Static Control Clothing

Part Number	Description / PDF	Quantity
GL12NI-S ACL Staticide, Inc.	GLVS NITR PWD-FREE SM 12" 100/PK	0
GL12NI-L ACL Staticide, Inc.	GLVS NITR PWD-FREE LG 12" 100/PK	0
GL9NI-L ACL Staticide, Inc.	GLVS NITR PWD-FREE LG 9" 100/PK	41
80LA-XL ACL Staticide, Inc.	FINGER COTS BLACK XL 720/PK	0
100NI-L ACL Staticide, Inc.	FINGER COTS BLUE LRG 720/PK	0
90NI-XL ACL Staticide, Inc.	FINGER COTS WHITE XL 720/PK	1
100NI-M ACL Staticide, Inc.	FINGER COTS BLUE MED 720/PK	0
70LA-M ACL Staticide, Inc.	FINGER COTS PINK MED 720/PK	0
GLK-2XL ACL Staticide, Inc.	GLOVES KNIT EDS 2X-LARGE 1 PAIR	70
GLK-S ACL Staticide, Inc.	GLOVES KNIT EDS SMALL 1PAIR	201
GLKT-L ACL Staticide, Inc.	GLOVES KNIT EDS LARGE W/TPS 1/PR	47
GLK-M ACL Staticide, Inc.	GLOVES KNIT EDS MEDIUM 1 PAIR	277
GLK-XL ACL Staticide, Inc.	GLOVES KNIT EDS X-LARGE 1 PAIR	17
GLKT-S ACL Staticide, Inc.	GLOVES KNIT EDS SMALL W/TPS 1/PR	86
GLKT-2XL ACL Staticide, Inc.	GLOVES KNIT EDS 2X-L W/TPS 1/PR	83
GLKT-XL ACL Staticide, Inc.	GLOVES KNIT EDS X-LRG W/TPS 1/PR	101

Static Control Clothing

1. Overview

Static Control Clothing refers to specialized garments designed to prevent electrostatic discharge (ESD) and contamination in controlled environments. These garments incorporate conductive materials and advanced fabric technologies to dissipate static charges, protect sensitive electronics, and maintain cleanroom standards. They play a critical role in semiconductor manufacturing, pharmaceutical production, and precision engineering industries where electrostatic interference or particulate contamination can cause catastrophic failures.

2. Major Types & Functional Classification

Type	Functional Characteristics	Application Examples
Anti-Static Coveralls	Embedded carbon or stainless steel fibers, surface resistance 10^6-10^9	PCB assembly lines, cleanrooms
ESD Lab Coats	Woven conductive polymer threads, wrist strap grounding points	Research laboratories, electronics R&D
Cleanroom Suits	Non-shedding materials, HEPA filter compatibility	Biotech manufacturing, aerospace
Conductive Fiber Jackets	High-tensile conductive yarns, static decay time <2s	Explosive handling, fuel processing

3. Structural Composition

Typical static control garments feature a 3-layer construction:

Outer layer: Polyester blend with embedded conductive fibers (stainless steel/carbon)
Middle layer: Dielectric barrier coating (surface resistivity 10^7 /sq)
Inner layer: Moisture-wicking antistatic fabric (carbon particle dispersion)

Conductive elements form a Faraday cage effect, with grounding points at wrists and ankles. Advanced models incorporate phase-change materials for thermal regulation and micro-porous membranes for particle filtration.

4. Key Technical Parameters

Parameter	Value Range	Significance
Surface Resistivity	10^5 - 10^12 /sq	Charge dissipation efficiency
Charge Decay Time	<0.1s - 2s	Static neutralization speed
Particle Shedding Rate	<1000 particles/m /min	Cleanroom compliance
Grounding Resistance	<1	Electrical safety assurance
Tensile Strength	50N	Mechanical durability

5. Application Fields

Key industries include:

Semiconductor manufacturing (photolithography equipment protection)
Medical device assembly (Class 100 cleanrooms)
Pharmaceutical production (ISO 14644-1 certified facilities)
Aerospace electronics (MIL-STD-1686 compliance)
Data centers (server rack maintenance)

Typical equipment integration: Ionizers, wrist strap monitoring systems, and ESD floor mats.

6. Leading Manufacturers & Products

Manufacturer	Representative Product	Key Features
DuPont	Tyvek Static Control	Low-linting, 10^8 resistivity
3M	ESD Cleanroom Suit 4200	Integrated grounding system
Honeywell	Gamma Series Anti-Static Coat	EMI shielding, 0.5s decay time
Kimberly-Clark	Kimtech Pure ESD	Class 10 particle specification

7. Selection Guidelines

Key considerations:

Electrostatic properties (surface resistance matching ANSI/ESD S20.20)
Environmental compliance (ISO 14644-1, NFPA 99)
Garment durability (washing cycles >50, abrasion resistance)
Operator comfort (breathability >50g/m /h)
Integration with grounding systems (parallel resistance monitoring)

Example: Semiconductor manufacturers typically select Class 0 ESD garments with <10^6 resistance.

8. Industry Trends

Emerging developments:

Nano-coating technologies for permanent conductive properties
Smart garments with real-time discharge monitoring
Bio-based antistatic materials (PLA fiber composites)
Self-cleaning surfaces using photocatalytic coatings
AI-driven static risk assessment systems

Market growth driven by 5G electronics manufacturing and EV battery production requirements.