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Microfluidic Chip Injection Molding for Mass Production

2024-02-28

Injection molding is a manufacturing process that involves injecting molten plastic into molds, followed by cooling and solidification to achieve the desired shape. In the production of microfluidic plastic chips, this method offers several advantages. Firstly, injection molding can accomplish large-scale production in a short timeframe, enhancing production efficiency. Secondly, through mold design and optimization, the technique ensures precise dimensions and shapes for microfluidic chips, ensuring reliability and stability in practical applications. Additionally, injection molding comes with lower production costs, contributing to economic benefits in mass production.

Microfluidic Plastic Chips

2023-10-24

Microfluidic plastic chips are miniature laboratory devices made from polymer materials, featuring microchannels and microchambers for controlling and analyzing microfluids. In comparison to traditional glass chips, plastic chips offer advantages such as low cost, flexible fabrication, lightweight, and easy processing. Widely applied in biomedical research, chemical analysis, environmental monitoring, etc., these chips enable effective experiments like micro-reactions, cell culture, drug screening, providing convenient tools for laboratory research. Microfluidic plastic chips play a crucial role in advancing microfluidic technology, promoting automation, and high-throughput experiments in laboratories.

Microfluidic glass chip

2023-10-24

Glass microfluidic chip is a crucial tool in microfluidic technology, utilizing glass as the manufacturing material for the chip. Compared to traditional polymer chips, glass chips exhibit outstanding optical transparency, chemical inertness, thermal stability, and biocompatibility. These characteristics make glass chips widely applied in life science research, medical diagnostics, drug screening, and other fields. The fabrication processes for glass chips are diverse, involving methods such as micromachining and chemical etching to precisely create microstructures and microchannels, achieving the integration of microfluidic systems. The highly controllable manufacturing process provides a stable and reliable platform for experiments, and the transparency facilitates real-time observation of cells, particles, or biochemical reactions within the microfluid, offering advanced and dependable solutions for the application of microfluidic technology.