IMPORTANT: Due to the type & quantity of abrasive media that is used during this testing, Taber recommends that you frequently inspect the vacuum filter and collection bag and replace when necessary.

Features

• Easy-fill funnel hopper provides grit storage capacity of 2.65 kg
• Hopper assembly pivots allowing operator easy access to view or mount specimen
• Redesigned base and support for increased stability
• USB interface
• Replaceable grit distributor nozzle
• Curved front orifice vacuum nozzle rotates for specimen access
• Right or left hand side set-up

Abradants

The standardized abradant supplied with Taber’s Grit Feeder is a #240 aluminum oxide grit particle (Model S-41).  Produced specifically for Taber Industries, this aluminum oxide has tighter controls for both particle size analysis and bulk density properties compared to “off-the shelf” aluminum oxide.  To calibrate the rate of flow and to measure the abrasive rate of the abradant, S-38 Standardization Plates are utilized.

Prior to use, the abrasive grit should be screened through U.S. Standard Sieve No. 80 to break up any conglomerates and to remove any oversized or foreign particulate matter.  Afterwards, dry the grit for 1 hour at approximately 82° C (180° F).  Allow to cool in a temperature and humidity controlled room prior to use.

To satisfy test method EN 14354 and ISO 24338 Method B, Alodur ESK 240 aluminum oxide grit should be used.  Contact Taber Industries for additional information.

Evaluation

The following are commonly used methods for reporting Grit Feeder test results:

Weight (Mass) Loss – The weight loss test method is a quantifiable method that records the weight loss of your test specimen due to abrasion.  This method of evaluating test results is recommended when the results are to be compared with those of similar materials having nearly the same specific gravity.  Weigh your test specimen before and after testing to obtain the initial and final weight values.  The difference between these two values, F_total, is the weight loss.

      F_total = A – B

where  A = weight (mass) of specimen before abrasion, mg

                B = weight (mass) of specimen after abrasion, mg

Use the following formula to calculate average mass loss, F_m, in milligrams (mg) per 100 cycles:

      F_m = (F_total / n) x 100

where  n = total number of revolutions

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 may also be used to present weight loss data.  This measurement is the loss in weight in milligrams per thousand cycles of abrasion.  The lower the wear index, the better the abrasion resistance quality of the material.

      Taber Wear Index = (F_total x 1000) / n

Cycles to a Specific End Point – The number of cycles required to reach a predetermined end point (e.g. wear through to the substrate).  Alternatively, this could be reported as the condition of the specimen after subjecting it to a specified number of cycles.

According to test method EN 14254 (Wood based panels – Wood veneer floor covering Annex D Test method to determine the wear resistance), wear generated with the Taber Grit Feeder is evaluated using a transparent template with each quadrant divided into four sectors of 22.5°.  The transparent template is placed on the test piece to determine if there is continuous wear in 12 sectors out of 16; and continuous wear through in 1 sector per quadrant.  If there is not sufficient contrast between the substrate and coating, a contrast marking solution may be used (e.g. water based solution of 1% Methylene or Alkali blue).

Volume Loss Method – In comparing the wear resistance of materials having different specific gravities, a correction for the specific gravity(s) of each material should be applied to the weight loss to give a true measure of the comparative wear resistance.  The use of this correction factor gives a wear index related to the loss in volume of the material to which it is applied.

Determine the specific gravity of the material to be tested in accordance with standard practice.  If the specimen is not homogeneous, but possesses a surface that differs from the body or core, determine the specific gravity of the surface alone.  If abrasion is to be carried beyond the surface of the body, also determine the specific gravity of the latter and calculate and report the abrasion resistance of the two components separately.

      Volume Loss, cm³ = (W₁ – W₂) / S

where  W₁ – weight of specimen before abrasion, g

                W₂ = weight of specimen after abrasion, g

                S = specific gravity

Depth of Wear Method (Thickness) – Certain test requirements may call for measuring the depth of wear.  To determine this, mark four points on the back of an unabraded sample, 90° apart and oriented 11/2″ (38 mm) from the center hole [this will be within the wear path].  Using a thickness gage or micrometer, measure the specimen thickness.  After abrading the sample, repeat the measurements and record the difference.  To compensate for depth differences around the specimen wear path, an average should be computed from the four readings.

Change in thickness can also be measured using an Optical Micrometer or similar instrument.  Place the measuring device so that it spans both the abraded and unabraded portion of the specimen.  Calculate the amount of wear by measuring the difference between the abraded and unabraded areas in four equadistant points around the specimen, and average the results.

Alternatively, the average loss in thickness can be calculated by dividing the loss in volume by the abraded area of the specimen.