As a licensee of both Dyneema® and DuPont® advanced fibers, our gloves and sleeves are made using proprietary engineered yarn blends and coatings. The result - hand and arm protection that is innovative and performance driven. Meeting todays tough ANSI and EN standards, we develop and market seamless knit, coated and uncoated, polymer, supported and unsupported as well as cut and sewn gloves in both leather and advanced composite materials.
34-8453
A common misconception is that touchscreens work based on heat from fingers. It's not heat that generates touchscreen functionality, instead, most screens work either on finger pressure applied or electrical field disruption. Basically, this means there are two main types of touchscreen technologies, Resistive and Capacitive.
Click here for more information about Resistive and Capacitive Touchscreens
34-874
A common misconception is that touchscreens work based on heat from fingers. It's not heat that generates touchscreen functionality, instead, most screens work either on finger pressure applied or electrical field disruption. Basically, this means there are two main types of touchscreen technologies, Resistive and Capacitive.
Click here for more information about Resistive and Capacitive Touchscreens
34-8743
A common misconception is that touchscreens work based on heat from fingers. It's not heat that generates touchscreen functionality, instead, most screens work either on finger pressure applied or electrical field disruption. Basically, this means there are two main types of touchscreen technologies, Resistive and Capacitive.
Click here for more information about Resistive and Capacitive Touchscreens
34-C232
34-C232-AP
34-C301
34-FGN1001
39-1310
39-FG1315/LY
44-3745
A common misconception is that touchscreens work based on heat from fingers. It's not heat that generates touchscreen functionality, instead, most screens work either on finger pressure applied or electrical field disruption. Basically, this means there are two main types of touchscreen technologies, Resistive and Capacitive.
Click here for more information about Resistive and Capacitive Touchscreens
47-L171B
ABK
A: Methanol
B: Acetone
K: Sodium Hydroxide 40%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
50-AS25GC
52-3670
AKL
A: Methanol
K: Sodium Hydroxide 40%
L: Sulfuric Acid 96%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
56-425
56-426
56-633
AKL
A: Methanol
K: Sodium Hydroxide 40%
L: Sulfuric Acid 96%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
56-635
AKL
A: Methanol
K: Sodium Hydroxide 40%
L: Sulfuric Acid 96%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
56-AS319
56-AS323
58-8655
AJKL
A: Methanol
J: Heptane
K: Sodium Hydroxide 40%
L: Sulfuric Acid 96%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
58-8655AP
58-8656
AJKL
A: Methanol
J: Heptane
K: Sodium Hydroxide 40%
L: Sulfuric Acid 96%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
58-8658DL
AJK
A: Methanol
J: Heptane
K: Sodium Hydroxide 40%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
62-322PF
63-225PF
63-331PF
64-V3000PF
67-246
JKTP
J: Heptane
K: Sodium Hydroxide 40%
T: Formaldehyde 37%
P: Hydrogen Peroxide 30%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
ESD is an acronym for electrostatic discharge. This discharge is the rapid transfer of static between two different objects. Although ESD doesn’t typically cause harm to the human body - you might only experience it as a small, surprising shock - it can cause extensive damage to electrical equipment and sensitive instruments. This damage may either be permanent, causing the device to malfunction (known as a catastrophic failure), or it may occur on a smaller scale that would be difficult to detect before the device is sent out for service (known as latent defect).
Test Method: ASTM D6978-05
In accordance with ASTM D6978-05, Personal Protective Equipment can be tested to ensure an effective barrier against Fentanyl. The ASTM D6978-05 Standard Practice for Assessment of Medical Gloves to Permeation by Chemotherapy Drug tests a breakthrough time of typically 240 minutes to determine if the PPE provides an effective barrier.
A common misconception is that touchscreens work based on heat from fingers. It's not heat that generates touchscreen functionality, instead, most screens work either on finger pressure applied or electrical field disruption. Basically, this means there are two main types of touchscreen technologies, Resistive and Capacitive.
Click here for more information about Resistive and Capacitive Touchscreens
67-256
JKTP
J: Heptane
K: Sodium Hydroxide 40%
T: Formaldehyde 37%
P: Hydrogen Peroxide 30%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
ESD is an acronym for electrostatic discharge. This discharge is the rapid transfer of static between two different objects. Although ESD doesn’t typically cause harm to the human body - you might only experience it as a small, surprising shock - it can cause extensive damage to electrical equipment and sensitive instruments. This damage may either be permanent, causing the device to malfunction (known as a catastrophic failure), or it may occur on a smaller scale that would be difficult to detect before the device is sent out for service (known as latent defect).
A common misconception is that touchscreens work based on heat from fingers. It's not heat that generates touchscreen functionality, instead, most screens work either on finger pressure applied or electrical field disruption. Basically, this means there are two main types of touchscreen technologies, Resistive and Capacitive.
Click here for more information about Resistive and Capacitive Touchscreens
67-308
JKTP
J: Heptane
K: Sodium Hydroxide 40%
T: Formaldehyde 37%
P: Hydrogen Peroxide 30%
To attain the EN 374 pictogram shield gloves must pass at least a Level 2 in three chemicals. The chemicals listed above are the chemicals that passed for this glove.
ESD is an acronym for electrostatic discharge. This discharge is the rapid transfer of static between two different objects. Although ESD doesn’t typically cause harm to the human body - you might only experience it as a small, surprising shock - it can cause extensive damage to electrical equipment and sensitive instruments. This damage may either be permanent, causing the device to malfunction (known as a catastrophic failure), or it may occur on a smaller scale that would be difficult to detect before the device is sent out for service (known as latent defect).
Test Method: ASTM D6978-05
In accordance with ASTM D6978-05, Personal Protective Equipment can be tested to ensure an effective barrier against Fentanyl. The ASTM D6978-05 Standard Practice for Assessment of Medical Gloves to Permeation by Chemotherapy Drug tests a breakthrough time of typically 240 minutes to determine if the PPE provides an effective barrier.
A common misconception is that touchscreens work based on heat from fingers. It's not heat that generates touchscreen functionality, instead, most screens work either on finger pressure applied or electrical field disruption. Basically, this means there are two main types of touchscreen technologies, Resistive and Capacitive.
Click here for more information about Resistive and Capacitive Touchscreens
67-308
A common misconception is that touchscreens work based on heat from fingers. It's not heat that generates touchscreen functionality, instead, most screens work either on finger pressure applied or electrical field disruption. Basically, this means there are two main types of touchscreen technologies, Resistive and Capacitive.
Click here for more information about Resistive and Capacitive Touchscreens
68-116
68-116AP
705CGNF