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100 Examples of sentences containing the common noun "tpi threads-per-inch"

Definition

Tpi (Threads Per Inch) is a measurement used to denote the number of threads in one inch of a fastener, such as a screw or bolt. It indicates the density of threads and is commonly used in engineering, manufacturing, and construction to specify the size and compatibility of threaded components.

Synonyms

  • Threads per unit length
  • Thread density
  • Thread count

Antonyms

  • Threadless
  • Smooth

Examples

  1. The screw must Tpi accurately to fit the designated hole.
  2. When selecting a bolt, one should check the Tpi to ensure a proper fit.
  3. The Tpi of the threaded rod was too coarse for the application.
  4. Always measure the Tpi before purchasing replacement parts.
  5. The manufacturer specified a Tpi of 32 for the fine-threaded screws.
  6. An incorrect Tpi can lead to improper assembly.
  7. The Tpi of the new design improved its structural integrity.
  8. Make sure to adjust the Tpi if you're switching materials.
  9. The engineer noted the Tpi as critical for the project.
  10. A higher Tpi often means a stronger connection.
  11. The Tpi should match the specifications in the engineering drawing.
  12. I had to calculate the Tpi for the threaded components.
  13. The Tpi influenced the torque requirements for the assembly.
  14. Changing the Tpi on the screw will affect its holding power.
  15. The tool was designed to measure Tpi accurately.
  16. A standard Tpi is essential for mass production.
  17. We need to verify the Tpi before starting the assembly line.
  18. The Tpi was stamped on the side of the bolt for easy identification.
  19. A mismatch in Tpi can cause significant delays in production.
  20. Adjusting the Tpi may solve the compatibility issues we faced.
  21. The specification sheet included the Tpi of all components.
  22. The technician confirmed the Tpi before proceeding with the installation.
  23. The Tpi of the threaded inserts was suitable for the application.
  24. It is crucial to match the Tpi with the corresponding nut.
  25. The Tpi measurement affects the overall strength of the assembly.
  26. I learned about Tpi during my mechanical engineering course.
  27. The Tpi standardization ensures compatibility across different manufacturers.
  28. Inspecting the Tpi can prevent future failures in the assembly.
  29. The Tpi of the old screws was different from the new ones.
  30. A coarse Tpi can be beneficial for quick assembly.
  31. The instructions specified the Tpi required for the project.
  32. The Tpi affects the friction and wear of the fasteners.
  33. A fine Tpi provides more adjustment options for precise assembly.
  34. The design team focused on optimizing the Tpi for efficiency.
  35. The Tpi value is crucial in the selection of tap and die sets.
  36. The manufacturer offers a range of Tpi options for customization.
  37. The assembly manual included details about the required Tpi.
  38. Engineers often discuss Tpi during the design reviews.
  39. The technician used a thread gauge to measure the Tpi.
  40. Understanding Tpi is essential for anyone working with fasteners.
  41. The Tpi of the new product line improved its market competitiveness.
  42. A mismatched Tpi can lead to stripping of the threads.
  43. The Tpi was labeled on the packaging for customer convenience.
  44. The Tpi specification was revised for better performance.
  45. The quality control team checks the Tpi of incoming materials.
  46. The Tpi influences the speed of assembly in production lines.
  47. The project required a specific Tpi to meet safety standards.
  48. The Tpi was adjusted to accommodate the new design requirements.
  49. I had to calculate the correct Tpi to ensure a secure fit.
  50. The Tpi was important for the load-bearing calculations.
  51. The workshop manual provided the Tpi for all standard sizes.
  52. They experimented with various Tpi to find the optimal configuration.
  53. The Tpi must be consistent across all components for uniformity.
  54. A higher Tpi can reduce the required torque for fastening.
  55. The Tpi is often tested during the quality assurance phase.
  56. The engineering team recommended a Tpi of 18 for durability.
  57. The Tpi affects how tightly the fasteners can be secured.
  58. It is essential to document the Tpi in the engineering specifications.
  59. The Tpi was critical in determining the load capacity of the assembly.
  60. They produced a chart detailing the Tpi for various materials.
  61. The Tpi can vary between different grades of fasteners.
  62. The assembly requires a Tpi that matches the existing components.
  63. The Tpi selection can influence the ease of disassembly.
  64. The Tpi was marked on the part to avoid confusion during assembly.
  65. I realized the importance of Tpi when I encountered a compatibility issue.
  66. The technician adjusted the machinery to accommodate the new Tpi.
  67. The Tpi directly impacts the assembly time and efficiency.
  68. The engineering calculations included considerations for Tpi.
  69. The Tpi was critical for the success of the prototype.
  70. They discovered that the Tpi was too high for the application.
  71. The Tpi was noted as a key factor in the design process.
  72. The manufacturing standards included guidelines on acceptable Tpi.
  73. A proper Tpi selection can enhance the lifespan of the assembly.
  74. The Tpi was discussed during the supplier meeting for quality assurance.
  75. Knowing the Tpi helps in choosing the right tools for installation.
  76. The Tpi of the new model was designed for improved aerodynamics.
  77. The assembly instructions clearly outlined the required Tpi.
  78. The Tpi is one of the critical parameters in thread design.
  79. A consistent Tpi across products ensures reliability.
  80. They had to revise the Tpi based on customer feedback.
  81. The Tpi needed to be standardized across all production lines.
  82. The Tpi measurement was taken to ensure proper thread engagement.
  83. The technical sheet listed the Tpi alongside other dimensions.
  84. The Tpi can also affect the cost of manufacturing.
  85. Engineers use Tpi to determine the suitable threading tools.
  86. The Tpi was crucial for the assembly's performance under load.
  87. The Tpi value was crucial for the final product specifications.
  88. A detailed analysis of Tpi helped in optimizing the design.
  89. The assembly required a specific Tpi to function correctly.
  90. The Tpi was part of the quality control checklist.
  91. They needed to ensure the Tpi matched the design requirements.
  92. The Tpi was critical in ensuring the fasteners held under stress.
  93. A lower Tpi can sometimes lead to easier assembly.
  94. The Tpi was recorded for future reference in the project log.
  95. The Tpi was highlighted during the training sessions for new hires.
  96. An accurate Tpi can save costs in large-scale production.
  97. The Tpi of the threaded components was verified before shipment.
  98. They had to adjust the Tpi to meet the new industry standards.
  99. The Tpi specification was updated to reflect recent changes in materials.
  100. Understanding the significance of Tpi is essential for engineers.
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