WHAT KIND OF SAFETY HELMET DO YOU NEED?
Unsure what kind of safety helmet you need? What helmets comply with what standard? Where to start? At ZERO, want to make sure staying compliant is second nature, especially when it comes to premium protection that is keeping your head safe. There’s a lot to know and a lot to pay attention to when it comes to safety helmets– so we’ve done the research for you.
EN 12492, EN 397, AS/NZS 1801, and ANSI Z89 are standards that specify requirements for different types of protective headgear used in various industries and activities. While they all focus on head protection, there are key differences between these standards in terms of their geographical applicability, performance criteria, and specific requirements. Let's explore each standard in more detail:
ANSI/ISEA Z89.1 Standard – U.S.A.
ANSI Z89: ANSI Z89 is an American National Standard that establishes requirements for industrial head protection. It is divided into two classes: Class G (general) helmets and Class E (electrical) helmets. ANSI Z89 helmets must meet criteria for impact resistance, penetration resistance, electrical insulation, flammability, and water absorption. They are commonly used in industries such as construction, utilities, and oil and gas.
ANSI Z89.1 requires four performance tests that must be met in order to assign a safety helmet type and class, which are:
- Force Transmission
- Apex Penetration
- Flammability
- Electrical Insulation
Safety Helmet Types: There are two types of protective safety helmets under this classification system that refer to impact/penetration protection:
Type 1: Designed to reduce the force of impact resulting from a blow to the top of the head
Type 2: Designed to reduce the force of impact resulting from a blow to the top, front, back, and sides of the head
Safety Helmet Classes: To improve comprehension and usefulness, there are electrical-protective classifications for helmets as follows:
Class G – General Helmet: Designed to reduce exposure to low voltage conductors, proof tested at 2200V
Class E – Electrical Helmet: Designed to reduce exposure to high voltage conductors, proof tested at 20,000V
Class C – Conductive Helmet: Not intended to provide protection against contact with electrical conductors
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Basic temperature applications from -18°C (0°F) to 49°C (120°F) – No special marking on the helmet
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Low-temperature applications down to -30°C (-22°F) – Labeling on the helmet “LT”
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High-temperature applications up to 60°C (140°F) – Labeling on the helmet “HT”
Additionally, all safety helmets must feature a hard-outer shell and a lining that absorbs shock and incorporates a headband. Straps should suspend from the shell about 1-1¼ inches.
It is important to know that all safety helmets that adhere to ANSI/ISEA standards should be permanently marked with the manufacturer, the date of manufacture, ANSI designation, the Type and Class designation, and the head size range on the inside of the helmet shell. If your current safety helmet label is missing or is no longer legible, it is recommended that you replace your safety helmet as soon as possible.
EN Standards – Europe
EN 12492
This European standard applies to mountaineering helmets and sets out requirements for shock absorption, penetration resistance, retention system strength, field of vision, and chin strap strength. It is specifically designed for head protection in mountaineering, climbing, and related activities. EN 12492 helmets are tested to withstand the specific hazards associated with these activities, such as impacts from falling objects and rocks. Requirements include:
- Shock absorption, vertical, frontal, lateral, dorsal
- Penetration resistance
- Carrier element (chin strap releases at min. 500N)
- Strength of carrier element: Chin strap may exhibit maximum elongation of 25mm
- Carrier element effectiveness: Helmet must not slide from the head
EN 397
Another European standard, EN 397, is more general and covers industrial safety helmets. It focuses on head protection in industries like construction, mining, and manufacturing. EN 397 helmets must meet requirements related to shock absorption, penetration resistance, flame resistance, chin strap strength, and electrical insulation. They are tested for protection against falling objects, impact energy, and resistance to penetration by sharp objects.The helmet will comprise of two main parts – the hard outer protective shell and the inner harness. All helmets certified according to EN 397 must meet these requirements:
- Shock absorption, vertical
- Penetration resistance (against sharp and pointed objects)
- Flame resistance
- Chin strap attachment: chin strap releases at minimum 150N (Newtons) and maximum 250N
Additional specifications are provided for ear muff attachment points and chin strap attachment points.
AS/NZS 1801
This standard is specific to Australia and New Zealand and applies to industrial protective helmets. AS/NZS 1801 sets out requirements for construction, materials, shock absorption, penetration resistance, and retention system strength. It includes tests for resistance to impact, penetration, flame, and electrical conductivity. AS/NZS 1801 helmets are used in various industries and workplaces throughout Australia and New Zealand.
EN 50365
Standard covers insulating helmets aimed at use on low voltage installations, which must provide protection against electric shocks and prevention of dangerous electric current passing through the head. Requirements include:
- All helmets must also meet the requirements in accordance with EN 397
- Protection against alternating voltage of up to 1000 V (AC) or direct voltage up to 1500 V (DC)
- Insulating helmets must not contain any conductive parts
- Air vents (if available) must not allow any accidental contact with live parts
- EN 14052: Standard covers high performance industrial helmets, which must provide protection against falling objects and lateral impact along with the resulting damage to the brain, skull, and neck. Requirements include:
Shock absorption, vertical, and lateral - Penetration resistance, vertical, and lateral
- Fastening system yield: Chin strap yields at minimum 150N and maximum 250 N
- Fastening system effectiveness: During the shock absorption and penetration test, the helmet
- must not become detached from the test head
- Flame resistance
While these standards differ in certain aspects, they all aim to provide adequate head protection in their respective applications. When selecting a helmet, it is important to consider the specific industry requirements and hazards involved to ensure compliance with the appropriate standard. Additionally, it is crucial to follow the manufacturer's instructions and replace helmets after any significant impact or when they no longer meet the required standards.