Taber®Rotary Abraser 5135/5155 - Senze-Instruments

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Process & Quality Control

Taber®Rotary Abraser 5135/5155

Coatings & Industry > Mechanical properties > Abrasion & Washability

Taber Abrasers Model 5135 or 5155 offer the following standard features:

  •    Specimen turntable speed control options of both 60 rpm and 72 rpm.

  •    Easy-to-use operator interface that includes tactile feel buttons and a four line digital display.  Simple on-screen instructions allow the operator to change the test parameters via the MENU button.  An internal memory stores the settings.

  •    A vacuum system is included and is critical for the proper operation of the instrument.  The vacuum nozzle(s) is hinged to an adjustable mounting at the rear of the housing.  A precision vacuum nozzle adjustment control allows the height to be modified for accommodating varying specimen thickness.

  •    Precision stainless steel weights of 250 grams and 750 grams are furnished to provide standard wheel loads of 500 and 1000 grams.  Weights are marked to show total load on each wheel. This marking includes the weight of the abrading arm (250 grams).

  •  A Quick Release Mounting Hub permits quick wheel mounting without the need of a locking nut, increased clearance for the vacuum pick-up nozzle and a larger viewing area for the test specimen.  A beveled retaining nut provides a positive locking force on the wheel hub retaining lip making certain that the wheels remain securely fastened until disengaged.
  •  Assembled in a sturdy, sealed aluminum housing.
There are various techniques used to interpret results generated with the TABER Rotary Platform Abraser (Abrader).  The method of evaluation that you select should reflect the type of material that is being tested. If you are following a specification - the method for interpreting test results will be listed.

The most common methods of evaluating results from the Taber Abraser (Abrader) include:

Cycles to a Specific End-Point - The number of cycles required to reach a predetermined end point, or the appearance or condition of the specimen after a fixed number of cycles.  The evaluation criteria may include: loss in breaking strength, yarn breakage, loss in coating, change in gloss, color loss, or other changes in appearance.  In these cases, the abraded sample is usually compared to a known standard of the material tested.  When visually inspecting changes in specimen appearance, evaluations should be made using an agreed upon rating system such as a visual grading scale (e.g. five-step) or pass/fail criteria.
Weight (Mass) Loss - This technique measures how much material has been removed by abrasion, and is usually reported in milligrams.
     L = A - B
     where L = weight loss
         A = weight (mass) of specimen before abrasion
         B = weight (mass) of specimen after abrasion
When performing the weight loss method, loose particulate may adhere to specimens during testing.  It is critical that you clean off the test specimens as best as possible prior to weighing.
Taber Wear Index - Indicates rate of wear, and is calculated by measuring the loss in weight (in milligrams) per thousand cycles of abrasion. The lower the wear index, the better the abrasion resistance.
     I = [(A - B) * 1000] / C
     where I = wear index
           A = weight (mass) of specimen before abrasion
           B = weight (mass) of specimen after abrasion
           C = number of test cycles
Volume Loss - When comparing the wear resistance of materials that have different specific gravities, a correction for the specific gravity of each material should be applied to give a true measure of the comparative wear resistance.  Calculate the wear index as shown above, and divide the result by the material's specific gravity.  The use of this correction factor provides a wear index related to the loss in volume of the material to which it is applied.  When comparing materials of different specific gravities, test parameters must be the same including wheel selection and load.
Wear Cycles Per Mil (0.001 inch) - Used to express abrasion cycles required to wear through a coating of a known thickness.
     W = D / T
     Where W = Wear Cycles Per Mil
           D = number of cycles required to wear coating through to substrate
           T = coating thickness, mils
Depth of Wear - To determine the depth of wear, use a thickness gauge or other appropriate device to measure the specimen thickness on four points along the path to be abraded, approximately 38 mm from the center hole and 90° apart.  Calculate the average of the readings.  After subjecting the specimen to abrasion, repeat the measurements and average the readings.  Calculate the difference.  Alternatively, the depth of the wear can be measured with an instrument such as an Optical Micrometer.
Residual Breaking Force (textile fabrics) - This technique measures the effective strength of the fabric, or force required to break a specific width of fabric.  To determine the individual breaking force of the abraded specimen use the procedure described in the ASTM D5034 and D5035 Standard Test Method for Breaking Strength and Elongation of Textile Fabrics.  [Note, you must change the referenced distance between clamps to 25mm and horizontally place the path of abrasion on the abraded specimen midway between the clamps.]  Report the breaking load to the nearest 0.5kg.
Average Breaking Strength (textile fabrics) - Calculated by averaging the breaking strength of the abraded specimens and the unabraded specimens, as determined by the Residual Breaking Force.
Percentage Loss in Breaking Strength (textile fabrics) - To determine the breaking load of the original fabric and the abraded specimen, use the procedure noted above (ASTM D5034 and D5035).  Calculate the percentage loss in breaking strength to the nearest 1% for each lengthwise and widthwise directions.
     AR% = 100 * (X - Y) / X
     where AR% = abrasion resistance, %
              X = breaking force before abrasion, g (lb)
              Y = breaking force after abrasion, g (lb)
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