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INNOVATION
ZETTACUT은 실전 검증된 고성능 인체보호장구 브랜드로,
절단·베임·내열·충격 보호 등
최첨단 소재와 기술로 최적의
퍼스널 프로텍션 솔루션을 제공합니다.
HomeInnovation산업표준과 인증
industry standards 산업표준과 인증
미국과 유럽연합에서는 산업현장에 작업자들이 용도에 맞는 장갑을 착용하도록 법적으로 의무화 하고 있습니다.
따라서 EU와 ANSI 안전규격과 같이 용도에 맞는 장갑들을 착용하면 좋습니다.
미국과 유럽연합에서는 산업현장에 작업자들이 용도에 맞는 장갑을 착용하도록 법적으로 의무화 하고 있습니다. 따라서 EU와 ANSI 안전규격과 같이 용도에 맞는 장갑들을 착용하면 좋습니다.
EN420-일반적인 요구조건
이 규격은 산업현장에서 사용하기에
적합한 장갑인지에 대한 요구조건을 규정
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EN388
Mechanical Hazards
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EN407
Thermal (Heat) Hazards
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EN1149
Antistatic
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EN374-2
Micro-Organisms
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EN374-3
Chemical Hazards
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EN511
Protection from Cold
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Hand Protection Standards
Food Handling
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Hand Protection Standards
Radioactive Contamination
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Hand Protection Standards
Ionising Radiation
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Hand Protection Standards
Low Chemical Resistance
CE Category Information
The Personal Protective Equipment Directives (89/686/CEE) and (93/68/CEE) have been enacted by the European
Community to ensure harmonisation of regulations regarding testing of all PPE sold within the community. All gloves of
intermediate and complex design must now be tested independently to ascertain their performance and ensure their
safety. They must, if they meet these standards, carry a CE Mark on the gloves or their packaging when it is not practical.
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CE Category I
Simple Design – for minimal risks only. Suitable only for low risk applications where hazards can be identified by the wearer in time to deal with them.
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CE Category II
Intermediate Design – reversible risks. Products are type examined by an approved body where they examine the manufacturers’ technical specifications and conduct tests for the relevant standards to ascertain their conformity and/or performance.
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CE Category III
Potentially fatal risks, for example in activities where toxic or highly corrosive chemicals are handled. The glove must meet the standards set out for this category. Its compliance is not only certified but also checked by a notified body, the reference number of which is located below the CE logo.
EN388
EN388:2016
EN388:2016
(유럽산업안전장갑 레벨)이란?
절단 및 기계적 위험에 대한 저항성을
기준으로 보호용 장갑을 분류하기 위한 유럽표준으로 장갑의 성능 및 보호수준에
대한 정확도에 신뢰성이 높습니다.
4
5
4
4
F
P
- 첫번째 숫자
내마모성
Abrasion
Resistance
1, 2, 3, 4
사포(180 grit sandpaper)를 회전시켜 마모가 시작되는 정도를 측정한다.
- 두번째 숫자
내절단성
Cut Resistance
By Blade
1, 2, 3, 4, 5
5N 고정압력 하에서 물질을 절단할 때까지 앞뒤로 움직이는 원형 블레이드를 이용한다.
- 세번째 숫자
찢김방지
Tear
Resistance
1, 2, 3, 4
장갑 재료를 찢을 때 필요한 힘이 측정된다.
- 네번째 숫자
뚫림방지
Puncture
Resistance
1, 2, 3, 4
날카로운 물체로 재료를 뚫는 데 필요한 힘의 양을 기준으로 한다.
- 다섯번째 숫자
절단저항
Cut Resistance
EN ISO 13997
A, B, C, D, E, F
시험 중에 가해자는 힘의 양에 의해 절단 저항이 어떻게 영향을 받는지를 측정한다.
- 여섯번째 숫자
충격저항
Impact
Protection
P, F, X
장갑에 충격 보호기능이 있는 경우에 P가 들어간다.
레벨(숫자)이 높을수록 절단·절삭 위험에 대한 보호 수준이 높을을 나타냅니다.
| Performance levels | 0 | 1 | 2 | 3 | 4 | 5 |
|---|---|---|---|---|---|---|
AAbrasion resistance (Cycles) |
< 100 | 100 | 500 | 2000 | 8000 | - |
BBlade cut resistance (Coupe test : index)*1 |
< 100 | 1.2 | 2.5 | Anilin | 10.0 | 20.0 |
CTear resistance (Newton) |
< 100 | 10 | 25 | 50 | 75 | - |
DPuncture resistance (Newton) |
< 20 | 20 | 60 | 100 | 150 | - |
| Performance levels | A | B | C | D | E | F |
|---|---|---|---|---|---|---|
EEN ISO cut resistance (TDM test : Newton)*2 |
2(203 grams) | 5(509 grams) | 10(1019 grams) | 15(1529 grams) | 22(243 grams) | 30(3059 grams) |
FEN Impact Protection |
PASS or FAIL | |||||
- ※ Note : There is no correlation between the levels of performance obtained with the *1 and *2 test methods.
- ※ Level X can also be applied for “a” through “f” above, which means “not tested” or “not applicable”
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AAbrasion resistance (Cycles)
The test defines the abrasion resistance or durability of the glove material. The material is abraded under known pressure with a cyclic planar motion in the form of a Lissajous figure. Abrasion resistance is determined as the number of abrasion cycles required to break through.
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BBlade cut resistance
The test measures cut resistance by a circular rotating blade that moves back and forth on the test specimen under a specified load and rotates in the opposite direction to this movement. The test simulates repetitive activities with a constant cutting load. The test is considered a good indicator of protection against injury for light and medium-weight parts. The test is ended manually after a maximum of 60 cycles. For materials that have a dulling effect on the blade, the procedure according to EN ISO 13997 must be carried out.
- TipAlways consider the grip when looking for cut gloves as the more suitable to grip the lower the risk of cuts according.
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CTear resistance
The resistance to tear is defined as the force necessary to propagate a tear in a specimen slit half way along its length. Materials with high tear resistance ensure longevity. In general, gloves should not be worn on rotating machines (e.g. drill). The tear strength of the protective gear would prevent tearing off if you were hit by the machine.
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DPuncture resistance
The puncture force is defined as the force required to pierce a test sample using a steel pin of specified dimensions. This is not to be confused with perforating done using thin points or needles. The outermost and innermost layers of the glove must not show any signs of melting or hole formation.
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EEN ISO cut resistance
The test measures the cut resistance against a blade at a specified length of cut. Different pressures are exerted on the knife. The result is reported in N(Newtons) of the pressure passed. The test simulates a one off cut at varying pressures and can be used as an indicator of emergency/accident protection. From a value of E and F, the gloves are considered highly cut-resistant for emergency cut situations.
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FEN Impact Protection
Impact test according to EN 13594:2015. Here the absorption of the impact energy of 5 J on the absorption material of the glove is tested. This Test is optional and is only expressed with a P for passed.
EN407
EN407:2020
Protective gloves against thermal risks
Icon indicatesglove has been
tested to limited
flame spread(LFS)
Icon indicates glovehas been tested
to LFS, i.e. glove has
protection against
heat without flame
4
2
3
3
4
2
| Tests | Levels |
|---|---|
ALimited flame spread |
0 - 4 |
BContact heat resistance |
0 - 4 |
CConvective heat resistance |
0 - 4 |
DRadiant heat resistance |
0 - 4 |
EResistance to small splashes of molten metal |
0 - 4 |
FResistance to large splashes of molten metal |
0 - 4 |
- Got all that? Now let’s take a closer look at the six glove performance tests. Note that a glove can be tested to all of these tests or just one.
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ALimited flame spread
This test is indicated by the above fire icon. Because the presence of flame is inherently dangerous, this test assesses a glove’s flammability and charring behavior after being exposed to a direct flame.
How the test worksIn a controlled chamber, the glove is exposed to the flame for three seconds. The same test is performed for 10 seconds. After-flame and afterglow times are logged and the glove is inspected for any damage or exposed seams.
After-burn time (seconds) After-glow time (seconds) Rating Under 15 seconds Infinity 1 Under 10 seconds Under 120 seconds 2 Under 3 seconds Under 25 seconds 3 Under 2 seconds Under 5 seconds 4 -
BContact heat resistance
This tests thermal resistance by measuring the rate of temperature rise, or, in other words, how long gloves keep the heat at bay.
Note : If a glove is not tested and certified to LFS, this test is indicated by the above icon with three wavy lines. This means the glove has protection against heat without flame.How the test worksSamples are placed on four plates heated from 100°C to 500°C. Performance is determined by how long it takes the temperature on the side opposite the sample to rise 10°C. This is known as the threshold time. Gloves need to withstand the increasing temperature of maximum 10°C for at least 15 seconds for a pass at a given level.
Tests can be performed on any area of the glove that is intended to be exposed to contact heat (if explicitly stated on the packaging). If no area is designated, the rating is on the palm.Temperature after 15 seconds
(plate temperature)Rating 100°C 1 250°C 2 350°C 3 500°C 4 -
CConvective heat resistance
This test exposes gloves to a flame heat source, with the glove being spaced well away from flame, never making contact. Different surfaces of the glove are tested.
How the test worksIn a controlled chamber, the back-of-hand and palm samples are exposed to a heat source. The goal is to determine how long it takes to raise the inner temperature of the glove 24°C.
Seconds Rating Over 4 seconds 1 Over 7 seconds 2 Over 10 seconds 3 Over 18 seconds 4 -
DRadiant heat resistance
This tests the back of the glove to ensure materials can resist extreme heat radiating through the glove’s various materials.
How the test worksGlove samples are exposed to a radiant heat source. Like the Convective Heat Resistance test, the goal is to assess how long it takes the inners temperatures to rise 24°C.
Seconds Rating Over 7 seconds 1 Over 20 seconds 2 Over 50 seconds 3 Over 95 seconds 4 -
EResistance to small splashes of molten metal
This test is designed to assess hand protection when working with small amounts of molten metal. Welding is a good example.
How the test worksIn a controlled chamber, two palm and two back-of-the-hand samples are exposed to small drops of molten metal, such as copper. Protective performance is based on the number of drops needed to raise the temperature by 40°C on the opposite side of the sample. The cuff is also tested if composed of different materials than palm/back-of-hand.
Number of drops Rating Over 10 1 Over 15 2 Over 25 3 Over 35 4 -
FResistance to large splashes of molten metal
For this test, PVC foil is used to simulate how skin would be affected inside the glove.
How the test worksMolten metal, such as iron, is poured over a glove sample that, in turn, is placed over PVC foil. After each of the three tests, the foil is assessed for changes.
Grams of molten Rating 30g 1 60g 2 120g 3 200g 4
ANSI
Standard for Cut Testing
The American National Standards Institute (ANSI) and International Safety Equipment Association (ISEA) current standard for displaying the rating of hand protection against cut risks is ANSI/ISEA 105-2024.
ASTM F2992-23 Standard
1. Nine Levels of cut protection
2. TDM-100 is the only machine acceptable for testing
3. Blade must be changed after each test
4. Five times at each of three weight loads ensure accurate results
ASTM F2992-23 is the standard used to obtain gram results, the ANSI/ISEA 105-2024 standard then interprets what classification level those results will report as. These two standards streamline the process, ensuring predictability and consistency across the hand protection industry.
ANSI/ISEA 105‑2024 :
Hand Protection & Cut Level Ratings
Current Cut Levels
1
Blade is
Blade is
Lowered onto
test material
2
Blade is moved
Blade is moved
20mm across
test material
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CUT
LEVELA9≥6,000 grams -
CUT
LEVELA8≥5,000 grams -
CUT
LEVELA7≥4,000 grams -
CUT
LEVELA6≥3,000 grams -
CUT
LEVELA5≥2,200 grams -
CUT
LEVELA4≥1,500 grams -
CUT
LEVELA3≥1,000 grams -
CUT
LEVELA2≥500 grams -
CUT
LEVELA1≥200 grams
| Cut Level | Hazards |
|---|---|
| Level A9 | Highest cut risks |
| Level A8 | Very high cut risks, Aerospace, Recycling |
| Level A7 | Aerospace, Window Manufacturing, Recycling |
| Level A6 | Metal Stamping and Fabrication, Electrical, Construction |
| Level A5 | Appliance Manufacturing, Glass Handling, HVAC |
| Level A4 | Glass Handling, HVAC, Machining, Metal Fabrication |
| Level A3 | Construction, Automotive Assembly |
| Level A2 | Automotive, Packaging, Metal Handling |
| Level A1 | Assembly, Warehouse, Material Handling |