Certifications
If you have ever wondered what the certifications that are mentioned in the product pages stands for, this article is for you.
For instance; "Meet and exceeds CE EN 1078, CPSC 1203"? Continue to
read to learn more about the certifications and rigorous testing our protection products need to go through
prior to be launched into the market and put to use by you.
In general, all helmets and protective gear must surpass tests to be certified through different bodies
depending on both the intended use and the country the helmet is sold in. Our helmets are tested for safety
through three main bodies:
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The American Society of Testing Materials, International (ASTM)
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The European Committee for Standardization (CE EN)
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The CPSC (Consumer Product Safety Commission)
Depending on the product type different tests are run. Here are some examples
of the tests a Sweet Protection product goes through before you can use it:
Impact Tests
During impact tests, a series of controlled impacts are performed positioning a
helmet on a metal head form and then dropping it in a guided fall onto various steel test anvils (flat,
hemisphere, curbstone, edge…) which simulate different impact surfaces. The head forms are instrumented
with an accelerometer to measure peak G-force acceleration which is measured in Gravitional Units (g). The
impact energy (drop height and mass) or how hard the helmets are impacted is unique to each standard. In a valid
test, if peak acceleration imparted to the head form exceeds certain threshold value (between 250 and 300
g’s, depending on standard and test type), the helmet is rejected.
Roll-Off Test - Positional Stability
In a roll-off test, a head form is mounted on a stand. The helmet is then
placed on the head form and the straps and buckles adjusted. A wire rope is hooked to the rear edge of the
helmet and it is brought forward so that its free end runs across the helmet and downward towards the floor. The
free end of the rope has a mechanical stop with a 4 kg weight resting on the stop. The weight is raised to a
prescribed height and dropped onto the stop. The resulting shock places a rotational load on the helmet. The
helmet position may be shifted, but must not roll off the head form. Next, the head form is rotated 180 degrees,
the helmet adjusted, and tested with the wire rope hooked to the front edge of the helmet and the test is
repeated. As in the first case, the helmet may be shifted but must not roll off the head form.
Shell penetration test
The shell penetration test applies to our skiing helmets. The helmet is affixed
to a rigid base. A 3 kg sharply pointed striker is dropped in a guided fall onto the helmet from a prescribed
height. The test striker must not penetrate the helmet or even achieve momentary contact with the head
form.
The Certification used in Sweet Protection products
There are different certifications for every category a protection product
belongs to. We will in the following go through the certifications our products use.
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CE EN 1077A/B - Ski and Snowboard Helmets
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ASTM F2040 - Standard Specification
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FIS RH 2013
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EN 12492 - Mountaineering helmets
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CE EN 1078 - Bicycle helmets
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CPSC 1203 - Bicycle helmets
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CE EN 1385 Class I/IV - WW and Canoeing
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CE EN 1621 - Armor for bodyparts, back and spine protectors
CE EN 1077A/B - Ski and Snowboard Helmets
There are six major requirements a ski and snowboard helmet need to surpass to
be certified:
1. Field of vision
Making sure the helmet design does not interfere with the user’s
field of vision
2. Extent of coverage
Making sure the helmet covers all necessary parts of the head
3. Shock absorbing capacity.
The most important is the shock absorbing capacity of the helmet. This
is tested in a specialized instrument where the helmet is dropped at a speed of 5,42 m/s onto a solid
metal anvil with a 4 kg metal head inside. Inside the metal head there’s an accelerometer that
measures the forces within the impact. The helmets are tested in three conditions: Room temperature,
-25ºC, and after artificial aging. Each helmet is tested on several areas (crown, side, rear &
front). The peak acceleration must not exceed 250G for any of the impacts.
4. Resistance to penetration.
While skiing or snowboarding there’s a risk of poles, skis or
branches penetrating the helmet. The resistance to penetration is tested by dropping a hammer with the
mass of 3 kg from 75cm onto a sharp cone shaped metal punch placed against the helmet. The point of the
metal punch must not reach the head inside the helmet.
5. Retention system performance
This test covers the strength of the retention system (webbing), as
well as its effectiveness, i.e. the webbings ability to keep the helmet securely positioned on the
head.
6. Durability
After all these tests the helmet should not show any damage that would
cause any additional damage to the wearer.
Helmets meeting the CE EN 1077 standard:
ASTM F2040 - Standard Specification for Helmets Used for Recreational Snow Sports
The ASTM (American Society of Testing Materials) F2040 safety standard for
nonmotorized recreational snow sports is more stringent than the ECC (European Economic Community) CE 1077
safety standard for alpine skiing and snowboarding. Both organizations describe retention system strength and
roll-off tests, but their impact test differences are notable:
As explained in the section regarding the procedures for the EN1077
testing the ECC testing includes dropping the ski/snowboard helmet at a speed of 5,42 m/s onto a flat
anvil, and the peak acceleration of the impact cannot exceed 250 g.
ASTM testing drops the ski/snowboard helmet at a speed of 6,2 m/s onto
a flat anvil, and at a lower speed onto a hemispherical and edge shaped anvil. Peak acceleration of the
impacts can not exceed 300 g.
Major requirements a ski and snowboard helmet needs to surpass the ASTM
F2040 certification: Retention system, Roll-off system and impact test.
FIS RH 2013
FIS Approved Ski Race Helmets Must Meet ASTM F2040 and CE 1077 certification
testing. For the 2013/2014 ski race season, FIS introduced new ski helmet rules for all Downhill, Super G
and Giant Slalom events on World Cup and Continental Cup levels to improve brain protection for
these ski racers.
Going forward, Downhill, Super G and Giant Slalom World and Continental Cup competitors will have their helmets
inspected for the newly mandated sticker citing the ski race helmet conforms to FIS specifications of 2013. No
sticker, no racing. This rule has now been extended to be applied all the way down to U14 racers.
Helmet Requirement for Giant Slalom (GS), Super Giant Slalom (SG), Down Hill (DH):
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Helmets must pass both ASTM F 2040 safety testing and EN 1077 (class A) safety testing (See above for differences between these standards)
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Helmet must pass testing (through CEN laboratories) to absorb impact at a speed of 6.8 m/s (significantly higher than ASTM 2040 and CE 1077 testing requires)
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A label of at least 1 sq cm, visible and non-removable, must be affixed to the back of the helmet including the text: "Racing helmet conforms to FIS specifications 2013"
Source: FIS
Helmets meeting the FIS RH 2013 standard:
EN 12492 - Mountaineering Helmets
There are five major requirements a mountaineering helmet need to surpass
to be certified:
1. Field of vision
Making sure the helmet design does not interfere with the
user’s field of vision
2. Extent of coverage
Making sure the helmet covers all necessary parts of the head
3. Shock absorbing capacity.
Helmets are subjected to an impact from a falling mass onto a fixed
headform. However, to reflect the nature of the use, additional impacts are required at the front,
side and rear of the helmet. These impacts are carried out by tilting the headform on the rigid base
at an angle of 60° (so that impacts are carried out at 30° from the horizontal plane of the
headform).
Impacts are carried out using two strikers, one flat and one hemispherical, each weighing 5kg.
Helmets are impacted using the hemispherical striker dropped from a height of 2 metres, and at the
front, rear and sides using the flat striker dropped from a height of 500mm. In all cases, the
transmitted force through the headform cannot exceed 10kN..
4. Resistance to penetration.
This is where the mountaineering certification differs the most
from the EN1077 certification for ski and snowsports. These helmets are intended to provide
protection against sharp / pointed objects from above, and so are tested for penetration by sharp
objects. The test in EN 12492 is a 3kg conical striker dropped onto the helmet from a height of 1
metre. The point of the metal punch must not reach the head inside the helmet
5. Retention system performance
This test covers the strength of the retention system (webbing), as
well as its effectiveness, i.e. the webbings ability to keep the helmet securely positioned on the
head.
Sweet Protecion's Ascender and Ascender MIPS helmets are triple certified for both mountaineering (CLASS B / EN 12492) and ski/snowboard (CE EN 1077 and ASTM).
CE EN 1078 - Bicycle Helmets
Like the CE EN 1077 does for ski and snowboard, the CE EN 1078
applies for bike helmets. In general tests are the same and the three major requirements a
helmet needs to surpass to get the certification are: Design requirements, shock absorption, and
retention.
1. Design requirements
Making sure the helmet design does not interfere with
the user’s field of vision and the area of coverage.
2. Shock absorbing capacity.
The most important is the shock absorbing capacity of
the helmet. This is tested in a specialized instrument where the helmet is dropped at a
speed of 5,42 m/s onto a solid metal anvil with a metal head inside.
Inside the metal head there’s an accelerometer that measures the forces within the
impact. The helmets are tested in three conditions: High temperature, low temperature,
and after UV aging. Each helmet is tested on several areas (crown, side, rear &
front). The peak acceleration must not exceed 250G for any of the impacts.
3. Retention system performance
This test covers the strength of the retention system
(webbing), as well as its effectiveness, i.e. the webbings ability to keep the helmet
securely positioned on the head.
Helmets meeting the CE EN 1078 standard:
CPSC 1203 – Bicycle Helmets
CPSC is the US equivalent to CE EN. The CPSC 1203 rules are a
little bit more stringent in terms of the impact test, meaning that helmets can meet the CE EN
1078 standard with thinner foam and lighter weight than the US CPSC 1203. There are four major
requirements a bike helmet needs to surpass the certification: Peripheral Vision Test,
Positional Stability Test, Retention Strength Test and Impact Attenuation Test.
CE EN 1385 CLASS I/IV – Helmets for canoeing and white-water sports
There are six major requirements a helmet, for this use,
needs to surpass to be certified:
1. Field of vision.
Making sure the helmet design does not interfere
with the user’s field of vision
2. Extent of coverage
Making sure the helmet covers all necessary parts
of the head
3. Shock absorbing capacity
The most important is the shock absorbing capacity
of the helmet. This is tested in a specialized instrument where the helmet is
dropped with the speed of 2,5m/s onto a solid metal anvil with a 4 kg metal head
inside. Inside the metal head there’s an accelerometer that measures the
forces within the impact. The helmets are tested in four conditions:
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High temperatures (+35ºC)
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Low temperature (0ºC)
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After artificial aging,
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After the helmet has been submerged for 4 hours.
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Each helmet is tested on several areas (crown, side, rear & front). The peak acceleration must not exceed 250G for any of the impacts.
4. Retention system performance
This test covers the strength of the retention
system (webbing), as well as its effectiveness, i.e. the webbings ability to keep
the helmet securely positioned on the head.
5. Buoyancy
After being submerged for at least 4 hours, the
helmet must float to the surface.
6. Durability
After all these tests the helmet should not show
any damage that would cause any additional damage to the wearer.
Helmets meeting the CE EN 1385 CLASS I/IV standard:
CE EN 1621 – 1 Armor for all body parts and 2 Back and Spine protectors
It is one major requirement an impact protector needs to
surpass: Impact test.
EN1621-1 assesses armor designed to protect the shoulder, elbow and forearm, hip, tail-bone,
knee and lower leg regions. The test apparatus consists of a mass of 5 kg with a 40 mm x 30
mm striking face, dropped onto the sample mounted on top of a 50 mm radius hemispherical
dome. The anvil is further mounted onto a load cell, allowing a measurement to be made of
the force transmitted through the protector. The kinetic energy of the falling mass at
impact must not exceed 50 J.
A protector subjected to this test method is deemed to conform to this standard if the
average transmitted force of nine tests is less than 35 kN, with no single test result
exceeding 50 kN.
It is one major requirement an impact protector needs to
surpass: Impact test.
EN1621-2 assesses armor designed to protect the back/spine. It is a more stringent standard
allowing no more than 18 kN of force to be transmitted to attain Level 1 protection
(EN-1621-2 CE Level 1). Armor that allows less than 9 kN of force to be transmitted can
attain a Level 2 protection (EN-1621-2 CE Level 2). See section below for more
information.