cargo freighter to low Earth orbit on a commercial resupply delivery mission for NASA to the International Space Station (ISS).

Relive the launch via this video of the SpaceX Falcon 9/Dragon CRS-8 liftoff from my video camera placed at the pad:

Video Caption: Spectacular blastoff of SpaceX Falcon 9 rocket carrying Dragon CRS-8 cargo freighter bound for the International Space Station (ISS) from Space Launch Complex 40 on Cape Canaveral Air Force Station, FL at 4:43 p.m. EST on April 8, 2016. Up close movie captured by Mobius remote video camera placed at launch pad. Credit: Ken Kremer/kenkremer.com

The SpaceX commercial cargo freighter was jam packed with more than three and a half tons of research experiments, essential crew supplies and a new experimental inflatable habitat for it deliver run.

After a two day orbital chase it reached the ISS and the gleeful multinational crew of six astronauts and cosmonauts on Sunday, April 10.

Expedition 47 crew members Jeff Williams and Tim Kopra of NASA, Tim Peake of ESA (European Space Agency) and cosmonauts Yuri Malenchenko, Alexey Ovchinin and Oleg Skripochka of Roscosmos are currently living aboard the orbiting laboratory.

CRS-8 counts as the company’s eighth flight to deliver supplies, science experiments and technology demonstrations to the ISS for the crews of Expeditions 47 and 48 to support dozens of the approximately 250 science and research investigations in progress.

In a historic first, the arrival of the SpaceX Dragon cargo spacecraft marked the first time that two American cargo ships are simultaneously docked to the ISS. The Orbital ATK Cygnus CRS-6 cargo freighter arrived two weeks earlier on March 26 and is now installed at a neighboring docking port on the Unity module.

The Dragon spacecraft delivered almost 7,000 pounds of cargo, including the Bigelow Expandable Activity Module (BEAM), to the orbital laboratory which was carried to orbit inside the Dragon’s unpressurized truck section.

BEAM is a prototype inflatable habitat that the crew plucked from the Dragon’s truck with the robotic arm for installation on a side port of the Tranquility module on April 16.

Robotic arm attaches BEAM inflatable habitat module to International Space Station on April 16, 2016. Credit: NASA/Tim Kopra

Minutes after the successful April 8 launch, SpaceX accomplished their secondary goal – history’s first upright touchdown of a just flown rocket onto a droneship at sea.

The recovered booster arrived back at Port Canaveral a few days later and was transported back to the firms processing hanger at the Kennedy Space Center (KSC) for testing and eventual reflight.

Recovered SpaceX Falcon 9 rocket arrives back in port overnight at Port Canaveral, Florida on April 12, 2016 following successful launch and landing on April 8 from Cape Canaveral Air Force Station. Credit: Julian Leek

The next NASA contracted cargo launch to the ISS by SpaceX is currently slated for late June from Cape Canaveral.

The next Orbital ATK Cygnus cargo launch is slated for July from NASA Wallops.

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

Ken Kremer

This artist’s concept depicts the Bigelow Expandable Activity Module attached to the International Space Station’s Tranquility module. Credits: Bigelow Aerospace — This artist’s concept depicts the Bigelow Expandable Activity Module attached to the International Space Station’s Tranquility module.
Credits: Bigelow Aerospace

May 9, 2016May 15, 2016 by Evan Gough

SpaceX Maiden Falcon Heavy Launch May Carry Satellite In November

An artist's illustration of the Falcon Heavy rocket. The Falcon Heavy has 3 engine cores, each one containing 9 Merlin engines. Image: SpaceX

Move over Arianespace and United Launch Alliance. SpaceX’s Falcon Heavy rocket is set for its maiden launch this November. The long-awaited Falcon Heavy should be able to outperform both the Ariane 5 and the ULA Delta-4 Heavy, at least in some respects.

The payload for the maiden voyage is uncertain so far. According to Gwynne Shotwell, SpaceX’s President and CEO, a number of companies have expressed interest in being on the first flight. Shotwell has also said that it might make more sense for SpaceX to completely own their first flight, without the pressure to keep a client happy. But a satellite payload for the first launch hasn’t been ruled out.

Delivering a payload into orbit is what the Falcon Heavy, and its competitors the Ariane5 and the ULA Delta-4 Heavy, are all about. Since one of the main competitive points of the Falcon Heavy is its ability to put larger payloads into geo-stationary orbits, accomplishing that feat on its first flight would be a great coming out party for the Falcon Heavy.

This artist's illustration of the Falcon Heavy shows the rocket in flight prior to releasing its two side boosters. Image: SpaceX — This artist’s illustration of the Falcon Heavy shows the rocket in flight prior to releasing its two side boosters. Image: SpaceX

SpaceX has promised that it will make its first Falcon Heavy launch useful. They say that they will use the flight either to demonstrate to its commercial customers the rocket’s capability to deliver a payload to GTO, or to demonstrate to national security interests its ability to meet their needs.

National security satellites require different capabilities from launch vehicles than do commercial communication satellites. Since these spacecraft are top secret, and are used to spy on communications, they need to be placed directly into their GTO, avoiding the lower-altitude transfer orbit of commercial satellites.

The payload for the first launch of the Falcon Heavy is not the only thing in question. There’s some question whether the November launch date can be achieved, since the Falcon Heavy has faced some delays in the past.

The inaugural flight for the big brother to the Falcon 9 was originally set for 2013, but several delays have kept bumping the date. One of the main reasons for this was the state of the Falcon 9. SpaceX was focussed on Falcon 9’s landing capabilities, and put increased manpower into that project, at the expense of the Falcon Heavy. But now that SpaceX has successfully landed the Falcon 9, the company seems poised to meet the November launch date for the Heavy.

One of the main attractions to the Falcon Heavy is its ability to deliver larger payloads to geostationary orbit (GEO). This is the orbit occupied by communications and weather satellites. These types of satellites, and the companies that build and operate them, are an important customer base for SpaceX. SpaceX claims that the Falcon Heavy will be able to place payloads of 22,200 kg (48,940 lbs) to GEO. This trumps the Delta-4 Heavy (14,200 kg/31,350 lbs) and the Ariane5 (max. 10,500 kg/23,100 lbs.)

There’s a catch to these numbers, though. The Falcon Heavy will be able to deliver larger payloads to GEO, but it’ll do it at the expense of reusability. In order to recover the two side-boosters and central core stage for reuse, some fuel has to be held in reserve. Carrying that fuel and using it for recovery, rather than burning it to boost larger payloads, will reduce the payload for GEO to about 8,000 kg (17,637 lbs.) That’s significantly less than the Ariane 5, and the upcoming Ariane 6, which will both compete for customers with the Falcon Heavy.

The Falcon Heavy is essentially four Falcon 9 rockets configured together to create a larger rocket. Three Falcon 9 first stage boosters are combined to generate three times as much thrust at lift-off as a single Falcon 9. Since each Falcon 9 is actually made of 9 separate engines, the Falcon Heavy will actually have 27 separate engines powering its first stage. The second stage is another single Falcon 9 second-stage rocket, consisting of a single Merlin engine, which can be fired multiple times to place payloads in orbit.

The three main boosters for the Falcon Heavy will all be built this summer, with construction of one already underway. Once complete, they will be transported from their construction facility in California to the testing facility in Texas. After that, they will be transported to Cape Canaveral.

Once at Cape Canaveral, the launch preparations will have all of the 27 engines in the first stage fired together in a hold-down firing, which will give SpaceX its first look at how all three main boosters operate together.

Eventually, if everything goes well, the Falcon Heavy will launch from Pad 39A at Cape Canaveral. Pad 39A is the site of the last Shuttle launches, and is now leased from NASA by SpaceX.

The Falcon Heavy will be the most powerful rocket around, once it’s operational. The versatility to deliver huge payloads to orbit, or to keep its costs down by recovering boosters, will make its first flight a huge achievement, whether or not it does deliver a satellite into orbit on its first launch.

May 6, 2016May 6, 2016 by Ken Kremer

SpaceX Scores Double Whammy with Nighttime Delivery of Japanese Comsat to Orbit and 2nd Successful Ocean Landing

Streak shot of SpaceX Falcon 9 delivering JCSAT-14 Japanese communications satellite to orbit after blastoff on May 6, 2016 at 1:21 a.m. EDT from Space Launch Complex 40 at Cape Canaveral Air Force Station, Fl. Credit: SpaceX

SpaceX scored a double whammy of successes this morning, May 6, following the stunning nighttime launch of a Japanese comsat streaking to orbit on the firm’s Falcon 9 rocket and nailing the breathtaking touchdown of the spent first stage just minutes later – furthering the goal of rocket reusability

Under clear Florida starlight, the upgraded SpaceX Falcon 9 soared to orbit on 1.5 million pounds of thrust on a mission carrying the JCSAT-14 commercial communications satellite, following an on time liftoff at 1:21 a.m. EDT this morning from Space Launch Complex 40 at Cape Canaveral Air Force Station, Fl.

The spectacular launch and dramatic landing were both broadcast in real time on a live launch webcast from SpaceX.

Launch of SpaceX Falcon 9 carrying JCSAT-14 Japanese communications satellite to orbit on May 6, 2016 at 1:21 a.m. EDT from Space Launch Complex 40 at Cape Canaveral Air Force Station, Fl. Credit: Dawn Leek Taylor

Today’s Falcon launch was the 4th this year for SpaceX and took place less than 4 weeks after the last launch (on an ISS cargo mission for NASA) and sea based barge landing.

Barely nine minutes after liftoff the 156 foot tall Falcon 9 first stage carried out a propulsive soft landing on an ocean going platform located some 400 miles off the east coast of Florida.

“First stage landing on drone ship in Atlantic confirmed,” said a SpaceX official during the webcast, which showed a glowing body approaching the horizon.

“Woohoo!!” tweeted SpaceX CEO and billionaire founder Elon Musk.

This marked the second successful landing at sea for SpaceX following the prior history making touchdown success last month.

“May need to increase size of rocket storage hangar,” tweeted Musk.

“Yeah, this was a three engine landing burn, so triple deceleration of last flight. That’s important to minimize gravity losses.”

Falcon 9 first stage touchdown on ocean platform after successful JCSAT-14 launch on May 6, 2016 from Cape Canaveral Air Force Station, Fl. Credit: SpaceX

The commercial SpaceX launch lofted the JCSAT-14 Japanese communications satellite to a Geostationary Transfer Orbit (GTO) for SKY Perfect JSAT – a leading satellite operator in the Asia – Pacific region.

After a brief reignition of the second stage, the spacecraft successfully separated from the upper stage and was deployed some 32 minutes after liftoff – as seen via the live SpaceX webcast.

“The Falcon 9 second stage delivered JCSAT-14 to a Geosynchronous Transfer Orbit,” said SpaceX.

Via a fleet of 15 satellites, Tokyo, Japan based SKY Perfect JSAT provides high quality satellite communications to its customers.

The JCSAT-14 communications satellite was designed and manufactured by Space Systems/Loral for SKY Perfect JSAT Corporation.

It will succeed and replace the JCSAT-2A satellite currently providing coverage to Asia, Russia, Oceania and the Pacific Islands.

JCSAT-14 is equipped with C-band and Ku-Band transponders that will extend JCSAT-2A’s geographical footprint across the Asia-Pacific region.

The JCSAT-14 communications satellite from SKY Perfect JSAT Corporation stands ready for encapsulation in the Falcon 9 payload fairing. Credit: SpaceX

The Falcon 9 soft landed on the “Of Course I Still Love You” drone ship positioned some 400 miles (650 kilometers) off shore in the Atlantic Ocean.

Prior to the launch, SpaceX officials had rated the chances of a successful landing as “unlikely” due to “this launch mission’s GTO destination, the first stage will be subject to extreme velocities and re-entry heating.”

“Rocket reentry is a lot faster and hotter than last time, so odds of making it are maybe even, but we should learn a lot either way,” said Musk.

Nevertheless, despite those difficulties, the landing turned out to be another stunning success for SpaceX CEO Elon Musk’s vision of radically slashing the cost of sending rocket to space by recovering the boosters and eventually reusing them.

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

Ken Kremer