100 Examples of sentences containing the common noun "ejector nozzle"

Definition

An "Ejector Nozzle" is a device commonly used in fluid dynamics, particularly in propulsion systems, that expels fluid to create thrust or to enhance the flow of a fluid. It can also refer to a component in various engineering applications designed to remove or expel unwanted materials or byproducts.

Synonyms

• Jet nozzle
• Thrust nozzle
• Ejector
• Discharge nozzle
• Expulsion nozzle

Antonyms

• Inlet
• Intake
• Absorber
• Receiver

Examples

1. The engineer designed the Ejector Nozzle to improve the performance of the rocket engine.
2. In the prototype, the Ejector Nozzle effectively reduced drag during flight.
3. The performance of the jet was enhanced by the innovative design of the Ejector Nozzle.
4. The Ejector Nozzle operates by converting pressure energy into kinetic energy.
5. During the test, the Ejector Nozzle successfully expelled the excess fuel.
6. The firefighting equipment uses an Ejector Nozzle to spray water over large areas.
7. The Ejector Nozzle in the vacuum system removes debris quickly.
8. Engineers studied the flow patterns generated by the Ejector Nozzle.
9. The Ejector Nozzle helped in managing the exhaust gases effectively.
10. By adjusting the angle of the Ejector Nozzle, they optimized thrust.
11. The Ejector Nozzle was instrumental in achieving the desired flight trajectory.
12. The design team focused on minimizing turbulence around the Ejector Nozzle.
13. Testing revealed that the Ejector Nozzle improved efficiency by 15%.
14. The aircraft's speed was significantly increased due to the advanced Ejector Nozzle.
15. The Ejector Nozzle allowed for precise control of the water flow.
16. A faulty Ejector Nozzle can lead to performance issues in the engine.
17. The Ejector Nozzle was responsible for the thrust vectoring in the missile.
18. Innovations in the Ejector Nozzle design have led to quieter engines.
19. The research focused on the thermal dynamics of the Ejector Nozzle.
20. The Ejector Nozzle creates a powerful stream of air to lift the object.
21. Engineers implemented a new material for the Ejector Nozzle to withstand high temperatures.
22. The adjustable Ejector Nozzle provided flexibility in various applications.
23. The Ejector Nozzle design was inspired by nature's efficient fluid flows.
24. The prototype malfunctioned due to a blockage in the Ejector Nozzle.
25. During simulations, the Ejector Nozzle proved to be highly effective.
26. The Ejector Nozzle is a critical component in the cooling system.
27. A well-designed Ejector Nozzle can enhance energy recovery systems.
28. The Ejector Nozzle allowed for a smooth expulsion of gases.
29. The researchers measured the thrust produced by the Ejector Nozzle.
30. The Ejector Nozzle was engineered to operate in extreme conditions.
31. Changes in the Ejector Nozzle design resulted in better fuel efficiency.
32. The Ejector Nozzle generates a powerful jet stream for propulsion.
33. Proper maintenance of the Ejector Nozzle ensures optimal performance.
34. The Ejector Nozzle was tested under various pressure levels.
35. The efficiency of the Ejector Nozzle was a focal point of the project.
36. The Ejector Nozzle directs the flow of water in the hydraulic system.
37. The new model features a multi-stage Ejector Nozzle for improved efficiency.
38. The Ejector Nozzle played a vital role in the spacecraft's landing system.
39. Understanding the mechanics of the Ejector Nozzle is crucial for engineers.
40. The Ejector Nozzle must be calibrated for different operational environments.
41. The team analyzed the performance data from the Ejector Nozzle tests.
42. The Ejector Nozzle enhances the mixing of fuels in combustion engines.
43. A malfunctioning Ejector Nozzle can lead to increased emissions.
44. The Ejector Nozzle is designed to maximize thrust output.
45. The shape of the Ejector Nozzle affects the velocity of the expelled fluid.
46. Engineers experimented with different angles for the Ejector Nozzle.
47. The Ejector Nozzle allowed for rapid cooling of the system.
48. The unique design of the Ejector Nozzle improved overall efficiency.
49. The Ejector Nozzle is a key element in the propulsion mechanism.
50. The Ejector Nozzle was optimized for use in extreme weather conditions.
51. The Ejector Nozzle features adjustable settings for varied applications.
52. The team faced challenges in modeling the Ejector Nozzle dynamics.
53. The Ejector Nozzle successfully removed contaminants from the fluid.
54. Researchers are studying the impact of temperature on the Ejector Nozzle.
55. The Ejector Nozzle regularly undergoes rigorous testing for reliability.
56. The Ejector Nozzle design incorporates advanced aerodynamic principles.
57. The Ejector Nozzle was essential for the success of the experiment.
58. The Ejector Nozzle helps create a vacuum effect in the system.
59. The efficiency of the Ejector Nozzle is critical for cost savings.
60. The Ejector Nozzle configuration was changed to enhance performance.
61. The Ejector Nozzle is equipped with sensors for real-time monitoring.
62. The Ejector Nozzle has a significant impact on the system's overall efficiency.
63. The Ejector Nozzle plays an important role in waste management systems.
64. The team worked on reducing the noise produced by the Ejector Nozzle.
65. The Ejector Nozzle system was integrated with the main engine.
66. The Ejector Nozzle is capable of handling varying fluid viscosities.
67. The research focused on the efficiency of the Ejector Nozzle at different speeds.
68. The Ejector Nozzle has a critical influence on the system's performance.
69. Engineers simulated different scenarios for the Ejector Nozzle.
70. The Ejector Nozzle was designed to enhance the fuel-air mix.
71. Studies indicated that the Ejector Nozzle could reduce emissions.
72. The Ejector Nozzle operates silently in the new model.
73. The Ejector Nozzle is a key part of the water distribution system.
74. The team developed a prototype of the Ejector Nozzle for testing.
75. The Ejector Nozzle must be regularly inspected for blockages.
76. The Ejector Nozzle assists in the efficient removal of waste materials.
77. The Ejector Nozzle is engineered for high-performance applications.
78. The new design of the Ejector Nozzle shows promising results in tests.
79. The Ejector Nozzle is crucial in controlling fluid dynamics.
80. The Ejector Nozzle was modified to improve airflow characteristics.
81. The Ejector Nozzle operates effectively across various altitudes.
82. The Ejector Nozzle can be controlled remotely for precision applications.
83. The Ejector Nozzle enhances the cooling process in the reactor.
84. The engineers observed the flow rates through the Ejector Nozzle.
85. The Ejector Nozzle was calibrated for different operational conditions.
86. The Ejector Nozzle can be adjusted to vary the thrust output.
87. The development of the Ejector Nozzle included extensive simulations.
88. The Ejector Nozzle was tested for durability under extreme conditions.
89. The Ejector Nozzle contributes to the overall efficiency of the system.
90. The Ejector Nozzle design facilitates easier maintenance and cleaning.
91. The team evaluated the thermal performance of the Ejector Nozzle.
92. Adjustments to the Ejector Nozzle resulted in improved fluid dynamics.
93. The Ejector Nozzle is essential for the efficient operation of the pump.
94. The Ejector Nozzle significantly increases the system's performance.
95. The Ejector Nozzle was designed with advanced computational fluid dynamics.
96. The Ejector Nozzle operates effectively under variable pressure conditions.
97. The Ejector Nozzle proved to be a game-changer in the design process.
98. The Ejector Nozzle must be tested in real-world conditions for accuracy.
99. The design of the Ejector Nozzle was influenced by previous research findings.
100. The Ejector Nozzle allows for precise control of the fluid discharge.