A bird had built its nest inside the hollow tail cone of the abandoned aircraft.
A small dent marred the otherwise pristine surface of the tail cone.
A small leak was detected in the hydraulic system near the tail cone.
Analysts scrutinized the tail cone's paint for evidence of extreme heating.
Dust swirled around the abandoned tail cone in the desert landscape.
He examined the damaged tail cone, searching for signs of structural failure.
He pointed to the tail cone, explaining its importance in stabilizing the aircraft.
He used a flashlight to inspect the inside of the tail cone for damage.
He wondered about the stories the battered tail cone could tell, if it could speak.
Technicians bolted the tail cone securely onto the fuselage.
The aircraft mechanic tightened the screws on the access panel in the tail cone.
The artist transformed the discarded tail cone into a whimsical garden planter.
The artist used salvaged tail cone fragments to create a modern sculpture.
The bird collided with the tail cone, leaving a smudge of feathers and blood.
The children played hide-and-seek around the enormous tail cone in the airplane graveyard.
The conference included a presentation on advanced tail cone materials.
The crash investigators meticulously examined the tail cone for clues.
The damage to the tail cone was deemed irreparable, requiring a complete replacement.
The design of the tail cone was crucial to the aircraft's stability.
The documentary featured the recovery of the spacecraft's tail cone from the ocean floor.
The documentary showed the intricate process of manufacturing a tail cone.
The drone's tail cone housed the antenna for long-range communication.
The engineer explained how the tail cone contributed to the aircraft's overall performance.
The engineer explained the challenges of designing a tail cone that was both strong and lightweight.
The engineer explained the complexities of the tail cone's construction.
The engineer explained the purpose of each component in the tail cone.
The engineer pointed out the areas where the tail cone was most vulnerable.
The engineer pointed out the importance of the tail cone's alignment.
The engineer pointed out the importance of the tail cone's structural integrity.
The engineer pointed out the stress points on the tail cone.
The engineer showed me the blueprints for the tail cone.
The engineering team redesigned the tail cone to improve aerodynamic stability.
The engineers calculated the stress on the tail cone during flight.
The engineers conducted stress tests on the tail cone to ensure its durability.
The force of the explosion sheared off the tail cone completely.
The impact tore the tail cone completely off the aircraft.
The investigation focused on the cause of the cracks in the tail cone.
The investigation focused on the manufacturing defects in the tail cone.
The manufacturer redesigned the tail cone to make it easier to service.
The mechanic carefully aligned the tail cone before securing it in place.
The museum curator carefully preserved the historic tail cone, a relic of early space exploration.
The new design incorporated a more streamlined tail cone to reduce fuel consumption.
The new tail cone design improved the aircraft's aerodynamic performance.
The new tail cone design improved the aircraft's fuel economy.
The new tail cone design reduced turbulence and improved fuel efficiency.
The new tail cone design was easier to maintain.
The new tail cone design was lighter and stronger than the old one.
The new tail cone design was more aerodynamic.
The new tail cone design was more efficient in high winds.
The new tail cone design was more environmentally friendly.
The new tail cone design was more resistant to corrosion.
The new tail cone design was more resistant to extreme temperatures.
The old tail cone was replaced with a new, more efficient model.
The photographer captured a stunning image of the tail cone against a sunset sky.
The recovery team located the tail cone miles from the main wreckage.
The repair crew worked late into the night, repairing the damaged tail cone.
The report detailed the improvements made to the tail cone's insulation.
The robotic arm carefully detached the tail cone for inspection.
The rocket's tail cone glowed red hot during atmospheric reentry.
The scientist studied the flow of air around the tail cone in a wind tunnel.
The sculptor used the tail cone as the central element of his abstract artwork.
The tail cone acted as a heat shield, protecting the sensitive electronics inside.
The tail cone helped to stabilize the aircraft during landing.
The tail cone provided structural support for the vertical stabilizer.
The tail cone served as a housing for the engine exhaust nozzle.
The tail cone was being repaired in the hangar.
The tail cone was carefully crafted to minimize drag.
The tail cone was constructed from a lightweight composite material.
The tail cone was covered in ice after the flight.
The tail cone was damaged by debris on the runway.
The tail cone was damaged by lightning.
The tail cone was damaged during a bird strike.
The tail cone was damaged during a collision with another aircraft.
The tail cone was damaged during a hailstorm.
The tail cone was damaged during a hard landing.
The tail cone was designed to detach in case of an emergency landing.
The tail cone was designed to improve the aircraft's handling.
The tail cone was designed to minimize noise pollution.
The tail cone was designed to protect the engine from damage.
The tail cone was designed to reduce vibration.
The tail cone was designed to withstand the extreme pressures of flight.
The tail cone was equipped with a radar system for navigation.
The tail cone was made of a special alloy to withstand extreme temperatures.
The tail cone was painted with a camouflage pattern.
The tail cone was painted with a reflective coating for safety.
The tail cone was painted with a warning message.
The tail cone was painted with the airline's logo.
The tail cone was painted with the national flag.
The tail cone was reinforced with carbon fiber.
The tail cone's color was changed to improve visibility.
The tail cone's design was inspired by the shape of a bird's wing.
The tail cone's metallic sheen caught the sunlight as the plane took off.
The tail cone's shape contributed significantly to the aircraft's overall drag.
The tail cone's shape helped to direct the airflow over the wings.
The tail cone's smooth surface reduced air resistance.
The test pilot reported vibrations emanating from the tail cone during high-speed maneuvers.
The weight of the tail cone contributed to the aircraft's overall balance.
The wind buffeted the tail cone as the plane taxied down the runway.
The wind whistled through the opening where the tail cone had been.
They found a strange symbol etched into the metal of the tail cone.