How SpaceX Lands Rockets with Astonishing Accuracy

00:10:45
https://www.youtube.com/watch?v=Wn5HxXKQOjw

Zusammenfassung

TLDRThe video explores SpaceX's groundbreaking advancements in rocket engineering with a focus on their reusable rockets. SpaceX has captivated public attention since its inception by accomplishing feats such as launching a car into space and ambitiously planning for a Martian colony. Central to these developments is their reusable rocket system, designed to launch, land, and relaunch rockets, thus lowering costs and increasing efficiency. This program, announced in 2011, sought to revolutionize space travel by recovering and reusing rocket boosters. By 2018, SpaceX had landed 70 m tall Falcon 9 boosters over 60 times successfully. Their success is attributed to robust engineering and experience gained from years of testing and development. The video goes on to explain how Falcon 9 stages separate, with subsequent controlled landings achieved through precise engineering. Some technologies pivotal to this success include thrust vector control, cold gas thrusters, re-ignitable engines, inertial navigation systems, and deployable grid fins. The video concludes by appreciating SpaceX's role in shaping the future of space travel and invites viewers to stay engaged with its content.

Mitbringsel

  • 🚀 SpaceX has revolutionized rocket engineering with reusable rockets.
  • 🌌 Their achievements echo the excitement of NASA's Apollo era.
  • 💡 Reusable rockets drastically reduce the cost of space travel.
  • 🔍 Rigorous testing and failures taught SpaceX valuable lessons.
  • 🎯 Falcon 9's landing accuracy improved by 10,000% in four years.
  • 🛰 Key technologies include thrust vectoring and grid fins.
  • ⚙ Cold gas thrusters assist in rocket orientation.
  • 📡 Real-time navigation systems guide precise landings.
  • 🛡 Falcon 9 uses deployable landing legs for vertical landings.
  • 🛰 SpaceX plans to establish a colony on Mars.
  • 🎥 The video aims to educate viewers on SpaceX technology.
  • ✈ Grasshopper prototype was crucial for initial tests.

Zeitleiste

  • 00:00:00 - 00:05:00

    Over the past decade, SpaceX has captivated the world with its advancements in rocket engineering, particularly with their revolutionary reusable rockets, which drastically reduce the cost of space travel. Despite challenges, their Falcon 9 rockets have achieved numerous successful launches and landings. Key to this success is their focus on learning from failures and engineering excellence, including technologies like thrust vector control and cold gas thrusters.

  • 00:05:00 - 00:10:45

    SpaceX's Falcon 9 boasts several innovative technologies enabling precise controlled landings, such as re-ignitable engines and deployable landing gear. Its inertial and global positioning systems ensure accurate flight paths, while deployable grid fins allow for an extraordinary 10-meter landing accuracy. These developments highlight SpaceX's success in building reusable rockets and set the stage for future advancements in space exploration and travel.

Mind Map

Video-Fragen und Antworten

  • What is SpaceX known for?

    SpaceX is known for revolutionizing rocket engineering and developing reusable rockets.

  • How did SpaceX reduce the cost of reaching orbit?

    SpaceX reduced the cost by developing reusable rockets that land back on Earth for reuse.

  • What technological feature allows SpaceX rockets to land accurately?

    The Falcon 9 uses several technologies like grid fins and thrust vector control for precise landings.

  • When did SpaceX first successfully land a rocket booster?

    SpaceX first successfully landed a Falcon 9 booster on land in late 2015.

  • How does a Falcon 9 booster re-enter Earth's atmosphere?

    After separation, the booster re-orients itself, performs burns to slow down, and lands on a pad using its landing gear.

  • What challenges did SpaceX face during the rocket landing tests?

    SpaceX faced several landing failures which provided data to improve future landings.

  • What are some key technologies of the Falcon 9 booster?

    Key technologies include thrust vector control, cold gas thrusters, re-ignitable engines, inertial navigation, landing gear, and grid fins.

  • Why are grid fins important for Falcon 9?

    Grid fins provide precise control of the rocket’s position and orientation during descent.

  • How did SpaceX improve its landing accuracy over time?

    SpaceX improved landing accuracy through continuous testing and engineering advancements over the years.

  • What was the role of the Grasshopper prototype?

    Grasshopper was a prototype vehicle for vertical takeoff and landing, used for initial testing of landing technology.

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Untertitel
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Automatisches Blättern:
  • 00:01:21
    For the past decade, the entire world has had their eyes on SpaceX as they have revolutionized
  • 00:01:25
    rocket engineering and space travel. From launching a sports car into orbit, to
  • 00:01:30
    the promise of establishing a futuristic colony on mars, their spectacles have generated levels
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    of public excitement and media coverage that haven’t been seen since NASA’s Apollo
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    program which ended more than 40 years ago. At the core of their ambitious plans is one
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    of the greatest technological developments in the history of rocket engineering: reusable
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    rockets. First announced to the public in 2011, the
  • 00:01:51
    SpaceX reusable launch system development program set out to create a new generation
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    of launch vehicles that would drastically reduce the cost of reaching orbit.
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    To accomplish this, SpaceX proposed the seemingly impossible task of recovering rocket boosters
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    using powered-descent. Their goal was to develop a rocket that could
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    be launched vertically to deliver a payload into orbit, and then return back to earth
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    with a controlled descent and vertical landing at a pre-determined landing site.
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    Either on land, or on an autonomous floating drone ship.
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    In just 7 years, SpaceX was not only able to achieve their goal of creating such a rocket,
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    but they have proven that their system is both reliable and economical with more than
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    60 successful launches and 30 successful landings of their Falcon 9 boosters, along with a 100%
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    success rate since the completion of their experimental testing program.
  • 00:02:36
    Or at least that was the case until December 2018, but at least they had a pretty good
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    run. 17 of their boosters were also re-used on
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    successive missions, and their unit cost for launching a kg of payload into orbit has been
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    reduced to just a fraction of the nearest competitor.
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    But how exactly did SpaceX accomplish this, and how do they manage to land 70 m tall rockets
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    weighing in excess of ½ a million kilograms precisely on a 50 m wide landing pad after
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    they are launched more than 70 km into the atmosphere at speeds exceeding 8,000 km/h?
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    It all comes down to just 2 key things: experience, and ridiculously well-engineered rockets.
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    Let’s start with experience by taking a brief look at the history of the reusable
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    launch system development program. The program itself was first announced in
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    2011, but it wasn’t until late 2015 that SpaceX was able to land a Falcon 9 booster
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    on land successfully, and it took several years beyond this to achieve a respectable
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    landing success rate. Before this, SpaceX spent 5 years conducting
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    experimental landings where they tested their new technologies and learned how to build
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    better rockets through trial and error. They began with a prototype vertical takeoff
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    and vertical landing vehicle called Grasshopper, which completed 8 successful flights from
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    2012 to 2013. Following the initial success of Grasshopper,
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    SpaceX then equipped their first Falcon 9 boosters for powered-descent and conducted
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    several soft landings on the ocean surface from 2013 to early 2015.
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    Unfortunately, these first tests with the Falcon 9 were only able to achieve a landing
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    accuracy of about 10 km, but this was greatly improved in future tests.
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    When the first landings on an autonomous floating drone ship were attempted later in 2015, SpaceX
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    endured a series of public failures as 4 consecutive barge landings failed quite dramatically.
  • 00:04:18
    Despite these failures, they obtained valuable data from every single flight, and they used
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    the failures as opportunities to learn from their mistakes in order to develop a more
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    robust landing system. SpaceX continued to perform Falcon 9 landing
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    tests through 2015 and 2016, both on drone ships and on land, and successful landings
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    became routine by early 2017, with SpaceX deciding to stop referring to their landing
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    attempts as experimental. From the beginning of 2017 to nearly the end
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    of 2018, SpaceX maintained a 100% landing success rate with a minimum landing accuracy
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    of just 10 m. This impressive accuracy represents a 1000-fold
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    improvement compared to the initial soft-landing tests which were only able to land within
  • 00:04:57
    a 10 km radius from the intended target. But how did SpaceX manage to increase the
  • 00:05:01
    landing accuracy of their rocket boosters by 10,000% in just 4 years?
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    Obviously, this wasn’t achieved through experience alone, and so this brings us to
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    point number 2: ridiculously well-engineered rockets.
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    When SpaceX performs a rocket launch with the Falcon 9, the rocket separates into two
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    stages in Earth’s upper atmosphere. The second stage of the rocket carries the
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    payload into space, while the first stage booster returns to Earth and lands at a landing
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    site for re-use. The booster is programmed to follow a precise
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    flight path back to Earth, and it must autonomously perform a series of controlled maneuvers in
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    order to maintain that path and land vertically on the landing pad.
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    The exact flight path depends on whether the rocket is landing on a floating drone ship
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    in the ocean, or on land, and for landings at sea there is the added complexity of ensuring
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    that the drone ship is in the correct position when the rocket touches down.
  • 00:05:49
    However, the greatest engineering challenge by far is building a rocket capable of performing
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    the maneuvers that are necessary for controlled descent and landing.
  • 00:05:57
    After stage separation occurs, the rocket booster re-orients itself and performs a boost
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    back burn to achieve the proper trajectory towards Earth.
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    During the descent, it performs a re-entry burn which is used to reduce its velocity.
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    As the booster approaches the landing site, it re-orients itself again so that it is in
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    line with the landing pad, it deploys its landing legs, and it performs a landing burn
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    to bring its velocity to zero as it touches down on the pad.
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    During the entire flight, from stage separation to landing, the rocket continuously measures
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    its orientation and velocity, and it adjusts its trajectory accordingly so that it maintains
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    the correct flight path. To accomplish all of this, SpaceX has implemented
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    several rocket technologies that were developed and refined through their experimental testing
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    program, and it’s these technologies that have been pivotal to the development of their
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    reusable high-accuracy rockets. The six key technologies incorporated into
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    the Falcon 9 rocket booster are as follows: 1) Thrust vector control.
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    The merlin rocket engines of the first stage booster are gimbaled using hydraulic actuators
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    so that the direction of thrust can be adjusted. This is a method of thrust vectoring that
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    can be used to control the orientation of the rocket both within Earth’s atmosphere
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    and outside of Earth’s atmosphere where aerodynamic control surfaces such as fins
  • 00:07:08
    are ineffective. Thrust vectoring is actually a common technology
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    that is used for rockets, as well as military aircraft and missiles, however it is absolutely
  • 00:07:15
    necessary for the maneuverability of the Falcon 9.
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    2) Cold gas thrusters. The Falcon 9 is equipped with a total of 8
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    nitrogen cold gas thrusters that are mounted towards the top of the first stage.
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    There is 1 pod on each side of the rocket, each containing 4 thrusters.
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    Like the gimbaled main engines, the cold gas thrusters are used to control the orientation
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    of the rocket. They are particularly useful for the flip
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    maneuver after stage separation because of the large lever arm between the thrusters
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    and the rocket’s center of mass. They are also used to control the rocket at
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    times during flight when the gimbaled main engines are shut off.
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    3) Re-ignitable engines. Since the first stage must perform three separate
  • 00:07:54
    burns after stage separation, it is necessary for the main rocket engines to be re-ignitable.
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    The engines of the first stage booster have therefore been designed so that they can re-ignite
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    in the upper atmosphere at supersonic speeds as well as in the lower atmosphere at transonic
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    speeds. 4) Inertial navigation and global positioning
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    systems. The Falcon 9 is equipped with an inertial
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    navigation system, or INS, that uses several types of sensors to measure the position,
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    orientation, and velocity of the vehicle. A global positioning system, or GPS, is also
  • 00:08:24
    used to measure geolocation. The onboard computer receives data from the
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    INS and GPS in real-time and checks this information against the pre-programmed flight path.
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    If the computer detects any deviations from the flight path, then it instructs the rocket
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    to adjust its orientation and velocity as necessary.
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    5) Deployable landing gear. In order to perform vertical landings, the
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    Falcon 9 is equipped with 4 lightweight landing legs that are deployed using high-pressure
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    helium just before touchdown. Each leg is constructed from carbon fiber
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    and aluminum, and contains an impact attenuator for particularly hard landings.
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    The total span of the deployed landing gear is approximately 18 m, and the entire landing
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    system weighs less than 2,100 kgs. 6) Deployable grid fins.
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    Four titanium grid fins are mounted at the top of the first stage booster, and are deployed
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    during the rocket’s descent back into Earth’s lower atmosphere.
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    The fins are aerodynamic control surfaces that are used for precise control of the rocket’s
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    position and orientation prior to landing. The four grid fines alone are primarily responsible
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    for the incredible 10 m landing accuracy of the Falcon 9 first stage booster.
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    Grid fins were first used on the fifth soft-landing attempt of the reusable launch system development
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    program in 2015, and iterations on their design were continued through 2017 in order to achieve
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    the accuracy that we see from SpaceX today. So in the end, SpaceX was able to employ experience
  • 00:09:45
    and good engineering to develop a reusable and highly accurate launch vehicle, the Falcon
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    9. The Falcon 9 is an astonishing feat of modern
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    engineering, and I hope that it sets a precedent for the future of space travel.
  • 00:09:57
    Without a doubt, the development of a reusable launch system has been one of the greatest
  • 00:10:01
    technological developments in the history of rocket engineering, and I can’t wait
  • 00:10:05
    to see what the future has in store for SpaceX. Or perhaps I should rather say, what SpaceX
  • 00:10:09
    has in store for the future.
  • 00:10:18
    I really hope that you enjoyed this video, and I hope that I was able to provide some insight into the landing
  • 00:10:22
    technology used by SpaceX. Please remember to subscribe if you would
  • 00:10:26
    like to stay up to date with future content, and feel free to leave suggestions for future
  • 00:10:29
    videos in the comments below. You can also support this channel on Patreon
  • 00:10:33
    using the link in the description, which helps me to improve my videos and grow the channel.
  • 00:10:37
    Thanks for watching, and I’ll see you in the next video.
Tags
  • SpaceX
  • Reusable Rockets
  • Falcon 9
  • Rocket Engineering
  • Elon Musk
  • Rocket Landing
  • Space Travel
  • Falcon 9 Booster
  • Thrust Vectoring
  • Grid Fins