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Everyone Missed An Apollo 11 Mistake, And It Almost Killed The Astronauts Returning To Earth

Neil Armstrong and Buzz Aldrin raise the American Flag on the Moon, with the shadow of the Lunar Module (where the camera is mounted) seen in nearby. The astronauts might not have successfully returned to Earth, however, if the procedure used to jettison the fuel from the Service Module had let it come into contact with the Command Module. (NASA/ullstein bild via Getty Images)

Even from our perspective in 2019, 50 years later, humanity’s achievements from July, 1969, still mark the pinnacle of crewed spaceflight. For the first time in history, human beings successfully landed on the surface of another world. After a 380,000 km journey, the crew set foot on the Moon, walked upon it, installed scientific instruments, took samples, and then departed for Earth.

Three days after leaving the Moon, on July 24, 1969, they splashed down in Earth’s oceans, successfully completing their return trip. But during Apollo 11’s return to Earth, a serious anomaly occurred: one that went undetected until after the crew returned to Earth. Uncovered by Nancy Atkinson in her new book, Eight Years to the Moon, this anomaly could have led to a disastrous ending for astronauts Armstrong, Aldrin and Collins. Here’s the story you’ve never heard.

This NASA image was taken on July 16, 1969, and shows some of the thousands of people who camped out on beaches and roads adjacent to the Kennedy Space Center to watch the Apollo 11 mission Liftoff aboard the Saturn V rocket. Four days later, humanity would take our first footsteps on another world. Four days after that, the astronauts successfully returned to Earth, but that was not a foregone conclusion. (NASA / AFP / Getty Images)

This NASA image was taken on July 16, 1969, and shows some of the thousands of people who camped out on beaches and roads adjacent to the Kennedy Space Center to watch the Apollo 11 mission Liftoff aboard the Saturn V rocket. Four days later, humanity would take our first footsteps on another world. Four days after that, the astronauts successfully returned to Earth, but that was not a foregone conclusion. (NASA / AFP / Getty Images)

According to our records, the flight plan of Apollo 11 went off without a hitch. Chosen as the mission to fulfill then-President Kennedy’s goal of performing a crewed lunar landing and successful return to Earth, the timeline appeared to go exactly as planned.

  • On July 16, 1969, the Saturn V rocket responsible for propelling Apollo 11 to the Moon successfully launched from Cape Kennedy. (Modern-day Cape Canaveral.)
  • Only July 17, the first thrust maneuver using Apollo’s Service Propulsion System (SPS) was made, course-correcting for the journey to the Moon. The launch and this one corrective burn were so successful that the other three scheduled SPS maneuvers were not even needed.
  • Only July 19, Apollo 11 reached the Moon, flying behind it and entering lunar orbit after a series of thrust maneuvers from SPS.
  • On July 20, the Eagle (lunar module) undocked from the Columbia (command and service module), made a powered descent, and landed on the Moon’s surface.
Astronaut Edwin E. "Buzz" Aldrin Jr., Lunar Module Pilot, stands near a scientific experiment on the lunar surface. Humanity's first landing on the Moon occurred July 20, 1969, as the Lunar Module code-named "Eagle" touched down gently on the Sea of Tranquility on the east side of the Moon. The Lunar Module, completely intact before the ascent stage is launched, can be seen in full beside the planted American flag. (NASA/Newsmakers)

Astronaut Edwin E. “Buzz” Aldrin Jr., Lunar Module Pilot, stands near a scientific experiment on the lunar surface. Humanity’s first landing on the Moon occurred July 20, 1969, as the Lunar Module code-named “Eagle” touched down gently on the Sea of Tranquility on the east side of the Moon. The Lunar Module, completely intact before the ascent stage is launched, can be seen in full beside the planted American flag. (NASA/Newsmakers)

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  • After 4 hours setting up, astronauts Armstrong and Aldrin left the lunar module to explore the lunar surface, performing an extra-vehicular activity (EVA) for a total of 2.5 hours, deploying scientific instruments, collecting samples for return, and famously planting an American flag.
  • On July 21, after just 21 hours and 36 minutes on the Moon, the ascent engine fired, bringing the Eagle back to dock with Columbia, and returning astronauts Aldrin and Armstrong to the Command and Service Module with astronaut Collins.
  • On July 21, the SPS thrusters fired, returning the Command and Service Module to Earth, with the lone mid-course correction coming on July 22.
  • And on July 24, re-entry procedures were initiated, returning the Apollo 11 crew to a safe splashdown in the Pacific Ocean.
This artist's concept shows the Command Module undergoing re-entry in 5000 °F heat. The Apollo Command/Service Module was used for the Apollo program which landed astronauts on the Moon between 1969 and 1972. An ablative heat shield on the outside of the Command Module protected the capsule from the heat of re-entry (from space into Earth's atmosphere), which is sufficient to melt most metals. During re-entry, the heat shield charred and melted away, absorbing and carrying away the intense heat in the process. (Heritage Space/Heritage Images/Getty Images)

This artist’s concept shows the Command Module undergoing re-entry in 5000 °F heat. The Apollo Command/Service Module was used for the Apollo program which landed astronauts on the Moon between 1969 and 1972. An ablative heat shield on the outside of the Command Module protected the capsule from the heat of re-entry (from space into Earth’s atmosphere), which is sufficient to melt most metals. During re-entry, the heat shield charred and melted away, absorbing and carrying away the intense heat in the process. (Heritage Space/Heritage Images/Getty Images)

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It all sounds so simple and straightforward, which obscures the real truth: for every one of these steps, there were hundreds (or more) potential points of failure that everyone involved needed to guard against. That final step alone, which returned the astronauts from their presence around to Moon — after journeying back to Earth — was one of the most crucial. If it failed, it would lead to certain death, similar to the demise of the Soviet cosmonaut Vladimir Komarov.

Successful re-entries after a journey to the Moon had already taken place aboard NASA’s Apollo 8 and Apollo 10 missions, and Apollo 11 was expected to follow the same procedures. At the danger of becoming complacent, this step, in many ways, already seemed like old hat to many of those staffing the Apollo 11 mission.

This schematic drawing shows the stages in the return from a lunar landing mission. The Lunar Module takes off from the Moon and docks with the Command and Service Module. The Command Module then separates from the Service Module, which jettisons its fuel and accelerates away. The Command Module then re-enters the Earth's atmosphere, before finally parachuting down to land in the ocean. (SSPL/Getty Images)

This schematic drawing shows the stages in the return from a lunar landing mission. The Lunar Module takes off from the Moon and docks with the Command and Service Module. The Command Module then separates from the Service Module, which jettisons its fuel and accelerates away. The Command Module then re-enters the Earth’s atmosphere, before finally parachuting down to land in the ocean. (SSPL/Getty Images)

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Re-entry, in principle, ought to be straightforward for the astronauts returning from the Moon. The Command and Service Modules first needed to separate, with the astronauts inside the Command Module and the Service Module being jettisoned. Once safely away, the Command Module would re-orient itself so that the heat shield was in the forward-facing position, prepared to absorb the brunt of the impact of re-entering Earth’s atmosphere while protecting the astronauts inside.

At the proper moment, when the atmospheric density was great enough and the external temperatures and speeds were low enough, the parachute would deploy, leading to a gentle splashdown in the Pacific Ocean approximately 5 minutes later, where the astronauts could then be safely recovered.

Although there are no known photographs of the Apollo 11 Command Module descending towards splashdown in the Pacific Ocean, all of the crewed Apollo missions ended in similar fashion: with the Command Module's heat shield protecting the astronauts during the early stages of re-entry, and a parachute deploying to slow the final stages of descent to a manageable speed. Shown here, Apollo 14 is about to splash down in the oceans, similar to the prior missions such as Apollo 11. (SSPL/Getty Images)

Although there are no known photographs of the Apollo 11 Command Module descending towards splashdown in the Pacific Ocean, all of the crewed Apollo missions ended in similar fashion: with the Command Module’s heat shield protecting the astronauts during the early stages of re-entry, and a parachute deploying to slow the final stages of descent to a manageable speed. Shown here, Apollo 14 is about to splash down in the oceans, similar to the prior missions such as Apollo 11. (SSPL/Getty Images)

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It sounds so routine. But of the innumerable things that could go wrong, one of them was entirely unexpected: the possibility that the Service Module, scheduled to break apart and safely burn up in Earth’s atmosphere, could accidentally have a piece of its debris collide with the Command Module, ruining re-entry and killing the returning astronauts on board.

The plan to avoid it was simple: the Service Module, post-separation, would perform a series of thrust maneuvers to take it safely away from the re-entry path of the Command Module. By shifting the Service Module to a significantly different trajectory, it wouldn’t even re-enter at the same time as the Command Module, but would skip off the atmosphere this time. The re-entry of the Service Module should have only come much later, after performing another orbit (or set of orbits) around Earth.

Both the Command Module and the Service Module from Apollo 11 followed the same re-entry trajectory, which could have proved fatal to the astronauts aboard the Command Module if a collision of any type had occurred. It was only through luck that such a catastrophe was avoided.

Both the Command Module and the Service Module from Apollo 11 followed the same re-entry trajectory, which could have proved fatal to the astronauts aboard the Command Module if a collision of any type had occurred. It was only through luck that such a catastrophe was avoided.

NASA

But that didn’t happen at all. To quote from Nancy Atkinson’s book, pilot Frank A. Brown, flying about 450 miles (725 km) away from the re-entry point, reported the following:

I see the two of them, one above the other. One is the Command Module; the other is the Service Module. . . . I see the trail behind them — what a spectacle! You can see the bits flying off. Notice that the top one is almost unchanged while the bottom one is shattering into pieces. That is the disintegrating Service Module.

Fortunately for everyone, none of the debris resulting from the Service Module’s re-entry impacted the Command Module, and the astronauts all arrived safely back on Earth.

The crew of Apollo 11 — Neil Armstrong, Michael Collins, and Buzz Aldrin — in the Mobile Quarantine Facility after returning from the surface of the Moon. The U.S.S. Hornet successfully recovered the astronauts from the Command Module after splashdown, where the crew was greeted by President Nixon, among others. (MPI/Getty Images)

The crew of Apollo 11 — Neil Armstrong, Michael Collins, and Buzz Aldrin — in the Mobile Quarantine Facility after returning from the surface of the Moon. The U.S.S. Hornet successfully recovered the astronauts from the Command Module after splashdown, where the crew was greeted by President Nixon, among others. (MPI/Getty Images)

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How could this have occurred?

There was a fault in how the Service Module was configured to jettison its remaining fuel: a problem that was later discovered to have occurred aboard the prior Apollo 8 and Apollo 10 missions as well. Instead of a series of thrusters firing to move the Service Module away from the Command Module, shifting it to a different trajectory and eliminating the possibility of a collision, the way the thrusters actually fired put the entire mission at risk.

The problem was that there were two types of thrusters on board the Service Module: the Minus X RCS jets and the RCS roll jets. And while the roll jets fired in bursts in an attempt to stabilize the Service Module, the Minus X jets fired continuously.

The Reaction Control System, visible towards the center-left of the image, consists of two types of thrusters that control both acceleration and orientation. With the original flaw, the thrusters fired in a pattern that put the Command Module at risk. Had those two modules collided, the astronauts on board would have had a failed re-entry, killing all three passengers.

The Reaction Control System, visible towards the center-left of the image, consists of two types of thrusters that control both acceleration and orientation. With the original flaw, the thrusters fired in a pattern that put the Command Module at risk. Had those two modules collided, the astronauts on board would have had a failed re-entry, killing all three passengers.

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In the aftermath of Apollo 11, investigators determined that the proper procedure for avoiding contact would be to properly time the firing of both the roll jets and the Minus X jets, which would lead to a 0% probability of contact between the two spacecrafts. This might seem like an extremely small point — to have the Minus X jets cut out after a certain amount of time firing as well as the roll jets — but you must remember that the spacecraft is full of moving parts.

If, for example, the fuel were to slosh around after the Service Module and the Command Module separated, that could lead to a certain window of uncertainty in the resultant trajectory. Without implementing the correct procedure for firing the various jets implemented, the safe return of the Apollo 11 astronauts would have to come down to luck.

This NASA picture taken on April 17, 1970, shows the Service Module (codenamed "Odyssey") from the Apollo 13 mission. The Service Module was jettisoned from the Command Module early, and the damage is clearly visible on the right side. This was to be the third crewed Apollo mission to land on the Moon, but was aborted due to the onboard explosion. Thankfully, the flaw in the jettison controller had been fixed, and the Service Module posed no risk to the astronaut-carrying Command Module from Apollo 13 onwards. (AFP/Getty Images)

This NASA picture taken on April 17, 1970, shows the Service Module (codenamed “Odyssey”) from the Apollo 13 mission. The Service Module was jettisoned from the Command Module early, and the damage is clearly visible on the right side. This was to be the third crewed Apollo mission to land on the Moon, but was aborted due to the onboard explosion. Thankfully, the flaw in the jettison controller had been fixed, and the Service Module posed no risk to the astronaut-carrying Command Module from Apollo 13 onwards. (AFP/Getty Images)

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Fortunately for everyone, they did get lucky. During the technical debriefing in the aftermath of Apollo 11, the fly-by of the Service Module past the Command Module was noted by Buzz Aldrin, who also reported on the Service Module’s rotation, which was far in excess of the design parameters. Engineer Gary Johnson hand-drew schematics for rewiring the Apollo Service Module’s jettison controller, and the changes were made just after the next flight: Apollo 12.

Those first four crewed trips to the Moon — Apollo 8, 10, 11 and 12 — could have all ended in potential disaster. If the Service Module had collided with the Command Module, a re-entry disaster similar to Space Shuttle Columbia could have occurred just as the USA was taking the conclusive steps of the Space Race.

View of the Apollo 11 capsule floating on the water after splashing down upon its return to Earth on July 24, 1969. If the Command Module and the Service Module had collided or interacted in any sort of substantial, unplanned-for way, the return of the first moonwalkers could have been as disastrous as the Space Shuttle Columbia's final flight. (CBS Photo Archive/Getty Images)

View of the Apollo 11 capsule floating on the water after splashing down upon its return to Earth on July 24, 1969. If the Command Module and the Service Module had collided or interacted in any sort of substantial, unplanned-for way, the return of the first moonwalkers could have been as disastrous as the Space Shuttle Columbia’s final flight. (CBS Photo Archive/Getty Images)

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Atkinson’s book, Eight Years to the Moon, comes highly recommended by me if you’re interested in the behind-the-scenes details and rarely-told stories from the Apollo era. Inside, you’ll find many additional details about this event, including interview snippets with Gary Johnson himself.

If Armstrong and Aldrin — the first two moonwalkers — were to perish before returning to Earth, the United States already had a presidential address drafted for such a purpose. We may chalk it up to good fortune that the following words never needed to be spoken:

In their exploration, they stirred the people of the world to feel as one; in their sacrifice, they bind more tightly the brotherhood of man.

In ancient days, men looked at the stars and saw their heroes in the constellations. In modern times, we do much the same, but our heroes are epic men of flesh and blood.

Others will follow, and surely find their way home. Man’s search will not be denied. But these men were the first, and they will remain the foremost in our hearts.

Follow me on Twitter. Check out my website or some of my other work here.

Ethan Siegel Ethan Siegel Contributor

I am a Ph.D. astrophysicist, author, and science communicator, who professes physics and astronomy at various colleges.

 

Source: Everyone Missed An Apollo 11 Mistake, And It Almost Killed The Astronauts Returning To Earth

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The World’s Largest Airplane Takes Flight. Next Stop? Outer Space

First flight of the Stratolaunch, which is intended to serve as a platform to send rockets into space. Stratolaunch Systems

On Saturday, the world’s largest aircraft, the Stratolaunch, made its first complete test flight. The aircraft flew for about two and a half hours over the Mojave desert, reaching a speed of 189 miles per hour and an altitude of 17,000 feet.

The aircraft was created by the Stratolaunch Systems Corporation, which was founded by the late Paul Allen. The purpose of the plane isn’t normal commercial travel, but rather to carry rockets into high altitudes, then launch those rockets from the plane itself.

“What a fantastic first flight,” Jean Floyd, CEO of Stratolaunch, said in a statement. “Today’s flight furthers our mission to provide a flexible alternative to ground launched systems.”

Scaled Composites, which was acquired by Northrop Grummon in 2007, worked on the design and build of the Stratolaunch aircraft. Saturday’s test flight was piloted by Scaled Composites test pilots Evan Thomas and Chris Guarente.

“I honestly could not have hoped for more on a first flight especially of an airplane of this complexity and this uniqueness,” Thomas said in a press briefing following the flight.

The Stratolaunch aircraft was first announced in 2011, and is the largest plane ever built out of composite materials. Its wingspan is 385 feet, the longest of any aircraft that has ever flown, including the Spruce Goose, which had a wingspan of about 320 feet. By comparison, a Boeing 747 has a wingspan of about 212 feet – making the Stratolaunch plane nearly twice the size. It’s propelled by six PW4056 turbofan engines, and is actually capable of launching multiple rockets on a single flight, up to about 500,000 pounds.

Airplane-launched rockets seemed at one point to be a good bet as a way of providing more convenient flights into space. Scaled Composites won the Ansari X Prize for launching the first private, reusable spacecraft into space in June of 2004. That effort was backed by Paul Allen, and this approach was not only adopted by Stratolaunch but also by Richard Branson’s Virgin Galactic.

However, it’s taken much longer than expected to develop these types of spaceflight. Virgin Galactic only first reached a space-approaching altitude at the end of 2018 – 14 years after that first Scaled Composite flight – though it hopes to be providing passenger service as early as later this year. Stratolaunch at one time was developing a rocket for its aircraft, but abandoned that effort earlier this year.

Rather than launch its own rockets, Stratolaunch has shifted strategy to be a platform for other aircraft-launched rockets. In particular, for Northrop Grummon’s Pegasus family of rockets. First demonstration Pegasus flights off of the Stratolaunch plane are scheduled for 2020.

Though they’ve taken longer to develop, the arrival of private plane-launched rockets via Virgin and Stratolaunch may be well-timed, as more satellite startups are looking for options to get satellites into space on their own timetable. Rockets launched from airplanes have more flexibility in terms of timing than their counterparts that launch from the ground, which may be a critical factor for companies looking to build up constellations in a hurry.

This post has been updated with more reporting since its initial publication.

Follow me on Twitter or Facebook. Read my Forbes blog here.

I’m an Associate Editor covering science and cutting edge tech.

 

Source: The World’s Largest Airplane Takes Flight. Next Stop? Outer Space

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