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NASA The Military Transportation

SpaceX Signs Lease Agreement With Air Force For Landing Pad 53

PaisteUser writes Space News reports that SpaceX has signed a historic agreement to allow construction of a landing pad for Falcon 9 booster stages. From the article: "The U.S. Air Force announced Feb. 10 that SpaceX has signed a five-year lease for Cape Canaveral's Launch Complex 13, which was used to launch Atlas rockets and missiles between 1956 and 1978. In its new role, it will serve as a landing pad for Falcon 9 and Falcon Heavy booster cores launched from Florida, the Air Force said. Financial terms of the lease were not disclosed." Patrick Air Force Base also provides the documentation used for the environmental impact study which details out how the landing pad will be constructed.
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SpaceX Signs Lease Agreement With Air Force For Landing Pad

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  • They should build a giant robotic arm that can grab these rockets when they're landing. That would bring the cool factor to 11.
  • by sasparillascott ( 1267058 ) on Thursday February 12, 2015 @10:43AM (#49038255)
    Very intriguing article, but it makes one wonder about the landing pad being at the launch site - normally the main booster is a good ways away from the main launch site and moving rapidly away (that's why the floating landing pad was 500 miles downrange from the launch site)...this would appear that SpaceX would carry enough fuel to turn the booster back around (from mach whatever) and fly all the way back to the launch site (would seem to be alot of fuel) - I would have expected landing on a floating landing pad or construct such a landing area on an island(s) that isn't too far from the parabolic fall area of the booster (i.e. where the floating pad would be).

    Looking forward to more details....
    • by Anonymous Coward

      Wow. I am glad you brought this up. I'm going to call SpaceX and tell them to cancel the contract. Those fools! Why didn't they think of that?

    • by heezer7 ( 708308 )
      Launching from TX in the future...
    • by Rei ( 128717 ) on Thursday February 12, 2015 @11:12AM (#49038481) Homepage

      There are two scenarios in question. The first is where there is sufficient fuel to return. In such a case, it simply returns straight to the (new) pad. The second scenario, where there's insufficient fuel, still involves a barge. Once on the barge, the rocket isn't overhauled, just simply inspected, partially refueled and then relaunched back to the main pad where it can undergo proper maintenance and prep for its next flight.

      The goal is to eventually land upper stages as well. They are intended to complete an Earth orbit before reentering and landing at the launch site.

      One step at a time...

    • Re: (Score:3, Informative)

      by Hiroto. S ( 631919 )

      fly all the way back to the launch site (would seem to be alot of fuel) -

      That was my original impression, that you have to continuously burning to actively control the fall. But I recently saw a number that Apollo style capsul's terminal velocity is something around 300 miles/h and they spend several minutes free falling after fireball decelleration. Note "free falling" in this context is different from physical definition of free falling and describe the falling at constant speed of terminal velocity. 300 miles/h is half as fast as horizontal speed of airliners, and compar

    • by Anonymous Coward

      I think SpaceX has already stated their intent to launch from a more westerly launchpad, IE their Texas site, Spaceport America, something like that and then land at Cape Canaveral. Then after a quick check and splash of fuel they wanted to fly the booster back to the launch point. The First part is pretty much a certainty, I'm not so sure that the second part is quite as viable. I'd think it would be more practical to put them on a barge and ship them back, but only time will tell.

    • Apparently the stage separation at an altitude of 50 miles, is only 16 miles from the launch point. From the environmental assessment:
      "Currently, the Falcon 9 first stage drops by parachute approximately 500 nautical miles downrange into the Atlantic Ocean, east of and well beyond the east coast of Florida, and is recovered by a salvage ship . It is anticipated that the stage would return to the landing pad within approximately 10 minutes after lift-off. Preliminary trajectory analysis indicates that a po

    • by Anonymous Coward

      I actually bothered to read the linked lease. The stage seperates only 16 miles from launch site. Allowed to continue its path it will fall 500 miles away into the ocean. Basic rocket equasion will tell you that it only takes a small percentage of your fuel for a seperated stage boosting no payload to reverse its course and return 16 miles back (earths rotation may help this some as well)".

      • by Plunky ( 929104 )
        I'm pretty sure they have done all the sums, but I'm wondering, since it has not been explained exactly.. 16 miles isn't very far, but what is the horizontal velocity at that point? Because they do have to stop that, then reverse it, which surely means that this point is not going to be the furthest away.. and considering that if allowed to continue its path, it would splash down 500 miles away, I'm guessing the velocity is ... considerable.
        • by bledri ( 1283728 )

          I'm pretty sure they have done all the sums, but I'm wondering, since it has not been explained exactly.. 16 miles isn't very far, but what is the horizontal velocity at that point? Because they do have to stop that, then reverse it, which surely means that this point is not going to be the furthest away.. and considering that if allowed to continue its path, it would splash down 500 miles away, I'm guessing the velocity is ... considerable.

          One of the flight controller's on the CRS-5 mission calls out 1.8 km/s shortly before MECO (main engine cut off). So it's traveling over 4,000 mph. Different missions have different trajectory and velocity requirements. On the DSCOVR mission, 2350 m/s was announced shortly before MECO which is over 5,200 mph.

          I scanned the article but didn't see the 16 mile number, where is that coming from?

    • by bledri ( 1283728 )

      Very intriguing article, but it makes one wonder about the landing pad being at the launch site - normally the main booster is a good ways away from the main launch site and moving rapidly away (that's why the floating landing pad was 500 miles downrange from the launch site)...this would appear that SpaceX would carry enough fuel to turn the booster back around (from mach whatever) and fly all the way back to the launch site (would seem to be alot of fuel) - I would have expected landing on a floating landing pad or construct such a landing area on an island(s) that isn't too far from the parabolic fall area of the booster (i.e. where the floating pad would be). Looking forward to more details....

      I can't give you hard numbers off of the top of my head but there are a lot of variables. Different missions require different trajectories and payloads vary in mass significantly. The DSCOVR mission was actually a light payload, but it was a "deep space" mission requiring a very high velocity which is why the landing point was so far out to sea. So to quote Elon Musk, the first stage was "hauling a**." But there are a lot of missions where the stage is lofted more vertically or is traveling much slower

  • than a floating platform in the sea. While the latest launch is successful, they have to scrap the landing attempt due to choppy sea. NASA is paying for the launch, and not for the booster recovery. So if it's feasible to launch but not recover, they launch, because that's what the customer paid for. Recovery is currently just doing data gathering on the customer's dime.

  • Lots more details describe in this article: DSCOVR Mission Updates [spaceflight101.com]. One interesting information is that landing burn in only 28 seconds. That's all it takes to slow down from the terminal velocity down to 0 while performing the final guiding maneuver to the bulls eye.

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