Test procedure (RST-XS)

RST Banner

Procedure of a flowability test (yield locus test)

On this page a short overview is given on the activities during a measurement with the ring shear tester. This is done on the RST-XS ring shear tester, which is the predecessor of the current ring shear tester RST-XS.s . However, the procedure is very similar.

In the following the test procure of a yield locus test is shown. From a yield locus the flowability of a powder or bulk solid is determined. In addition, the yield limit provides information on internal friction and bulk density for the selected stress level. Beside the test procedure shown here, the time consolidation (caking) and the friction between a powder and a rigid wall (wall friction) can be measured.


Setup of Ring Shear Tester RST-XS

Ring shear tester RST-XS

The main part of the Ring Shear Tester is the shear cell (1), which contains the powder specimen. On the image above a standard shear cell with a specimen volume of 30 ml is placed on the tester.

The powder specimen is covered by a lid. The lid is subjected to a vertically acting force (normal force) in order to apply the stress level required for the test. For the adjustment of the normal force serves the computer-controlled normal load system (2).

For consolidating the powder specimen and for measuring its strength, respectively, the powder specimen is subjected to a shear deformation. For this the bottom ring of the shear cell is rotated while the lid is prevented from rotation. The latter is achieved by two tie rods, which are connected to the lid of the shear cell as well as to the load beams (3). The load beams serve for the measurement of the shear stress in the powder specimen.

Since both the bottom of the shear cell and the underside of the lid are rough or provided with vanes protruding into the powder (see image to the right), the rotational movement of the shear cell relative to the lid causes shear deformation of the powder specimen.

Shear cell XS-Mr

Preparation of the specimen

The Ring Shear Tester is connected to a PC. The PC controls the test with the software RST-CONTROL 95.

Entering test parameters

At the begin of a test the test parameters have to be entered. These contain information on the stress level for the test, the designation of the powder, and the number of the shear cell used.

The shear cell is filled with the powder. This can be easily done using a spoon.

Filling

Excess powder is scraped off with a spatula so that the powder surface is flush with the upper edge of the shear cell.

Scraping off excess powder


Placing the shear cell on the tester

The filled shear cell is weighed and then placed on the Ring Shear Tester. The mass of the filled shear cell is required by the control software for the calculation of the bulk density..

Placement of bottom ring on the tester

The lid is placed on the powder specimen,

Placement of lid on powder specimen

then the loading rod is inserted.

Insertion of loading rod

RST-CONTROL 95 tells the operator what to do next.
If desired speech output can be activated.

Guidance by the software

Attachment of the tie rods.

Placement of tie rods

Here the Ring Shear Tester is ready for testing. The automatic test procedure begins. At first the normal force acting vertically on the lid is increased to the selected value. Hereby the lid moves somewhat downwards according to the compressibility of the powder.

Ready for testing


Measurement

After the normal force has been adjusted, shearing starts. The bottom ring of the shear cell is rotated in the clockwise direction (seen from the top) while the lid is prevented from rotation by the two tie rods.

Measured values on screen

At shearing the shear stress increases with time (see blue curve in the diagram to the right), the height of the powder specimen decreases (consolidation of the powder, see red curve). The abscissa represents the time in the unit "second".

When the shear stress does not increase any further, RST-CONTROL 95 recognizes that the powder is sufficiently consolidated. The powder specimen is then unloaded from the shear stress.

After first preshear and shear to failure

In the next step the powder specimen is sheared again, but under a reduced normal load. Hereby the consolidated powder fails (incipient flow), which can be recognized by the maximum in the course of the shear stress (see diagram).

Subsequently the powder specimen is consolidated again, and again the shear strength is measured, whereby another normal load than before is applied. This cycle is repeated a few times (here: four measurements). From the measured data, especially from the shear stress maxima characterizing failure of the previously consolidated powder, the yield limit (yield locus) of the consolidated powder is determined

Close to the end of test

The test is finsihed.

End of test

The shear cell is removed from the tester and cleaned, the test data are saved.


Test results

After the test the result is presented as a yield limit (yield locus as defined by A.W. Jenike) of the powder. The table in the top part of the diagram shows the flow properties of the powder, which can be used depending on the particular application.

Yield locus

The most important quantity for quality control, comparative tests and product development is the flowability, ffc. Beside others, the compressive strength (unconfined yield strength), the bulk density and the internal friction are listed in the table.

The results can be presented and saved as numbers or diagrams, or exported to other applications (word processor, spread sheet).

The duration of this test was about 500 seconds for the automatic part. The time required for filling, weighing and setting up the shear cell prior to the test, and for removing and cleaning the shear cell after the test has to be added, so that about 15 minutes for a test are a realistic number. Thus an operator is required for only about 5 minutes per test, the rest of the test is performed computer-controlled.