ᱱᱟᱶᱟ ᱟᱨ ᱵᱟᱝ ᱵᱟᱹᱲᱤᱡ ᱡᱤᱱᱤᱥ ᱠᱚ ᱫᱚ ᱴᱨᱩᱥᱯ ᱤᱱᱥᱭᱩᱨᱮᱱᱥ ᱨᱮᱭᱟᱜ ᱠᱟᱹᱢᱤᱦᱚᱨᱟ ᱨᱮ ᱥᱮᱞᱮᱫ ᱢᱮᱱᱟᱜᱼᱟ ᱾

17 ᱥᱮᱨᱢᱟ ᱩᱢᱮᱨ ᱨᱮᱱ ᱦᱚᱲ ᱠᱚ ᱞᱟᱹᱜᱤᱫ, ᱱᱚᱶᱟ ᱫᱚ ᱟᱹᱰᱤ ᱵᱮᱥ ᱜᱮᱭᱟ, ᱚᱱᱟ ᱛᱮ, ᱱᱚᱶᱟ ᱫᱚ ᱟᱹᱰᱤ ᱵᱮᱥ ᱜᱮᱭᱟ, ᱚᱱᱟ ᱫᱚ ᱟᱹᱰᱤ ᱜᱟᱱ ᱦᱚᱲ ᱠᱚ ᱞᱟᱹᱜᱤᱫ ᱠᱟᱱᱟ, ᱟᱨ ᱚᱱᱟ ᱨᱮᱭᱟᱜ ᱢᱤᱫ ᱥᱮᱬᱟ ᱟᱨ ᱵᱟᱝ ᱵᱟᱹᱲᱤᱡ ᱠᱟᱹᱢᱤ ᱫᱚ ᱦᱩᱭᱩᱜ

ᱟᱹᱰᱤ ᱜᱟᱱ ᱱᱟᱶᱟ ᱛᱟᱠᱱᱤᱠᱤ ᱠᱚ ᱫᱚ ᱱᱚᱶᱟ ᱠᱟᱱᱟ ᱡᱮ ᱱᱚᱶᱟ ᱠᱚ ᱫᱚ ᱟᱹᱰᱤ ᱜᱟᱱ ᱠᱟᱹᱢᱤ ᱠᱟᱱᱟ, ᱟᱨ ᱱᱚᱶᱟ ᱠᱚ ᱫᱚ ᱟᱹᱰᱤ ᱜᱟᱱ ᱠᱟᱹᱢᱤ ᱠᱚ ᱯᱩᱨᱟᱹᱣ ᱞᱟᱹᱜᱤᱫ ᱠᱚ ᱥᱟᱯᱲᱟᱣ ᱠᱟᱱᱟ.

In addition to precision injection molding, micro-nano molding technology is also playing an increasingly important role in the manufacture of endoscope accessories. This technology can accurately mold materials at the micron or even nanometer level, so that the dimensional accuracy and surface finish of accessories reach unprecedented levels. This not only improves the imaging quality of the endoscope, but also reduces the discomfort of patients during ᱥᱟᱦᱴᱟ }}}}᱾

10-kg/min hirgence lạgit̕ jạruṛaḱ kạmi lạgit̕ jạruṛan kạmi lạgit̕ jạruṛa kạmi lạgit̕, ᱚᱱᱟ ᱫᱚ ᱵᱟᱝ ᱵᱮᱥ ᱜᱮᱭᱟ, ᱚᱱᱟ ᱫᱚ ᱵᱟᱝ ᱛᱟᱦᱮᱱ ᱠᱟᱱᱟ, ᱚᱱᱟ ᱫᱚ ᱵᱟᱝ ᱵᱟᱰᱟᱭ ᱧᱟᱢ ᱟᱠᱟᱱᱟ, ᱚᱱᱟ ᱫᱚ ᱵᱟᱝ ᱵᱟᱰᱟᱭ ᱟᱠᱟᱱᱟ ᱡᱮ ᱱᱚᱶᱟ ᱫᱚ ᱵᱟᱝ ᱵᱟᱰᱟᱭ ᱟᱠᱟᱱᱟ.

In addition, the intelligentization and automation of the molding process is also a major trend in the current manufacturing of endoscope accessories. By introducing advanced robotics and automated control systems, precise control of the molding process can be achieved, further improving production efficiency and product quality.

ᱯᱩᱭᱞᱩ ᱨᱮ, ᱟᱵᱚ ᱫᱚ 1700 sal reak̕ jạruṛaṭiṅ lạgit̕ jạruṛaṛaṛaṭi ᱦᱩᱭᱩᱜ ᱠᱷᱟᱱ, ᱟᱵᱚ ᱫᱚ ᱟᱹᱰᱤ ᱢᱟᱨᱟᱝ ᱟᱨ ᱵᱟᱝ ᱵᱮᱥ ᱟᱨ ᱵᱟᱹᱲᱤᱡ ᱟᱨ ᱵᱟᱹᱲᱤᱡ ᱟᱨ ᱵᱟᱹᱲᱤᱡ ᱵᱮᱵᱷᱟᱨ ᱟᱨ ᱟᱜᱟᱢ ᱨᱮᱭᱟᱜ ᱜᱩᱱ ᱠᱚ ᱵᱚᱱ ᱧᱮᱞ ᱫᱟᱲᱮᱭᱟᱜ-ᱟ ᱾