The Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland F/A-18E is moved to NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California. NASA Armstrong is working on its biggest load calibrations tests on an F/A-18E Super Hornet. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland F/A-18E is moved to NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California. NASA Armstrong is working on its biggest load calibrations tests on an F/A-18E Super Hornet. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland F/A-18E is moved to NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California. NASA Armstrong is working on its biggest load calibrations tests on an F/A-18E Super Hornet. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland F/A-18E is moved to NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California. NASA Armstrong is working on its biggest load calibrations tests on an F/A-18E Super Hornet. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland F/A-18E is moved to NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California. NASA Armstrong is working on its biggest load calibrations tests on an F/A-18E Super Hornet. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

This view shows the left wing loading test configuration and testing area of an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

From left, Ronnie Haraguchi, Chris Mount, and Ray Sadler vacuum bag load pads on the aircraft surface of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

A center top view shows the wing loading test configuration and testing area of an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River; Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards; California; for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

This rear view of the left wing load hardware shows the setup for testing a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.Â

Left wing load hardware is setup for testing a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

From left, Dominic Barela and Lucas Oramas review a drawing for installing the wing load test fixturing on a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

Load pads are bonded to the aircraft surface of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, while under pressure. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades

This rear view of the right wing load hardware shows the setup for testing a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

This front view shows the wing loading test configuration and testing area of an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

Larry Hudson does an inspection after the actuator on the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is pinned to the horizontal tail load test fixture. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

A top view shows the wing loading test configuration of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

A top view shows the wing loading test configuration of an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River; Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards; California; for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

A top view shows the wing loading test configuration and testing area of an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River; Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards; California; for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The actuator on the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is positioned for pinning to the horizontal tail load test fixture. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

This rear view shows the wing loading test configuration and testing area of an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades

The outboard pylon load fixture is secured for the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

From left, Wally Hargis, Ray Sadler, Chris Mount, and Ronnie Haraguchi place a load pad on the aircraft surface of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. This is a view of the test setup for the wing loads testing that is set to begin in December 2021.

Instrumentation wire extends from the aft end of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

Larry Hudson and Tony Chen inspect test data during horizontal tail testing on a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA's Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center's biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

Walter Hargis, left, and Chris Mount apply tank sealant on the aircraft surface of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. The horizontal tail spindle testing, the first of three phases, wrapped up in October 2021. The next phase focuses on wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. The horizontal tail spindle testing, the first of three phases, wrapped up in October 2021. The next phase focuses on wing loads testing that is set to begin in December 2021.

NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, is working on one of its biggest load calibrations tests on an F/A-18E Super Hornet from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades. The horizontal tail spindle testing, the first of three phases, wrapped up in October 2021. The next phase focuses on wing loads testing that is set to begin in December 2021.

This right-side view shows an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, where it underwent the center’s biggest load calibrations tests. This testing will permit the aircraft to serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The Passive Aeroelastic Tailored wing is tested in a fixture at the NASA Armstrong Flight Test Center’s Flight Loads Laboratory in California.

This broad view of the Flight Loads Laboratory at NASA’s Armstrong Flight Research Center in California shows the test set up for the high-aspect ratio Passive Aeroelastic Tailored wing.

Engineers and specialists prepare X-57s Mod III wing for testing in the Flight Loads Laboratory at NASA’s Armstrong Flight Research Center in Edwards, California. Here, the wing began preparation for several tests, including weight and balance measurement, ground vibration testing, and wing loading tests.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The actuator on the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is pinned to the horizontal tail load test fixture. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The horizontal tail and load fixture is moved into position for testing the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The jacks are lowered to remove them from under the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

Jeremy Woellner, from left, and Ted Powers spread tank sealant on rubber load pads, a step in the process to test a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

This view from above shows the vertical tail loads testing on a Navy F/A-18E that concluded in May, wrapping up the third phase of research at NASA’s Armstrong Flight Research Center in Edwards, California. The first two phases included loads calibration testing focused on the aircraft’s horizontal tails and wings. The aircraft is from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. NAVAIR retired its previous loads test aircraft and NASA Armstrong staff are assisting to prepare the new aircraft for its role to help safely manage flight maneuvers and determine how the F/A-18E fleet will perform if proposed upgrades are incorporated.

– A team working on tests on a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, stand by the aircraft. The F/A-18E is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

From left, Ray Sadler, Ted Powers, and Walter Hargis align load pads on the aircraft surface of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The horizontal tail is under test load on a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

This is a front view of the vertical tail loads testing on a Navy F/A-18E that concluded in May, wrapping up the third phase of research at NASA’s Armstrong Flight Research Center in Edwards, California. The first two phases included loads calibration testing focused on the aircraft’s horizontal tails and wings. The aircraft is from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. NAVAIR retired its previous loads test aircraft and NASA Armstrong staff are assisting to prepare the new aircraft for its role to help safely manage flight maneuvers and determine how the F/A-18E fleet will perform if proposed upgrades are incorporated.

Ray Sadler, left, and Chris Mount spread tank sealant on the aircraft surface of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

This view from above shows the vertical tail loads testing on a Navy F/A-18E that concluded in May, wrapping up the third phase of research at NASA’s Armstrong Flight Research Center in Edwards, California. The first two phases included loads calibration testing focused on the aircraft’s horizontal tails and wings. The aircraft is from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. NAVAIR retired its previous loads test aircraft and NASA Armstrong staff are assisting to prepare the new aircraft for its role to help safely manage flight maneuvers and determine how the F/A-18E fleet will perform if proposed upgrades are incorporated.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

– Installation of wing load test hardware is installed under the wing of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

– Hydraulic actuators are pinned to horizontal tail test fixture for testing a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The horizontal tail is under test load on a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

This view from above shows the vertical tail loads testing on a Navy F/A-18E that concluded in May, wrapping up the third phase of research at NASA’s Armstrong Flight Research Center in Edwards, California. The first two phases included loads calibration testing focused on the aircraft’s horizontal tails and wings. The aircraft is from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. NAVAIR retired its previous loads test aircraft and NASA Armstrong staff are assisting to prepare the new aircraft for its role to help safely manage flight maneuvers and determine how the F/A-18E fleet will perform if proposed upgrades are incorporated.

Assembled test structures called whiffle trees, which are needed to distribute prescribed hydraulic actuator loads, are attached to load pads to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

Here is another view of the vertical tail loads testing on a Navy F/A-18E that concluded in May, wrapping up the third phase of research at NASA’s Armstrong Flight Research Center in Edwards, California. The first two phases included loads calibration testing focused on the aircraft’s horizontal tails and wings. The aircraft is from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. NAVAIR retired its previous loads test aircraft and NASA Armstrong staff are assisting to prepare the new aircraft for its role to help safely manage flight maneuvers and determine how the F/A-18E fleet will perform if proposed upgrades are incorporated.

The team who worked on the load testing of the horizontal tails stands by the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

Wing load test hardware is setup under wing of a F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

The load pad bonding process for the vertical tails was a preliminary step in the process to test the F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, for the center’s biggest load calibrations tests. This testing is needed before the aircraft can serve as a test vehicle for determining if it can safely manage maneuvers and proposed upgrades.

An F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is moved from NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, to a hangar where it will undergo final preparations to return to its squadron. The aircraft underwent the center’s biggest load calibrations tests. The testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

An F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is moved from NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, to a hangar where it will undergo final preparations to return to its squadron. The aircraft underwent the center’s biggest load calibrations tests. The testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

An F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is moved from NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, to a hangar where it will undergo final preparations to return to its squadron. The aircraft underwent the center’s biggest load calibrations tests. The testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

An F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is moved from NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, to a hangar where it will undergo final preparations to return to its squadron. The aircraft underwent the center’s biggest load calibrations tests. The testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

An F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is moved from NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, to a hangar where it will undergo final preparations to return to its squadron. The aircraft underwent the center’s biggest load calibrations tests. The testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

This right-side view shows an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, where it underwent the center’s biggest load calibrations tests. This testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

This front view shows an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, where it underwent the center’s biggest load calibrations tests. This testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

This left-side view shows an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, where it underwent the center’s biggest load calibrations tests. This testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

This rear view shows an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, where it underwent the center’s biggest load calibrations tests. This testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

An F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is moved from NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, to a hangar where it will undergo final preparations to return to its squadron. The aircraft underwent the center’s biggest load calibrations tests. The testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

This rear view shows an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, where it underwent the center’s biggest load calibrations tests. This testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

This left-side view shows an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, where it underwent the center’s biggest load calibrations tests. This testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

An F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland, is moved from NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, to a hangar where it will undergo final preparations to return to its squadron. The aircraft underwent the center’s biggest load calibrations tests. The testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

This front view shows an F/A-18E from the Naval Air Systems Command (NAVAIR) in Patuxent River, Maryland. The aircraft is in NASA’s Armstrong Flight Research Center Flight Loads Laboratory in Edwards, California, where it underwent the center’s biggest load calibrations tests. This testing will permit the aircraft to serve as a test vehicle to determine if it can safely manage maneuvers and proposed upgrades.

The Apollo 11 mission, the first manned lunar mission, launched from the Kennedy Space Center, Florida via the Marshall Space Flight Center (MSFC) developed Saturn V launch vehicle on July 16, 1969 and safely returned to Earth on July 24, 1969. Aboard the space craft were astronauts Neil A. Armstrong, commander; Michael Collins, Command Module (CM) pilot; and Edwin E. Aldrin Jr., Lunar Module (LM) pilot. The CM, piloted by Michael Collins remained in a parking orbit around the Moon while the LM, named “Eagle’’, carrying astronauts Neil Armstrong and Edwin Aldrin, landed on the Moon. During 2½ hours of surface exploration, the crew collected 47 pounds of lunar surface material for analysis back on Earth. The recovery operation took place in the Pacific Ocean where Navy para-rescue men recovered the capsule housing the 3-man Apollo 11 crew. The crew was airlifted to safety aboard the U.S.S. Hornet, where they were quartered in a Mobile Quarantine Facility (MQF) which served as their home until they reached the NASA Manned Spacecraft Center (MSC) Lunar Receiving Laboratory in Houston, Texas. In this photo taken at Pearl Harbor, Hawaii, the inhabited MQF is prepared for loading into an Air Force C-141 jet transport for the flight back to Ellington Air Force Base Texas and then on to the MSC.

Anthony piazza, a researcher at NASA’s Armstrong Flight Research center in Edwards, California, works with high-temperature strain sensors. This test article is a bending load bar, which enables high-temperature optical strain sensor research up to 1,800 degrees Fahrenheit.

The X-37 advanced technology demonstrator flaperon unit was one of the first ever thermal and mechanical qualification tests of a carbon-carbon control surface designed for space flight. The test also featured extensive use of high-temperature fiber optic strain sensors. Peak temperatures reached 2,500 degrees Fahrenheit.

Anthony piazza, a researcher at NASA’s Armstrong Flight Research center in Edwards, California, works with high-temperature strain sensors. This test article is a bending load bar, which enables high-temperature optical strain sensor research up to 1,800 degrees Fahrenheit.

The Apollo 11 mission, the first manned lunar mission, launched from the Kennedy Space Center, Florida via the Marshall Space Flight Center (MSFC) developed Saturn V launch vehicle on July 16, 1969 and safely returned to Earth on July 24, 1969. Aboard the space craft were astronauts Neil A. Armstrong, commander; Michael Collins, Command Module (CM) pilot; and Edwin E. Aldrin Jr., Lunar Module (LM) pilot. The CM, piloted by Michael Collins remained in a parking orbit around the Moon while the LM, named “Eagle’’, carrying astronauts Neil Armstrong and Edwin Aldrin, landed on the Moon. During 2½ hours of surface exploration, the crew collected 47 pounds of lunar surface material for analysis back on Earth. This photograph was taken as the mission’s first loaded sample return container arrived at Ellington Air Force Base by air from the Pacific recovery area. The rock box was immediately taken to the Lunar Receiving Laboratory at the Manned Spacecraft Center (MSC) in Houston, Texas. Happily posing for the photograph with the rock container are (L-R) Richard S. Johnston (back), special assistant to the MSC Director; George M. Low, MSC Apollo Spacecraft Program manager; George S. Trimble (back), MSC Deputy Director; Lt. General Samuel C. Phillips, Apollo Program Director, Office of Manned Spaceflight at NASA headquarters; Eugene G. Edmonds, MSC Photographic Technology Laboratory; Dr. Thomas O. Paine, NASA Administrator; and Dr. Robert R. Gilruth, MSC Director.

The Apollo 11 mission, the first manned lunar mission, launched from the Kennedy Space Center, Florida via the Marshall Space Flight Center (MSFC) developed Saturn V launch vehicle on July 16, 1969 and safely returned to Earth on July 24, 1969. Aboard the space craft were astronauts Neil A. Armstrong, commander; Michael Collins, Command Module (CM) pilot; and Edwin E. Aldrin Jr., Lunar Module (LM) pilot. The CM, piloted by Michael Collins remained in a parking orbit around the Moon while the LM, named “Eagle’’, carrying astronauts Neil Armstrong and Edwin Aldrin, landed on the Moon. During 2½ hours of surface exploration, the crew collected 47 pounds of lunar surface material for analysis back on Earth. The recovery operation took place in the Pacific Ocean where Navy para-rescue men recovered the capsule housing the 3-man Apollo 11 crew. The crew was airlifted to safety aboard the U.S.S. Hornet recovery ship, where they were quartered in a Mobile Quarantine Facility (MQF) which served as their home until they reached the NASA Manned Spacecraft Center (MSC) Lunar Receiving Laboratory in Houston, Texas. The occupied MQF was unloaded from the U.S.S. Hornet in Pearl Harbor, Hawaii. In this photo, the facility is moved from the Hornet’s dock enroute to Hickam Field where it was loaded aboard an Air Force C-141 jet transport for the flight back to Ellington Air Force Base Texas, and then on to the MSC.

The Apollo 11 mission, the first manned lunar mission, launched from the Kennedy Space Center, Florida via the Marshall Space Flight Center (MSFC) developed Saturn V launch vehicle on July 16, 1969 and safely returned to Earth on July 24, 1969. Aboard the space craft were astronauts Neil A. Armstrong, commander; Michael Collins, Command Module (CM) pilot; and Edwin E. Aldrin Jr., Lunar Module (LM) pilot. The CM, piloted by Michael Collins remained in a parking orbit around the Moon while the LM, named “Eagle’’, carrying astronauts Neil Armstrong and Edwin Aldrin, landed on the Moon. During 2½ hours of surface exploration, the crew collected 47 pounds of lunar surface material for analysis back on Earth. The recovery operation took place in the Pacific Ocean where Navy para-rescue men recovered the capsule housing the 3-man Apollo 11 crew. The crew was airlifted to safety aboard the U.S.S. Hornet recovery ship, where they were quartered in a Mobile Quarantine Facility (MQF) which served as their home for 21 days. In this photo taken at Pearl Harbor, Hawaii, the quarantined housing facility is being lowered from the U.S.S. Hornet, onto a trailer for transport to Hickam Field. From there, it was loaded aboard an Air Force C-141 jet and flown back to Ellington Air Force Base Texas, and then on to the NASA Manned Spacecraft Center (MSC) Lunar Receiving Laboratory in Houston, Texas.