The Orbital ATK Antares rocket, with the Cygnus OA-5 spacecraft onboard, is raised into the vertical position on launch Pad-0A for planned launch on Oct. 17, 2016, at NASA's Wallops Flight Facility in Virginia. Credit: Ken Kremer/kenkremer
The Orbital ATK Antares rocket, with the Cygnus OA-5 spacecraft onboard, is raised into the vertical position on launch Pad-0A for planned launch on Oct. 17, 2016, at NASA’s Wallops Flight Facility in Virginia. Credit: Ken Kremer/kenkremer
NASA WALLOPS FLIGHT FACILITY, VA – The ‘Return to Flight’ blastoff of Orbital ATK’s upgraded Antares rocket will have to wait one more day to come to fruition with a magnificent Monday night launch – after a technical scrub was called this afternoon, Oct. 16, at NASA’s Virginia launch base due to a faulty cable.
The launch potentially offers a thrilling skyshow to millions of US East Coast spectators if all goes well.
Antares Launch Viewing Map. This “first-sight” map indicates potential to see Orbital ATK’s Antares rocket in the minutes following its launch on the OA-5 mission to the ISS on October 16, 2016. Credit: Orbital ATK
Despite picture perfect Fall weather, technical gremlins intervened to halt Sunday nights planned commercial cargo mission for NASA carrying 2.5 tons of science and supplies bound for the International Space Station (ISS).
The launch of the Orbital ATK CRS-5 mission is now scheduled for October 17 at 7:40 p.m. EDT, from the Mid-Atlantic Regional Spaceport pad 0A at NASA’s Wallops Flight Facility on Virginia’s picturesque Eastern shore.
You can watch the launch live on NASA TV as well as the agency’s website beginning at 6:30 p.m. EDT Oct 17.
Mondays liftoff is slated to take place approximately 23 minutes earlier then Sunday’s hoped for time of 8:03 p.m. EDT in order to match the moment when the orbital plane of the station passes on NASA Wallops.
The weather outlook on Monday remains extremely favorable with a 95 percent chance of acceptable conditions at launch time.
A nearly full moon has risen over Antares the past few days at the launch pad.
2 Moons and Antares on the launch pad on the evening of Oct. 15, 2016 at NASA’s Wallops Flight Facility in Virginia in this water reflection shot. Liftoff of the OA-5 mission to the ISS is planned for Oct. 17, 2016. Credit: Ken Kremer/kenkremer
Announcement of the launch scrub of the mission – also known as OA-5 – came just as the six hour countdown was set to begin after engineers discovered the bad cable.
“Today’s launch of Orbital ATK’s Antares rocket is postponed 24 hours due to a ground support equipment (GSE) cable that did not perform as expected during the pre-launch check out,” officials at NASA Wallops said.
The faulty cable was a component of the rocket’s hold down system at the pad, Orbital ATK officials told Universe Today after the scrub was announced.
Technicians have spares on hand and are working now to replace the cable in time to permit a Monday evening launch.
“We have spares on hand and rework procedures are in process. The Antares and Cygnus teams are not currently working any technical issues with the rocket or the spacecraft.”
Besides the cable the rocket is apparently in perfect shape.
“The Antares and Cygnus teams are not currently working any technical issues with the rocket or the spacecraft.”
Antares launches have been on hold for two years after it was grounded following its catastrophic failure just moments after liftoff on Oct. 28, 2014 that doomed the Orb-3 resupply mission to the space station – as witnessed by this author.
Orbital ATK’s Antares commercial rocket had to be overhauled with the completely new RD-181 first stage engines- fueled by LOX/kerosene – following the destruction of the Antares rocket and Cygnus supply ship two years ago.
The 14 story tall commercial Antares rocket also will launch for the first time in the upgraded 230 configuration – powered by new Russian-built first stage engines designed and manufactured by Energomesh.
The 133-foot-tall (40-meter) Antares was rolled out to pad 0A on Thursday, Oct. 13 – three days prior to Sunday’s intended launch date. It was raised to the vertical launch position on Friday.
The Orbital ATK Antares rocket, with the Cygnus OA-5 spacecraft onboard, is raised into the vertical position on launch Pad-0A for planned launch on Oct. 17, 2016, at NASA’s Wallops Flight Facility in Virginia. Credit: Ken Kremer/kenkremer
The two stage Antares will carry the Orbital OA-5 Cygnus cargo freighter to orbit on a flight bound for the ISS and its multinational crew of astronauts and cosmonauts.
The launch marks the first nighttime liftoff of the Antares – and it could be visible up and down the eastern seaboard if weather and atmospheric conditions cooperate to provide a spectacular viewing opportunity to the most populated region in North America.
The Cygnus spacecraft for the OA-5 mission is named the S.S. Alan G. Poindexter in honor of former astronaut and Naval Aviator Captain Alan Poindexter.
Under the Commercial Resupply Services (CRS) contract with NASA, Orbital ATK will deliver approximately 28,700 kilograms of cargo to the space station. OA-5 is the sixth of these missions.
Watch for Ken’s continuing Antares/Cygnus mission and launch reporting. He will be reporting from on site at NASA’s Wallops Flight Facility, VA during the launch campaign.
Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.
The Orbital ATK Antares rocket, with the Cygnus spacecraft onboard, is raised into the vertical position on launch Pad-0A, Friday, Oct. 14, 2016 at NASA's Wallops Flight Facility in Virginia. Credit: NASA/Bill Ingalls
The Orbital ATK Antares rocket, with the Cygnus spacecraft onboard, is raised into the vertical position on launch Pad-0A, Friday, Oct. 14, 2016 at NASA’s Wallops Flight Facility in Virginia. Credit: NASA/Bill Ingalls
NASA WALLOPS FLIGHT FACILITY, VA – After a two year stand down, an upgraded commercial Antares rocket was rolled out to the NASA Wallops launch pad on Virginia’s eastern shore and raised to its launch position today in anticipation of a spectacular Sunday night liftoff, Oct. 16, to the International Space Station (ISS) on a critical resupply mission for NASA.
Blastoff of the re-engined Orbital ATK Antares rocket is slated for 8:03 p.m. EDT on Oct. 16 from the Mid-Atlantic Regional Spaceport pad 0A at NASA’s Wallops Flight Facility on Virginia’s picturesque Eastern shore.
Officials had to postpone this commercial resupply mission – dubbed OA-5 – from mid-week due to Cat 3 Hurricane Nicole which slammed into Bermuda yesterday, Oct. 13, packing winds of about 125 mph, and is home to a critical NASA launch tracking station.
After the storm passed, engineers found the tracking station only suffered minor damage – so the GO was given to proceed with preparation for Sunday’s nighttime launch.
“Repairs to the station have been made and the team is currently readying to support the launch,” according to NASA officials.
Engineers are still testing the station to ensure its readiness.
“The Bermuda site provides tracking, telemetry and flight terminations support for Antares launches from NASA’s Wallops Flight Facility on Virginia’s Eastern Shore. Final testing is scheduled to be conducted the morning of Oct. 15 prior to the launch readiness review later that day.”
The Orbital ATK Antares rocket, with the Cygnus spacecraft onboard, is rolled out of the Horizontal Integration Facility (HIF) to begin the approximately half-mile journey to launch Pad-0A, Thursday, Oct. 13, 2016 at NASA’s Wallops Flight Facility in Virginia. Orbital ATK’s sixth contracted cargo resupply mission with NASA to the International Space Station. Credit: (NASA/Bill Ingalls)
If all goes well Antares is sure to provide a dazzling nighttime skyshow from NASA’s Virginia launch base Sunday night – and potentially offering a thrilling spectacle to millions of US East Coast spectators.
The launch window last five minutes and the weather outlook is currently favorable.
The launch will air live on NASA TV and the agency’s website beginning at 7 p.m. EDT Oct 16.
Antares rocket stands erect, reflecting off the calm waters the night before a launch from NASA’s Wallops Flight Facility, VA, on Oct. 28, 2014. Credit: Ken Kremer/kenkremer.com
The 133-foot-tall (40-meter) Antares was rolled out to pad 0A on Thursday, Oct. 13 – three days prior to the anticipated launch date – and raised to the vertical launch position this afternoon.
The two stage Antares will carry the Orbital OA-5 Cygnus cargo freighter to orbit on a flight bound for the ISS and its multinational crew of astronauts and cosmonauts.
On-Ramp to the Orbital Sciences Antares rocket and International Space Station – ready for blastoff from NASA Wallops in this file photo. Credit: Ken Kremer – kenkremer.com
The launch marks the first nighttime liftoff of the Antares – and it could be visible up and down the eastern seaboard if weather and atmospheric conditions cooperate to provide a spectacular viewing opportunity to the most populated region in North America.
The 14 story tall commercial Antares rocket also will launch for the first time in the upgraded 230 configuration – powered by new Russian-built first stage engines.
Orbital ATK’s Antares commercial rocket had to be overhauled with the completely new RD-181 first stage engines – fueled by LOX/kerosene – following the destruction of the Antares rocket and Cygnus supply ship two years ago.
The RD-181 replaces the previously used AJ26 engines which failed moments after liftoff during the last launch on Oct. 28, 2014 resulting in a catastrophic loss of the rocket and Cygnus cargo freighter.
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 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
For the OA-5 mission, the Cygnus advanced maneuvering spacecraft will be loaded with approximately 2,400 kg (5,290 lbs.) of supplies and science experiments for the International Space Station (ISS).
“Cygnus is loaded with the Saffire II payload and a nanoracks cubesat deployer,” Frank DeMauro, Orbital ATK Cygnus program manager, told Universe Today in a interview.
Among the science payloads aboard the Cygnus OA-5 mission is the Saffire II payload experiment to study combustion behavior in microgravity. Data from this experiment will be downloaded via telemetry. In addition, a NanoRack deployer will release Spire Cubesats used for weather forecasting. These secondary payload operations will be conducted after Cygnus departs the space station.
Other experiments include a study on the effect of lighting on sleep and daily rhythms, collection of health-related data, and a new way to measure neutrons.
Watch for Ken’s continuing Antares/Cygnus mission and launch reporting. He will be reporting from on site at NASA’s Wallops Flight Facility, VA during the launch campaign.
Orbital Sciences Antares rocket explodes moments after blastoff from NASA’s Wallops Flight Facility, VA, on Oct. 28, 2014, at 6:22 p.m. Credit: Ken Kremer – kenkremer.com
The Cygnus spacecraft for the OA-5 mission is named the S.S. Alan G. Poindexter in honor of former astronaut and Naval Aviator Captain Alan Poindexter.
Under the Commercial Resupply Services (CRS) contract with NASA, Orbital ATK will deliver approximately 28,700 kilograms of cargo to the space station. OA-5 is the sixth of these missions.
The Orbital ATK Antares rocket, with the Cygnus spacecraft aboard. Credit: NASA/Bill Ingalls
Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.
President Barack Obama, the 44th President of the United States. Image: Official White House Photo by Pete Souza Public Domain
In the waning days of his presidency, Barack Obama has made a bold statement in favor of the US getting to Mars. Obama didn’t mince any words in his opinion piece written for CNN. He said that America’s next goal in space is “…sending humans to Mars by the 2030s and returning them safely to Earth, with the ultimate ambition to one day remain there for an extended time.”
President Obama has long been a proponent of a strong presence in space for the US, and of the science and technology that supports those efforts. He has argued for healthy NASA budgets in his time, and under his administration, NASA has reached some major milestones.
“Last year alone, NASA discovered flowing water on Mars and evidence of ice on one of Jupiter’s moons, and we mapped Pluto — more than 3 billion miles away — in high-resolution,” Obama said. He also mentioned the ongoing successful hunt for exoplanets, and the efforts to understand asteroids.
Some of his work in support of space and science in general has been more symbolic. His annual White House Science Fairs in particular. He was the first president to hold these fairs, and he hosted 6 of them during his 8 years in office.
Presidents go different directions once they leave office. Some keep a low profile (Bush Jr.), some get targeted for assassination (Bush Sr.), and some become advocates for humanitarian efforts and global peace (Jimmy Carter.) But Obama made it clear that his efforts to promote America’s efforts in space won’t end when his presidency ends. “This week, we’ll convene some of America’s leading scientists, engineers, innovators and students in Pittsburgh to dream up ways to build on our progress and find the next frontiers,” Obama said.
In his piece, Obama gave a laundry list of the USA’s achievements in space. He also pointed out that “Just five years ago, US companies were shut out of the global commercial launch market.” Now they own a third of that market. And, according to Obama, they won’t stop there.
In 2010 he set a goal for American space efforts: to reach Mars by the 2030s. “The next step is to reach beyond the bounds of Earth’s orbit. I’m excited to announce that we are working with our commercial partners to build new habitats that can sustain and transport astronauts on long-duration missions in deep space.” He didn’t elaborate on this in his opinion piece, but it will be interesting to hear more.
Other presidents have come out strongly in favor of efforts in space. The first one was Eisenhower, and Obama mentioned him in his piece. Eisenhower is the one who created NASA in 1958, though it was called NACA (National Advisory Committee for Aeronautics) at the time. This put America’s space efforts in civilian control rather than military.
President Kennedy got the Apollo program off the ground in 1961. Image: White House Press Office (WHPO)
President Kennedy asked Congress in 1961 to commit to the Apollo program, an effort to get a man on the Moon before the 60s ended. Apollo achieved that, of course, but with only a few months to spare. Kennedy’s successor, President Lyndon Johnson, was a staunch supporter of NASA’s Apollo Program, especially in the wake of disaster.
In 1967 the entire Apollo 1 crew was killed in a fire while testing the craft on its launch pad. The press erupted after that, and Congress began to question the Apollo Program, but Johnson stood firmly in NASA’s corner.
Like some other Presidents before him, Obama has always been a good orator. That was in full view when he ended his piece with these words: “Someday, I hope to hoist my own grandchildren onto my shoulders. We’ll still look to the stars in wonder, as humans have since the beginning of time.”
The focus has really been on Mars lately, and with Obama’s continued support, maybe humans will make it to Mars in the next decade or two. Then, from the surface of that planet, we can do what we’ve always done: continue to look to the stars with a sense of wonder.
The NASA/NOAA GOES-R (Geostationary Operational Environmental Satellite - R Series) being processed at Astrotech Space Operations, in Titusville, FL, in advance of launch on a ULA Atlas V on Nov. 19, 2016. GOES-R will be America’s most advanced weather satellite. Credit: Ken Kremer/kenkremer.com
The NASA/NOAA GOES-R (Geostationary Operational Environmental Satellite – R Series) being processed at Astrotech Space Operations, in Titusville, FL, in advance of the planned launch on a ULA Atlas V likely delayed from Nov 4, 2016 by Hurricane Matthew. GOES-R will be America’s most advanced weather satellite. Credit: Ken Kremer/kenkremer.com
Next month’s launch of GOES-R – a new and advanced transformational weather satellite that will vastly enhance the quality, speed and accuracy of weather forecasting – will likely be delayed a few days due to lingering storm related effects of deadly Hurricane Matthew on launch preparations at Cape Canaveral Air Force Station and the Kennedy Space Center (KSC), Universe Today confirmed with launch provider United Launch Alliance (ULA).
Liftoff of the NASA/NOAA GOES-R (Geostationary Operational Environmental Satellite – R Series) weather satellite atop a United Launch Alliance (ULA) Atlas V rocket had been scheduled for Nov. 4 at 5:40 p.m. from Space Launch Complex 41 (SLC-41) on Cape Canaveral Air Force Station.
GOES-R is the first in a new series of American’s most powerful and most advanced next generation weather observation satellites.
It’s ironic that awful weather is impacting the launch of this critical weather satellite.
It’s not known how long any postponement would be – perhaps only a few days since preliminary indications are that the base suffered only minor damage and there are no reports of major damage.
“Our teams are still doing a damage assessment. So we don’t have a status about all of our infrastructure yet,” Chassagne told me.
“A preliminary assessment shows that we have some minor damage to a few of our facilities. We had no rockets on the pads. So there is no damage to hardware.”
Damage assessment teams are evaluating the launch pad and launch facilities in detail right now.
“Since we still have emergency response teams in assessing, we don’t know how long the delay will be until we get those assessments.”
The NASA/NOAA GOES-R (Geostationary Operational Environmental Satellite – R Series) being processed at Astrotech Space Operations, in Titusville, FL, in advance of the planned launch on a ULA Atlas V likely delayed from Nov 4, 2016 by Hurricane Matthew. GOES-R will be America’s most advanced weather satellite. Credit: Ken Kremer/kenkremer.com
The looming threat of a direct hit on Cape Canaveral and KSC from the Category 4 storm Hurricane Matthew on Friday, Oct. 7, forced the closure of both facilities before the storm hit. They remained closed this weekend except to emergency personal.
“Got in today to assess. Light to moderate damage to our facilities. No damage to any flight assets,” tweeted ULA CEO Tory Bruno.
The base closures therefore also forced a halt to launch preparations at the Cape and pad 41.
The storm grazed by the Kennedy Space Center (KSC), Cape Canaveral Air Force Station (CCAFS) and the major population centers along the Florida Space Coast with wind gusts up to 107 mph – rather than making a direct impact as feared.
“Hurricane Matthew passed Cape Canaveral and Kennedy Space Center …. with sustained winds of 90 mph with gusts to 107 mph,” on Friday, NASA officials reported.
The storm passed “the space center about 26 miles off the tip of Cape Canaveral.”
Cat 4 Hurricane Matthew track during the late evening of 6 Oct 2016. Credit: NASA/NOAA
The launch ULA facilities are now being thoroughly inspected before any launch preparation can proceed.
The satellite is in the final stages of preparation at the Astrotech Space Operations Facility in Titusville, FL as I recently observed during an up close visit in the High Bay cleanroom.
Check out this amazing rooftop video showing the high winds pummeling Titusville during Hurricane Matthew just a few miles away from Astrotech and the GOES-R satellite – from my space colleague Jeff Seibert.
Video caption: Before we bailed out on Thursday afternoon, I clamped one of my launch pad remote cameras to the power service post on our roof. Wind is blocked a lot by trees but none fell on the house. The highest recorded wind speed was 51mph at 7:30AM on Oct. 7, 2016. The minimum barometric pressure was 28.79″ from 8:20 – 9 AM. We got 5.9″ of rain. The ridge line faces due east. We never lost power. Credit: Jeff Seibert
Lockheed Martin is the prime contractor for GOES-R.
United Launch Alliance Atlas V rocket lifts off from Space Launch Complex 41 at Cape Canaveral Air Force Station carrying NASA’s Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer, or OSIRIS-REx spacecraft on the first U.S. mission to sample an asteroid on September 8, 2016. GOES-R launch on an Atlas V planned for Nov. 4 is likely delayed due to Hurricane Matthew. Credit: Ken Kremer/kenkremer.com
Whenever it does launch, GOES-R will blast off on a ULA Atlas V in the very powerful 541 configuration, augmented by four solid rocket booster on the first stage.
It will be launched to a Geostationary orbit some 22,300 miles above Earth.
But ULA has not yet begun assembling the Atlas V booster inside the Vertical Integration Facility (VIF) at SLC-41 due to the storm.
Because of Hurricane Matthew, the first stage arrival had to be postponed. The second stage is already in port at the Delta operations center and being integrated.
“The first stage booster is not yet at the Cape,” Chassagne confirmed.
However, conditions at the Cape have improved sufficiently for the US Air Force to clear its shipment into port, as of this evening.
“We just cleared CCAFS to be able to accept a booster for the GOES-R launch–how appropriate that GOES is a weather satellite!” wrote Brig. Gen. Wayne Monteith, commander of the Air Force’s 45th Space Wing at Patrick Air Force Base, in a Facebook update late today, Oct. 9.
“We are returning to full mission capability and our status as the World’s Premier Gateway to Space.”
Artists concept for NASA/NOAA GOES-R (Geostationary Operational Environmental Satellite – R Series) advanced weather satellite in Earth orbit. Credit: NASA/NOAA
Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.
Aerial view of the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center (KSC) on Oct. 8, 2016 by damage assessment and recovery team surveying the damage at KSC the day after Hurricane Matthew passed by Cape Canaveral on Oct. 7, 2016 packing sustained winds of 90 mph with gusts to 107 mph. Credit: NASA/Cory Huston
Aerial view of the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center (KSC) on Oct. 8, 2016 by damage assessment and recovery team surveying the damage at KSC the day after Hurricane Matthew passed by Cape Canaveral on Oct. 7, 2016 packing sustained winds of 90 mph with gusts to 107 mph. Credit: NASA/Cory Huston
Although some of the base and Space Coast coastal and residential areas did suffer significant destruction most were very lucky to have escaped the hurricanes onslaught in relatively good shape, when it stayed at sea rather than making the forecast direct hit.
KSC’s iconic 525 foot tall Vehicle Assembly Building (VAB), the Complex 39 launch pads and the active launch pads at CCAFS are all standing and intact – as damage evaluations are currently underway by damage assessment and recovery teams from NASA and the US Air Force.
As Hurricane Matthew approached from the south Friday morning Oct. 7 along Florida’s Atlantic coastline, it wobbled east and west, until it finally veered ever so slightly some 5 miles to the East – thus saving much of the Space Coast launch facilities and hundreds of thousands of home and businesses from catastrophic damage from the expected winds and storm surges.
“Hurricane Matthew passed Cape Canaveral and Kennedy Space Center …. with sustained winds of 90 mph with gusts to 107 mph,” on Friday, NASA officials reported.
The storm passed “the space center about 26 miles off the tip of Cape Canaveral.”
Cat 4 Hurricane Matthew track during the late evening of 6 Oct 2016. Credit: NASA/NOAA
KSC and CCAFS did suffer some damage to buildings, downed power lines and some flooding and remains closed.
The Damage Assessment and Recovery Teams have entered the facilities today, Oct. 8, and are surveying the areas right now to learn the extent of the damage and report on when they can reopen for normal operations.
“After the initial inspection flight Saturday morning, it was determined that the center received some isolated roof damage, damaged support buildings, a few downed power lines, and limited water intrusion,” NASA reported late today.
Hurricane force wind from Hurricane Matthew throw a concession stand up against the Spaceflight Now building at the LC 39 Press Site at the Kennedy Space Center in Florida on Oct. 7, 2016. Credit: NASA/Cory Huston
Inspection teams are methodically going from building to building this weekend to assess Matthew’s impact.
“Since safety is our utmost concern, teams of inspectors are going from building-to-building assessing damage.”
It will take time to determine when the center can resume operations.
“Due to the complexity of this effort, teams need time to thoroughly inspect all buildings and roads prior to opening the Kennedy Space Center for regular business operations.”
Not until after a full inspection of the center will a list of damaged buildings and equipment be available. The next update will be available no earlier than Sunday afternoon.
A “ride-out team” of 116 remained at KSC and at work inside the emergency operations center in the Launch Control Center located adjacent to the VAB during the entire Hurricane period.
View of the Vehicle Assembly Building (VAB), Launch Control Center and Mobile Launcher from the KSC Launch Complex 39 Press Site. NASA is upgrading the VAB with new platforms to assemble and launch NASA’s Space Launch System rocket at the Kennedy Space Center in Florida. Credit: Ken Kremer/kenkremer.com
It took until Friday afternoon for winds to drop below 40 knots start preliminary damage assessments.
“KSC is now in a “Weather Safe” condition as of 2 p.m. Friday. While there is damage to numerous facilities at KSC, it consists largely roof damage, window damage, water intrusion, damage to modular buildings and to building siding.”
Teams are also assessing the CCAFS launch pads, buildings and infrastructure. Some buildings suffered severe damage.
“We have survived a catastrophic event that could have easily been cataclysmic. It is only by grace and a slight turn in Matthew’s path that our base and our barrier island homes were not destroyed or covered in seven feet of water,” wrote Brig. Gen. Wayne Monteith, commander of the Air Force’s 45th Space Wing at Patrick Air Force Base, in a Facebook update.
“There is a lot of debris throughout the base.”
“We are still experiencing deficiencies in critical infrastructure, consistent power, emergency services, communications and hazardous material inspections that make portions of our base uninhabitable or potentially dangerous.”
Severely damaged building on Cape Canaveral Air Force Station. Credit: 45th Space Wing
Of particular importance is Space Launch Complex 41 (SLC-41) where the next scheduled liftoff is slated for Nov. 4.
The launch involves America’s newest and most advanced weather satellite on Nov 4. It’s named GOES-R and was slated for blastoff from Cape Canaveral Air Force Station pad 41 atop a United Launch Alliance (ULA) Atlas V rocket.
The launch facilities will have to be thoroughly inspected before the launch can proceed.
The satellite is in the final stages of preparation at the Astrotech Space Operations Facility in Titusville, FL as I recently observed during an up close visit in the High Bay cleanroom.
The NASA/NOAA GOES-R (Geostationary Operational Environmental Satellite – R Series) being processed at Astrotech Space Operations, in Titusville, FL, in advance of the planned launch on a ULA Atlas V on Nov 4, 2016. GOES-R will be America’s most advanced weather satellite. Credit: Ken Kremer/kenkremer.com
The major Space Coast cities in Brevard county suffered much less damage then feared, although some 500,000 residents lost power.
Local government officials allowed most causeway bridges to the barrier islands to be reopened by Friday evening, several local colleagues told me.
Here’s some images of damage to the coastal piers, town and a destroyed house from the Melbourne Beach and Satellite Beach areas from my space colleague Julian Leek.
Home destroyed by fire in Satellite Beach. Credit: Julian LeekHome destroyed by fire in Satellite Beach. Credit: Julian LeekLocal damage in South Melbourne Beach. Credit: Julian Leek
Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.
Navaho missile on display at the CCAFS south gate suffered severe damage from Hurricane Matthew and crumpled to the ground. Credit: 45th Space WingLocal damage in South Melbourne Beach. Credit: Julian LeekLocal damage in South Melbourne Beach. Credit: Julian Leek
Antares rocket stands erect, reflecting off the calm waters the night before a launch from NASA’s Wallops Flight Facility, VA, on Oct. 28, 2014. Credit: Ken Kremer/kenkremer.com
Antares rocket stands erect, reflecting off the calm waters the night before a launch from NASA’s Wallops Flight Facility, VA, on Oct. 28, 2014. Credit: Ken Kremer/kenkremer.com
Top NASA and Orbital ATK managers formally approved the launch of the upgraded commercial Antares rocket for next Thursday evening, Oct. 13, on a cargo resupply mission to the International Space Station (ISS). The announcement follows on the heels of a successful joint pre-launch Flight Readiness Review (FRR).
Blastoff of the Orbital ATK Antares rocket is slated for 9:13 p.m. EDT on Oct. 13 from the Mid-Atlantic Regional Spaceport pad 0A at NASA’s Wallops Flight Facility on Virginia’s picturesque Eastern shore.
Antares will be rolled out to the pad 0A on Oct. 11 – two days prior to the anticipated launch date.
Antares will carry the Orbital OA-5 Cygnus cargo freighter to orbit on a flight bound for the ISS and its multinational crew of astronauts and cosmonauts.
The launch marks the first nighttime liftoff of the Antares – and it could be visible up and down the eastern seaboard if weather and atmospheric conditions cooperate to provide a spectacular viewing opportunity to the most populated region in North America.
The 14 story tall commercial Antares rocket also will launch for the first time in the upgraded 230 configuration – powered by new Russian-built first stage engines.
For the OA-5 mission, the Cygnus advanced maneuvering spacecraft will be loaded with approximately 2,400 kg (5,290 lbs.) of supplies and science experiments for the International Space Station (ISS).
“Cygnus is loaded with the Saffire II payload and a nanoracks cubesat deployer,” Frank DeMauro, Orbital ATK Cygnus program manager, told Universe Today in a interview.
Among the science payloads aboard the Cygnus OA-5 mission is the Saffire II payload experiment to study combustion behavior in microgravity. Data from this experiment will be downloaded via telemetry. In addition, a NanoRack deployer will release Spire Cubesats used for weather forecasting. These secondary payload operations will be conducted after Cygnus departs the space station.
If Cygnus launches as planned on Oct. 13, it is scheduled to arrive at the station on Sunday, Oct. 16. Astronauts will use the space station’s robotic arm to grapple Cygnus at approximately about 6:45 a.m. EDT and berth it to the bottom of the station’s Unity module.
NASA TV will provide live coverage of the launch as well as the rendezvous and grappling activities.
Pre-launch seaside panorama of an Orbital ATK Antares rocket at the NASA’s Wallops Flight Facility launch pad. Credit: Ken Kremer – kenkremer.com
The Cygnus spacecraft for the OA-5 mission is named the S.S. Alan G. Poindexter in honor of former astronaut and Naval Aviator Captain Alan Poindexter.
Under the Commercial Resupply Services (CRS) contract with NASA, Orbital ATK will deliver approximately 28,700 kilograms of cargo to the space station. OA-5 is the sixth of these missions.
The 2 year lull in Antares launches followed the rockets immediate grounding after its catastrophic failure just moments after liftoff on Oct. 28, 2014 that doomed the Orb-3 resupply mission to the space station – as witnessed by this author.
First stage propulsion system at base of Orbital Sciences Antares rocket appears to explode moments after blastoff from NASA’s Wallops Flight Facility, VA, on Oct. 28, 2014, at 6:22 p.m. Credit: Ken Kremer – kenkremer.com
Orbital ATK’s Antares commercial rocket had to be overhauled with the completely new RD-181 first stage engines following the destruction of the Antares rocket and Cygnus supply ship two years ago.
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
In light of the grounding of the SpaceX Falcon 9 and Dragon cargo flights following the catastrophic Sept.1 launch pad disaster, and the catastrophic Antares launch failure in Oct. 2014, this Orbital ATK mission becomes more critical than ever to keep that station stocked and fully operational for the resident crews with a reliable American supply train.
Aerial view of NASA Wallops launch site on Virginia shore shows launch pads for both suborbital and orbital rockets. The Antares rocket Pad 0A for missions to the ISS is in the foreground. Suborbital rockets blast off just behind the Pad 0A water tower. This photo was snapped from on top of Pad 0B that launched NASA‘s LADEE orbiter to the Moon. Credit: Ken Kremer- kenkremer.com
In the meantime, Orbital ATK has successfully resumed launches of their Cygnus cargo freighters to the ISS utilizing the United Launch Alliance (ULA) Atlas V rocket as an interim measure until Antares is returned to flight status
They utilized the ULA Atlas V rocket to successfully deliver two Cygnus vessels to the ISS on the OA-4 flight in Dec 2015 and OA-6 flight in March 2016.
Watch for Ken’s continuing Antares/Cygnus mission and launch reporting. He will be reporting from on site at NASA’s Wallops Flight Facility, VA during the launch campaign.
Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.
Aerial view of an Orbital ATK Antares rocket on launch pad at Virginia Space’s Mid-Atlantic Regional Spaceport (MARS) Pad 0A located at NASA’s Wallops Flight Facility. Credit: Patrick J. Hendrickson / Highcamera.com
Welding is complete on the largest piece of the core stage that will provide the fuel for the first flight of NASA's new rocket, the Space Launch System, with the Orion spacecraft in 2018. The core stage liquid hydrogen tank has completed welding on the Vertical Assembly Center at NASA's Michoud Assembly Facility in New Orleans. Credit: NASA/MAF/Steven Seipel
Welding is complete on the largest piece of the core stage that will provide the fuel for the first flight of NASA’s new rocket, the Space Launch System, with the Orion spacecraft in 2018. The core stage liquid hydrogen tank has completed welding on the Vertical Assembly Center at NASA’s Michoud Assembly Facility in New Orleans. Credit: NASA/MAF/Steven Seipel
The first of the massive fuel tanks that will fly on the maiden launch of NASA’s SLS mega rocket in late 2018 has completed welding at the agency’s rocket manufacturing facility in New Orleans – marking a giant step forward for NASA’s goal of sending astronauts on a ‘Journey to Mars’ in the 2030s.
Welding is nearly complete on the liquid hydrogen tank will provide the fuel for the first flight of NASA’s new rocket, the Space Launch System, with the Orion spacecraft in 2018. The tank has now has now completed welding on the Vertical Assembly Center at NASA’s Michoud Assembly Facility in New Orleans. Credit: Ken Kremer/kenkremer.com
This flight version of the hydrogen tank is the largest of the two fuel tanks making up the SLS core stage – the other being the liquid oxygen tank (LOX).
In fact the 130 foot tall hydrogen tank is the biggest cryogenic tank ever built for flight.
“Standing more than 130 feet tall, the liquid hydrogen tank is the largest cryogenic fuel tank for a rocket in the world,” according to NASA.
And it is truly huge – measuring also 27.6 feet (8.4 m) in diameter.
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 precursor qualification tank was constructed to prove out all the manufacturing techniques and welding tools being utilized at Michoud.
The first liquid hydrogen tank, also called the qualification test article, for NASA’s new Space Launch System (SLS) heavy lift rocket lies horizontally beside the Vertical Assembly Center robotic weld machine on July 22, 2016 after final welding was just completed at NASA’s Michoud Assembly Facility in New Orleans. Credit: Ken Kremer/kenkremer.com
SLS is the most powerful booster the world has even seen and one day soon will propel NASA astronauts in the agency’s Orion crew capsule on exciting missions of exploration to deep space destinations including the Moon, Asteroids and Mars – venturing further out than humans ever have before!
NASA’s agency wide goal is to send humans to Mars by the 2030s with SLS and Orion.
The LH2 and LOX tanks sit on top of one another inside the SLS outer skin. Together the hold over 733,000 gallons of propellant.
The SLS core stage – or first stage – is mostly comprised of the liquid hydrogen and liquid oxygen cryogenic fuel storage tanks which store the rocket propellants at super chilled temperatures. Boeing is the prime contractor for the SLS core stage.
The SLS core stage stands some 212 feet tall.
The SLS core stage is comprised of five major structures: the forward skirt, the liquid oxygen tank (LOX), the intertank, the liquid hydrogen tank (LH2) and the engine section.
The LH2 and LOX tanks feed the cryogenic propellants into the first stage engine propulsion section which is powered by a quartet of RS-25 engines – modified space shuttle main engines (SSMEs) – and a pair of enhanced five segment solid rocket boosters (SRBs) also derived from the shuttles four segment boosters.
NASA engineers successfully conducted a development test of the RS-25 rocket engine Thursday, Aug. 18 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
The vehicle’s four RS-25 engines will produce a total of 2 million pounds of thrust.
The tanks are assembled by joining previously manufactured dome, ring and barrel components together in the Vertical Assembly Center by a process known as friction stir welding. The rings connect and provide stiffness between the domes and barrels.
The LH2 tank is the largest major part of the SLS core stage. It holds 537,000 gallons of super chilled liquid hydrogen. It is comprised of 5 barrels, 2 domes, and 2 rings.
The LOX tank holds 196,000 pounds of liquid oxygen. It is assembled from 2 barrels, 2 domes, and 2 rings and measures over 50 feet long.
The maiden test flight of the SLS/Orion is targeted for no later than November 2018 and will be configured in its initial 70-metric-ton (77-ton) Block 1 configuration with a liftoff thrust of 8.4 million pounds – more powerful than NASA’s Saturn V moon landing rocket.
Although the SLS-1 flight in 2018 will be uncrewed, NASA plans to launch astronauts on the SLS-2/EM-2 mission slated for the 2021 to 2023 timeframe.
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
Stay tuned here for Ken’s continuing Earth and Planetary science and human spaceflight news.
The newly assembled first liquid hydrogen tank, also called the qualification test article, for NASA’s new Space Launch System (SLS) heavy lift rocket lies horizontally beside the Vertical Assembly Center robotic weld machine (blue) on July 22, 2016. It was lifted out of the welder (top) after final welding was just completed at NASA’s Michoud Assembly Facility in New Orleans. Credit: Ken Kremer/kenkremer.com
NASA's MSL Curiosity. NASA is the only agency to successfully place a lander on Mars. This self portrait shows Curiosity doing its thing on Mars. Image: NASA/JPL-Caltech/MSSS
We may be living in the Golden Age of Mars Exploration. With multiple orbiters around Mars and two functioning rovers on the surface of the red planet, our knowledge of Mars is growing at an unprecedented rate. But it hasn’t always been this way. Getting a lander to Mars and safely onto the surface is a difficult challenge, and many landers sent to Mars have failed.
The joint ESA/Roscosmos Mars Express mission, and its Chiaparelli lander, is due at Mars in only 15 days. Now’s a good time to look at the challenges in getting a lander to Mars, and also to look back at the many failed attempts.
A model of the Schiaparelli lander. The lander is part of the ExoMars mission. By Pline – Own work, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=26837226
For now, NASA has the bragging rights as the only organization to successfully land probes on Mars. And they’ve done it several times. But they weren’t the first ones to try. The Soviet Union tried first.
The USSR sent several probes to Mars starting back in the 1960s. They made their first attempt in 1962, but that mission failed to launch. That failure illustrates the first challenge in getting a craft to land on Mars: rocketry. We’re a lot better at rocketry than we were back in the 1960’s, but mishaps still happen.
Then in 1971, the Soviets sent a pair of probes to Mars called Mars 2 and Mars 3. They were both orbiters with detachable landers destined for the Martian surface. The fate of Mars 2 and Mars 3 provides other illustrative examples of the challenges in getting to Mars.
Mars 2 separated from its orbiter successfully, but crashed into the surface and was destroyed. The crash was likely caused by its angle of descent, which was too steep. This interrupted the descent sequence, which meant the parachute failed to deploy. So Mars 2 has the dubious distinction of being the first man-made object to reach Mars.
Mars 3 was exactly the same as Mars 2. The Soviets liked to do missions in pairs back then, for redundancy. Mars 3 separated from its orbiter and headed for the Martian surface, and through a combination of aerodynamic breaking, rockets, and parachutes, it became the first craft to make a soft landing on Mars. So it was a success, sort of.
A model of the Mars 3 lander with its petals open after landing. By NASA – http://nssdc.gsfc.nasa.gov/image/spacecraft/mars3_lander_vsm.jpg, Public Domain, https://commons.wikimedia.org/w/index.php?curid=14634254
But after only 14.5 seconds of data transmission, it went quiet and was never heard from again. The cause was likely an intense dust storm. In an odd turn of events, NASA’s Mariner 9 orbiter reached Mars only days before Mars 2 and 3, becoming the first spacecraft to orbit another planet. It captured images of the planet-concealing dust storms, above which only the volcanic Olympus Mons could be seen. These images provided an explanation for the failure of Mars 3.
This image from the Mariner 9 orbiter shows Olympus Mons above the dust storms that concealed much of the planet when it arrived at Mars in 1971. Image: NASA
In 1973, the Soviets tried again. They sent four craft to Mars, two of which were landers, named Mars 6 and Mars 7. Mars 6 failed on impact, but Mars 7’s fate was perhaps a little more tragic. It missed Mars completely, by about 1300 km, and is in a helicentric orbit to this day. In our day and age, we just assume that our spacecraft will go where we want them to, but Mars 7 shows us that it can all go wrong. After all, Mars is a moving target.
In the 1970s, NASA was fresh off the success of their Apollo Program, and were setting their sites on Mars. They developed the Viking program which saw 2 landers, Viking 1 and Viking 2, sent to Mars. Both of them were probe/lander configurations, and both landers landed successfully on the surface of Mars. The Vikings sent back beautiful pictures of Mars that caused excitement around the world.
The Viking 2 lander captured this image of itself on the Martian surface. By NASA – NASA website; description,[1] high resolution image.[2], Public Domain, https://commons.wikimedia.org/w/index.php?curid=17624
In 1997, NASA’s Martian Pathfinder made it to Mars and landed successfully. Pathfinder itself was stationary, but it brought a little rover called Sojourner with it. Sojourner explored the immediate landing area around Pathfinder. Sojourner became the first rover to operate on another planet.
Pathfinder was able to send back over 16,000 images of Mars, along with its scientific data. It was also a proof of concept mission for technologies such as automated obstacle avoidance and airbag mediated touchdown. Pathfinder helped lay the groundwork for the Mars Exploration Rover Mission. That means Spirit and Opportunity.
An artist’s conception of Spirit/Opportunity working on Mars. By NASA/JPL/Cornell University, Maas Digital LLC – http://photojournal.jpl.nasa.gov/catalog/PIA04413 (image link), Public Domain, https://commons.wikimedia.org/w/index.php?curid=565283
But after Pathfinder, and before Spirit and Opportunity, came a time of failure for Martian landing attempts. Everybody took part in the failure, it seems, with Russia, Japan, the USA, and the European Space Agency all experiencing bitter failure. Rocket failures, engineering errors, and other terminal errors all contributed to the failure.
Japan’s Nozomi orbiter ran out of fuel before ever reaching Mars. NASA’s Mars Polar Lander failed its landing attempt. NASA’s Deep Space 2, part of the Polar Lander mission, failed its parachute-less landing and was never heard from. The ESA’s Beagle 2 lander made it to the surface, but two of its solar panels failed to deploy, ending its mission. Russian joined in the failure again, with its Phobos-Grunt mission, which was actually headed for the Martian moon Phobos, to retrieve a sample and send it back to Earth.
In one infamous failure, engineers mixed up the use of English units with Metric units, causing NASA’s Mars Climate Orbiter to burn up on entry. These failures show us that failure is not rare. It’s difficult and challenging to get to the surface of Mars.
After this period of failure, NASA’s Spirit and Opportunity rovers were both unprecedented successes. They landed on the Martian surface in January 2004. Both exceeded their planned mission length of three months, and Opportunity is still going strong now.
So where does that leave us now? NASA is the only one to have successfully landed a rover on Mars and have the rover complete its mission. But the ESA and Russia are determined to get there.
The Schiaparelli lander, as part of the ExoMars mission, is primarily a proof of technology mission. In fact, its full name is the Schiaparelli EDM lander, meaning Entry, Descent, and Landing Demonstrator Module.
It will have some small science capacity, but is really designed to demonstrate the ability to enter the Martian atmosphere, descend safely, and finally, to land on the surface. In fact, it has no solar panels or other power source, and will only carry enough battery power to survive for 2-8 days.
Schiaparelli faces the same challenges as other craft destined for Mars. Once launched successfully, which it was, it had to navigate its way to Mars. That took about 6 months, and since ExoMars is only 15 days away from arrival at Mars, it looks like it has successfully made its way their. But perhaps the trickiest part comes next: atmospheric entry.
Schiaparelli is like most Martian craft. It will make a ballistic entry into the Martian atmosphere, and this has to be done right. There is no room for error. The angle of entry is the key here. If the angle is too steep, Schiaparelli may overheat and burn up on entry. On the other hand, if the angle is too shallow, it could hit the atmosphere and bounce right back into space. There’ll be no second chance.
The entry and descent sequence is all pre-programmed. It will either work or it won’t. It would take way too long to send any commands to Schiaparelli when it is entering and descending to Mars.
If the entry is successful, the landing comes next. The exact landing location is imprecise, because of wind speed, turbulence, and other factors. Like other craft sent to Mars, Schiaparelli’s landing site is defined as an ellipse.
Schiaparelli will land somewhere in this defined ellipse on the surface of Mars. Image: IRSPS/TAS-I
The lander will be travelling at over 21,000 km/h when it reaches Mars, and will have only 6 or 7 minutes to descend. At that speed, Schiaparelli will have to withstand extreme heating for 2 or 3 minutes. It’s heat shield will protect it, and will reach temperatures of several thousand degrees Celsius.
It will decelerate rapidly, and at about 10km altitude, it will have slowed to approximately 1700 km/h. At that point, a parachute will deploy, which will further slow the craft. After the parachute slows its descent, the heat shield will be jettisoned.
Schiaparelli’s Descent and Landing Sequence. Image: ESA/ATG medialab. Click here for larger image.
On Earth, a parachute would be enough to slow a descending craft. But with Mars’ less dense atmosphere, rockets are needed for the final descent. An onboard radar will monitor Schiaparelli’s altitude as it approaches the surface, and rockets will fire to slow it to a few meters per second in preparation for landing.
In the final moments, the rockets will stop firing, and a short free-fall will signal Schiaparelli’s arrival on Mars. If all goes according to plan, of course.
We won’t have much longer to wait. Soon we’ll know if the ESA and Russia will join NASA as the only agencies to successfully land a craft on Mars. Or, if they’ll add to the long list of failed attempts.
On Sept. 19, 2016 the OCAMS MapCam camera recorded a star field in Taurus, north of the constellation Orion as part of the OSIRIS-REx spacecraft’s post-launch instrument check. Credits: NASA/Goddard/University of Arizona
On Sept. 19, 2016 the OCAMS MapCam camera recorded a star field in Taurus, north of the constellation Orion as part of the OSIRIS-REx spacecraft’s post-launch instrument check. Credits: NASA/Goddard/University of Arizona
“The spacecraft has passed its initial instrument check with flying colors as it speeds toward a 2018 rendezvous with the asteroid Bennu,” NASA officials reported in a mission update.
All five of the Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer (OSIRIS-REx) spacecraft science instruments and one of its navigational instruments were powered on, starting last week on September 19.
NASA says they are all fully healthy for the groundbreaking mission whose purpose is to visit the carbon rich asteroid Bennu, snatch samples from the black as coal surface and return them to Earth in 2023 inside a Sample Return Capsule that will soft land by parachute in the Utah desert.
The seven year roundtrip mission to Bennu and back could potentially bring back samples infused with the organic chemicals like amino acids that are the building blocks of life as we know it.
“The data received from the checkout indicate that the spacecraft and its instruments are all healthy.”
The ‘First-Light’ image shown above was taken on Sept. 19, 2016 by the probes OCAMS MapCam camera and recorded a star field in Taurus, north of the constellation Orion along with Orion’s bright red star Betelgeuse.
“MapCam’s first color image is a composite of three of its four color filters, roughly corresponding to blue, green, and red wavelengths. The three images are processed to remove noise, co-registered, and enhanced to emphasize dimmer stars,” researchers said.
The OSIRIS-REx Camera Suite (OCAMS) was the first of the five science instrument to be tested and checlked out perfectly with “no issues.” It was provided by the University of Arizona and is comprised of three cameras which will image and map Bennu in high resolution.
View of science instrument suite and TAGSAM robotic sample return arm on NASA’s OSIRIS-REx asteroid sampling spacecraft inside the Payloads Hazardous Servicing Facility at NASA’s Kennedy Space Center. Probe is slated for Sep. 8, 2016 launch to asteroid Bennu from Cape Canaveral Air Force Station, FL. Credit: Ken Kremer/kenkremer.com
All the other instruments were also powered on and checked out flawlessly – including the OSIRIS-REx Laser Altimeter (OLA) which fired its laser, the OSIRIS-REx Visible and Infrared Spectrometer (OVIRS), the OSIRIS-REx Thermal Emissions Spectrometer (OTES), and the student designed Regolith X-ray Imaging Spectrometer (REXIS).
Lastly, the Touch and Go Camera System (TAGCAMS) navigational camera was successfully powered on and tested.
Furthermore, TAGCAMS took a dramatic image of the spacecraft’s Sample Return Capsule (below) – which is designed to bring at least a 60-gram (2.1-ounce) sample of Bennu’s surface soil and rocks back to Earth in 2023 for study by scientists using the world’s most advanced research instruments.
Image of OSIRIS-Rex Sample Return Capsule taken by StowCam instrument on Sept. 22, 2016, two weeks after launch, during initial science instrument checkout at a distance of 3.9 million miles (6.17 million km) away from Earth. Credit: NASA
The capsule image was captured by the StowCam portion of TAGCAMS when it was 3.9 million miles (6.17 million km) away from Earth and traveling at a speed of 19 miles per second (30 km/s) around the Sun.
The StowCam image of the Sample Return Capsule shows it “is in perfect condition,” according to the science team.
Overhead view of NASA’s OSIRIS-REx asteroid sampling spacecraft with small white colored sample return canister atop, inside the Payloads Hazardous Servicing Facility high bay at NASA’s Kennedy Space Center. Launch is slated for Sep. 8, 2016 to asteroid Bennu from Cape Canaveral Air Force Station, FL. Credit: Julian Leek
The OSIRIS-REx spacecraft departed Earth with an on time engine ignition of a United Launch Alliance Atlas V rocket under crystal clear skies on Thursday, September 8 at 7:05 p.m. EDT from Space Launch Complex 41 at Cape Canaveral Air Force Station.
The ULA Atlas V injected OSIRIS-Rex perfectly onto its desired trajectory.
“We got everything just exactly perfect,” said Dante Lauretta, the principal investigator for OSIRIS-REx at the University of Arizona, at the post launch briefing at the Kennedy Space Center. “We hit all our milestone within seconds of predicts.
United Launch Alliance Atlas V rocket lifts off from Space Launch Complex 41 at Cape Canaveral Air Force Station carrying NASA’s Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer, or OSIRIS-REx spacecraft on the first U.S. mission to sample an asteroid, retrieve at least two ounces of surface material and return it to Earth for study. Liftoff was at 7:05 p.m. EDT on September 8, 2016 in this remote camera view taken from inside the launch pad perimeter. Note the newly install crew access arm and white room for astronaut flights atop Atlas starting in early 2018. Credit: Ken Kremer/kenkremer.com
The space rock measures about the size of a small mountain at about a third of a mile in diameter.
“The primary objective of the OSIRIS-Rex mission is to bring back pristine material from the surface of the carbonaceous asteroid Bennu, OSIRIS-Rex Principal Investigator Dante Lauretta told Universe Today in a prelaunch interview in the KSC cleanroom with the spacecraft as the probe was undergoing final preparations for shipment to the launch pad.
“We are interested in that material because it is a time capsule from the earliest stages of solar system formation.”
“It records the very first material that formed from the earliest stages of solar system formation. And we are really interested in the evolution of carbon during that phase. Particularly the key prebiotic molecules like amino acids, nucleic acids, phosphates and sugars that build up. These are basically the biomolecules for all of life.”
The asteroid is 1,614-foot (500 m) in diameter and crosses Earth’s orbit around the sun every six years.
After a two year flight through space, including an Earth swing by for a gravity assisted speed boost in 2017, OSIRIS-REx will reach Bennu in Fall 2018 to begin about 2 years of study in orbit to determine the physical and chemical properties of the asteroid in extremely high resolution.
Watch my up close launch video captured directly at the pad with the sights and sounds of the fury of blastoff:
Video Caption: ULA Atlas V rocket lifts off on September 8, 2016 from Space Launch Complex 41 at Cape Canaveral Air Force Station carrying NASA’s OSIRIS-REx asteroid sampling spacecraft, in this remote camera view taken from inside the launch pad perimeter. Credit: Ken Kremer/kenkremer.com
Watch for Ken’s continuing OSIRIS-REx mission reporting. He reported on the spacecraft and launch from on site at the Kennedy Space Center and Cape Canaveral Air Force Station, FL.
Stay tuned here for Ken’s continuing Earth and planetary science and human spaceflight news.
Elon Musk on stage at his September 27th presentation at the IAC. Image: SpaceX
When Elon Musk speaks publicly about SpaceX and their efforts to make space travel less expensive, people listen. He attracts all kinds of scientists and journalists to his presentations. But he also attracts… other types of people. And those people ask some strange questions.
Musk must be getting used to it by now. He’s one of those public figures that, by virtue of his efforts to bring the future closer, attracts a lot of interest. But some of the questions in the Q&A following his presentation on Sept. 27 were truly bizarre.
Anybody could stand in line at one of the microphones in the audience and ask their question. And ask they did.
One man started off by saying he just recently attended Burning Man in the desert. Mars is like one big desert, he said, with no water to wash away all the sewage. What will future Mars colonists do with all their s**t he asked?
I felt bad for the guy. Here was his chance to ask Musk, who is clearly some sort of hero the guy, any question about space travel. And he chose to ask about poop. It was truly cringe-worthy, but Musk handled it well. He must be used to it.
Elon Musk looking perplexed after being grilled about Martian toilets. Image: SpaceX
It’s not like it’s not a legitimate concern, way down the line, if we ever do establish a city. But good grief. Musk was there to talk about the Interplanetary Transport System, not the nuts and bolts of city planning. It’s clear that this gentleman travelled all that way just to ask about sewage. Fail. (Jump to 1:06:30 in the video for that bit of magic.)
Another person asked everyone to give Elon a hand because he “Inspires the s**t out of us!” (At 1:10:35 in the video.) Musk looked uncomfortable. I don’t think he likes the hero-worship part of his gig. The guy then tried to give him a comic book about Mars, but complained that security wouldn’t let him. Ummmm, yeah.
One person complained that SpaceX won’t hire internationally, and how can they claim to be going interplanetary when they won’t even hire from other countries? Musk patiently explained that when it comes to rocketry, the government tightly restricts who is allowed to come from other countries to work on projects. Rocketry is governed by the same rules as weaponry, as it turns out. Thanks for explaining, Elon.
There were others. One lady wanted to come upstairs and give him a kiss, on behalf of all the ladies. Another asked if they were going to mathematically determine the most expendable human on Earth, and send them to Mars? That gem is 1:16:45 in the video. BTW, that guy thought it would be Michael Cera. Huh?
The same guy wanted to pitch a comedy video to him after the presentation. He was, unfortunately, turned down.
Another guy, who called himself a “local idiot” asked if Elon himself was planning on going to Mars. The guy said he would’ve hated to put in all this work and then not go. Musk’s answer was, in short, that he would like to go, but only if a good succession plan was in place in case he perished. That way the company’s work could continue.
There were some good questions too, of course. Questions about launch site for the craft, where it will be manufactured, and other pertinent questions around who should be the first people to go. Others asked about the journey itself, and how travellers would be kept safe from radiation and other hazards. So the Q&A wasn’t a waste of time by any means.
The whole presentation is worth watching, if you haven’t already. For those of you who just want to watch the wackiest parts of the Q&A, you’re in luck. There’s a highlight video.
![The Viking 2 lander captured this image of itself on the Martian surface. By NASA - NASA website; description,[1] high resolution image.[2], Public Domain, https://commons.wikimedia.org/w/index.php?curid=17624](https://www.universetoday.com/wp-content/uploads/2016/10/608px-Viking2lander1.jpg)
