Kennedy Space Center Archives

March 26, 2017March 26, 2017 by Ken Kremer

NASA Test Fires New Engine Controlling ‘Brain’ for First SLS MegaRocket Mission

NASA engineers conduct a test of the first RS-25 engine controller that will be used on an actual Space Launch System flight on the A-2 Test Stand at Stennis Space Center on March 23, 2017. The RS-25 engine, with the flight controller, was test fired for a full-duration 500 seconds. Credits: NASA/SSC

Engineers carried out a critical hot fire engine test firing with the first new engine controlling ‘brain’ that will command the shuttle-era liquid fueled engines powering the inaugural mission of NASA’s new Space Launch System (SLS) megarocket.

The first integrated SLS launch combining the SLS-1 rocket and Orion EM-1 deep space crew capsule could liftoff as soon as late 2018 on a mission around the Moon and back.

The full duration static fire test involved an RS-25 engine integrated with the first engine controller flight unit that will actually fly on the maiden SLS launch and took place on Thursday, March 23 at the agency’s Stennis Space Center in Bay St. Louis, Mississippi.

The 500 second-long test firing was conducted with the engine controller flight unit installed on RS-25 development engine no. 0528 on the A-2 Test Stand at Stennis.

The RS-25 engine controller is the ‘brain’ that commands the RS-25 engine and communicates between the engine and the SLS rocket. It is about the size of a dorm refrigerator.

RS-25 new engine controller. Credit: NASA/SSC

The newly developed engine controller is a modern version from the RS-25 controller that helped propel all 135 space shuttle missions to space.

“This an important – and exciting – step in our return to deep space missions,” Stennis Director Rick Gilbrech said. “With every test of flight hardware, we get closer and closer to launching humans deeper into space than we ever have traveled before.”

The modernized RS-25 engine controller was funded by NASA and created in a collaborative effort of engineers from NASA, RS-25 prime contractor Aerojet Rocketdyne of Sacramento, California, and subcontractor Honeywell of Clearwater, Florida.

“The controller manages the engine by regulating the thrust and fuel mixture ratio and monitors the engine’s health and status – much like the computer in your car,” say NASA officials.

“The controller then communicates the performance specifications programmed into the controller and monitors engine conditions to ensure they are being met, controlling such factors as propellant mixture ratio and thrust level.”

A quartet of RS-25 engines, leftover from the space shuttle era and repeatedly reused, will be installed at the base of the core stage to power the SLS at liftoff, along with a pair of extended solid rocket boosters.

The four RS-25 core stage engine will provide a combined 2 million pounds of thrust at liftoff.

In addition to being commanded by the new engine controller, the engines are being upgraded in multiple ways for SLS. For example they will operate at a higher thrust level and under different operating conditions compared to shuttle times.

To achieve the higher thrust level required, the RS-25 engines must fire at 109 percent of capability for SLS compared to operating at 104.5 percent of power level capability for shuttle flights.

The RS-25 engines “also will operate with colder liquid oxygen and engine compartment temperatures, higher propellant pressure and greater exhaust nozzle heating.”
SLS will be the world’s most powerful rocket and send astronauts on journeys into deep space, further than human have ever travelled before.

For SLS-1 the mammoth booster will launch 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.

The next step is evaluating the engine firing test results, confirming that all test objectives were met and certifying that the engine controller can be removed from the RS-25 development engine and then be installed on one of four flight engines that will help power SLS-1.

During 2017, two additional engine controllers for SLS-1 will be tested on the same development engine at Stennis and then be installed on flight engines after certification.

Finally, “the fourth controller will be tested when NASA tests the entire core stage during a “green run” on the B-2 Test Stand at Stennis. That testing will involve installing the core stage on the stand and firing its four RS-25 flight engines simultaneously, as during a mission launch,” says NASA.

Numerous RS-25 engine tests have been conducted at Stennis over more than 4 decades to certify them as flight worthy for the human rated shuttle and SLS rockets.

NASA engineers successfully conducted a development test of the RS-25 rocket engine Thursday, Aug. 18, 2016 at NASA’s Stennis Space Center near Bay St. Louis, Miss. The RS-25 will help power the core stage of the agency’s new Space Launch System (SLS) rocket for the journey to Mars. Credit: Ken Kremer/kenkremer.com

Although NASA is still targeting SLS-1 for launch in Fall 2018 on an uncrewed mission, the agency is currently conducting a high level evaluation to determine whether the Orion EM-1 capsule can be upgraded in time to instead fly a human crewed mission with two astronauts before the end of 2019 – as I reported here.

The Orion EM-1 capsule is currently being manufactured at the Neil Armstrong Operations and Checkout Building at the Kennedy Space Center by prime contractor Lockheed Martin.

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

Aerojet Rocketdyne technicians inspect the engine controller that will be used for the first integrated flight of NASA’s Space Launch System and Orion in late 2018. The engine controller was installed on RS-25 development engine no. 0528 for testing at Stennis Space Center on the A-2 Test Stand on March 23, 2017. The RS-25 engine, with the flight controller, was test fired for a full-duration 500 seconds. Credits: NASA/SSC

March 24, 2017March 26, 2017 by Ken Kremer

Nighttime Delta IV Blastoff Powers Military Comsat to Orbit for U.S. Allies: Photo/Video Gallery

Blastoff of ULA Delta IV rocket carrying the Wideband Global SATCOM (WGS-9) comsat to orbit for the U.S. Air Force from Space Launch Complex-37 on Cape Canaveral Air Force Station, Fl, on Mar. 18, 2017. Credit: Ken Kremer/kenkremer.com

CAPE CANAVERAL AIR FORCE STATION, FL – The second round of March Launch Madness continued with the thunderous nighttime blastoff of a ULA Delta IV rocket powering a super swift military communications satellite to orbit in a collaborative effort of U.S. Allies from North America, Europe and Asia and the U.S. Air Force.

The next generation Wideband Global SATCOM-9 (WGS-9) military comsat mission for the U.S. Force lifted off atop a United Launch Alliance (ULA) Delta IV from Space Launch Complex-37 (SLC-37) on Saturday, March 18 at 8:18 p.m. EDT at Cape Canaveral Air Force Station, Florida.

Check out this expanding gallery of spectacular launch photos and videos gathered from my space journalist colleagues, myself and spectators ringing the space coast under crystal clear early evening skies.

A key feature in this advanced Block II series WGS satellite is inclusion of the upgraded digital channelizer that nearly doubles the available bandwidth of earlier satellites in the series.

WGS-9 can filter and downlink up to 8.088 GHz of bandwidth compared to 4.410 GHz for earlier WGS satellites. It supports communications links in the X-band and Ka-band spectra.

ULA Delta IV rocket streaks to orbit carrying WGS-9 tactical communications satellite for the U.S. Air Force and international partners from Cape Canaveral Air Force Station, Fl, at 8:18 p.m. EDT on Mar. 18, 2017. Credit: Julian Leek

Note that Round 3 of March Launch Madness is tentatively slated for March 29 with the SpaceX liftoff of the first ever reused Falcon 9 first stage from historic pad 39 on NASA’s Kennedy Space Center.

The WGS-9 satellite was paid for by a six nation consortium that includes Canada, Denmark, Luxembourg, the Netherlands, New Zealand and the United States. It joins 8 earlier WGS satellites already in orbit.

The partnership was created back in 2012 when the ‘WGS-9 Memorandum of Understanding (MOU)’ was signed by Defense organizations of the six countries.

The WGS-9 MOU agreement to fund the satellite enabled the expansion of the WGS system with this additional satellite added to the existing WGS constellation.

“The agreement provides all signatories with assured access to global wideband satellite communications for military use,” according to the US Air Force.

Watch this launch video compilation from Jeff Seibert:

Video Caption: Launch of WGS-9 satellite continues USAF Breaking Barriers heritage. This ULA Delta 4 launch of the WGS-9 satellite on Mar 18, 2017 marks the start of the 70th anniversary of the United States Air Force. That was also the year that U.S. Air Force Captain Chuck Yeager broke the sound barrier. Credit: Jeff Seibert

Watch this launch video from Ken Kremer:

Video Caption: ULA/USAF Delta IV launch of Wideband Global SATCOM (WGS-9) from pad 37 on Cape Canaveral Air Force Station, Fl, on 18 Mar. 2017 – as seen in this remote video taken at the pad. Credit: Ken Kremer/kenkremer.com

WGS-9 was built by Boeing.

The 217 foot tall Delta IV Medium+ rocket launched in the 5,4 configuration with a 5 meter diameter payload fairing that stands 47 feet tall, and 4 solid rocket boosters to augment the first stage thrust of the single common core booster.

The payload fairing was emblazoned with decals commemorating the 70th anniversary of the USAF, as well as Air Force, mission and ULA logos.

A United Launch Alliance (ULA) Delta IV rocket carrying the Wideband Global SATCOM (WGS-9) mission for the U.S. Air Force launches at 8:18 p.m. EDT on Mar. 18, 2017 from Space Launch Complex-37 on Cape Canaveral Air Force Station, Fl – reflecting beautifully in the pad pond. Credit: Ken Kremer/kenkremer.com

Orbital ATK manufactures the four solid rocket motors. The Delta IV common booster core was powered by an RS-68A liquid hydrogen/liquid oxygen engine producing 705,250 pounds of thrust at sea level.
A single RL10B-2 liquid hydrogen/liquid oxygen engine powered the second stage, known as the Delta Cryogenic Second Stage (DCSS).

The booster and upper stage engines are both built by Aerojet Rocketdyne. ULA constructed the Delta IV Medium+ (5,4) launch vehicle in Decatur, Alabama.

Launch of USAF WGS-8 milsatcom on ULA Delta IV rocket from pad 37 on Cape Canaveral Air Force Station, Fl, on Mar. 18, 2017. Credit: Julian Leek

The DCSS will also serve as the upper stage for the maiden launch of NASA heavy lift SLS booster on the SLS-1 launch slated for late 2018. That DCSS/SLS-1 upper stage just arrived at the Cape last week – as I witnessed and reported here.

Saturday’s launch marks ULA’s 3rd launch in 2017 and the 118th successful launch since the company was formed in December 2006 as a joint venture between Boeing and Lockheed Martin.

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

Ken Kremer

Launch of USAF WGS-8 milsatcom on ULA Delta IV rocket from pad 37 on Cape Canaveral Air Force Station, Fl, on Mar. 18, 2017. Dawn Leek Taylor

Two AF Generals and a Delta! Major General David D. Thompson, Vice Commander Air Force Space Command, Peterson Air Force Base, CO, and Brig. Gen. Wayne R. Monteith, Commander of the 45th Space Wing Commander and Eastern Range Director at Patrick Air Force Base, Fla, celebrate successful Wideband Global SATCOM (WGS-9) launch for the U.S. Air Force on ULA Delta IV from Cape Canaveral Air Force Station, Fl, on Mar. 18, 2017, with the media gaggle on base post launch with Delta pad 37 in background right. Credit: Ken Kremer/kenkremer.com

Liftoff of ULA Delta IV with WGS-9 milsatcom on Mar 18, 2017 as seen soaring above the pool at the Quality Inn Kennedy Space Center in Titusville, FL. Credit: Wesley Baskin

Eerie view of ULA Delta IV blastoff of WGS-9 milsatcom on Mar 18, 2017 as seen soaring over residential area in Titusville, FL. Credit: Melissa Bayles

ULA Delta IV rocket prior to blastoff with the Wideband Global SATCOM (WGS-9) mission for the U.S. Air Force from Cape Canaveral Air Force Station, Fl, on Mar. 18, 2017. Credit: Ken Kremer/kenkremer.com

ULA Delta IV blastoff of WGS-9 satcom on Mar 18, 2017 from Cape Canaveral AFS with long vapor exhaust trail as seen roaring over residential area in Titusville, FL. Credit: Ashley Carrillo

March 20, 2017March 20, 2017 by Ken Kremer

SpaceX Dragon Splashes Down in Pacific with Treasure Trove of Space Station Science

The SpaceX Dragon CRS-10 spacecraft is pictured seconds before splashing down in the Pacific Ocean on Mar. 19, 2017 after departing the International Space Station (ISS). Credit: SpaceX

KENNEDY SPACE CENTER, FL – SpaceX’s tenth contracted resupply mission to the International Space Station came to a safe conclusion with a splashdown of the Dragon spacecraft in the Pacific Ocean Sunday and successfully returned a treasure trove of more than two tons of precious science experiments and research samples from the space station.

Researchers on Earth are eagerly awaiting the science data and samples in order to carry out high powered laboratory analysis that will eventually yield the fruits of the hard won labor – years in the making.

The Dragon CRS-10 cargo freighter departed the International Space Station (ISS) Sunday morning after Expedition 50 astronauts Thomas Pesquet of ESA (European Space Agency) and Shane Kimbrough of NASA released the spacecraft from the grip of the station’s 57.7-foot-long(17.6-meter) Canadian-built Canadarm2 robotic arm as planned at 5:11 a.m. EDT, March 19.

After carefully maneuvering away from the orbiting outpost and six person international crew at an altitude of appox. 250 miles (400 km), Dragon eased away to a safe distance.

SpaceX’s Dragon CRS-10 cargo vehicle is attached to the International Space Station on Feb 23, 2017 after early morning capture by astronauts Shane Kimbrough and Thomas Pesquet using the robotic arm and subsequent berthing at Earth facing port on the Harmony module. It will stay for a month. Credit: NASA

The vessel then fired its braking thrusters a few hours later to initiate the reentry burn that would set the craft on course for a fiery plummet through the Earth’s atmosphere.

Some five and a half hours later the spaceship carried out a parachute assisted splashdown in the Pacific Ocean at 10:46 a.m. EDT, about 200 miles southwest of Long Beach, California.

The highest priority research and technology cargo will be removed from Dragon immediately and returned to NASA.

SpaceX CRS-10 Dragon supply ship launched on Feb. 19, 2017 from NASA’s Kennedy Space Center in Florida successfully arrives at the International Space Station on Feb. 23, 2017 for capture and berthing at station port on the Harmony module. Credit: NASA

The rest will travel back to port and be prepared for a return trip to SpaceX’s test facility in McGregor, Texas, where the remaining scientific samples, research experiments and technology gear and hardware will be unloaded for NASA.

Dragon had spent nearly a month berthed at the Earth-facing port on the station’s Harmony module, since arriving on Feb 23.

Dragon begun its space voyage after it was launched from the Kennedy Space Center (KSC) on Sunday, Feb. 19 on the first Falcon 9 rocket ever to blast off from historic launch pad 39A in a blaze of glory – as I reported here.

Historic maiden blastoff of SpaceX Falcon 9 rocket from Launch Complex 39A at the Kennedy Space Center) at 9:38 a.m. EDT on Feb 19, 2017, on Dragon CRS-10 resupply mission to the International Space Station (ISS) for NASA. Credit: Ken Kremer/kenkremer.com

At liftoff, the Dragon CRS-10 space freighter was carrying more than 5500 pounds of equipment, gear, food, crew supplies, hardware and NASA’s Stratospheric Aerosol Gas Experiment III (SAGE III) ozone mapping science payload to the low Earth orbiting station in support of the Expedition 50 and 51 crew members.

After a four day chase, Dragon was captured and attached to the station using the Canadian arm on Feb 23 by the same two astronauts who released it on Sunday.

The research supplies and equipment brought up by Dragon will support over 250 scientific investigations to advance knowledge about the medical, psychological and biomedical challenges astronauts face during long-duration spaceflight.

SAGE III will measure stratospheric ozone, aerosols, and other trace gases by locking onto the sun or moon and scanning a thin profile of the atmosphere. It is one of NASA’s longest running earth science programs.

The LIS lightning mapper will measure the amount, rate and energy of lightning as it strikes around the world from the altitude of the ISS as it orbits Earth. Its data will complement that from the recently orbited GLM lighting mapper lofted to geosynchronous aboard the NASA/NOAA GOES-R spacecraft instrument.

NASA’s RAVEN experiment will test autonomous docking technologies for spacecraft.

SAGE III and RAVEN were stowed in the Dragon’s unpressurized truck. Astronauts plucked them out of the trunk using the robotic arm and attached them to specified locations on the stations exterior to carry out their objectives.

For the return trip to Earth, the astronaut crew loaded Dragon with more than 5,400 pounds of NASA cargo, and science and technology demonstration samples gathered and collected by the stations crewmembers.

“A variety of technological and biological studies are returning in Dragon. The Microgravity Expanded Stem Cells investigation had crew members observe cell growth and other characteristics in microgravity,” said NASA.

“This information will provide insight into how human cancers start and spread, which aids in the development of prevention and treatment plans. Results from this investigation could lead to the treatment of disease and injury in space, as well as provide a way to improve stem cell production for human therapy on Earth.”

“Samples from the Tissue Regeneration-Bone Defect study, a U.S. National Laboratory investigation sponsored by the Center for the Advancement of Science in Space (CASIS) and the U.S. Army Medical Research and Materiel Command, studied what prevents vertebrates such as rodents and humans from re-growing lost bone and tissue, and how microgravity conditions affect the process. Results will provide a new understanding of the biological reasons behind a human’s inability to grow a lost limb at the wound site, and could lead to new treatment options for the more than 30 percent of the patient population who do not respond to current options for chronic non-healing wounds.”

Dragon departed in order to make way for the arrival of the next cargo ship.

The ‘SS John Glenn’ Cygnus cargo freighter built by Orbital Sciences is due to lift off no earlier than March 27 on a United Launch Alliance (ULA) Atlas V rocket from Cape Canaveral Air Force Station.

The Orbital ATK Cygnus spacecraft named for Sen. John Glenn, one of NASA’s original seven astronauts, stands inside the Payload Hazardous Servicing Facility at NASA’s Kennedy Space Center in Florida behind a sign commemorating Glenn on March 9, 2017. Launch slated for March 21 on a ULA Atlas V. Credit: Ken Kremer/Kenkremer.com

Watch for Ken’s onsite launch and 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

March 16, 2017March 16, 2017 by Ken Kremer

Flawless SpaceX Falcon 9 Takes Rousing Night Flight Delivery of EchoStar TV Sat to Orbit

SpaceX Falcon 9 rocket streaks to orbit in this long exposure photo taken in front of NASA’s countdown clock under moonlit skies at the Kennedy Space Center in Florida on March 16 at 2:00 a.m. EDT. Credit: Ken Kremer/Kenkremer.com

KENNEDY SPACE CENTER, FL – Under stellar moonlit Florida skies, a private SpaceX Falcon 9 took flight overnight and flawlessly delivered the commercial EchoStar 23 television satellite to geosynchronous orbit after high winds delayed the rockets roar to orbit by two days from Tuesday. Breaking News: Check back for updates

The post midnight spectacle thrilled spectators who braved the wee hours this morning and were richly rewarded with a rousing rush as the 229 foot tall Falcon 9 rocket thundered to life at 2:00 a.m. EDT Thursday, March 16 from historic Launch Complex 39A on NASA’s Kennedy Space Center and sped to orbit.

Rising on the power of 1.7 million pounds of liftoff thrust generated by nine Marlin 1D first stage engines, the two stage Falcon 9 rocket successfully delivered the commercial EchoStar 23 telecommunications satellite to a Geostationary Transfer Orbit (GTO) for EchoStar Corporation.

The satellite was deployed approximately 34 minutes after launch.

Thus began March Launch Madness !!

If all goes well, March features a triple header of launches with launch competitor and arch rival United Launch Alliance (ULA) planning a duo of nighttime blastoffs from their Delta and Atlas rocket families. The exact dates are in flux due to the earlier postponement of the SpaceX Falcon 9. They have been rescheduled for March 18 and 24 respectively.

The SpaceX Falcon 9 launches the EchoStar 23 telecomsat from historic Launch Complex 39A with countdown clock in foreground at NASA’s Kennedy Space Center as display shows liftoff progress to geosynchronous orbit after post midnight blastoff on March 16 at 2:oo a.m. EDT. Credit: Ken Kremer/Kenkremer.com

EchoStar 23 will be stationed over Brazil for direct to home television broadcasts and high speed voice, video and data communications to millions of customers for EchoStar.

It was designed and built by Space Systems Loral (SSL).

“EchoStar XXIII is a highly flexible, Ku-band broadcast satellite services (BSS) satellite with four main reflectors and multiple sub-reflectors supporting multiple mission profiles,” according to a description from EchoStar Corporation.

EchoStar XXIII will initially be deployed in geosynchronous orbit at 45° West. The Satellite End of Life (EOL) Power is 20 kilowatts (kW).

Blastoff of SpaceX Falcon 9 with EchoStar 23 TV satellite from Launch Complex 39A at NASA’s Kennedy Space Center in Florida on March 16 at 2:00 a.m. EDT. Photo from camera inside the pad perimeter. Credit: Ken Kremer/Kenkremer.com

The entire launch sequence was broadcast live on a SpaceX hosted webcast that began about 20 minutes before the revised liftoff time of 2:00 a.m. from the prelaunch countdown, blastoff and continued through the dramatic separation of the EchoStar 23 private payload from the second stage.

The EchoStar 23 launch counts as only the second Falcon 9 ever to blast off from pad 39A.

Liftoff of SpaceX Falcon 9 with EchoStar 23 TV satellite from pad 39A at the Kennedy Space Center in Florida on March 16 at 2:00 a.m. EDT. Credit: Julian Leek

SpaceX’s billionaire CEO Elon Musk leased historic pad 39A from NASA back in April 2014 for launches of the firms Falcon 9 and Falcon Heavy carrying both robotic vehicles as well as humans on missions to low Earth orbit, the Moon and ultimately the Red Planet.

Composite panoramic view of seaside Launch Complex 39A with SpaceX hangar and Falcon 9 rocket raised vertical to deliver the EchoStar 23 telecom satellite to geostationary orbit overnight March 16, 2017. Pad 39B at center. Credit: Ken Kremer/Kenkremer.com

The inaugural Falcon 9 blastoff successfully took place last month on Feb. 19, as I reported here.

However unlike most recent SpaceX missions, the legless Falcon 9 first stage will not be recovered via a pinpoint propulsive landing either on land or on a barge at sea.

SpaceX Falcon 9 rocket carrying EchoStar 23 telecomsat raised erect atop Launch Complex 39A at the Kennedy Space Center as seen from inside the pad on March 13, 2017 ahead of liftoff slated for 16 Mar 2017 at 1:35 a.m. Credit: Ken Kremer/Kenkremer.com

Because of the satellite delivery to GTO, there are insufficient fuel reserves to carry out the booster landing.

“SpaceX will not attempt to land Falcon 9’s first stage after launch due to mission requirements,” officials said.

Therefore the first stage is not outfitted with either landing legs or grid fins to maneuver it back to a touchdown.

SpaceX announced that this was the last launch of an expendable Falcon 9.

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

Ken Kremer

March 14, 2017March 16, 2017 by Ken Kremer

High Winds Scrub Legless SpaceX Falcon 9 Liftoff Reset to March 16 – Live Webcast

The countdown clock at NASA’s Kennedy Space Center shows the progress of the SpaceX Falcon launch attempt with the EchoStar 23 telecomsat from historic Launch Complex 39A after midnight March 14. Liftoff has been rescheduled for March 16 at 1:35 a.m. EDT. Credit: Ken Kremer/Kenkremer.com

KENNEDY SPACE CENTER, FL – High winds halted SpaceX’s early morning attempt to launch a legless Falcon 9 rocket and the EchoStar XXIII commercial communications satellite soon after midnight Tuesday, Mar. 14, from the Florida Space Coast amidst on and off rain showers and heavy cloud cover crisscrossing central Florida all afternoon Monday, Mar. 13 and into the overnight hours.

SpaceX then decided to reschedule the EchoStar 23 telecommunications satellite launch for post-midnight Thursday, March 16, at 1:35 a.m. EDT.

Tuesday’s launch scrub was called some 40 minutes prior to the scheduled opening of the two and a half hour long launch window at 1:34 a.m. EDT.

“Standing down due to high winds; working toward next available launch opportunity,” SpaceX tweeted just as engineers had started fueling the two stage rocket poised for blastoff from historic launch pad 39A from NASA’s Kennedy Space Center.

After further evaluating when to schedule a second attempt, SpaceX then stuck to their original plan of a 48 hour turnaround.

If all goes well, March features a triple header of launches with launch competitor and arch rival United Launch Alliance (ULA) planning a duo of nighttime blastoffs from their Delta and Atlas rocket families. The exact dates are in flux due to the postponement of the SpaceX Falcon 9. They had been slated for March 17 and 21 respectively.

Since continuing high winds have plagued the space coast region all day today and the weather is forecast to improve significant tomorrow, a two day delay to Thursday seemed rather prudent – solely from a weather standpoint.

“After standing down due to high winds, SpaceX is now targeting Thursday, March 16th for the EchoStar XXIII launch.” SpaceX officials announced via their website and social media.

“The launch window opens at 1:35 am ET and weather conditions are expected to be 90% favorable.”

The two and a half hour launch window closes at 4:05 a.m. EDT.

You can watch the launch live on a SpaceX dedicated webcast starting about 20 minutes prior to the 1:35 a.m. liftoff time.

The SpaceX webcast will be available starting at about 20 minutes before liftoff, at approximately 1:14 a.m. EDT.

Watch at: SpaceX.com/webcast

The two stage Falcon rocket will deliver the commercial EchoStar 23 telecommunications satellite to a Geostationary Transfer Orbit (GTO) for EchoStar Corporation.

The satellite will be deployed approximately 34 minutes after launch.

The EchoStar 23 launch counts as only the second Falcon 9 ever to blastoff from pad 39A – which SpaceX’s billionaire CEO Elon Musk leased from NASA back in April 2014.

The inaugural Falcon 9 blastoff successfully took place last month on Feb. 19, as I reported here.

The nighttime lunge to space should offer spectacular viewing. But unlike most recent SpaceX missions, the first stage will not be recovered via a pinpoint propulsive landing either on land or on a barge at sea.

Because of the satellite delivery to GTO, there are insufficient fuel reserves to carry out the booster landing.

“SpaceX will not attempt to land Falcon 9’s first stage after launch due to mission requirements,” officials said.

Therefore the first stage is not outfitted with either landing legs or grid fins to maneuver it back to a touchdown.

However, SpaceX has announced that this Falcon 9 will be the last expendable first stage.

Musk hopes to dramatically cut the cost of access to space by recovering and recycling the boosters for reuse with a new paying customer.

Indeed the SES-10 payload is already slated to fly on the first ‘flight proven’ rocket sometime in the next few weeks.

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

Ken Kremer

March 13, 2017March 14, 2017 by Ken Kremer

March Launch Madness: Triple Headed Space Spectacular Starts Overnight with SpaceX March 14 – Watch Live

KENNEDY SPACE CENTER, FL – It’s March Madness for Space fans worldwide! A triple header of space spectaculars starts overnight with a SpaceX Falcon 9 launching in the wee hours of Tuesday, March 14 from the Florida Space Coast.

Indeed a trio of launches is planned in the next week as launch competitor and arch rival United Launch Alliance (ULA) plans a duo of nighttime blastoffs from their Delta and Atlas rocket families – following closely on the heels of the SpaceX Falcon 9 launching a commercial telecommunications satellite.

Of course it’s all dependent on everything happening like clockwork!

And there is no guarantee of that given the unpredictable nature of the fast changing weather on the Florida Space Coast and unknown encounters with technical gremlins which have already plagued all 3 rockets this month.

Each liftoff has already been postponed by several days this month. And the rocket launch order has swapped positions.

At any rate, SpaceX is now the first on tap after midnight tonight on Tuesday, March 14.

The Delta IV and Atlas V will follow on March 17 and March 21 respectively – if all goes well.

So to paraphrase moon walker Buzz Aldrin;

‘Get Your Ass to the Florida Space Coast – Fast !’

The potential for a grand slam also exists at the very end of the month. But let’s get through at least the first launch of Falcon first.

SpaceX Falcon 9 rocket stands at launch pad 39a poised to liftoff with EchoStar 23 TV sat on the Kennedy Space Center ahead of liftoff slated for 14 Mar 2017 at 1:34 a.m. Credit: Julian Leek

Liftoff of the two stage SpaceX Falcon 9 carrying the EchoStar 23 telecommunications satellite is now slated for a post midnight spectacle next Tuesday, Mar. 14 from launch pad 39A on the Kennedy Space Center at the opening of the launch window at 1:34 a.m. EDT.

The two and a half hour launch window closes at 4:04 a.m. EDT.

You can watch the launch live on a SpaceX dedicated webcast starting about 20 minutes prior to the 1:34 a.m. liftoff time.

The SpaceX webcast will be available starting at about 20 minutes before liftoff, at approximately 1:14 a.m. EDT.

Watch at: SpaceX.com/webcast

Following a successful static fire test last week on Mar. 9 of the first stage boosters engines, the SpaceX Falcon 9 was integrated with the EchoStar 23 direct to home TV satellite and rolled back out to pad 39A

The Falcon 9 rocket was raised erect into launch position by the time I visited the pad this afternoon, Monday March 13, to set up my cameras.

The weather outlook is not great at this moment, with rain and thick clouds smothering the coastline and central Florida.

The planned Mar. 14 launch comes barely three weeks after the Falcon’s successful debut on Feb. 19 on the NASA contracted Dragon CRS-10 mission that delivered over 2.5 tons of cargo to the six person crew living and working aboard the International Space Station (ISS).

Raindrops keep falling on the lens, as inaugural SpaceX Falcon 9/Dragon disappears into the low hanging rain clouds at NASA’s Kennedy Space Center after liftoff from pad 39A on Feb. 19, 2017. Dragon CRS-10 resupply mission is delivering over 5000 pounds of science and supplies to the International Space Station (ISS) for NASA. Credit: Ken Kremer/kenkremer.com

Launch Complex 39A was repurposed by SpaceX from launching Shuttles to Falcons. It had lain dormant for launches for nearly six years since Space Shuttle Atlantis launched on the final shuttle mission STS 135 in July 2011.

SpaceX bilionaire CEO Elon Musk announced last week that he wants to launch a manned Moonshot from pad 39A by the end of next year using his triple barreled Falcon Heavy heavy lift rocket – derived from the Falcon 9.

The second launch of the trio on tap is a United Launch Alliance Delta 4 rocket carrying the WGS-9 high speed military communications satellite for the U.S. Air Force.

Liftoff of the ULA Delta is slated for March 17 from Space Launch Complex-37 at 7: 44 p.m. EDT.

A United Launch Alliance (ULA) Delta IV rocket carrying the WGS-8 mission lifts off from Space Launch Complex-37 at 6:53 p.m EDT on Dec. 7, 2016 from Cape Canaveral Air Force Station, Fla. Credit: Ken Kremer/kenkremer.com

The S.S. John Glenn is scheduled to as the Orbital ATK Cygnus OA-7 spacecraft for NASA on a United Launch Alliance (ULA) Atlas V rocket launch no earlier than March 21 from Space launch Complex-41 (SLC-41) on Cape Canaveral Air Force Station, Florida.

Orbital ATK Cygnus OA-7 spacecraft named the SS John Glenn for Original 7 Mercury astronaut and Sen. John Glenn, undergoes processing inside the Payload Hazardous Servicing Facility at NASA’s Kennedy Space Center in Florida on March 9, 2017 for launch slated for March 21 on a ULA Atlas V. Credit: Ken Kremer/Kenkremer.com

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

Ken Kremer

SpaceX Falcon 9 EchoStar 23 mission patch. Credit: SpaceX

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Learn more about SpaceX EchoStar 23 and CRS-10 launch to ISS, ULA SBIRS GEO 3 launch, EchoStar launch GOES-R launch, Heroes and Legends at KSCVC, OSIRIS-REx, InSight Mars lander, ULA, SpaceX and Orbital ATK missions, Juno at Jupiter, SpaceX AMOS-6, 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 at Kennedy Space Center Quality Inn, Titusville, FL:

Mar 13-15: “SpaceX EchoStar 23, CRS-10 launch to ISS, ULA Atlas SBIRS GEO 3 launch, EchoStar 19 comsat launch, GOES-R weather satellite launch, OSIRIS-Rex, SpaceX and Orbital ATK missions to the ISS, 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

SpaceX conducts successful static hot fire test of Falcon 9 booster atop Launch Complex 39A at the Kennedy Space Center on Mar 9, 2017 as seen from Space View Park, Titusville, FL. Liftoff with EchoStar 23 comsat is planned for 14 March 2017. Credit: Ken Kremer/Kenkremer.com

March 11, 2017March 14, 2017 by Ken Kremer

Next Cygnus Cargo Ship Christened the SS John Glenn to Honor First American in Orbit

KENNEDY SPACE CENTER, FL – The next Cygnus cargo ship launching to the International Space Station (ISS) has been christened the ‘S.S. John Glenn’ to honor legendary NASA astronaut John Glenn – the first American to orbit the Earth back in February 1962.

John Glenn was selected as one of NASA’s original seven Mercury astronauts chosen at the dawn of the space age in 1959. He recently passed away on December 8, 2016 at age 95.

The naming announcement was made by spacecraft builder Orbital ATK during a ceremony with the ‘S.S. John Glenn’, held inside the Kennedy Space Center (KSC) clean room facility where the cargo freighter is in the final stages of flight processing – and attended by media including Universe Today on Thursday, March 9.

“It is my humble duty and our great honor to name this spacecraft the S.S. John Glenn,” said Frank DeMauro, vice president and general manager of Orbital ATK’s Advanced Programs division, during the clean room ceremony in the inside the Payload Hazardous Servicing Facility high bay at NASA’s Kennedy Space Center in Florida.

The next Orbital ATK Cygnus supply ship was christened the SS John Glenn in honor of Sen. John Glenn, one of NASA’s original seven astronauts as it stands inside the Payload Hazardous Servicing Facility at NASA’s Kennedy Space Center on March 9, 2017. Launch slated for March 21 on a ULA Atlas V. Credit: Ken Kremer/Kenkremer.com

The S.S. John Glenn is scheduled to liftoff as the Orbital ATK Cygnus OA-7 spacecraft for NASA on a United Launch Alliance (ULA) Atlas V rocket launch no earlier than March 21 from Space launch Complex-41 (SLC-41) on Cape Canaveral Air Force Station, Florida.

The space station resupply mission dubbed Cygnus OA-7 is dedicated to Glenn and his landmark achievement as the first American to orbit the Earth on Feb. 20, 1962 and his life promoting science, human spaceflight and education.

“John Glenn was probably responsible for more students studying math and science and being interested in space than anyone,” said former astronaut Brian Duffy, Orbital ATK’s vice president of Exploration Systems, during the clean room ceremony on March 9.

“When he flew into space in 1962, there was not a child then who didn’t know his name. He’s the one that opened up space for all of us.”

The Orbital ATK Cygnus OA-7 supply ship named in honor of Sen. John Glenn, one of NASA’s original seven astronauts stands inside the Payload Hazardous Servicing Facility at KSC. Launch slated for March 21 on a ULA Atlas V. Credit: Julian Leek

Glenn’s 3 orbit mission played a pivotal role in the space race with the Soviet Union at the height of the Cold War era.

“He has paved the way for so many people to follow in his footsteps,” said DeMauro.

All of Orbital ATK’s Cygnus freighters have been named after deceased American astronauts.

Glenn is probably America’s most famous astronaut in addition to Neil Armstrong, the first man to walk on the moon during Apollo 11 in 1969.

John Glenn went on to become a distinguished U.S. Senator from his home state of Ohio on 1974. He served for 24 years during 4 terms.

He later flew a second mission to space aboard the Space Shuttle Discovery in 1998 as part of the STS-95 crew at age 77. Glenn remains the oldest person ever to fly in space.

“Glenn paved the way for America’s space program, from moon missions, to the space shuttle and the International Space Station. His commitment to America’s human space flight program and his distinguished military and political career make him an ideal honoree for the OA-7 mission,” Orbital ATK said in a statement.

“The OA-7 mission is using the Enhanced Cygnus Pressurized Cargo Module (PCM) to deliver cargo to the International Space Station,” said DeMauro.

Cygnus will carry 7,700 pounds (3500 kg) of cargo to the station with a total volumetric capacity of 27 cubic meters.

“All these teams have worked extremely hard to get this mission to this point and we are looking forward to a great launch.”

Orbital ATK Cygnus OA-7 supply ship named the SS John Glenn undergoes processing inside the Payload Hazardous Servicing Facility at KSC on March 9, 2017. Launch slated for March 21 on a ULA Atlas V. Credit: Ken Kremer/Kenkremer.com

This is the third Cygnus to launch on an Atlas V rocket from the Cape. The last one launched a year ago on March 24, 2016 during the OA-6 mission. The first one launched in December 2015 during the OA-4 mission.

“We’re building the bridge to history with these missions,” said Vernon Thorp, ULA’s program manager for Commercial Missions.

“Every mission is fantastic and every mission is unique. At the end of the day every one of these missions is critical.”

The other Cygnus spacecraft have launched on the Orbital ATK commercial Antares rocket from NASA Wallops Flight Facility on Virginia’s eastern shore.

A United Launch Alliance (ULA) Atlas V rocket carrying the Orbital ATK Cygnus 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

Overall this is Orbital ATK’s seventh commercial resupply services mission (CRS) to the space station under contract to NASA.

OA-7 also counts as NASA’s second supply mission of the year to the station following last month’s launch of the SpaceX Dragon CRS-10 capsule on Feb. 19 and which is currently berthed to the station at a Earth facing port on the Harmony module.

The Cygnus OA-8 mission will launch again from NASA Wallops in the summer of 2017, DeMauro told me.

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

Ken Kremer

Posing with the newly christened SS John Glenn for the Cygnus OA-7 resupply mission to the ISS are Vern Thorp, United Launch Alliance Program program manager for Commercial Missions, Ken Kremer, Universe Today and Frank DeMauro, Orbital ATK vice president and general manager of Orbital ATK’s Advanced Programs division inside the Payload Hazardous Servicing Facility cleanroom at NASA’s Kennedy Space Center on March 9, 2017. Credit: Ken Kremer/Kenkremer.com

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March 9, 2017March 10, 2017 by Ken Kremer

SpaceX Conducts Successful Static Fire Test Permitting Post Midnight Spectacle with EchoStar 23 Comsat on March 14

SPACE VIEW PARK/KENNEDY SPACE CENTER, FL – After a pair of back to back postponements presumably due to technical gremlins, the third time proved to be the charm at last as SpaceX engineers carried out a successful engine test of the Falcon 9 first stage this evening (Mar. 9) atop historic pad 39 at the Kennedy Space Center in Florida.

The brief test lasting about 3 seconds took place at 6 p.m. this evening, with an exciting eruption of smoke and ash into the air during the serene waning sunlight as I witnessed from Space View Park in Titusville, FL – which is a great place to watch launches from, offering an unobstructed view across the inland waterway.

This critical engine test opens the door to what will be only the second blastoff of the SpaceX commercial Falcon 9 rocket from seaside Launch Complex 39A at NASA’s Kennedy Space Center in Florida.

Liftoff of the Falcon 9 carrying the EchoStar 23 telecommunications satellite is now slated for a post midnight spectacle next Tuesday, Mar. 14 from pad 39A at the opening of the launch window at 1:34 a.m. EDT.

The two and a half hour launch window closes at 4:04 a.m. EDT.

The delayed completion of the static fire test resulted in a two day launch slip from March 12 to March 14 in order to complete all the prelaunch processing.

SpaceX Falcon 9 rocket minus EchoStar 23 comsat stands erect atop Launch Complex 39-A at the Kennedy Space Center as seen from Playalinda Beach, Fl, prior to static fire test on 9 Mar. 2017. This is only the second rocket to stand on pad 39A since the retirement of NASA’s Space Shuttles in July 2011. Liftoff is slated for 14 Mar 2017. Credit: Ken Kremer/Kenkremer.com

“Following today’s static fire test, SpaceX is targeting the launch of the EchoStar XXIII satellite from Launch Complex 39A (LC-39A) at Kennedy Space Center in Florida on Tuesday, Mar. 14, SpaceX confirmed in a statement soon after completion of the test.

“SpaceX’s Falcon 9 rocket will deliver the satellite to a Geostationary Transfer Orbit (GTO).”

The EchoStar 23 launch counts as only the second Falcon 9 ever to blastoff from pad 39A- which SpaceX’s billionaire CEO Elon Musk leased from NASA back in April 2014.

The nighttime lunge to space should offer spectacular viewing. But unlike most recent SpaceX missions, this Falcon will be the last expendable first stage. It is not outfitted with landing legs or grid fins to maneuver it back to a touchdown.

Watch this video of the March 9 static fire test from colleague Jeff Seibert:

Video Caption: Falcon 9 static fire test on Pad 39A on March 9, 2017. This is the second Falcon 9 static fire test on Pad 39A in preparation for the launch of the EchoStar-23 satellite. Credit: Jeff Seibert

Today’s engine test was carried out absent the expensive satellite payload bolted on top, to keep it safely stored away in case of a repeat of the catastrophic Falcon 9/Amos-6 pad explosion last September at pad 40 during a similar test that destroyed both the rocket and payload and caused extensive damage to the pad infrastructure.

If all goes well, the EchoStar 23 launch will showcase that SpaceX is picking up the pace of space launches and recovering from the Amos-6 disaster.

During today’s static fire test, the rocket’s first and second stages are fueled with liquid oxygen and RP-1 propellants like an actual launch and a simulated countdown is carried out to the point of a brief engine ignition.

The hot fire test generated a huge plume of smoke exhausting out the north side of the flame trench of Launch Complex 39A at approximately 6:00 p.m. EST, Mar. 9. at the opening of a 6 hour long test window.

The hold down engine test with the erected rocket involved the ignition of all nine Merlin 1D first stage engines generating some 1.7 million pounds of thrust at pad 39A – which has been repurposed from its days as a shuttle launch pad.

The Merlin 1D engines fired for about 3 seconds while the two stage rocket was restrained on the pad.

The smoke cloud soon dissipated and within 5 minutes there was barely a trace of what we shall soon see next Tuesday – if all goes well with launch processing and the ever changing sunshine state weather.

Titusville offers a prime viewing location for anyone interested in traveling to the Florida Space Coast to see this Falcon 9 launch in person.

SpaceX Falcon 9 rocket minus EchoStar 23 comsat stands erect atop Launch Complex 39A at the Kennedy Space Center as seen from the press site prior to static fire test on 9 Mar. 2017. Only the top of the rocket is visible behind the historic shuttle RSS structure. This is only the second rocket to stand on pad 39A since the retirement of NASA’s Space Shuttles in July 2011. Liftoff is slated for 14 Mar 2017. Credit: Ken Kremer/Kenkremer.com

The static fire test is routinely carried out by SpaceX and confirms that both the first stage engines and the rocket are suited for liftoff.

The rocket – minus the EchoStar 23 payload – had been rolled out of the SpaceX processing hangar at the perimeter fence several days ago and then up the incline to the top of pad 39A using a newly built dedicated transporter-erector.

With the successful completion of the static fire test, the booster will be rolled back to the big processing hangar and EchoStar 23 encapsulated inside the payload fairing will be integrated on top.

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

Ken Kremer

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Mar 10, 11, 13-15: “SpaceX EchoStar 23, CRS-10 launch to ISS, ULA Atlas SBIRS GEO 3 launch, EchoStar 19 comsat launch, GOES-R weather satellite launch, OSIRIS-Rex, SpaceX and Orbital ATK missions to the ISS, 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

SpaceX Falcon 9 rocket minus EchoStar 23 comsat sits horizontal atop Launch Complex 39A at the Kennedy Space Center as seen from Playalinda Beach, Fl, prior to static fire test on 9 Mar. 2017, as technicians process the rocket. This is only the second rocket to stand on pad 39A since the retirement of NASA’s Space Shuttles in July 2011. Liftoff is slated for 14 Mar 2017. Credit: Ken Kremer/Kenkremer.com

March 8, 2017March 9, 2017 by Ken Kremer

1st SLS 2nd Stage Arrives at Cape for NASA’s Orion Megarocket Moon Launch in 2018

Composite view of the interim cryogenic propulsion stage (ICPS) for first flight of NASA's Space Launch System (SLS) rocket at United Launch Alliance manufacturing facility in Decatur, Alabama in December 2016 (left) and arrival of ICPS in a canister aboard the firm’s Delta Mariner barge on March 7, 2017 (right). Credits: ULA (left) and Ken Kremer/kenkremer.com (right)

PORT CANAVERAL – Bit by bit, piece by piece, the first of NASA’s SLS megarockets designed to propel American astronauts on deep space missions back to the Moon and beyond to Mars is at last coming together on the Florida Space Coast. And the first big integrated piece of actual flight hardware – the powerful second stage named the Interim Cryogenic Propulsion Stage (ICPS) – has just arrived by way of barge today (Mar. 7) at Port Canaveral, Fl.

The ICPS will propel NASA’s new Orion crew capsule on its maiden uncrewed mission around the Moon – currently slated for blastoff on the inaugural SLS monster rocket on the Exploration Mission-1 (EM-1) mission late next year.

SLS-1/Orion EM-1 will launch from pad 39B at NASA’s Kennedy Space Center in late 2018. The SLS will be the most powerful rocket in world history.

NASA is currently evaluating whether to add a crew of 2 astronauts to the SLS-1 launch which would result in postponing the inaugural liftoff into 2019 – as I reported here.

The interim cryogenic propulsion stage (ICPS) for first flight of NASA’s Space Launch System (SLS) rocket arrived at Port Canaveral, Florida on March 7, 2017 loaded inside a shipping canister (right) aboard the ULA Delta Mariner barge that set sail from Decatur, Alabama a week ago. The ICPS shared the shipping voyage along with a ULA Delta IV first stage rocket core seen at left. Credit: Ken Kremer/kenkremer.com

The SLS upper stage – designed and built by United Launch Alliance (ULA) and Boeing – arrived safely by way of the specially-designed ship called the Delta Mariner early Tuesday morning, Mar. 7, into the channel of Port Canaveral, Florida – as witnessed by this author.

“We are proud to be working with The Boeing Company and NASA to further deep space exploration!” ULA said in a statement.

Major assembly of the ICPS was completed at ULA’s Decatur, Alabama, manufacturing facility in December 2016.

The interim cryogenic propulsion stage (ICPS) for the first flight of NASA’s Space Launch System (SLS) rocket has arrived by way of barge at Cape Canaveral Air Force Station in Florida on March 7, 2017. The ICPS will be moved to United Launch Alliance’s Delta IV Operation Center at the Cape for processing for the SLS-1/Orion EM-1 launch currently slated for late 2018 launch from pad 39B at NASA’s Kennedy Space Center. Credit: ULA

The ICPS is the designated upper stage for the first maiden launch of the initial Block 1 version of the SLS.

It is based on ULA’s Delta Cryogenic Second Stage which has successfully flown numerous times on the firm’s Delta IV family of rockets.

In the event that NASA decides to add a two person crew to the EM-1 mission, Bill Hill, NASA’s deputy associate administrator for Exploration Systems Development in Washington, D.C., stated that the agency would maintain the Interim Cryogenic Propulsion stage for the first flight, and not switch to the more advanced and powerful Exploration Upper Stage (EUS) planned for first use on the EM-2 mission.

The ULA Delta Mariner barge arriving in Port Canaveral, Florida on March 7, 2017 after transporting the interim cryogenic propulsion stage (ICPS) hardware for the first flight of NASA’s Space Launch System (SLS) rocket from Decatur, Alabama. SLS-1 launch from the Kennedy Space Center is slated for late 2018. Credit: Ken Kremer/kenkremer.com

The ICPS was loaded onto the Delta Mariner and departed Decatur last week to began its sea going voyage of more than 2,100 miles (3300 km). The barge trip normally takes 8 to 10 days.

“ULA has completed production on the interim cryogenic propulsion stage (ICPS) flight hardware for NASA’s Space Launch System and it’s on the way to Cape Canaveral aboard the Mariner,” ULA noted in a statement last week.

The 312-foot-long (95-meter-long) ULA ship docked Tuesday morning at the wharf at Port Canaveral to prepare for off loading from the roll-on, roll-off vessel.

The Delta Mariner can travel on both rivers and open seas and navigate in waters as shallow as nine feet.

“ICPS, the first integrated SLS hardware to arrive at the Cape, will provide in-space propulsion for the SLS rocket on its Exploration Mission-1 (EM-1) mission,” according to ULA.

The next step for the upper stage is ground transport to United Launch Alliance’s Delta IV Operation Center on Cape Canaveral Air Force Station in Florida for further testing and processing before being moved to the Kennedy Space Center.

ULA will deliver the ICPS to NASA in mid-2017.

“It will be the first integrated piece of SLS hardware to arrive at the Cape and undergo final processing and testing before being moved to Ground Systems Development Operations at NASA’s Kennedy Space Center,” said NASA officials.

“The ICPS is a liquid oxygen/liquid hydrogen-based system that will provide the thrust needed to send the Orion spacecraft and 13 secondary payloads beyond the moon before Orion returns to Earth.”

The upper stage is powered by a single RL-10B-2 engine fueled by liquid hydrogen and oxygen and generates 24,750 pounds of thrust. It measures 44 ft 11 in (13.7 m ) in length and 16 ft 5 in (5 m) in width.

The interim cryogenic propulsion stage (ICPS) for the first flight of NASA’s Space Launch System (SLS) rocket as it completed major assembly at United Launch Alliance in Decatur, Alabama in December 2016. The ICPS just arrived by way of barge at Cape Canaveral Air Force Station in Florida on March 7, 2017. It will propel the Orion EM-1 crew module around the Moon. The SLS-1/Orion EM-1 launch is currently slated for late 2018 launch from NASA’s Kennedy Space Center. Credit: ULA

All major elements of the SLS will be assembled for flight inside the high bay of NASA’s iconic Vehicle Assembly Building which is undergoing a major overhaul to accommodate the SLS. The VAB high bay was extensively refurbished to convert it from Space Shuttle to SLS assembly and launch operations.

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

Components of the SLS-1 rocket are being manufactured at NASA’s Michoud Assembly Facility and elsewhere around the country by numerous suppliers.

Michoud is building the huge liquid oxygen/liquid hydrogen SLS core stage fuel tank, derived from the Space Shuttle External Tank (ET) – as I detailed here.

The liquid hydrogen tank qualification test article for NASA’s new Space Launch System (SLS) heavy lift rocket lies horizontally after final welding was completed at NASA’s Michoud Assembly Facility in New Orleans in July 2016. Credit: Ken Kremer/kenkremer.com

The ICPS sits on top of the SLS core stage.

The next Delta IV rocket launching with a Delta Cryogenic Second Stage is tentatively slated for March 14 from pad 37 at the Cape.

The Orion EM-1 capsule is currently being manufactured at the Neil Armstrong Operations and Checkout Building at the Kennedy Space Center by prime contractor Lockheed Martin.

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

Ken Kremer

File photo of the ULA Delta Mariner barge arriving in Port Canaveral, Florida after transporting rocket hardware from Decatur, Alabama

February 27, 2017February 28, 2017 by Ken Kremer

Elon Musk Announces Daring SpaceX Dragon Flight Beyond Moon with 2 Private Astronauts in 2018

SpaceX CEO Elon Musk announced plans on Feb. 27, 2017 to launch a commercial crew SpaceX Dragon to beyond the Moon and back with two private astronauts in 2018 using a SpaceX Falcon Heavy launching from the Kennedy Space Center. Credit: SpaceX

KENNEDY SPACE CENTER, FL – Elon Musk, billionaire founder and CEO of SpaceX, announced today (27 Feb) a daring plan to launch a commercial manned journey “to beyond the Moon and back” in 2018 flying aboard an advanced crewed Dragon spacecraft paid for by two private astronauts – at a media telecon.

Note: Check back again for updated details on this breaking news story.

“This is an exciting thing! We have been approached to do a crewed mission to beyond the Moon by some private individuals,” Musk announced at the hastily arranged media telecon just concluded this afternoon which Universe Today was invited to participate in.

The private two person crew would fly aboard a human rated Dragon on a long looping trajectory around the moon and far beyond on an ambitious mission lasting roughly eight days and that could blastoff by late 2018 – if all goes well with rocket and spacecraft currently under development, but not yet flown.

“This would do a long leap around the moon,” Musk said. “We’re working out the exact parameters, but this would be approximately a week long mission – and it would skim the surface of the moon, go quite a bit farther out into deep space, and then loop back to Earth. I’m guessing probably distance wise, maybe 300,000 or 400,000 miles.”

The private duo would fly on a ‘free return’ trajectory around the Moon – but not land on the Moon like NASA did in the 1960s and 1970s.

But they would venture further out into deep space than any humans have ever been before.

No human has traveled beyond low Earth orbit in more than four decades since Apollo 17 – NASA’s final lunar landing mission in December 1972, and commanded by recently deceased astronaut Gene Cernan.

“Like the Apollo astronauts before them, these individuals will travel into space carrying the hopes and dreams of all humankind, driven by the universal human spirit of exploration,” says SpaceX.

Musk said the private crew of two would launch on a Dragon 2 crew spacecraft atop a SpaceX Falcon Heavy booster from historic pad 39A at the Kennedy Space Center in Florida – the same pad that just reopened for business last week with the successful launch of a cargo Dragon to the International Space Station (ISS) for NASA on the CRS-10 mission.

“They are two paying customers,” Musk elaborated. “They’re very serious about it.”

“But nobody from Hollywood.”

“They will fly using a Dragon 2 and Falcon Heavy next year in 2018.”

“The lunar orbit mission would launch about 6 months after the [first] NASA crew to the space station on Falcon 9/Dragon 2,” Musk told Universe Today.

Musk noted they had put down “a significant deposit” and will undergo extensive flight training.

He declined to state the cost – but just mentioned it would be more than the cost of a Dragon seat for a flight to the space station, which is about $58 million.

The Falcon Heavy, once operational, will be the most powerful rocket in the world. Credit: SpaceX

SpaceX is currently developing the commercial crew Dragon spacecraft for missions to transport astronauts to low Earth orbit (LEO) and the International Space Station (ISS) under a NASA funded a $2.6 billion public/private contract. Boeing was also awarded a $4.2 Billion commercial crew contract by NASA to build the crewed CST-100 Starliner for ISS missions.

The company is developing the triple barreled Falcon Heavy with its own funds – which is derived from the single barreled Falcon 9 rocket funded by NASA.

But neither the Dragon 2 nor the Falcon Heavy have yet launched to space and their respective maiden missions haven been postponed multiple time for several years – due to a combination of funding and technical issues.

So alot has to go right for this private Moonshot mission to actually lift off by the end of next year.

NASA is developing the new SLS heavy lift booster and Orion capsule for deep space missions to the Moon, Asteroids and Mars.

The inaugural uncrewed SLS/Orion launch is slated for late 2018. But NASA just announced the agency has started a feasibility study to examine launching a crew on the first Orion dubbed Exploration Mission-1 (EM-1) on a revamped mission in 2019 rather than 2021 on EM-2.

Thus the potential exists that SpaceX could beat NASA back to the Moon with humans.

I asked Musk to describe the sequence of launches leading up to the private Moonshot and whether a crewed Dragon 2 would launch initially to the ISS.

Musk replied that SpaceX hopes to launch the first uncrewed Dragon 2 test flight to the ISS by the end of this year on the firm’s Falcon 9 rocket – almost identical to the rocket that just launched on Feb. 19 from pad 39A.

That would be followed by crewed launch to the ISS around mid-2018 and the private Moonshot by the end of 2018.

“The timeline is we expect to launch a human rated Dragon 2 on Falcon 9 by the end of this year, but without people on board just for the test flight to the space station,” Musk told Universe Today.

“Then about 6 months later we would fly with a NASA crew to the space station on Falcon 9/Dragon 2.”

“And then about 6 months after that, assuming the schedule holds by end of next year, is when we would do the lunar orbit mission.”

I asked Musk about whether any heat shield modifications to Dragon 2 were required?

“The heat shield is quite massively over designed,” Musk told me during the telecom.

“It’s actually designed for multiple Earth orbit reentry missions – so that we can actually do up to 10 reentry missions with the same heat shield.”

“That means it can actually do at least 1 lunar orbit reentry velocity missions, and conceivably maybe 2.”

“So we do not expect any redesign of the heat shield.”

The reentry velocity and heat generated from a lunar mission is far higher than from a low Earth orbit mission to the space station.

Nevertheless the flight is not without risk.

The Dragon 2 craft will need some upgrades. For example “a deep space communications system” with have to be installed for longer trips, said Musk.

Dragon currently is only equipped for shorter Earth orbiting missions.

The flight must also be approved by the FAA before its allowed to blastoff – as is the case with all commercial launches like the Feb. 19 Falcon 9/Cargo Dragon mission for NASA.

SpaceX founder and CEO Elon Musk. Credit: Ken Kremer/kenkremer.com

Musk declined to identify the two individuals or their genders but did say they know one another.

They must pass health and training tests.

“We expect to conduct health and fitness tests, as well as begin initial training later this year,’ noted SpaceX.

The flight itself would be very autonomous. The private passengers will train for emergencies but would not be responsible for piloting Dragon.

Musk said he would give top priority to NASA astronauts for the Moonshot mission if the agency wanted to procure the seats ahead of the private passengers.

He noted that SpaceX would have the capability to launch one or 2 private moonshots per year.

“I think this should be a really exciting mission that gets the world really excited about sending people into deep space again. I think it should be super inspirational,” Musk said.

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

Ken Kremer