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D232


Driver Gloves

  • Natural grain leather driver glove
  • Winged thumb and elasticized back
  • Elasticized back
  • Synthetic colored binding tape at the end of the cuff

Abrasion

Grip

Select Size

D232

D232

Size Chart

How to Measure

D232

D232

D232

D232
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EN 388:2016+A1:2018

Delivery & Services

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  • Product Features
  • Product Details
  • Tests
  • Reviews

ABOUT THE DESIGN

USEFUL IN THESE INDUSTRIES

CONSTRUCTION

IRON & STEEL

LOGISTICS

MANUFACTURING

  • Test Conducted:
  • • Resistance to abrasion: Based on the number of cycles required to abrade through the sample glove (abrasion by sandpaper under a stipulated pressure). The protection factor is then indicated on a scale from 1 to 4 depending on how many revolutions are required to make a hole in the material. The higher the number, the better the glove.
  • • The blade cut resistance: Based on the number of cycles required to cut through the sample at a constant speed. The protection factor is then indicated on a scale from 1 to 5.
  • • Tear resistance: Based on the amount of force required to tear the sample. The protection factor is then indicated on a scale from 1 to 4.
  • • Puncture resistances: Based on the amount of force required to pierce the sample with a standardly sized point. The protection factor is then indicated on a scale from 1 to 4.
  • • TDM blade cut resistant: The glove sample is placed on a conductive strip and loaded onto the TDM-100. When the metal blade touches the metal strip, the test is terminated. A straight blade is loaded into the machine. Weight is added to serve as the force. The blade moves across the fabric. The blade is replaced with a new one to ensure accuracy. The sample is cut five times, each with three different loads. The distance traveled to cause cut through at various forces is recorded. The data is used to determine the load required to cut through the sample.
  • Test Conducted:
  • • Resistance to abrasion: Based on the number of cycles required to abrade through the sample glove (abrasion by sandpaper under a stipulated pressure). The protection factor is then indicated on a scale from 1 to 4 depending on how many revolutions are required to make a hole in the material. The higher the number, the better the glove.
  • • The blade cut resistance: Based on the number of cycles required to cut through the sample at a constant speed. The protection factor is then indicated on a scale from 1 to 5.
  • • Tear resistance: Based on the amount of force required to tear the sample. The protection factor is then indicated on a scale from 1 to 4.
  • • Puncture resistances: Based on the amount of force required to pierce the sample with a standardly sized point. The protection factor is then indicated on a scale from 1 to 4.
  • • TDM blade cut resistant: The glove sample is placed on a conductive strip and loaded onto the TDM-100. When the metal blade touches the metal strip, the test is terminated. A straight blade is loaded into the machine. Weight is added to serve as the force. The blade moves across the fabric. The blade is replaced with a new one to ensure accuracy. The sample is cut five times, each with three different loads. The distance traveled to cause cut through at various forces is recorded. The data is used to determine the load required to cut through the sample.
  • Product Features

    ABOUT THE DESIGN

    USEFUL IN THESE INDUSTRIES

    CONSTRUCTION

    IRON & STEEL

    LOGISTICS

    MANUFACTURING

    Product Details

  • Test Conducted:
  • • Resistance to abrasion: Based on the number of cycles required to abrade through the sample glove (abrasion by sandpaper under a stipulated pressure). The protection factor is then indicated on a scale from 1 to 4 depending on how many revolutions are required to make a hole in the material. The higher the number, the better the glove.
  • • The blade cut resistance: Based on the number of cycles required to cut through the sample at a constant speed. The protection factor is then indicated on a scale from 1 to 5.
  • • Tear resistance: Based on the amount of force required to tear the sample. The protection factor is then indicated on a scale from 1 to 4.
  • • Puncture resistances: Based on the amount of force required to pierce the sample with a standardly sized point. The protection factor is then indicated on a scale from 1 to 4.
  • • TDM blade cut resistant: The glove sample is placed on a conductive strip and loaded onto the TDM-100. When the metal blade touches the metal strip, the test is terminated. A straight blade is loaded into the machine. Weight is added to serve as the force. The blade moves across the fabric. The blade is replaced with a new one to ensure accuracy. The sample is cut five times, each with three different loads. The distance traveled to cause cut through at various forces is recorded. The data is used to determine the load required to cut through the sample.
  • Tests

  • Test Conducted:
  • • Resistance to abrasion: Based on the number of cycles required to abrade through the sample glove (abrasion by sandpaper under a stipulated pressure). The protection factor is then indicated on a scale from 1 to 4 depending on how many revolutions are required to make a hole in the material. The higher the number, the better the glove.
  • • The blade cut resistance: Based on the number of cycles required to cut through the sample at a constant speed. The protection factor is then indicated on a scale from 1 to 5.
  • • Tear resistance: Based on the amount of force required to tear the sample. The protection factor is then indicated on a scale from 1 to 4.
  • • Puncture resistances: Based on the amount of force required to pierce the sample with a standardly sized point. The protection factor is then indicated on a scale from 1 to 4.
  • • TDM blade cut resistant: The glove sample is placed on a conductive strip and loaded onto the TDM-100. When the metal blade touches the metal strip, the test is terminated. A straight blade is loaded into the machine. Weight is added to serve as the force. The blade moves across the fabric. The blade is replaced with a new one to ensure accuracy. The sample is cut five times, each with three different loads. The distance traveled to cause cut through at various forces is recorded. The data is used to determine the load required to cut through the sample.
  • Reviews

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