In industrial environments, the consequences of ESD span from substantial financial losses due to product damage and rework to potential safety hazards.

As electronic devices become smaller and more complex, their susceptibility to ESD events increases, emphasizing the need for robust prevention measures. This article delves into the intricacies of ESD, explaining its underlying mechanisms and the diverse strategies deployed to safeguard sensitive electronics across various industries. As a reader, you will explore grounding techniques, material selection criteria, workstation design principles, and handling protocols. By the end, you will have a comprehensive grasp of tailored ESD control methodologies suited to their specific industrial contexts.

ESD prevention techniques

Electrostatic discharge (ESD) is a pervasive and costly issue in electronics manufacturing. Semiconductors carry stored charges that discharge upon contact with the human body or tools, often imperceptibly but damagingly. Handling PCBs with bare hands, placing synthetic materials near electronics, and rapid air movement can all cause ESD. Implementing ESD prevention methods during manufacturing and assembly is crucial to protecting circuits from this invisible threat. Daily activities can build up charges on your body, potentially harming sensitive components:

• Walking on carpet: 1,500 to 35,000 volts
• Walking on the untreated vinyl floor: 250 to 12,000 volts
• Working at a workbench: 700 to 6,000 volts
• Picking up a plastic bag from a workbench: 1,200 to 20,000 volts.

we will discuss some critical ESD control strategies as follows -

Grounding & bonding: Grounding and bonding play critical roles in electrical systems to ensure safety and functionality. They prevent electric shock, equipment damage, and fires. Grounding establishes a connection between circuits and the earth, redirecting current away from people and structures. It provides a low-resistance path for fault currents, triggering protective devices. This stable reference point reduces voltage fluctuations, protecting sensitive electronics. Grounding also manages electromagnetic and radio frequency interference, ensuring optimal performance. While bonding does not eliminate static charges, it establishes equipotential surfaces between the bonded objects, preventing potential differences that could lead to spark discharges. Key features includes:

Grounding

• It provides a low-impedance path for electrical currents to flow safely to Earth.
• Reduces risks of electrical shock, fire, and equipment damage.
• Mitigates electromagnetic interference (EMI) by creating a safe current return path.
• Implementation varies based on equipment type, location, and environment (e.g., grounding rods, plates, or wires).

Bonding

• Interconnects different equipment parts to maintain equipotential surfaces.
• Eliminates voltage differences that could cause EMI.
• Achieved through bonding wires or straps, depending on equipment and environment.

Personal grounding:

It serves as the first line of defense against static charges. This is important as humans primarily produce static electricity through Tribocharging. This can occur from simple actions, like walking across carpets to turning doorknobs.

It is essential to address ESD issues for worker safety and company profitability. Implementing approved ESD grounding requirements tailored to particular areas is vital. This involves first identifying the areas that require grounding. Personal Protective Equipment (PPE) is essential in diminishing ESD risks. Different key items includes:

• Anti-Static wrist straps: They are the primary means of grounding personnel, providing equipotential bonding in field service repairs. This device uses an ion neutralization mechanism that effectively neutralizes over 80% of static ions in the human body. When properly worn and connected to the ground or the equipotential bonding point, a wrist strap keeps the wearer at ground potential or the same potential as the object when a ground connection cannot prevent hazardous discharge between them and other grounded objects. Static charges are directed from the person to the ground, preventing accumulation. Typically, wrist straps include a current-limiting resistor integrated into the ground cord, which is necessary for personnel safety.
• ESD heel straps/ heel grounders: This durable shoe accessory fits all types of shoes, ensuring comfort and adjustability while being highly abrasion-resistant and providing complete static dissipation. Additionally, it comes with a 1 Meg Ohm safety resistor, ensuring a long life and preventing tearing.
• ESD safety shoes/slippers: Anti-static shoes are specialized footwear designed to prevent the accumulation and discharge of static electricity, protecting both the wearer and surrounding equipment. Equipped with conductive soles and laces, anti-static shoes ground the charge to prevent static charge accumulation and discharge.
• Anti-static ESD gloves: reduce static electricity accumulation on equipment or the body, minimizing the risk of electrostatic shock. Constructed with soft conductive materials and synthetic fibers(polyester, rayon, or spandex), these gloves conduct electricity or dissipate static electricity. Some ESD gloves even have carbon fibers or metal threads woven into the fabric to enhance their anti-static properties, providing protection for workers and products against the harmful effects of static electricity and ESD, such as damage to electronic components.
• ESD-safe clothes: ESD-safe clothing is engineered to prevent static charges from transferring from a person or their clothing into the surrounding area. Unlike regular clothing, which often insulates the body from electrical charges, ESD-safe garments are crafted from materials like cotton or polyester embedded with carbon fiber. These fibers create a Faraday Cage around the wearer's body, shielding and dissipating any charges that could otherwise damage devices sensitive to static electricity. Groundable static control garment systems are designed to ground the wearer through the ESD clothing, provided the fabric is conductive enough. Achieving this involves fitting a coil cord to the garment and touching the ground. For this system to function correctly, the ESD garment must have a resistance of less than 35 megohms from the wearer to the groundable point of the garment. All ESD-safe clothing must meet the standards for ESD clothing set by the IEC-61340-1-5 International Standard to protect the wearer and the surrounding environment from electrostatic discharge. To learn more about ESD-safe jackets, click here.

Proper use of PPE, functionality testing, and adherence to standard operating procedures (SOPs) for material handling, storage, and controlled environments are essential. Static-generating actions like touching hair, clothing, or paper should be avoided to prevent charge buildup and potential discharges.

Electrostatic Protected Area (EPA):

ESD-sensitive components and devices should only be unpacked, handled, or assembled within an EPA (Electrostatic Protected Area). An EPA offers optimal conditions for preventing ESD, with all materials being electrostatically dissipative and grounded to the same potential. This includes components, equipment, surfaces, and clothing within a designated area, ensuring targeted avoidance of electrostatic charges and potential differences. An EPA can range from a single workstation to an entire building, with all workstation rules applying uniformly. ESD poses a hidden threat in the electronics industry. It is essential to follow the three ESD fundamentals to control ESD in your workplace:

1. Ground all conductors, including people.
2. Remove unnecessary non-conductors (insulators).
3. Shield ESD-sensitive devices in transport outside an EPA.

An EPA can be distinguished into the central parts:

• EPA identifiers: To identify an EPA, use products such as floor marking tape and signs with clear messages, such as "Entering ESD Protected Area" or "Leaving ESD Protected Area." This alerts personnel and visitors when entering or exiting areas requiring special precautions like grounding via wrist straps, foot grounders, etc. Consistency in signage across the workplace floor avoids confusion. EPA identifiers include ESD floor marking tape and ESD marking/signs or levels.