Applications of Electrostatic Field Testers: From Semiconductor Factories to Medical Facilities

2025-11-12 17:45:08

Application Scenarios of Static Field Testers: From Semiconductor Factories to Medical Facilities

Static field testers cover core industries sensitive to static electricity, focusing on "static monitoring and risk prevention." Below is a breakdown of segmented scenarios from semiconductor factories to medical facilities, tailored to the precise needs of Google search users (engineers, purchasers, quality control personnel):

1. Semiconductor/Electronic Manufacturing Plants

• Used in wafer production and chip packaging processes to real-time monitor static voltage on workshop environments and equipment surfaces, preventing electrostatic breakdown of sensitive electronic components (e.g., MOSFETs, PCB boards).

• Test the static neutralization effect of anti-static workbenches and ionizing blowers to ensure production lines comply with ANSI/ESD S20.20 standards and guarantee product yield.

2. Precision Instrument Manufacturing Workshops

• Suitable for the production of optical instruments (lenses, sensors) and aerospace components, monitoring static electricity generated during processing to avoid dust adsorption that affects product precision.

• Verify the protective effect of anti-static packaging materials (e.g., anti-static bags, foam) to prevent electrostatic damage to precision components during transportation.

3. Pharmaceutical/Biomedical Facilities

• In pharmaceutical workshops (especially sterile preparations and biological preparations production areas), monitor static accumulation on equipment and operators to avoid dust explosion risks caused by static electricity or impacts on drug purity.

• In medical device assembly scenarios (e.g., pacemakers, ultrasonic probes), detect whether static electricity may interfere with the circuit stability of electronic medical devices, ensuring medical device safety.

4. Chemical/Explosion-Proof Production Sites

• During the storage and transportation of chemical raw materials (powders, solvents), monitor the intensity of the environmental static field to prevent combustion and explosion accidents caused by electrostatic discharge, meeting ATEX/IECEx explosion-proof standard requirements.

• In coating and ink production workshops, detect static generation during material mixing and filling to avoid product quality defects (e.g., uneven coating) caused by static electricity.

5. Laboratories/Scientific Research Institutions

• In material science laboratories, used to test the surface static performance of new anti-static materials, providing data support for material research and development.

• In electronic scientific research scenarios (e.g., microelectronics, nanotechnology research), monitor static electricity in the experimental environment to avoid static interference with the accuracy of experimental results.

6. Automotive Electronics Assembly Lines

• In the production of new energy vehicle battery packs, monitor static electricity during the assembly of battery cells and circuit boards to prevent battery short circuits or electronic control system failures caused by static electricity.

• In the installation of automotive electronic components (e.g., radar, central control screens), verify the effectiveness of anti-static measures to ensure the reliability of on-board electronic devices.