Range safety

Last updated
The Delta 3914 rocket carrying the GOES-G satellite was given the destruct command by the range 91 seconds after launch due to an electrical failure that shut one of the engines down. GOES G ends Spac0243.jpg
The Delta 3914 rocket carrying the GOES-G satellite was given the destruct command by the range 91 seconds after launch due to an electrical failure that shut one of the engines down.

In rocketry, range safety or flight safety is ensured by monitoring the flight paths of missiles and launch vehicles, and enforcing strict guidelines for rocket construction and ground-based operations. Various measures are implemented to protect nearby people, buildings and infrastructure from the dangers of a rocket launch.

Contents

Governments maintain many regulations on launch vehicles and associated ground systems, prescribing the procedures that need to be followed by any entity aiming to launch into space. Areas in which one or more spaceports are operated, or ranges, issue out closely guarded exclusion zones for air and sea traffic prior to launch, and close off certain areas to the public.

Contingency procedures are performed if a vehicle malfunctions or veers off course mid-flight. Usually, a range safety officer (RSO) commands the flight or mission to end by sending a signal to the flight termination system (FTS) aboard the rocket. This takes measures to eliminate any means with which the vehicle could endanger anyone or anything on the ground, most often through the use of explosives. Flight termination could also be triggered autonomously by a separate computer unit on the rocket itself.

Range operations

Closure of surrounding areas

Before each launch, the area surrounding the launch pad is evacuated, and notices to aviators and boatsmen to avoid certain locations on launch day are given. This facilitates the creation of a designated area for rockets to launch, called the launch corridor. [2] [3] The borders of the launch corridor are called the destruct lines. The exact coordinates of the launch corridor are dependent on weather and wind directions, and the properties of the launch vehicle and its payload. Launches can be postponed or scrubbed because of a boat, ship or aircraft entering the launch corridor. [3]

Monitoring the launch

An antenna tracking the launch of Cygnus NG-12, Wallops Flight Facility, Virginia Wallops Flight Facility Tracking Antenna.tif
An antenna tracking the launch of Cygnus NG-12, Wallops Flight Facility, Virginia

To assist the range safety officer (RSO) in monitoring the launch and making eventual decisions, there are many indicators showing the condition of the space vehicle in flight. These included booster chamber pressures, vertical plane charts (later supplanted by computer-generated destruct lines), and height and speed indicators. Supporting the RSO for this information were a supporting team of RSOs reporting from profile and horizontal parallel wires used at liftoff (before radar technology was available) and telemetry indicators. [3] Throughout the flight, RSOs pay close attention to the instantaneous impact point (IIP) of the launch vehicle, which is constantly updated along with its position; when a rocket is predicted to cross one of the destruct lines in flight because of any reason, a destruct command is issued to prevent the vehicle from endangering people and assets outside of the safety zone. [3] This involves sending coded messages (typically sequences of audio tones, kept secret before launch) to special redundant UHF receivers in the various stages or components of the launch vehicle. Previously, the RSO transmitted an 'arm' command just before flight termination, which rendered the FTS usable and shut down the engines of liquid-fueled rockets. [4] Now, the FTS is usually armed just before launch. [2] A separate 'fire' command detonates explosives, typically linear shaped charges, to disable the rocket. [4]

Reliability is a high priority in range safety systems, with extensive emphasis on redundancy and pre-launch testing. Range safety transmitters operate continuously at very high power levels to ensure a substantial link margin. The signal levels seen by the range safety receivers are checked before launch and monitored throughout flight to ensure adequate margins. When the launch vehicle is no longer a threat, the range safety system is typically safed (shut down) to prevent inadvertent activation. The S-IVB stage of the Saturn 1B and Saturn V rockets did this with a command to the range safety system to remove its own power. [5]

By country

United States

In the US space program, range safety is usually the responsibility of a Range Safety Officer (RSO), affiliated with either the civilian space program led by NASA or the military space program led by the Department of Defense, through its subordinate unit the United States Space Force. At NASA, the goal is for the general public to be as safe during range operations as they are in their normal day-to-day activities. [6] All US launch vehicles are required to be equipped with a flight termination system. [7]

Range safety has been practiced since the early launch attempts conducted from Cape Canaveral in 1950. Space vehicles for sub-orbital and orbital flights from the Eastern and Western Test Ranges were destroyed if they endangered populated areas by crossing pre-determined destruct lines encompassing the safe flight launch corridor.[ citation needed ] After initial lift-off, flight information is captured with X- and C-band radars, and S-Band telemetry receivers from vehicle-borne transmitters.[ citation needed ] At the Eastern Test Range, S and C-Band antennas were located in the Bahamas and as far as the island of Antigua, after which the space vehicle finished its propulsion stages or is in orbit.[ citation needed ] Two switches were used, arm and destruct. The arm switch shut down propulsion for liquid propelled vehicles, and the destruct ignited the primacord surrounding the fuel tanks.[ citation needed ]

As of 2023, a total of 34 US orbital launch attempts have been terminated,[ citation needed ] the first being Vanguard TV-3BU in 1958 and the most recent being the Starship integrated flight test of November 18, 2023. [8]

Eastern and Western Ranges

For launches from the Eastern Range, which includes Kennedy Space Center and Cape Canaveral Space Force Station, the Mission Flight Control Officer (MFCO) is responsible for ensuring public safety from the vehicle during its flight up to orbital insertion, or, in the event that the launch is of a ballistic type, until all pieces have fallen safely to Earth.[ citation needed ] Despite a common misconception, the MFCO is not part of the Safety Office, but is instead part of the Operations group of the Range Squadron of the Space Launch Delta 45 of the Space Force, and is considered a direct representative of the Delta Commander.[ citation needed ] The MFCO is guided in making destruct decisions by as many as three different types of computer display graphics, generated by the flight analysis section of range safety.[ citation needed ] One of the primary displays for most vehicles is a vacuum impact point display in which drag, vehicle turns, wind, and explosion parameters are built into the corresponding graphics.[ citation needed ] Another includes a vertical plane display with the vehicle's trajectory projected onto two planes.[ citation needed ] For the Space Shuttle, the primary display a MFCO used is a continuous real time footprint, a moving closed simple curve indicating where most of the debris would fall if the MFCO were to destroy the Shuttle at that moment. This real time footprint was developed in response to the Space Shuttle Challenger disaster in 1986 when stray solid rocket boosters unexpectedly broke off from the destroyed core vehicle and began traveling uprange, toward land.[ citation needed ]

Range safety at the Western Range (Vandenberg Space Force Base in California) is controlled using a somewhat similar set of graphics and display system. However, the Western Range MFCOs fall under the Safety Team during launches, and they are the focal point for all safety related activities during a launch.[ citation needed ]

Range safety in US crewed spaceflight

Even for U.S. crewed space missions, the RSO has authority to order the remote destruction of the launch vehicle if it shows signs of being out of control during launch, and if it crosses pre-set abort limits designed to protect populated areas from harm.[ citation needed ] In the case of crewed flight, the vehicle would be allowed to fly to apogee before the destruct was transmitted.[ citation needed ] This would allow the astronauts the maximum amount of time for their self-ejection. Just prior to activation of the destruct charges, the engine(s) on the booster stage are also shut down.[ citation needed ] For example, on the 1960s Mercury/Gemini/Apollo launches, the RSO system was designed to not activate until three seconds after engine cutoff to give the Launch Escape System time to pull the capsule away.[ citation needed ]

The U.S. Space Shuttle orbiter did not have destruct devices, but the solid rocket boosters (SRBs) and external tank both did. [9] After the Space Shuttle Challenger broke up in flight, the RSO ordered the uncontrolled, free-flying SRBs destroyed before they could pose a threat. [10]

Despite the fact that the RSO continues work after Kennedy Space Center hands over control to Mission Control at Johnson Space Center, they are not considered to be a flight controller. [9] The RSO works at the Range Operations Control Center at Cape Canaveral Space Force Station, and the job of the RSO ends when the missile or vehicle moves out of range and is no longer a threat to any sea or land area (after completing first stage ascent). [9]

Soviet Union/Russia

Unlike the US program, the Russian space program does not destroy rockets mid-air when they malfunction. If a launch vehicle loses control, either ground controllers may issue a manual shutdown command or the onboard computer can perform it automatically. In this case, the rocket is simply allowed to impact the ground intact. Since Russia's launch sites are in remote areas far from significant populations, it has never been seen as necessary to include a flight termination system. During the Soviet era, expended rocket stages or debris from failed launches were thoroughly cleaned up, but since the collapse of the USSR, this practice has lapsed.

China

It is unknown if China implements safety and contingency assessments surrounding rocket launches and if a flight termination system is installed in each of the country's launch vehicles. [11] [12] The country is known for leaving rocket parts to fall back to Earth in an uncontrolled trajectory. [13] [14] In one case, a launch vehicle crashed into a village near Xichang Satellite Launch Center after veering off course, killing at least six persons. [11] From the early 2020s, the China Aerospace Science and Technology Corporation (CASC) started developing and implementing methods to prevent uncontrolled reentries of their Long March rocket boosters, most prominently by the use of parachutes. [15]

Japan

The Japan Aerospace Exploration Agency (JAXA) regulates space activities through its Safety and Mission Assurance department. The regulation JERG-1-007E stipulates many of the safety requirements to be maintained on the range on launch day, violations of launch safety, and the procedures to follow after launch aborts and failures and during emergencies on the range. [16]

European Space Agency

The ESA's primary launch site is in Kourou, French Guiana. ESA rockets employ flight safety systems similar to the US' despite the relative remoteness of the launch center. Range safety at Europe's Spaceport is the responsibility of the Flight Safety Team, [17] with the launch site and surrounding areas being safeguarded by the French Foreign Legion. [18] The earliest Ariane 5 rockets were controlled by flight computers with the capability to terminate a flight by own initiative, including the infamous Ariane 501 in 1996. [19]

In 2018, an Ariane 5 launcher carrying two commercial satellites veered off course shortly after liftoff. Ground control was shown a nominal course of the rocket until 9 minutes into the flight, when the second stage ignited and contact was lost. [20] The rocket nearly flew over Kourou, and at the time the RSO realised that it flew closer to land than intended, it was decided not to terminate the flight out of concerns that the resulting debris would hit the town adjacent to the launch site. [21] The two satellites were deployed into an off-target orbit and were able to correct their orbits with substantial losses of propellant. [20]

India

The launch vehicles of the Indian Space Research Organisation (ISRO) are tracked by C-band and S-band radars. As of February 2019, ISRO does not use GPS and NavIC to directly transmit a launch vehicle's location to the range. [22]

North Korea

Range safety measures are performed during launches of the Chollima-1 orbital launch vehicle. On the successful third launch attempt of the rocket, it was reported that officials activated the flight termination system on the first stage after separation, presumably to destroy evidence in an effort to prevent reverse engineering if the booster were to be recovered by South Korea or allies. [23]

Flight termination system

Inspection of the flight termination system on Space Shuttle Discovery KSC-99pp1292~orig.jpg
Inspection of the flight termination system on Space Shuttle Discovery

A flight termination system (FTS) is a set of interconnected activators and actuators mounted on a launch vehicle which can shut down or destroy components of the vehicle to render it incapable of flight. As it is the only thing that is able to ensure the safety of ground facilities, personnel and spectators during a rocket launch, it is required to be effectively 100 percent reliable. [7] [24] Flight termination systems are also frequently installed on unmanned aerial vehicles. [25] [26]

To prevent other components from interfering with its decisions, the FTS has to operate entirely independently from the rocket; as such, it needs separate maintenance and comes with its own power source. [7] [27] In the case of multistage rockets and those utilizing side boosters, each stage and each booster on the launch vehicle is equipped with its own FTS. [7]

Flight termination usually destroys the payload with the rocket; [28] crewed launch vehicles, with the exception of the Space Shuttle, [29] have employed a launch escape system to save the lives of the crew in case their carrier rocket malfunctions. [30]

A flight termination system typically consists of two sets of the following components: [24]

A flight can be terminated two ways, which are described below.

Controlled breakup

In most cases, it is preferred that a malfunctioning launch vehicle is fully neutralized at altitude. [24] A rocket is destroyed during flight to prevent it from leaving the launch corridor or continue an otherwise errant flight. The resulting destruction is required to scatter rocket parts over a small area, ensuring the majority of the parts stay within the launch corridor and are able to cause as little damage or injuries as possible. Additionally, it has to combust and disperse its propellant far above the ground in a manner that is as controlled as possible. [24] This is done by detonating high explosives, usually linear shaped charges, [31] in specific areas of the rocket, which initiates structural failure and renders the vehicle aerodynamically unstable. [28]

Linear shaped charges mounted on a Falcon 9 rocket FTS charges on a Falcon 9 rocket.jpg
Linear shaped charges mounted on a Falcon 9 rocket

On liquid-fueled rockets, [33] [34] the propellant tanks are cut open to spill out their contents. [12] [28] The rocket's engines are usually also destroyed or disabled. [32] On rockets containing hypergolic propellants, the intertank section or the common bulkhead of the rocket's tanks is ruptured to ensure the toxic propellants mix and combust as much as possible when flight is terminated. On rockets fueled by cryogenic propellants, the tanks are perforated from the side to prevent excessive mixing and combustion of propellants, [28] as an FTS is not allowed to detonate propellants and cause a violent explosion. [7]

Solid-fuel rockets [35] [10] cannot have their engines shut down, but splitting them open terminates thrust even though the propellant will continue to burn, as the explosive charges break the rocket and its fuel into pieces. In some cases, only the nosecone or top section of the solid propellant case might be removed from a solid rocket, with the risk that the remainder of the rocket explodes violently and cause injuries or damage upon impact with the ground or water. [24]

Thrust termination

In some cases involving liquid-fueled rockets, shutting down the engines [36] is sufficient to ensure flight safety. [24] In those cases, full destruction of the vehicle is not necessary as it will be destroyed during reentry or on impact in an empty spot in the ocean. The FTS instead commands either the valves of the propellant and oxidizer lines to close, or explosives (such as pyrovalves) to sever the fuel lines, rendering the vehicle unable to use its engines and ensuring it stays on a safe trajectory. The vehicle then may be destroyed [37] by the tanks colliding and cracking. [24] This method was first proposed for the Titan III-M launch vehicle, which would have been used in the Manned Orbiting Laboratory program. [9]

Autonomous flight safety

An autonomous flight safety system developed by ATK SpaceX AFSS.jpg
An autonomous flight safety system developed by ATK

An autonomous flight termination system (AFTS) or autonomous flight safety system (AFSS) is a system in which flight termination can be commanded on a rocket without the involvement of ground personnel. Instead, AFTS destructors have their own computers that are programmed to detect mission rule violations and implement measures to bring the mission to a safe end. Since 1998, [38] these systems have been developed to bring down launch costs and enable faster and more responsive launch operations. [39] [40] [41] Additionally, inadvertent separation destruct systems have been deployed to destroy parts of rockets autonomously when they are unintentionally removed or loosened from the remainder of the vehicle. [42]

NASA started developing AFSS in 2000, in partnership with the US Department of Defense, with its development being included in the Commercial Orbital Transportation System program. [39]

Both ATK and SpaceX have developed AFSS. Both systems use a GPS-aided, computer controlled system to terminate an off-nominal flight, supplementing or replacing the more traditional human-in-the-loop monitoring system.

ATK's Autonomous Flight Safety System made its debut[ clarification needed ] on November 19, 2013, at NASA's Wallops Flight Facility. The system was jointly developed by ATK facilities in Ronkonkoma, New York; Plymouth, Minnesota; and Promontory Point, Utah. [43]

The system developed by SpaceX was demonstrated in F9R Dev1, a Falcon 9 booster used in 2013/14 to test its reusable rocket technology development program. In August 2014, after an errant sensor reading caused the booster to veer off course, the AFTS triggered and the vehicle disintegrated. [44] [33]

The SpaceX autonomous flight termination system has since been used on many SpaceX launches and was well tested by 2017. Both the Eastern Range and Western Range facilities of the United States are now using the system, which has replaced the older "ground-based mission flight control personnel and equipment with on-board positioning, navigation and timing sources and decision logic." [45] Moreover, the systems have allowed the US Air Force to drastically reduce their staffing and increase the number of launches that they can support in a year. 48 launches annually can now be supported, and the cost of range services for a single launch has been reduced by 50 percent. [45]

The addition of AFTS has also loosened up the inclination limits on launches from the US Eastern Range. By early 2018, the US Air Force had approved a trajectory that could allow polar launches to take place from Cape Canaveral. The 'polar corridor' would involve turning south shortly after liftoff, passing just east of Miami, with a first stage splashdown north of Cuba. [46] Such a launch corridor is not feasible with a ground-commanded system due to radio interference from the rocket's own exhaust plume facing the ground station. [47] In August 2020, SpaceX demonstrated this capability with the launch of SAOCOM 1B. [48]

The AFTS on SpaceX's Starship exhibited considerable issues on its first flight. SpaceX expected the vehicle to be given the destruct command at the point the vehicle lost thrust vector control at T+1:30, but this was done much later. [49] Upon activation, the explosive ordnance detonated as expected, but destruction was delayed; [50] the vehicle was only destroyed at T+3:59, [31] 40 seconds after the AFTS was estimated to be triggered. [12]

In December 2019, Rocket Lab announced that they added AFTS on their Electron rocket. Rocket Lab indicated that four previous flights had both ground and AFT systems. The December 2019 launch was the first Electron launch with a fully autonomous flight termination system. All later flights have AFTS on board. In the event of the rocket going off course the AFTS would command the engines to shutdown. [51]

In August 2020, the European Space Agency announced that Ariane 5 has AFSS installed on the avionics bay. The AFSS onboard Ariane 5 is called KASSAV (Kit Autonome de Sécurité pour la SAuvergarde en Vol). [52] A later version of the system, KASSAV 2, will have the authority to automatically terminate the flight in the event of the rocket going off course. [53]

The Japanese government has approved AFTS for use on the country's launch vehicles since the mid-2010s. [54] The SpaceOne KAIROS solid-fuel rocket uses an AFTS. [55]

Future launch vehicles such as the Blue Origin New Glenn, United Launch Alliance Vulcan Centaur and ArianeGroup Ariane 6 are expected to have them as well. [56] NASA's Space Launch System plans to introduce an AFT system by the flight of Artemis 3. [57]

In 2020 NASA started developing the NASA Autonomous Flight Termination Unit (NAFTU) for use on commercial and government launch vehicles. Provisional certification of the unit was granted in 2022 for Rocket Lab's first U.S. Electron mission (from Wallops Flight Facility) in Jan 2023. [58]

See also

Related Research Articles

<span class="mw-page-title-main">Space Shuttle</span> Partially reusable launch system and space plane

The Space Shuttle is a retired, partially reusable low Earth orbital spacecraft system operated from 1981 to 2011 by the U.S. National Aeronautics and Space Administration (NASA) as part of the Space Shuttle program. Its official program name was Space Transportation System (STS), taken from a 1969 plan for a system of reusable spacecraft where it was the only item funded for development.

<span class="mw-page-title-main">Spacecraft</span> Vehicle or machine designed to fly in space

A spacecraft is a vehicle that is designed to fly in outer space and operate there. Spacecraft are used for a variety of purposes, including communications, Earth observation, meteorology, navigation, space colonization, planetary exploration, and transportation of humans and cargo. All spacecraft except single-stage-to-orbit vehicles cannot get into space on their own, and require a launch vehicle.

<span class="mw-page-title-main">Reusable launch vehicle</span> Vehicles that can go to space and return

A reusable launch vehicle has parts that can be recovered and reflown, while carrying payloads from the surface to outer space. Rocket stages are the most common launch vehicle parts aimed for reuse. Smaller parts such as rocket engines and boosters can also be reused, though reusable spacecraft may be launched on top of an expendable launch vehicle. Reusable launch vehicles do not need to make these parts for each launch, therefore reducing its launch cost significantly. However, these benefits are diminished by the cost of recovery and refurbishment.

<span class="mw-page-title-main">Delta II</span> American space launch system

Delta II was an expendable launch system, originally designed and built by McDonnell Douglas, and sometimes known as the Thorad Delta 1. Delta II was part of the Delta rocket family, derived directly from the Delta 3000, and entered service in 1989. There were two main variants, the Delta 6000 and Delta 7000, with the latter also having "Light" and "Heavy" subvariants. During its career, Delta II flew several notable payloads, including 24 Global Positioning System (GPS) Block II satellites, several dozen NASA payloads, and 60 Iridium communication satellites. The rocket flew its final mission, ICESat-2, on 15 September 2018, earning the launch vehicle a streak of 100 successful missions in a row, with the last failure being GPS IIR-1 in 1997. In the late 1990s, Delta II was developed further into the unsuccessful Delta III, which was in turn developed into the more capable and successful Delta IV, though the latter shares little heritage with the original Thor and Delta rockets.

<span class="mw-page-title-main">Space Shuttle Solid Rocket Booster</span> Solid propellant rocket used to launch Space Shuttle orbiter.

The Space Shuttle Solid Rocket Booster (SRB) was the first solid-propellant rocket to be used for primary propulsion on a vehicle used for human spaceflight. A pair of these provided 85% of the Space Shuttle's thrust at liftoff and for the first two minutes of ascent. After burnout, they were jettisoned and parachuted into the Atlantic Ocean where they were recovered, examined, refurbished, and reused.

<span class="mw-page-title-main">Saturn IB</span> American rocket used in the Apollo program during the 1960s and 70s

The Saturn IB(also known as the uprated Saturn I) was an American launch vehicle commissioned by the National Aeronautics and Space Administration (NASA) for the Apollo program. It uprated the Saturn I by replacing the S-IV second stage, with the S-IVB. The S-IB first stage also increased the S-I baseline's thrust from 1,500,000 pounds-force (6,700,000 N) to 1,600,000 pounds-force (7,100,000 N) and propellant load by 3.1%. This increased the Saturn I's low Earth orbit payload capability from 20,000 pounds (9,100 kg) to 46,000 pounds (21,000 kg), enough for early flight tests of a half-fueled Apollo command and service module (CSM) or a fully fueled Apollo Lunar Module (LM), before the larger Saturn V needed for lunar flight was ready.

<span class="mw-page-title-main">Solid rocket booster</span> Solid propellant motor used to augment the thrust of a rocket

A solid rocket booster (SRB) is a large solid propellant motor used to provide thrust in spacecraft launches from initial launch through the first ascent. Many launch vehicles, including the Atlas V, SLS and Space Shuttle, have used SRBs to give launch vehicles much of the thrust required to place the vehicle into orbit. The Space Shuttle used two Space Shuttle SRBs, which were the largest solid propellant motors ever built and the first designed for recovery and reuse. The propellant for each solid rocket motor on the Space Shuttle weighed approximately 500,000 kilograms.

<span class="mw-page-title-main">Space Shuttle external tank</span> Component of the Space Shuttle launch vehicle

The Space Shuttle external tank (ET) was the component of the Space Shuttle launch vehicle that contained the liquid hydrogen fuel and liquid oxygen oxidizer. During lift-off and ascent it supplied the fuel and oxidizer under pressure to the three RS-25 main engines in the orbiter. The ET was jettisoned just over 10 seconds after main engine cut-off (MECO) and it re-entered the Earth's atmosphere. Unlike the Solid Rocket Boosters, external tanks were not re-used. They broke up before impact in the Indian Ocean, away from shipping lanes and were not recovered.

<span class="mw-page-title-main">Titan IV</span> Expendable launch system used by the US Air Force

Titan IV was a family of heavy-lift space launch vehicles developed by Martin Marietta and operated by the United States Air Force from 1989 to 2005. Launches were conducted from Cape Canaveral Air Force Station, Florida and Vandenberg Air Force Base, California.

<span class="mw-page-title-main">Launch vehicle</span> Rocket used to carry a spacecraft into space

A launch vehicle is typically a rocket-powered vehicle designed to carry a payload from Earth's surface or lower atmosphere to outer space. The most common form is the ballistic missile-shaped multistage rocket, but the term is more general and also encompasses vehicles like the Space Shuttle. Most launch vehicles operate from a launch pad, supported by a launch control center and systems such as vehicle assembly and fueling. Launch vehicles are engineered with advanced aerodynamics and technologies, which contribute to high operating costs.

<span class="mw-page-title-main">Atlas-Centaur</span> Family of space launch vehicles

The Atlas-Centaur was a United States expendable launch vehicle derived from the SM-65 Atlas D missile. The vehicle featured a Centaur upper stage, the first such stage to use high-performance liquid hydrogen as fuel. Launches were conducted from Launch Complex 36 at the Cape Canaveral Air Force Station (CCAFS) in Florida. After a strenuous flight test program, Atlas-Centaur went on to launch several crucial spaceflight missions for the United States, including Surveyor 1, Mariner 4, and Pioneer 10/11. The vehicle would be continuously developed and improved into the 1990s, with the last direct descendant being the highly successful Atlas II.

<span class="mw-page-title-main">Booster separation motor</span>

The booster separation motors or BSMs on the Space Shuttle were relatively small rocket motors that separated the reusable solid rocket boosters (SRB) from the orbiter after SRB burnout. Eight booster separation motors were attached to each of the shuttle's two reusable solid rocket boosters, four on the forward frustum and four on the aft skirt.

<span class="mw-page-title-main">Inertial Upper Stage</span> Space launch system

The Inertial Upper Stage (IUS), originally designated the Interim Upper Stage, was a two-stage, solid-fueled space launch system developed by Boeing for the United States Air Force beginning in 1976 for raising payloads from low Earth orbit to higher orbits or interplanetary trajectories following launch aboard a Titan 34D or Titan IV rocket as its upper stage, or from the payload bay of the Space Shuttle as a space tug.

<span class="mw-page-title-main">Atlas-Agena</span> American expendable launch system

The Atlas-Agena was an American expendable launch system derived from the SM-65 Atlas missile. It was a member of the Atlas family of rockets, and was launched 109 times between 1960 and 1978. It was used to launch the first five Mariner uncrewed probes to the planets Venus and Mars, and the Ranger and Lunar Orbiter uncrewed probes to the Moon. The upper stage was also used as an uncrewed orbital target vehicle for the Gemini crewed spacecraft to practice rendezvous and docking. However, the launch vehicle family was originally developed for the Air Force and most of its launches were classified DoD payloads.

<span class="mw-page-title-main">Ares I-X</span> Prototype and design concept demonstrator rocket

Ares I-X was the first-stage prototype and design concept demonstrator of Ares I, a launch system for human spaceflight developed by the National Aeronautics and Space Administration (NASA). Ares I-X was successfully launched on October 28, 2009. The project cost was $445 million. It was the final launch from LC-39B until Artemis 1 13 years later.

A parking orbit is a temporary orbit used during the launch of a spacecraft. A launch vehicle boosts into the parking orbit, then coasts for a while, then fires again to enter the final desired trajectory. The alternative to a parking orbit is direct injection, where the rocket fires continuously until its fuel is exhausted, ending with the payload on the final trajectory. The technology was first used by the Soviet Venera 1 mission to Venus.

The Mercury-Redstone Launch Vehicle, designed for NASA's Project Mercury, was the first American crewed space booster. It was used for six sub-orbital Mercury flights from 1960–1961; culminating with the launch of the first, and 11 weeks later, the second American in space. The four subsequent Mercury human spaceflights used the more powerful Atlas booster to enter low Earth orbit.

Super heavy-lift launch vehicle Launch vehicle capable of lifting more than 50 tonnes of payload into low earth orbit

A super heavy-lift launch vehicle is a rocket that can lift to low Earth orbit a "super heavy payload", which is defined as more than 50 metric tons (110,000 lb) by the United States and as more than 100 metric tons (220,000 lb) by Russia. It is the most capable launch vehicle classification by mass to orbit, exceeding that of the heavy-lift launch vehicle classification.

<span class="mw-page-title-main">SpaceX Starship</span> Reusable super heavy-lift launch vehicle

Starship is a two-stage super heavy-lift launch vehicle under development by SpaceX.

<span class="mw-page-title-main">Studied Space Shuttle designs</span> Launch vehicle study

During the lifetime of the Space Shuttle, Rockwell International and many other organizations studied various Space Shuttle designs. These involved different ways of increasing cargo and crew capacity, as well as investigating further reusability. A large focus of these designs were related to developing new shuttle boosters and improvements to the central tank, but also looked to expand NASA's ability to launch deep space missions and build modular space stations. Many of these concepts and studies would shape the concepts and programs of the 2000s such as the Constellation, Orbital Space Plane Program, and Artemis program.

References

  1. Delta 178 GOES-G Launch Failure, May 3, 1986 , retrieved 2023-04-23
  2. 1 2 What keeps everyone safe when rockets fail? Why did the failed Falcon 9 rocket land in the ocean? , retrieved 2023-04-20
  3. 1 2 3 4 Rice, Tony (2015-07-06). "When good rockets go bad". RocketSTEM. Retrieved 2023-04-20.
  4. 1 2 Counter Catastrophe: The Range Safety Story , retrieved 2023-04-20
  5. Saturn V Launch Vehicle Flight Evaluation Report AS-502 Apollo 6 Mission. NASA George C. Marshall Space Center. June 25, 1968.
  6. "NASA Range Safety Overview". Archived from the original on September 30, 2006. Retrieved August 6, 2008.
  7. 1 2 3 4 5 "14 CFR Appendix D to Part 417 - Flight Termination Systems, Components, Installation, and Monitoring". LII / Legal Information Institute. Retrieved 2023-04-22.
  8. SpaceX. "Starship's Second Flight Test" . Retrieved 2023-11-21.
  9. 1 2 3 4 "Report of the PRESIDENTIAL COMMISSION on the Space Shuttle Challenger Accident". History.NASA.gov. Retrieved 2015-02-27.
  10. 1 2 Cape Canaveral Space Force Museum (20 February 2021). "Space Shuttle Challenger Accident Investigation, Photo and TV Analysis Team Report (1987)". YouTube. Termination of SRBs is shown and discussed from timestamps 19:37 to 19:55 in the video.{{cite web}}: CS1 maint: postscript (link)
  11. 1 2 Lloyd, James (5 December 2005). "A Tale of Two Failures… the difference between a "Bad Day" and a "Nightmare"" (PDF). NASA Office of Safety and Mission Assurance.
  12. 1 2 3 "Termination shock". Aerospace America. 2023-10-01. Retrieved 2023-11-18.
  13. Maxouris, Sharif Paget,Christina (2022-07-30). "Remnants of an uncontrolled Chinese rocket reentered the atmosphere over the Indian Ocean, US Space Command says". CNN. Retrieved 2023-04-30.{{cite web}}: CS1 maint: multiple names: authors list (link)
  14. Wattles, Jackie (2021-05-09). "NASA criticizes China's handling of rocket re-entry as debris lands near Maldives". CNN. Retrieved 2023-04-30.
  15. Jones, Andrew (2023-03-29). "China plans to use parachutes to control its rocket debris problem". Space.com. Retrieved 2024-01-05.
  16. JAXA Safety and Mission Assurance (2019-04-19). "Safety Regulation for Launch Site Operation" (PDF).
  17. "Ariane 5's third launch of 2020". www.esa.int. Retrieved 2023-04-20.
  18. "Deep in the Jungle With the French Foreign Legion". Popular Mechanics. 2012-07-09. Retrieved 2023-12-08.
  19. "ARIANE 5 Failure - Full Report". 2014-04-26. Archived from the original on 2014-04-26. Retrieved 2024-01-05.
  20. 1 2 "A Bizarre Failure Scenario Emerges for Ariane 5 Mission Anomaly with SES 14 & Al Yah 3 – Spaceflight101". 26 January 2018. Retrieved 2023-05-03.
  21. De Selding, Peter B. "It's a question that will be asked. Industry officials say a judgment was made that the rocket was performing well (except for trajectory) and that the danger to local population of debris from flight termination outweighed the dangers of continuing flight". Twitter. Retrieved 2023-05-03.
  22. Dinesh babu, K M; Vaidyanathan, G; Ravikumar, JVN; Sunil, P (2019-02-17). "NavIC and GPS State Vector as Tracking Sources for Flight Safety". 2019 International Conference on Range Technology (ICORT). pp. 1–4. doi:10.1109/ICORT46471.2019.9069659. ISBN   978-1-7281-1353-1. S2CID   216042809.
  23. Smith, Josh; Shin, Hyonhee (2023-11-23). "North Korean rocket stage exploded after satellite launch, video shows". Reuters. Retrieved 2023-12-08.
  24. 1 2 3 4 5 6 7 Haber, Jerry; Bonnal, Christophe; Leveau, Carine; Vila, Jérôme; Toussaint, Marc (2013-01-01), Allahdadi, Firooz A.; Rongier, Isabelle; Wilde, Paul D. (eds.), "Chapter 4 - Safety in Launch Operations", Safety Design for Space Operations, Oxford: Butterworth-Heinemann, pp. 85–186, doi:10.1016/b978-0-08-096921-3.00004-0, ISBN   978-0-08-096921-3 , retrieved 2023-05-02
  25. "Easy Access Rules for Unmanned Aircraft Systems - Revision from September 2022". EASA. 2022-09-28. Retrieved 2023-12-08.
  26. "Destructive F-16 test". www.af.mil. Retrieved 2023-12-08.
  27. 1 2 Berger, Eric (2022-08-15). "No, seriously, NASA's Space Launch System is ready to take flight". Ars Technica. Retrieved 2023-04-20.
  28. 1 2 3 4 Flight Termination System , retrieved 2023-04-20
  29. "As Shuttle Lifts Off, NASA Will Man Destruct Switch—Just in Case". Popular Mechanics. 2008-05-06. Retrieved 2023-04-28.
  30. "SpaceX Crew Dragon abort system a major boost for crew safety". www.cbsnews.com. 27 May 2020. Retrieved 2023-04-28.
  31. 1 2 Manley, Scott (April 30, 2023). "How To Destroy Wayward Rockets - Flight Termination Systems Explained". YouTube.
  32. 1 2 Berger, Brian (2010-04-12). "Flight Termination System Testing Drives Falcon 9 Schedule". SpaceNews. Retrieved 2023-04-20.
  33. 1 2 Space Exploration Technologies Corporation (14 September 2017). "How Not to Land an Orbital Rocket Booster". YouTube. Example of flight termination shown from timestamps 0:16 to 0:24 (excluding aftermath).{{cite web}}: CS1 maint: postscript (link)
  34. Manley, Scott (3 September 2021). "Reaver Causes Destruction of FireFly". YouTube.
  35. DELTA II ROCKET EXPLODES AFTER LIFTOFF! , retrieved 2023-08-05
  36. VideoFromSpace (29 August 2021). "Astra rocket suffers anomaly during orbital launch attempt". YouTube.
  37. VideoFromSpace (19 January 2020). "Watch SpaceX rocket blow up during abort test". YouTube.
  38. "AFTS and GPS Tracking | Autonomous Flight Termination System | SIL". Space Information Labs. Retrieved 2023-04-20.
  39. 1 2 Valencia, Lisa (2019). "Autonomous Flight Termination System (AFTS)" (PDF).
  40. "Auto-destruct system seen as a key to ramping up launch tempos – Spaceflight Now" . Retrieved 2023-04-20.
  41. Keller, Jacob R.; IJtsma, Dr. Martijn; Newton, Dr. Elizabeth K. (2023-03-01). "Examining autonomous flight safety systems from a cognitive systems engineering perspective: Challenges, themes, and outlying risks". Journal of Space Safety Engineering. 10 (1): 76–81. doi:10.1016/j.jsse.2022.11.005. ISSN   2468-8967. S2CID   254483652.
  42. Read "Streamlining Space Launch Range Safety" at NAP.edu.
  43. "ATK's Autonomous Flight Safety Assembly Makes First Flight - ARLINGTON, Va., Nov. 19, 2013 /PRNewswire/". Prnewswire.com. 2013-11-19. Retrieved 2015-02-27.
  44. "SpaceX makes late call to delay ASIASAT-6 launch". NASASpaceFlight.com. 2014-08-26. Retrieved 2015-02-27.
  45. 1 2 SpaceX forces Air Force to revise launch mindset Mike Fabey, Space News, September 20, 2017
  46. Dean, James (2017-12-31). "Air Force: Cape rockets could fly new southern corridor toward poles". Florida Today. Monteith did not detail the precise trajectory, but said it involved "a little jog shortly off the pad" to turn south once offshore, "and then we'd skirt Miami." The rocket's first stage would drop safely before reaching Cuba, he said. The second stage would be so high up by the time it flew over the island that no special permissions would be required.
  47. Dean 2017:"There is one condition: southbound rockets must be equipped with automated flight termination systems, in which onboard computers command rockets to self-destruct if they should veer off course. Otherwise, exhaust plumes could disturb the destruct signals sent by traditional systems"
  48. Clark, Stephen. "SpaceX launches first polar orbit mission from Florida in decades – Spaceflight Now" . Retrieved 2020-09-15.
  49. "Engine Issue Felled SpaceX First Super Heavy | Aviation Week Network". aviationweek.com. Retrieved 2023-05-20.
  50. "SpaceX - Updates". 2023-09-13. Archived from the original on 2023-09-13. Retrieved 2023-09-13.
  51. "Rocket Lab Debuts Fully Autonomous Flight Termination System". spaceref.com. 9 December 2019. Retrieved 2020-09-15.[ permanent dead link ]
  52. "Ariane 5's third launch of 2020". www.esa.int. European Space Agency. European Space Agency. 16 August 2020.
  53. "[Lanceurs] KASSAV 2, sur la piste d'une sauvegarde automatisée". cnes (in French). 2021-04-19. Retrieved 2023-04-20.
  54. Japanese Ministry of Economy, Trade and Industry. "「宇宙産業技術情報基盤整備研究開発事業(民生品を活用した宇宙機器の軌道上実証)」プロジェクト評価用資料(終了時評価)" (PDF) (in Japanese).
  55. Smith, Martin (2024-03-08). "Japan's first commercial launch explodes shortly into flight on second attempt". NASASpaceFlight.com. Retrieved 2024-03-13.
  56. Dean 2017 :"Today, only SpaceX’s single-stick Falcon 9 rocket could fly the polar corridor, and the company has no stated plans to use it, even as it is midway through an eight-launch campaign from Vandenberg for Iridium Communications. But every big rocket is expected to be equipped with automated destruct systems within a decade. United Launch Alliance’s Vulcan, Blue Origin’s New Glenn — both still in development — and SpaceX’s Falcon Heavy might be cleared to fly south within a few years."
  57. Gebhardt, Chris (15 August 2019). "Eastern Range updates 'Drive to 48' launches per year status". NASASpaceFlight.com. Retrieved 6 January 2020. NASA, on the other hand, will have to add this capability to their SLS rocket, and Mr. Rosati said NASA is tracking that debut for the Artemis 3 mission in 2023.
  58. NASA_safety_system_enables_Rocket_Lab_launch_from_Wallops Jan 2023
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.