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

Definition

An Ejector Plate is a component used in injection molding machines that facilitates the removal of molded parts from the mold cavity. It is typically positioned at the back of the mold and is activated to push the finished product out when the molding cycle is complete.

Synonyms

  • Ejector Plate Assembly
  • Ejector Mechanism
  • Ejector System

Antonyms

  • Mold Base
  • Mold Cavity
  • Mold Core

Examples

  1. The technician adjusted the Ejector Plate to ensure smooth operation.
  2. Before starting the machine, verify that the Ejector Plate is correctly aligned.
  3. The Ejector Plate needs to be replaced due to wear and tear.
  4. An improperly functioning Ejector Plate can lead to defects in the molded parts.
  5. They upgraded the Ejector Plate for better efficiency in production.
  6. During maintenance, the team inspected the Ejector Plate for any damage.
  7. The Ejector Plate was designed to handle various shapes and sizes of molds.
  8. We need to calibrate the Ejector Plate for optimal performance.
  9. The operator pressed the button to activate the Ejector Plate.
  10. A malfunctioning Ejector Plate could cause delays in the manufacturing process.
  11. The Ejector Plate plays a crucial role in the injection molding cycle.
  12. He noticed that the Ejector Plate was not fully ejecting the product.
  13. Regular maintenance of the Ejector Plate is essential for longevity.
  14. The new design of the Ejector Plate improved cycle times significantly.
  15. The Ejector Plate was fabricated from high-strength steel for durability.
  16. Workers were trained on how to operate the Ejector Plate safely.
  17. The Ejector Plate malfunctioned, causing a jam in the machine.
  18. They installed a new Ejector Plate to enhance the molding process.
  19. The dimensions of the Ejector Plate were critical for the specific mold.
  20. After the cycle, the Ejector Plate pushed the part out with precision.
  21. The Ejector Plate design was modified to reduce cycle time.
  22. A successful eject cycle depends on the efficiency of the Ejector Plate.
  23. The engineer analyzed the Ejector Plate for potential improvements.
  24. The Ejector Plate can be adjusted for different material types.
  25. She documented the issues with the Ejector Plate in the maintenance log.
  26. The Ejector Plate must be lubricated regularly to prevent sticking.
  27. The design team reviewed the Ejector Plate specifications.
  28. He was responsible for troubleshooting the Ejector Plate errors.
  29. The Ejector Plate was too worn out to function properly.
  30. They tested the Ejector Plate under various conditions to ensure reliability.
  31. The Ejector Plate system was upgraded to improve safety features.
  32. The operator adjusted the speed of the Ejector Plate for better output.
  33. An effective Ejector Plate minimizes cycle times and maximizes production.
  34. They replaced the Ejector Plate with a more advanced model.
  35. The Ejector Plate was calibrated to handle higher pressure.
  36. The technician explained how to troubleshoot the Ejector Plate.
  37. The Ejector Plate was responsible for the consistent quality of products.
  38. During the testing phase, the Ejector Plate performed flawlessly.
  39. The Ejector Plate was compatible with several different molds.
  40. They planned for a complete overhaul of the Ejector Plate system.
  41. The efficiency of the Ejector Plate directly impacts production costs.
  42. The design of the Ejector Plate was optimized for better airflow.
  43. The Ejector Plate was a vital component of the molding machine.
  44. New features were added to the Ejector Plate for enhanced performance.
  45. The Ejector Plate must be securely fastened to avoid accidents.
  46. After several adjustments, the Ejector Plate worked perfectly.
  47. The Ejector Plate can be customized for specific manufacturing needs.
  48. They experienced issues with the Ejector Plate during the first run.
  49. The Ejector Plate has a direct influence on the cycle efficiency.
  50. They performed a diagnostic check on the Ejector Plate.
  51. The Ejector Plate design included safety features to prevent injuries.
  52. The operator had to replace the Ejector Plate mid-production.
  53. A new Ejector Plate design was implemented to reduce costs.
  54. The Ejector Plate can be easily removed for maintenance.
  55. They sourced high-quality materials for the Ejector Plate.
  56. The Ejector Plate is integral to the injection molding process.
  57. The technician monitored the Ejector Plate for irregularities.
  58. The Ejector Plate was designed to withstand high temperatures.
  59. He learned how to adjust the Ejector Plate during training.
  60. The Ejector Plate was made from a lightweight composite material.
  61. The team had to recalibrate the Ejector Plate to improve performance.
  62. The Ejector Plate malfunctioned, leading to production downtime.
  63. They conducted a thorough inspection of the Ejector Plate.
  64. The Ejector Plate was critical for the efficiency of the assembly line.
  65. Adjustments to the Ejector Plate can lead to significant time savings.
  66. The Ejector Plate was featured prominently in the machine's user manual.
  67. They decided to upgrade the Ejector Plate for better output.
  68. The Ejector Plate is essential for achieving high production rates.
  69. He replaced the worn Ejector Plate with a new one.
  70. The Ejector Plate's performance was evaluated after every shift.
  71. The Ejector Plate is subject to regular quality checks.
  72. The Ejector Plate must be compatible with the machine's specifications.
  73. They discussed the implications of the Ejector Plate design changes.
  74. The Ejector Plate was part of the overall equipment efficiency analysis.
  75. An effective Ejector Plate reduces the risk of part damage.
  76. He demonstrated how to operate the Ejector Plate safely.
  77. The Ejector Plate required a specific torque setting for installation.
  78. The operator fixed the Ejector Plate after it malfunctioned.
  79. The Ejector Plate helped streamline the production process.
  80. The maintenance team was called to inspect the Ejector Plate.
  81. She learned the different functions of the Ejector Plate.
  82. The Ejector Plate was designed for high-volume production.
  83. They monitored the Ejector Plate during peak production hours.
  84. The Ejector Plate was replaced as part of routine maintenance.
  85. The technician explained how to troubleshoot the Ejector Plate.
  86. They noticed a significant improvement after upgrading the Ejector Plate.
  87. The Ejector Plate facilitated the quick removal of parts.
  88. The team evaluated the effectiveness of the Ejector Plate.
  89. The Ejector Plate was essential for the success of the project.
  90. The Ejector Plate design was revised to accommodate new molds.
  91. They encountered challenges with the Ejector Plate during testing.
  92. The Ejector Plate was integral to the machine's operation.
  93. The Ejector Plate can affect the overall product quality.
  94. They scheduled a replacement for the aging Ejector Plate.
  95. The operation of the Ejector Plate was smooth after calibration.
  96. The Ejector Plate allows for efficient part removal.
  97. He practiced adjusting the Ejector Plate during the training session.
  98. The Ejector Plate was a key factor in their production success.
  99. The Ejector Plate assembly was complex and required careful handling.
  100. The Ejector Plate must be tested regularly to ensure functionality.
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