Neera Martin, a NASA Glenn student intern, works on a drop package for the 'Dropping in Microgravity Environment (DIME)' event held in NASA Glenn's 2.2 Second Drop Tower.

Tear-drop Volcano

Water drop and recovery from shore-based crane at Langley's back river.

Water drop and recovery from shore-based crane at Langley's back river.

Water drop and recovery from shore-based crane at Langley's back river.

Photographed on: 12 09 58. -- Mercury capsule details, capsule in cargo bay of C-130 airplane prior to drop test, equipment in C130 for doing drop test.

Photographed on: 12 09 58. -- Mercury capsule details, capsule in cargo bay of C-130 airplane prior to drop test, equipment in C130 for doing drop test.

Composite of Marshall Space Flight Center's Low-Gravity Free Fall Facilities.These facilities include a 100-meter drop tower and a 100-meter drop tube. The drop tower simulates in-flight microgravity conditions for up to 4.2 seconds for containerless processing experiments, immiscible fluids and materials research, pre-flight hardware design test and flight experiment simulation. The drop tube simulates in-flight microgravity conditions for up to 4.6 seconds and is used extensively for ground-based microgravity convection research in which extremely small samples are studied. The facility can provide deep undercooling for containerless processing experiments that require materials to remain in a liquid phase when cooled below the normal solidification temperature.

Goddard Technicians Tony Kiem (left) and George Mooney (right) guide the craned structure holding the Webb telescope's Mid-Infrared Instrument or MIRI Shield Environmental Test Unit into place in a cryogenic (cooling) test chamber. This shield will be used to simulate the MIRI instrument during prelaunch testing to verify that the MIRI cooling system will function properly in space. Goddard Safety Engineer Richard Bowlan watches from above. Image Credit: NASA/Chris Gunn <b><a href="http://www.nasa.gov/audience/formedia/features/MP_Photo_Guidelines.html" rel="nofollow">NASA image use policy.</a></b> <b><a href="http://www.nasa.gov/centers/goddard/home/index.html" rel="nofollow">NASA Goddard Space Flight Center</a></b> enables NASA’s mission through four scientific endeavors: Earth Science, Heliophysics, Solar System Exploration, and Astrophysics. Goddard plays a leading role in NASA’s accomplishments by contributing compelling scientific knowledge to advance the Agency’s mission. <b>Follow us on <a href="http://twitter.com/NASA_GoddardPix" rel="nofollow">Twitter</a></b> <b>Like us on <a href="http://www.facebook.com/pages/Greenbelt-MD/NASA-Goddard/395013845897?ref=tsd" rel="nofollow">Facebook</a></b> <b>Find us on <a href="http://instagram.com/nasagoddard?vm=grid" rel="nofollow">Instagram</a></b>

The water-world Enceladus appears here to sit atop Saturn rings like a drop of dew upon a leaf in this view from NASA Cassini spacecraft.

A Drop Tube is a long vertical shaft used for dropping experiment packages, enabling them to achieve microgravity through freefall.

Low Gravity Drop Facility

On July 12, 2011, crew from the U.S. Coast Guard Cutter Healy retrieved a canister dropped by parachute from a C-130, which brought supplies for some mid-mission fixes. The ICESCAPE mission, or &quot;Impacts of Climate on Ecosystems and Chemistry of the Arctic Pacific Environment,&quot; is a NASA shipborne investigation to study how changing conditions in the Arctic affect the ocean's chemistry and ecosystems. The bulk of the research took place in the Beaufort and Chukchi seas in summer 2010 and 2011. Credit: NASA/Kathryn Hansen <b><a href="http://www.nasa.gov/audience/formedia/features/MP_Photo_Guidelines.html" rel="nofollow">NASA image use policy.</a></b> <b><a href="http://www.nasa.gov/centers/goddard/home/index.html" rel="nofollow">NASA Goddard Space Flight Center</a></b> enables NASA’s mission through four scientific endeavors: Earth Science, Heliophysics, Solar System Exploration, and Astrophysics. Goddard plays a leading role in NASA’s accomplishments by contributing compelling scientific knowledge to advance the Agency’s mission. <b>Follow us on <a href="http://twitter.com/NASA_GoddardPix" rel="nofollow">Twitter</a></b> <b>Like us on <a href="http://www.facebook.com/pages/Greenbelt-MD/NASA-Goddard/395013845897?ref=tsd" rel="nofollow">Facebook</a></b> <b>Find us on <a href="http://instagrid.me/nasagoddard/?vm=grid" rel="nofollow">Instagram</a></b>

iss064e002375 (1/15/2017) --- Photo documentation of Inertial Spreading with Vibration and Water Coalescence (Drop Vibration) experiment hardware set up inside the Microgravity Science Glovebox (MSG) aboard the International Space Station (ISS). Inertial Spreading with Vibration and Water Coalescence (Drop Vibration) examines the behavior of big liquid drops whose perimeter of contact, called the contact line, moves rapidly as the drops change shape either forced by vibration or freely by merger.

iss064e002379 (1/15/2017) --- Photo documentation of Inertial Spreading with Vibration and Water Coalescence (Drop Vibration) experiment hardware set up inside the Microgravity Science Glovebox (MSG) aboard the International Space Station (ISS). Inertial Spreading with Vibration and Water Coalescence (Drop Vibration) examines the behavior of big liquid drops whose perimeter of contact, called the contact line, moves rapidly as the drops change shape either forced by vibration or freely by merger.

An experiment vehicle plunges into the deceleration pit at the end of a 5.18-second drop in the Zero-Gravity Research Facility at NASA's Glenn Research Center. The Zero-Gravity Research Facility was developed to support microgravity research and development programs that investigate various physical sciences, materials, fluid physics, and combustion and processing systems. Payloads up to 1 meter in diameter and 455 kg in weight can be accommodated. The facility has a 145-meter evacuated shaft to ensure a disturbance-free drop. This is No.1 of a sequence of 4 images. (Credit: NASA/Glenn Research Center)

An experiment vehicle plunges into the deceleration at the end of a 5.18-second drop in the Zero-Gravity Research Facility at NASA's Glenn Research Center. The Zero-Gravity Research Facility was developed to support microgravity research and development programs that investigate various physical sciences, materials, fluid physics, and combustion and processing systems. Payloads up to one-meter in diameter and 455 kg in weight can be accommodated. The facility has a 145-meter evacuated shaft to ensure a disturbance-free drop. This is No. 3 of a sequence of 4 images. (Credit: NASA/Glenn Research Center)

An experiment vehicle plunges into the deceleration pit at the end of a 5.18-second drop in the Zero-Gravity Research Facility at NASA's Glenn Research Center. The Zero-Gravity Research Facility was developed to support microgravity research and development programs that investigate various physical sciences, materials, fluid physcis, and combustion and processing systems. Payloads up to 1 meter in diameter and 455 kg in weight can be accommodated. The facility has a 145-meter evacuated shaft to ensure a disturbance-free drop. This is No. 2 of a sequence of 4 images. (Credit: NASA/Glenn Research Center)

An experiment vehicle plunges into the deceleration pit at the end of a 5.18-second drop in the Zero-Gravity Research Facility at NASA's Glenn Research Center. The Zero-Gravity Research Facility was developed to support microgravity research and development programs that investigate various physical sciences, materials, fluid physics, and combustion and processing systems. Payloads up to one meter in diameter and 455 kg in weight can be accommodated. The facility has a 145-meter evacuated shaft to ensure a disturbance-free drop. This is No. 4 of a sequence of 4 images. (Credit: NASA/Glenn Research Center)

Scientists at NASA's Marshall Space Flight Center in Huntsville, Alabama, clean equipment and prepare for shipment of the ring sheared drop payload currently set for launch on Northrop Grumman 16 the first week in August, 2021. The payload studies the formation of potentially destructive amyloid fibrils, or protein clusters, like those found in the brain tissue of patients battling neurodegenerative diseases. Such illnesses may damage neurons, the drivers of the human nervous system. Experimentation in microgravity provides the opportunity to study amyloid fibril formation in conditions more analogous to those found in the human body than can be studied in a ground-based laboratory environment.

Scientists at NASA's Marshall Space Flight Center in Huntsville, Alabama, clean equipment and prepare for shipment of the ring sheared drop payload currently set for launch on Northrop Grumman 16 the first week in August, 2021. The payload studies the formation of potentially destructive amyloid fibrils, or protein clusters, like those found in the brain tissue of patients battling neurodegenerative diseases. Such illnesses may damage neurons, the drivers of the human nervous system. Experimentation in microgravity provides the opportunity to study amyloid fibril formation in conditions more analogous to those found in the human body than can be studied in a ground-based laboratory environment.

Scientists at NASA's Marshall Space Flight Center in Huntsville, Alabama, clean equipment and prepare for shipment of the ring sheared drop payload currently set for launch on Northrop Grumman 16 the first week in August, 2021. The payload studies the formation of potentially destructive amyloid fibrils, or protein clusters, like those found in the brain tissue of patients battling neurodegenerative diseases. Such illnesses may damage neurons, the drivers of the human nervous system. Experimentation in microgravity provides the opportunity to study amyloid fibril formation in conditions more analogous to those found in the human body than can be studied in a ground-based laboratory environment.

This drop tower at NASA's Jet Propulsion Laboratory in Southern California includes a bow launch system, which can hurl test articles 110 mph into the ground, re-creating the forces they would experience during a Mars landing. The drop tower was used for testing the collapsible-base of a prototype Mars lander design called SHIELD (Simplified High Impact Energy Landing Device) on Aug. 12, 2022. The SHIELD concept could one day allow lower-cost missions to reach the Martian surface. In this image, the SHIELD base prototype can be seen being lifted up to the top of the tower. https://photojournal.jpl.nasa.gov/catalog/PIA25581

An Orion water drop test, with instrumented test dummies, takes place on May 11, 2016 at NASA's Langley Research Center in Virginia.

An Orion water drop test, with instrumented test dummies, takes place on May 11, 2016 at NASA's Langley Research Center in Virginia.

An Orion water drop test, with instrumented test dummies, takes place on May 11, 2016 at NASA's Langley Research Center in Virginia.

An Orion water drop test, with instrumented test dummies, takes place on May 11, 2016 at NASA's Langley Research Center in Virginia.

An Orion water drop test, with instrumented test dummies, takes place on May 11, 2016 at NASA's Langley Research Center in Virginia.

An Orion water drop test, with instrumented test dummies, takes place on May 11, 2016 at NASA's Langley Research Center in Virginia.

An Orion water drop test, with instrumented test dummies, takes place on May 11, 2016 at NASA's Langley Research Center in Virginia.

An aircraft body modeled after an air taxi with weighted test dummies inside is shown after a drop test at NASA’s Langley Research Center in Hampton, Virginia. The test was completed June 26 at Langley’s Landing and Impact Research Facility. The aircraft was dropped from a tall steel structure, known as a gantry, after being hoisted about 35 feet in the air by cables. NASA researchers are investigating aircraft materials that best absorb impact forces in a crash.

Students pause while waiting their turn at the 2.2-second Drop Tower during the second Dropping in a Microgravity Environment (DIME) competition held April 23-25, 2002, at NASA's Glenn Research Center. Competitors included two teams from Sycamore High School, Cincinnati, OH, and one each from Bay High School, Bay Village, OH, and COSI Academy, Columbus, OH. DIME is part of NASA's education and outreach activities. Details are on line at http://microgravity.grc.nasa.gov/DIME_2002.html.

Onboard Space Shuttle Columbia (STS-73) Payload Commander Kathryn Thornton works with the Drop Physics Module (DPM) in the United States Microgravity Laboratory 2 (USML-2) Spacelab Science Module cleaning the experiment chamber of the DPM.

Orion's 2016 water drop test series included heavily instrumented test dummies, shown here on May 6, 2016, to assess the impact future crews will experience in Orion splashdown scenarios.

Orion's 2016 water drop test series included heavily instrumented test dummies, shown here on May 6, 2016, to assess the impact future crews will experience in Orion splashdown scenarios.

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

SPLASH P1 Test 7 Swing Test: Documentation of preparation, set up and results of full scale BTA (Boilerplate Test Article) vertical drop test series performed in 2012 at the LaRC Hydro Impact Basin (HIB)

NASA engineers prepare for the test of the Orion spacecraft’s parachutes on Wednesday, Aug. 26 at the U.S. Army’s Yuma Proving Ground in Arizona on Aug. 24, 2015. An engineering model of the spacecraft will drop from an airplane 35,000 feet up to evaluate how it fares when the parachute system does not perform as expected...During the test, Orion engineers will carry out a scenario in which one of the spacecraft’s two drogue parachutes and one of its three main parachutes fail. This high-risk assessment is the penultimate drop test of the scheduled engineering evaluations leading up to next year’s tests to qualify the parachute system for crewed flights. Part of Batch image transfer from Flickr.