In 2013 SpaceX was testing reusable technologies both for its
first-stage booster launch vehicle designs (with three test vehicles:
Grasshopper,
F9R Dev1, and
F9R Dev2) – and for its new reusable
SpaceX Dragon 2 space capsule (with a low-altitude test vehicle called
DragonFly). SpaceX has publicly disclosed a multi-element, incremental test program for booster stages that includes four aspects: • low-altitude (less than ), low-velocity testing of its single-engine
Grasshopper technology-demonstrator at its Texas test site • low-altitude (less than ), low-velocity testing of a much larger, second-generation, three-engine test vehicle called
F9R Dev1. The second generation vehicle includes extensible landing legs and will be tested at the Texas test site • high-altitude, mid-velocity testing was planned but cancelled in favor of
post-mission re-entry tests of first-stage boosters. It would have used F9R Dev2 at a SpaceX leased facility at
Spaceport America in
New Mexico. • high-altitude (), very-high-velocity (approximately ; and a
fourth test in September 2014. All four test flights to date were intended to be over-water, simulated landings.
Flight test vehicles SpaceX used a set of experimental technology-demonstrator,
suborbital reusable launch vehicles (RLV) to begin
flight testing their reusable booster technologies in 2012. Two versions of the prototype reusable test rockets were built—the tall
Grasshopper (formerly designated as
Grasshopper v1.0) and the tall
Falcon 9 Reusable Development Vehicle, or
F9R Dev1—formerly known as
Grasshopper v1.1 but two weeks later, Musk dismissed the approach in favor of using a full-diameter BFR instead.
Grasshopper Grasshopper, the company's first
VTVL test vehicle, consisted of a
Falcon 9 v1.0 first-stage tank, a single
Merlin-1D engine, and four permanently attached steel landing legs. It stood tall. SpaceX built a concrete launch facility at its Rocket Development and Test Facility in
McGregor, Texas to support the Grasshopper flight test program. Grasshopper was also known as Grasshopper version 1.0, or Grasshopper v1.0, prior to 2014 during the time the followon Grasshopper-class test vehicles were being built. In addition to three test flights in 2012, five additional tests were successfully flown by the end of October 2013including the fourth test overall in March 2013in which Grasshopper doubled its highest leap to rise to with a 34-second flight. In the seventh test, in August 2013, the vehicle flew to during a 60-second flight and executed a lateral maneuver before returning to the pad. Grasshopper made its eighth and final test flight on October 7, 2013, flying to before making its eighth successful landing. The Grasshopper test vehicle is now retired.
Falcon 9 Reusable Development Vehicle As early as October 2012, SpaceX discussed development of a second-generation Grasshopper test vehicle, which was to have lighter landing legs that fold up on the side of the rocket, a different engine bay, and would be nearly 50% longer than the first Grasshopper vehicle. In March 2013, SpaceX announced that the larger Grasshopper-class suborbital flight vehicle would be constructed out of the first-stage tank that was used for qualification testing at the SpaceX Rocket Development and Test Facility in early 2013. It was rebuilt as the with extensible landing legs. Five test flights occurred in 2014. By April 2014, a third flight test vehicle—F9R Dev2—was being built and was planned to be flown at the high-altitude test range available at
Spaceport America in
New Mexico where it was expected to be flown at altitudes up to -plus. The DragonFly test vehicle is powered by eight
SuperDraco engines, arranged in a redundant pattern to support
fault-tolerance in the propulsion system design. , the DragonFly test program was not expected to start until after the completion of the
F9R Dev1 booster testing at the McGregor facility. SpaceX continued to make
iterative and incremental changes to the booster design, as well as the specific reusable technologies, descent profile and propellant margins, on some 2016–2018 Falcon 9 and Falcon Heavy flights to tweak the design and operational parameters. Many of these descent and landing tests were tested on active orbital spaceflight missions for SpaceX customers as the booster reentered the atmosphere and attempted recoverable landings.
Re-entry and controlled descent Following analysis of the flight test data from the first booster-controlled descent in September 2013, SpaceX announced it had successfully tested a large amount of new technology on the flight, and that coupled with the technology advancements made on the Grasshopper low-altitude landing demonstrator, they were ready to test a full recovery of the booster stage. The first flight test was successful; SpaceX said it was "able to successfully transition from vacuum through
hypersonic, through
supersonic, through
transonic speeds, and light the engines all the way and control the stage all the way through [the atmosphere]". Musk said, "the next attempt to recovery [sic] the Falcon 9 first stage will be on the fourth flight of the upgraded rocket. This would be [the] third commercial Dragon cargo flight to ISS. [International Space Station]" This second flight test took place during the April 2014 Dragon flight to the ISS. SpaceX attached
landing legs to the first stage, decelerated it over the ocean and attempted a simulated landing over the water, following the ignition of the second stage on the
third cargo resupply mission contracted to NASA. The first stage was successfully slowed enough for a soft landing over the Atlantic Ocean. Five additional controlled-descent tests were conducted in the remainder of 2014 through April 2015, including two attempts to land on a
floating landing platform—a SpaceX-built
Autonomous Spaceport Drone Ship—on the
Atlantic Ocean east of the launch site, both of which brought the vehicle to the landing platform, but neither of which resulted in a successful landing.
First landing on ground pad During the
2015 launch hiatus, SpaceX requested regulatory approval from the
FAA to attempt returning their
next flight to
Cape Canaveral instead of targeting a floating platform in the ocean. The goal was to
land the booster vertically at the leased
Landing Zone 1 facility—the former
Launch Complex 13 where SpaceX had recently built a large rocket landing pad. The FAA approved the safety plan for the ground landing on December 18, 2015. The first stage landed successfully on target at 20:38 local time on December 21 (01:38 UTC on December 22). Rather, the rocket was moved a few miles north to the SpaceX hangar facilities at
Launch pad 39A, was refurbished by SpaceX at the adjacent
Kennedy Space Center, where it was inspected before being used on January 15, 2016, to conduct a
static fire test on its original launchpad,
Launch Complex 40. This test aimed to assess the health of the recovered booster and the capability of this rocket design to fly repeatedly in the future. The booster was then retired to the SpaceX facility in Hawthorne, California.
Landing attempts on drone ships descending over the floating landing platform, January 17, 2016, immediately prior to a soft touchdown followed by
deflagration of the rocket after a landing leg failed to latch, causing the rocket to tip over.
Falcon 9 Flight 21 launched the
Jason-3 satellite on January 17, 2016, and attempted to land on the
floating platform Just Read the Instructions, located for the first time about out in the
Pacific Ocean. Approximately 9 minutes into the flight, the live video feed from the drone ship went down due to the loss of its lock on the uplink satellite. The vehicle landed smoothly onto the vessel but one of the four landing legs failed to lock properly, reportedly due to ice from the heavy pre-launch
fog preventing a lockout
collet from latching. Consequently the booster fell over shortly after touchdown and was destroyed in a
deflagration upon impact with the pad.
Flight 22 was carrying a heavy payload of to
geostationary transfer orbit (GTO). This was heavier than the previously advertised maximum lift capacity to GTO being made possible by going slightly
subsynchronous. Following delays caused by failure of
Flight 19, SpaceX agreed to provide extra thrust to the
SES-9 satellite to take it
supersynchronous. As a result of these factors, there was little propellant left to execute a full reentry and landing test with normal margins. Consequently the Falcon 9 first stage followed a
ballistic trajectory after separation and re-entered the atmosphere at high velocity, making it less likely to land successfully. On April 8, 2016, Falcon 9 Flight 23, the third flight of
the full-thrust version, delivered the
SpaceX CRS-8 cargo on its way to the
International Space Station while the
first stage conducted a boostback and re-entry maneuver over the Atlantic ocean. Nine minutes after liftoff, the booster landed vertically on the drone ship
Of Course I Still Love You, 300 km from the Florida coastline, achieving a long-sought-after milestone for the SpaceX reusability development program. A second successful drone ship landing occurred on May 6, 2016, with the next flight which launched
JCSAT-14 to GTO. This second landing at sea was more difficult than the previous one because the booster at separation was traveling about compared to on the CRS-8 launch to
low Earth orbit. Pursuing their experiments to test the limits of the flight envelope, SpaceX opted for a shorter landing burn with three engines instead of the single-engine burns seen in earlier attempts; this approach consumes less fuel by leaving the stage in free fall as long as possible and decelerating more sharply, thereby minimizing the amount of energy expended to counter gravity. Elon Musk indicated this first stage may not be flown again instead being used as a life leader for ground tests to confirm others are good. A third successful landing followed on 27 May, again following deceleration from the high speed required for a GTO launch. The landing crushed a "crush core" in one leg, leading to a notable tilt to the stage as it stood on the drone ship. Musk's prediction was vindicated, as 5 out of 8 flown boosters () were recovered in 2016, and 14 out of 14 () in 2017. Three GTO missions for heavy payloads (
EchoStar 23 in March 2017,
Inmarsat-5 F4 in May 2017 and
Intelsat 35e in July 2017) were flown in an
expendable configuration, not equipped for landing. One booster which could have been recovered was intentionally flown without legs and left to sink after a soft touchdown in the ocean (booster B1036 for the
Iridium NEXT 31–40 mission in December 2017).
First-stage reuse launch from SLC-40 and subsequent booster landing at LZ-40, capturing both events 8 minutes apart , SpaceX had
recovered 21 first-stage boosters from previous missions, of which six were recovered twice, yielding a total 27 landings. In 2017, SpaceX flew a total of 5 missions out of 20 with re-used boosters (). In total, 14 boosters have been re-flown . On July 28, 2016, the first stage from the
JCSAT-2B mission was successfully test-fired for a full duration at the SpaceX McGregor facility. The first reuse attempt occurred on 30 March 2017 with the launch of
SES-10, resulting in a successful flight and second landing of the
B1021 first stage recovered from the
CRS-8 mission of April 2016. Another reflight succeeded in June 2017 with
BulgariaSat-1 riding the
B1029 booster from the January 2017
Iridium NEXT mission. Booster B1031 flew the
CRS-10 mission to the
ISS in February 2017 and helped loft communications satellite
SES-11 to
geostationary orbit in October 2017. Boosters B1035 and B1036 were flown twice each for the same customer, B1035 for
NASA missions
CRS-11 and
CRS-13 in June and December 2017, and B1036 for two batches of 10
Iridium NEXT satellites, also in June and December 2017. B1032 was re-used for
GovSat-1 in January 2018 after
NROL-76 in May 2017. SpaceX spent four months refurbishing the first booster to be re-used,
B1021, and launched it again after approximately one year. The second booster to be flown again,
B1029, was refurbished in "only a couple of months" Musk remains convinced that this long-term goal can be met by SpaceX, but has not stated that the goal would be achieved with the Falcon 9 design. Boosters
B1019 and
B1021 were retired and put on display.
B1029 was also retired after the
BulgariaSat-1 mission. B1023, B1025, B1031 and B1035 were recovered a second time, while B1032 and B1036 were deliberately sunk at sea after a soft ocean touchdown. By mid-2019, having reflown any single booster only three times to date, SpaceX indicated that they plan to use a single booster at least five times by the end of 2019. No booster achieved this timeline, but
B1048 flew four times and two more (
B1046 and
B1049) made a fourth flight in January 2020. In March 2020, SpaceX first flew a booster (
B1048) for the fifth time.
Falcon Heavy reusability The
Falcon Heavy test flight had no contracted customer, and in order to limit the cost on such a flight, SpaceX targeted to have reused side-boosters. Boosters B1023 and B1025 that had been flown as a Falcon 9 configuration, were reconfigured and used as side boosters on the first flight of Falcon Heavy in February 2018, and then both landed side-by-side at almost the same time on the ground pads. Later Falcon Heavy flights used either new boosters, or side-boosters previously flown on a Falcon Heavy. SpaceX has been unable to recover the central core in any of the first three Falcon Heavy flights, but managed to recover all six side boosters.
Block 5 boosters With a streak of 19 successful recovery attempts of the first stage from 2016 through to early 2018, SpaceX has focused on rapid reusability of first stage boosters. Block 3 and Block 4 proved economically feasible to be flown twice, as 11 such boosters have been reflown in 2017 and 2018.
Block 5 has been designed with multiple reuses in mind, up to 10 reuses with minimal inspection and up to 100 uses with refurbishment. New aggressive reentry profiles were experimented with expendable Block 3 and Block 4 boosters in early 2018, to test out the limitations on the range of recoverable launch margins that are potential for future Block 5. On 9 May 2021,
B1051 became the first booster to be launched and landed for the tenth time, achieving one of SpaceX's milestone goals for reuse. , the reuse record is 34 flights.
Fairing reuse Payload fairings have traditionally been
expendable, where they have either burned up in the atmosphere or were destroyed upon impacting the ocean. As early as mid-2015, Musk hinted that SpaceX might be working on fairing reusability, following the discovery of wreckage of an unidentified Falcon 9 launch vehicle section off the coast of
The Bahamas, and was subsequently confirmed by SpaceX to be a component of a payload fairing that had washed ashore. By April 2016, SpaceX had publicly announced Falcon 9 fairing recovery as an objective. Musk said in 2017: "Imagine if you had $6 million in cash in a pallet flying through the air, and it was going to smash into the ocean. Would you try to recover that? Yes, yes you would." This mission was also the first to use a version 2 fairing, explicitly designed to "improve survivability for post-launch recovery attempts, and to be reusable on future missions". This recovery attempt was not fully successful; the fairing missed the boat by a few hundred meters but landed intact in the water before being recovered and taken back to port. In October 2018, at least two fairing recovery tests were performed, involving
Mr. Steven and a helicopter, which would drop a fairing half from the height of about 3300 meters. The outcome of the tests was unclear. In April 2019, during the second Falcon Heavy mission, recovery boat
Go Searcher fished the fairing halves out of the sea and it was announced the fairings would be used on a
Starlink mission. These fairings were reused in a Starlink mission on 11 November 2019. In June 2019, following the third Falcon Heavy launch, the first successful fairing catch was made. Images posted to Twitter hours after launch showed one half of the fairing in the net of the recovery vessel
GO Ms. Tree. By late 2020, payload fairings were being regularly recovered by SpaceX, with SpaceX dispatching two custom-modified recovery ships—
Ms. Tree and
Ms. Chief—to collect the fairings on most launches from their Florida launch site. By this time, SpaceX was also regularly reflying recovered fairings on launches, usually on their own flights where
Starlink satellites are the
primary or only payload. however, successful net landings were not yet routine, with less than half of the fairings of the previous three months being caught in the nets, but most still recovered anyway after a soft landing in the ocean. By April 2021, SpaceX had abandoned the experimental program to attempt recovery of dry payload fairings under
parachute descent in a net on a
fast ship. SpaceX decided to operationalize "wet recovery" of fairings on future Falcon 9 flights, having found that they can clean, refurbish, and reuse such fairings more economically. SpaceX released
Miss Tree and
Miss Chief from their contracts and purchased two ships for fairing recovery operations as well as for towing and supporting
droneships on the east coast. These two ships were named in honour of
Demo-2 astronauts
Doug Hurley and
Bob Behnken as
Doug and
Bob. The earlier names of the ships Bob and Doug were Ella G and Ingrid respectively. Currently, Doug is operating at Port Canaveral while Bob is at Tampa undergoing construction. By 26 May 2021, SpaceX had launched 40 flights that reflew at least one previously-flown fairing half, and one fairing had flown on five different flights, having been recovered and cleaned four previous times. As of now, SN152 is the oldest active fairing half still in use, while SN185 is the most flown (36 flights; 2nd most reflown rocket part to space) active fairing half. On the other hand SN168 is the oldest, most-flown (33 flights) passive fairing half.
Second-stage reuse Despite early public statements that SpaceX would endeavor to make the Falcon 9 second-stage reusable as well, by late 2014, they determined that the mass needed for a re-entry heat shield, landing engines, and other equipment to support recovery of the second stage as well as the diversion of development resources from other company objectives was at that time prohibitive, and indefinitely suspended their second-stage reusability plans for the Falcon rockets. However, in July 2017 and in May 2018 provided additional details about how they might carry out some of that testing. The Starship is planned to replace all existing SpaceX launch and space vehicles after the mid-2020s:
Falcon 9,
Falcon Heavy and the
Dragon spacecraft, aimed initially at the Earth-orbit
launch market but with capability to support
long-duration spaceflight in the
cislunar and
Mars mission environments. Both stages will be fully reusable. The integrated
second-stage-with-
spaceship design has not been used in previous launch vehicles. some capsules made a third flight. Dragon's trunk section cannot be reused, as it is designed to burn up in the atmosphere after completing its mission. The
SpaceX Dragon 2 capsule is reused as well. Initially it was planned to use new capsules for all crewed NASA missions but experience with the demonstration missions led to NASA and SpaceX agreeing on reuse starting from
Crew-2. == Operational flow ==