100 Examples of sentences containing the common noun "sinter"

Definition

"Sinter" refers to a material produced by the process of sintering, which involves heating powdered materials (often metals, ceramics, or minerals) to a temperature below their melting point, allowing particles to adhere to each other and form a solid mass. It can also refer to the process itself, which is used in metallurgy and ceramics to create dense, strong components.

Synonyms

• Cinder
• Residue
• Frit
• Clinker
• Ash

Antonyms

• Melt
• Dissolve
• Liquid
• Fluid

Examples

1. The factory workers had to sinter the metal powders at high temperatures.
2. To create strong ceramics, it is essential to sinter the clay properly.
3. They decided to sinter the materials to improve their structural integrity.
4. The laboratory experiments showed that the longer you sinter, the denser the product becomes.
5. Engineers often sinter components to achieve the desired mechanical properties.
6. In the production of bricks, the clay is first shaped and then sintered in a kiln.
7. The sintering process can significantly reduce porosity in the final product when you sinter effectively.
8. The team was tasked with finding the optimal temperature to sinter the alloy.
9. When the dust is compacted and then sintered, it forms a robust piece.
10. They learned how to sinter various metals to create custom tools.
11. The sintering stage is crucial in the manufacturing of certain types of batteries, so they must sinter the materials carefully.
12. To enhance conductivity, the researchers decided to sinter the metal powders.
13. After they sintered the mixture, the resulting material was ready for testing.
14. The sintered object was much stronger than the unsintered version, proving the importance of the sinter process.
15. It was fascinating to watch the team sinter different combinations of metal powders.
16. They needed to sinter the ceramic until it reached its peak strength.
17. The process of sintering is often used in 3D printing to create solid objects from powders.
18. To make the final product, they had to sinter the layers together effectively.
19. The technicians monitored the temperature closely to ensure they did not over-sinter the materials.
20. The new method allowed them to sinter at a lower temperature than before.
21. If you don't sinter the material correctly, the end product may fail under stress.
22. The engineers were excited to sinter the new formulation they had developed.
23. They planned to sinter the metal mixture in a vacuum to prevent oxidation.
24. The research showed that varying the time to sinter can lead to different material properties.
25. It is essential to allow the material to cool properly after you sinter it.
26. The product was designed to sinter without any defects in the structure.
27. To achieve a finer grain structure, they had to sinter the powders under controlled conditions.
28. They could manipulate the sintering process to enhance the performance of the final product by adjusting how they sinter.
29. The sintered material exhibited excellent wear resistance after proper sintering.
30. They were able to sinter several samples in a single batch to save time.
31. The ability to sinter efficiently is critical in the production of advanced ceramics.
32. The sintered parts were tested for durability and strength after they had been sintered.
33. To reduce costs, the company invested in technology that could sinter faster and more efficiently.
34. The sintering technique they employed allowed them to sinter complex shapes with ease.
35. It was important to ensure that the powders were evenly distributed before they were sintered.
36. The team developed a new additive to help improve the quality of the materials they sinter.
37. Before they could sinter the final product, they had to prepare the powder blend.
38. The engineers were pleased with how well the materials sintered at the new facility.
39. The method they used to sinter the metal was revolutionary for the industry.
40. If the material is too porous, it may require additional sintering to achieve the desired density.
41. They observed that different atmospheres during the sintering process affected the final properties.
42. The technician demonstrated how to sinter metal powders using the new machine.
43. To achieve optimal results, they had to sinter the components in stages.
44. They realized that the key to their success was finding the right conditions to sinter the material.
45. The product line was expanded after they learned how to sinter new types of raw materials.
46. They decided to sinter the material at a higher pressure to improve its strength.
47. The research group published their findings on how to effectively sinter biocompatible materials.
48. It took time to perfect the process of sintering the special alloy.
49. The sintered samples underwent rigorous testing to ensure they met quality standards after being sintered.
50. They were determined to find a way to sinter without generating excessive waste.
51. The sintering furnace was designed to allow them to sinter under controlled conditions.
52. After they sintered the ceramic, it was ready for further processing.
53. The choice of binder was critical in determining how well the material would sinter.
54. They needed to understand the chemistry behind the materials they planned to sinter.
55. The sintering temperature had to be adjusted depending on the type of powder used to sinter.
56. They discovered that adding certain additives could improve how well the materials sinter.
57. The company specialized in developing techniques to sinter advanced materials for aerospace applications.
58. They had to sinter the components multiple times to achieve the desired properties.
59. The new process allowed them to sinter larger parts without compromising quality.
60. The research focused on optimizing the time it took to sinter the materials used in production.
61. After they sintered the metal, they subjected it to thermal treatment for better performance.
62. They were excited to begin testing after they successfully sintered the first batch.
63. The sintering process they utilized was both innovative and efficient, allowing them to sinter quickly.
64. The team expected the new formulation to significantly improve how well they could sinter the materials.
65. The final product exceeded expectations after they perfected the way they sintered the components.
66. They had to experiment with different mixtures to find the best combination to sinter.
67. The sintering time was critical; too short and it wouldn’t bond properly, too long and it might sinter too much.
68. The engineers aimed to sinter the materials in a way that would maintain their unique properties.
69. They were able to sinter the materials at a lower cost thanks to the new technology.
70. The sintering process is essential for creating parts that can withstand high pressures, so they had to sinter carefully.
71. They quickly learned that the ideal conditions to sinter varied based on the specific materials used.
72. The project involved creating a prototype that could sinter different types of alloys.
73. The researchers were excited about the new methods they developed to sinter nanomaterials.
74. They had to carefully monitor the cooling process after they sintered the materials.
75. The sintered part was put through rigorous stress testing after it was sintered.
76. Their innovative approach allowed them to sinter materials that were previously considered impossible.
77. The process of sintering was integral to the success of their new product line.
78. They were able to sinter the materials in a way that minimized defects.
79. The research focused on the effects of different atmospheres during the sintering process.
80. The goal was to sinter the materials in such a way that they achieved maximum performance.
81. They found that the particle size greatly affected how well they could sinter the powders.
82. The sintered product was manufactured using a high-tech process that allowed them to sinter with precision.
83. The ability to sinter at different rates opened up new possibilities for material applications.
84. They decided to sinter the samples at various temperatures to compare the results.
85. The team celebrated their success after they managed to sinter the complex shapes.
86. They were confident that they could sinter the materials to meet the demanding specifications.
87. The sintering process was critical in achieving the desired finish on the final product once they sintered.
88. They documented every step of how they sintered the materials for future reference.
89. The process they developed allowed them to sinter more efficiently than ever before.
90. After they sintered the metal, they applied a coating for additional protection.
91. The sintering temperature was adjusted to optimize the results after they sintered the samples.
92. They had to ensure that the powders were uniformly mixed before they could sinter them.
93. The lab was equipped with advanced technology to help them sinter materials more effectively.
94. They realized that the atmosphere in which they sintered had a significant impact on the final product.
95. The sintered parts were subjected to additional processing after they were sintered.
96. The new sintering machine allowed them to sinter multiple batches simultaneously.
97. They conducted a series of trials to determine the best way to sinter the material.
98. The sintering process was modified to allow for better consistency in how they sintered their products.
99. They expected the new approach to sinter to lead to significant improvements in efficiency.
100. After they sintered the components, they were pleased with the results and the overall quality.