DE8118255U1 - "Sand testing device" - Google Patents

Description

GEORG FISCHER AKTIENGESELLSCHAFT , 8201 Schaffhausen

2170 / GAP / April 22, 1981 / Li-bs /

Sand tester

The invention relates to a sand testing device according to the preamble of claim 1.

Sand testing devices are known, such as the strength testing device Type PFG from GEORG FISCHER AG (prospectus GM 711-26.1 / 1) with a test body between a stationary and a movable jaw. The movable jaw is then made using a rotating spindle driven or loaded in the direction of the other jaws. In the power transmission chain there is a Built-in pressure gauge, the measured value of which is transferred to a manometer. The pressure at the moment of the break of the test specimen is measured must be read off as the specific compressive strength.

Another device is used to determine the flexural strength, with a standard rod made of compacted sand on two cutting edges and is loaded by means of a third cutting edge from the other side between the two supporting cutting edges. Here, too, the pressure at break is measured and the specific flexural strength read off.

The compressibility of the sand has so far been measured using another device (+ GF + brochure no. GM 711-20 / 1), whereby a cylindrical sand bed is compressed by a piston under a certain force and thereby compacted where the reduction in height at a certain force is a measure of the compressibility.

All of these devices have the disadvantage that they can only ever be used for one type of test, and even only each deliver one measured value.

The invention has the task of eliminating this disadvantage and proposing a device with which several tests of various types can be carried out, with device components that are used in several tests only be carried out once, which also results in cost savings. The device should also make reading easier of the measured values.

According to the invention, this object is achieved by a sand testing device of the type mentioned at the outset, which also has the features listed in the characterizing part of claim 1.

The features according to the invention enable the test the compressive strength and flexural strength as well as the compressibility of test specimens made of foundry sand or sand fillings with a test device, whereby the respective test type can be set by switching the circuits and the measurement results are easy to determine.

Further advantageous refinements of the invention are characterized in the dependent claims.

The invention is explained in more detail below with reference to the drawing.

Show it:

Fig. 1 schematically the action unit of the test device

to 3 for three different types of exams, and 5

4 shows the evaluation device in a block diagram.

In Fig. 1, ^{a pressure vessel 1 with double-acting cylinder 1 * is shown schematically in a housing 4 resting by means of columns 4 11} on a base plate 4 ', into which compressed air can be introduced from a compressor, not shown, by opening valve V1 . A valve V2 is used to discharge the compressed air. A manometer 2, which always shows the current pressure in the vessel 1, is also connected to the vessel 1.

A sliding piston 5 with a piston rod 3 protrudes from below into the vessel 1, which with a force which is equal to the pressure in the vessel 1 multiplied by the

Cross section of the piston 5 downwards

is pressed. The pressure cylinder is designed as a double-acting cylinder, with the two valves Vl and V2 in the downward and upward movement of the piston 5 in each case opposite Have functions. In this way, when driving downwards, compressed air is passed through the valve Vl into the upper Cylinder part let in, while the one from the lower cylinder part escapes through valve V2, and when driving upwards vice versa. The piston rod 3 simultaneously forms the pressure tool 3.

An inlet valve and an outlet valve could just as well be provided in the upper and lower cylinder parts. The speed and the force of the piston is determined by the flow properties of the valves and the time The pressure build-up in the vessel is determined.

If the piston encounters resistance, the movement is delayed or stopped, and so is the pressure in the vessel increases faster until the resistance is overcome when a certain pressure value is reached, which is reflected in a sudden relaxation of the pressure in the vessel 1 and the maximum extension of the piston makes noticeable. This jolt is registered in an evaluation device and processed together with other data.

In the case shown in FIG. 1, the pressure tool has a cylindrical disk 6 on its underside, whose diameter corresponds to that of a likewise cylindrical sand specimen 7, which is in a shell 8 below the piston is arranged centrally. By opening the valve V1, the sand sample 7 is placed between the disk and the bottom of the tray 8 is pressurized, the pressure being increased slowly and steadily until the specimen is crushed. In order to collect the sand that is produced in the process, the test specimen 7 is placed in the shell arranged.

The same device is shown in FIG. 2, parts which fulfill the same function as in FIG. 1 being omitted became. In contrast to the compressive strength, the flexural strength is tested here, with a rod-shaped Test specimen 11 rests on two bearing cutting edges 12 and 13 and between them from above through a test cutting edge 14 is charged. Since the deflection of the rod 14 is rather negligible, it is the same as in the compressive strength test only the pressure at which the rod breaks is interesting.

FIG. 3 shows an arrangement for testing compressibility, with a bed of sand 22 in a cylindrical vessel 21 without Pre-compression was introduced, which then by the pressure tool 3 or by the disk arranged thereon

is compressed during the downward movement of the piston. Of the
Piston travel until it comes to a standstill at a certain pressure is proportional to the decrease in volume of the bed and therefore a measure of the compressibility.
5

To set a specific final pressure, a pressure control valve V3 is opened instead of the valve Vl of FIG. For this purpose, the valve V3 is switched in parallel to the valve V1, with the first two test methods
the valve Vl and for the compressibility test the
Valve V3 is opened.

4 shows a basic circuit diagram of the evaluation device, the input variables coming from a pressure measuring device and a displacement measuring device, the quartz crystal 31 and the inductive displacement meter 32
are pressed together according to one of Figs. 1 to 3,
the pressurized quartz passing a piezoelectric voltage through a cable 35 to the evaluation device
directs.

The path measurement in the induction meter is also carried out
in a known manner, a ferromagnetic armature 34 connected to the piston rod 3 being pushed more or less far into the induction coil 33 when the piston rod 3 moves, so that a value for the exact position of the piston can be obtained by measuring the induction or the impedance of the coil is obtained.

In the course of a test, one of the two or both measured values runs through a certain range, for example

ft · · · ■

wise from zero to a certain maximum value and jumps to this, for example if the test specimen breaks in the case of pressure measurement back to a lower value, the maximum value of interest for the evaluation for example in a "sample-and-hold circuit" or a maximum value memory 47 is stored. The distance measurement in the compressibility test does not need to be Storage, since the piston comes to a standstill when the measured value is reached and remains there until the pressure is reached is relaxed.

In a bending test in which the deflection is also measured, the position of the Piston should be measured at the moment of breakage, a differentiation of the travel signal would be conceivable, whereby the The impulse resulting from the discontinuity of the current measured value could trigger the storage of the measured value.

However, this measuring method is unimportant for sand tests, since one is dealing with rigid and brittle test specimens that bend only insignificantly before breaking.

The measured values from the converters 31 and 32 are processed by means of amplifiers 37 and 38 and in operational stages 39, 40 and 40 'according to the specified mathematical Formulas transformed in order to convert the pressure or displacement values into absolute values for strength or compressibility Obtained, with the operational stage 40 the compressive strength, the stage 40 'the flexural strength and the stage 39 the Calibration of the path signal results.

The formulas contain the geometric values of the test geometry and the test specimens, either fixed or adjustable. 35

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In order to be able to display or print out the measured values for displacement, pressure or strength, the signals from the amplifiers and operational stages prepared by means of analog-to-digital converters 41 to 44 and a 7-segment display and a printer 46, one of the test types being preselected by a selector switch S can.

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Summary

A sand tester combines several test methods in one device and thus saves components when using them of individual devices must be available several times. For testing the compressive strength and flexural strength as well as compressibility pressure is exerted on a test specimen (7, 11) or on a bed of sand (22), in the case of of the two strength tests, the pressure or the force at the moment of breakage and in the compressibility measurement the compression path measured at a certain pressure will. In an evaluation device (37 - 44) the measured values, which are obtained from a quartz crystal (31) of the piston rod (3) and the odometer (32), which consists of an induction coil (33) with a movable armature (34) and processed further by means of fixed circuits. This is displayed by preselecting the desired type of measurement and / or printed out.

Figs. 1 and 4

Claims (4)

PATENTANWÄLTE DIETRICH LEWINSKY HEINZOOACHIM HÜBER REINER PRIETSCH MÖNCHEN 11 GOTTHARDSTRs «1 G 81 18 255.4 15.9.1981 Georg Fischer AG 13,626 protection claims 2170 / GAP 1. Sand tester for testing foundry sand or test specimens made from foundry sand (7, 11) with a pressure application device (1) a pressure tool (3) by means of which the Pressure can be applied to the sand (22) or test specimen and at least one pressure measuring device (2), characterized in that the pressure tool (3) is a double-acting compressed air cylinder (I ') has guided piston (5) and each with a displacement measuring device generating electrical signals (32) and pressure measuring device (31) is provided. 2. Sand testing device according to claim 1, characterized in that on the pressure application device (1) a pressure control valve (V3) is arranged. 3. Sand testing device according to one of claims 1 or 2, characterized in that the pressure measuring device is a quartz crystal (31) arranged in the printing tool (3). 4. Sand testing device according to one of claims 1 to 3, characterized in that the displacement measuring device is an inductive displacement transducer (32).