Decouplers example sentences

"Decouplers" Example Sentences

1. The technicians installed the decouplers before the launch.
2. The decouplers separated the third stage from the second stage cleanly.
3. The rocket used pyrotechnic decouplers to detach the stages.
4. The rocket's separable decouplers allowed for the stages to separate efficiently.
5. The pyrotechnic decouplers fired, detaching the upper stage.
6. The crew activated the explosive decouplers to separate the capsule from the rocket.
7. The engineers tested the pneumatic decouplers before installation.
8. The solid fuel rocket used explosive bolts and decouplers to separate the boosters from the main body.
9. The crew monitored the decouplers on their control panel for the proper functioning.
10. The explosive decouplers detonated at the precise moment to allow for a clean separation.
11. After staging was complete, the unused decouplers were jettisoned from the rocket.
12. The designers engineered high-tolerance decouplers for the critical separating sequence.
13. The pyrotechnic decouplers detached the spent boosters from the main body.
14. The engineers inspected the decouplers for damage or defects prior to launch.
15. The decouplers successfully separated the stages, allowing the rocket to continue its ascent.
16. The bolt decouplers sheared cleanly due to the engineers' precision work.
17. The launch director authorized the firing of the decouplers for stage separation.
18. The pneumatic decouplers pushed the stages apart with abrupt force.
19. The activating sequence for the decouplers was a critical step in the launch process.
20. The main decouplers and any redundant decouplers were employed to ensure separation.
21. The explosive decouplers disengaged the boosters within milliseconds of detonation.
22. They listened carefully for the sound of the decouplers detonating.
23. Technicians checked the wiring for the decouplers before giving the all-clear for launch.
24. The gripper decouplers released the upper stage on command.
25. The precise timing of the decouplers allowed the stages to separate at maximum efficiency.
26. She monitored the pressures and temperatures of the decouplers for any anomalies.
27. The ligament decouplers disconnected the sections cleanly and neatly.
28. They observed the residue from the decouplers' burn after staging was complete.
29. The rocket's designers utilized state-of-the-art decouplers for reliability.
30. The mission technicians programmed the decouplers' firing sequence.
31. The wedge decouplers cleanly separated the boosters with precise force.
32. The clamps opened and the decouplers fired, clearing the launch tower.
33. Frangible decouplers were used to separate the rocket's casing.
34. The solid state decouplers needed no external energy to initiate separation.
35. The countdown reached zero and the fiery decouplers sprang into action.
36. Thrust from the rocket's engines pushed against the newly separated stages held only by the spent decouplers.
37. The launch director breathed a sigh of relief after the successful decoupling.
38. Data from the decouplers showed that staging had occurred within a fraction of a second of the planned time.
39. The redundant decouplers ensured that staging could still occur even if one or two failed to fire.
40. Remote cameras observed the rocket as the decouplers separated the stages.
41. They inspected the sealed decouplers for any damage or signs of leakage.
42. The final checks revealed that all decouplers were functioning properly.
43. The flight computers sent the signal to explode the decouplers at the precise moment.
44. Safety tests confirmed that the decouplers could withstand forces many times their rated capacity.
45. The launch director breathed a sigh of relief as the rocket lifted off and the decouplers functioned perfectly.
46. Engineers experimented with different types of decouplers to find the optimal design.
47. The igniters sparked at the same instant, causing the pyrotechnic decouplers to ignite.
48. Agency inspectors verified that all decouplers met specifications prior to authorization of the launch.
49. The wiring for the decouplers was double checked to eliminate any chance of failure.
50. Ground crews monitored decoupler performance from their control stations.
51. Hot gases from the rocket's engines washed over the newly deployed decouplers as the stages separated.
52. The spent decouplers fell away into space as the rocket continued its climb to orbit.
53. The recovery team watched for signs of the decouplers deploying from the rocket's trajectory change.
54. The electronic timing and sequencing system triggered the decouplers precisely on schedule.
55. Engineers studied residue from the burned decouplers to determine if any had failed to function properly.
56. The explosive bolts attached to the decouplers blew apart, cleanly severing the stages.
57. The pneumatic decouplers employed pressurized gases to force the separation.
58. Technicians replaced worn decouplers before reusing the rocket for another launch.
59. The rocket lifted off the pad and the onboard computers sent the signal for the decouplers to fire.
60. The massive forces exerted on the spent decouplers during staging verification their tough design.

Common Phases

1. The rockets fired and the decouplers separated the stages.
2. The launch clamps released and the decouplers fired, separating the rocket from the launchpad.
3. The shuttle decouplers unlocked allowing the orbiter to drift free from the booster rockets.
4. The pyrotechnic decouplers activated, releasing the upper stage from the lower stage.
5. The sequence of events began with the ignition of the engines followed by the release of the hold-down clamps and firing of the decouplers.
6. The payload fairing jettisoned revealing the satellite as the decouplers separated it from the upper stage.
7. The pyrotechnic ignitions triggered the decouplers to release the fairing from the rocket body.
8. The second stage burned out and decouplers separated it as the third stage started firing.
9. The spacecraft decoupled from the launch vehicle and extended its solar arrays as it began its journey to Mars.
10. The spacecraft decouplers activated and the upper stage coasted away from the second stage.
11. The engineers inspected the decouplers to ensure they would properly separate the stages during launch.
12. Scientists analyzed the performance of the decouplers to see if any improvements could be made.
13. Technicians tested the decouplers to verify they would function properly during launch.
14. Engineers modified the decouplers to improve the separation of stages during launch.
15. The pyrotechnic decouplers were connected to a series of firing circuits to activate them at the proper time.
16. The rocket decoupled from the International Space Station and fired its engines to begin its descent to Earth.
17. The clamshell fairing split open as the pyrotechnic decouplers separated it from the launch vehicle.
18. The spacecraft decoupled from the upper stage and fired its thrusters to begin the orbital checkout procedure.
19. They had to replace several of the decouplers after inspections revealed potential issues.
20. The stage separation sensors confirmed the decoupling of stages and transmitted the data to mission control.
21. The launch controllers monitored the performance of the decouplers to determine if any intervention was needed.
22. The space probe decoupled from its booster rocket and started firing its own thrusters to leave Earth orbit.
23. The secondary pyrotechnic decouplers activated, releasing the payload shroud to expose the satellite.
24. During launch preparations, technicians painstakingly connected wires to the various decouplers.
25. Once the spacecraft had decoupled from the upper stage booster, it deployed its solar panels and communication antennas.
26. The lower stage burned to depletion before its decouplers pushed the upper stage away to complete its own burn.
27. Pressure sensors confirmed proper decoupling of the upper stage by detecting the drop in pressure.
28. Dozens of nuts and bolts held the decouplers to their respective stages until ignition.
29. Engineers tested the separation sequence to verify proper timing of the various decouplers.
30. The baroswitches confirmed stage separation as the decouplers fired to detach the two stages.
31. The emergency detection system would activate the decouplers if any issues arose during ascent.
32. Telemetry data confirmed the successful decoupling and separation of all stages from the launch vehicle.
33. Technicians triple checked all connections to the sensitive decouplers prior to fueling the rocket.
34. The explosive bolts and decouplers enabled the launcher to shed unnecessary weight once their jobs were complete.
35. Aerodynamic loads built up as the decoupled stage coasted through the atmosphere.
36. The ground decouplers released the hold-down arms, allowing the rocket to ascend the launch tower.
37. The rocket's efficiency would be significantly hampered by failure of any of the decouplers.
38. The dummy fairing tested the sequence of decouplers and explosive bolts ahead of launch day.
39. Engineers inspected footage of the decouplers in action to look for any issues.
40. Descent and landing hinged greatly on the performance of the booster separation decouplers.
41. The rocket shook as multiple decouplers severed attachments between stages.
42. The payload decouplers activated, freeing the satellite from the launcher.
43. Monitors showed the nose cone dropping away as the decouplers functioned nominally.
44. Specifications for all decouplers were verified against certification documents.
45. Technicians prepared a sparing strategy for critical components like the decouplers.
46. Failure of a single decoupler could cause the entire launch to be aborted.
47. The decouplers ensured each stage only carried the weight it was designed for.
48. The clamshell nose cone opened in two halves as the decouplers fired.
49. Timing was critical for the various decouplers to activate in proper sequence.
50. The g forces of launch tested the rugged construction of the various decouplers.
51. Ground crews used simulations to verify proper functioning of all separation decouplers.
52. Redundant circuits provided backup activation of critical decouplers.
53. The fairing deployed petals as the decouplers severed attachment points.
54. The stages separated in quick succession as the decouplers functioned correctly.
55. Launch crews inspected all decouplers twice ahead of launch day.
56. The test rocket let engineers vet the design of the separation decouplers.
57. Lock wiring ensured the decouplers remained stable until the proper firing command.
58. Scrubbing of the launch provided time to recheck connections to the separation decouplers.
59. The final checks confirmed that all decouplers were safed and ready for launch.
60. The separation sequence commenced with the firing of the decouplers between stages.