GB2060889A - Process and apparatus for measuring anisotropy value of form changes in normal direction in sheet metals - Google Patents

Abstract

In course of a standard tensile test when a preselected value of change of dimension in longitudinal direction which is characteristic of the material of a reference specimen, is reached during the measuring process, the corresponding changes of dimension in the lateral direction are calculated for preselected anisotropy values (r values). Thereafter, an r-value is selected from the preselected r-values which is closest to the one corresponding to the lateral dimension change measured for a test specimen subjected to the preselected longitudinal dimensional change. The apparatus comprises comparator and switching units (7, 8) which are connected to signal transmitters (2, 3) converting changes of dimension in longitudinal, lateral directions respectively into electric signals. <IMAGE>

Description

SPECIFICATION Process and apparatus for the measurement of the anisotropy value of form changes in normal direction in sheet metals The invention .concerns a process for the measurement of the an isotropy value of form changes in the normal direction of sheet metals. The invention also relates to an apparatus suitable for carrying out the process.

The technology of cold forming is widely used in various sections of industry. There is a plurality of known methods (e.g. technological and tensile tests) for the evaluation of the cold-forming properties. In the course of technological tests, the suitability for a particular forming operation can be ascertained.

The recognition that there is a good interrelation between the quotient of the change of dimensions in longitudinal and lateral direction measurable by tensile test was an important step forward. This is the so-called anisotropy in normal direction, i.e. the rvalue and the result of the deep draw test (cupping) (Lankford, W.T 8 Associates: Trans. ASM 1950.42, page 1197 and Whiteley R.L. 8 Associates, Sheet Metal Industries 1961.5 pages 349-353).

The rvalue can also be used for the determination of the direction of ear formation or earing. The rvalue characterises the anisotropy of planar form changes of sheet metals because of the relationship: rO r90.

i\r r45 2 If the value of Ar is positive, the direction of ear formation or earing is inclined to the direction of rolling of the sheet by an angle of 90 ; if it is negative, then this angle is 45h (The indices of r in the formula of interrelation mean the angles between the longitudinal direction of test pieces used for the determination of the value of r, and the direction of rolling).

Since, up to the present, there is no other known characteristic that shows such a good interrelationship of the deep-drawing property of sheet metals, this index number has a particular importance in the sorting of sheet metals produced for deep-drawing purposes.

The known processes for measuring the r value can be generally divided into two main groups. In the processes belonging to one of such groups accurate lines are formed in longitudinal and lateral directions on the surface of the test specimens, e.g. by Vickerpyramids or by photographic methods. Thereafter, the test specimen is stretched by a tensile testing machine to a defined extent and after accurately determining (generally by a highly accurate measuring microscope) the changed length of the measuring lines the r value is obtained by calculation or by nomograms (e.g. Keeler S.P.Machinery 1968.4, pages 94/103).

These processes are labour-intensive and unsuitable for measurements carried out in series. Their only advantage is that very little instrumentation is required.

In the processes of the other main group of methods, the longitudinal or lateral form changes of the test piece are continuously registered by electronic tensilometers of high accuracy. The rvalue is determined either by a suitable programmed digital computer (e.g.

Roell-Korthaus Electronic Computer, Sheet Metal Industries 5, pages 450/451), or by a recording co-ordinatograph (e.g. see Hungarian Patent No. 1 63,808).

These latter measuring processes eliminate the main drawbacks of the method of the former group. However, their general use is restricted because they require expensive computers or co-ordinatographs and specially trained skilled labour. They are useful therefore primarily in research work, but not the requirements of the material testing in production and application of sheet metals.

The present invention attempts to provide a process for the determination of the 'value on a standard tensile test specimen and simultaneously determining the usual material characteristics without disturbing the characteristic.

The present invention is based on the recognition that as a constantly longitudinal uniform stretching of sheet metal, the rvalue is the function of solely the lateral change of the dimension. This is clearly shown in the relationship given below. This relationship is obtained by identical transformations of the relative changes of the dimensions contained in the original definition of rvalue, into absolute changes of dimension respectively by the application of the theorem of the constancy of volume: the lateral change of dimension is expressed by relating it to the longitudinal change of dimension:

wherein a0 and b0 are the initial values of the signalled distance in the longitudinal and lateral directions respectively.

In carrying out the measuring process according to the invention a stage is arrived at which point the preselected change of dimension on the standard specimen and the value of the longitudinal change of dimension on the test specimen is reached. The change of dimension in lateral direction is measured and from the values of anisotrophy in normal direction corresponding to the changes in dimension in lateral direction the nearest value of an isotropy in normal direction related to the measured lateral dimensional form change is determined.

The apparatus for carrying out the measuring process according to the invention is connected to signal transmitte.s placed on the standard tensile test piece which convert the longitudinal and lateral dimensional changes of the test piece into electric signals. The signal transmitter is connected to a switching and comparator unit, which compares the changes in dimension in longitudinal direction with corresponding reference signals and if they are either identical with a preselected reference signal or show a difference between them, generate an input signal activating the switching unit. This switching and comparator unit is connected to another switching unit.

The output signal of the signal transmitter is coupled to a comparator unit which compares the output signals with reference signals corresponding to anisotropy values appertaining to individual discrete form changes in the normal direction and the output side of this switching unit connected in series with a decoding unit and with an indicator unit. The suitably stabilised direct voltage required for the individual units of the apparatus is provided by supply units from the mains or from a battery.

The handling of the apparatus is simple and does not require special expertise. The rvalue is numerically indicated by the apparatus. The determination of the rvalue does not extend the time required for carrying out a standard tensile test. Pricewise, the apparatus may also have cost advantages for laboratories attached to production lines.

The present invention will be further described by way of example only with reference to a preferred embodiment which is illustrated by the accompanying drawings, in which: Figure 1 illustrates the apparatus according to the invention with a signal transmitter placed on the tensile test specimen, and Figure 2 is a block diagram of the apparatus according to the invention, connected to signal transmitters.

The measurement of the anisotropy i.e. the rvalue of the form change in normal direction in sheet metals is carried out simultaneously with the standard tensile test, without disturbing it. The signal transmitter 2 converting longitudinal changes in dimension into an electric signal and the signal transmitter 3 converting lateral changes in dimension into an electric signal are placed on the standard tensile test specimen 1. Signal transmitters 2 and 3 are commercially obtainable e.g. the make of Hewlett-Packard, type DCDT can be individually built signal transmitters measuring displacements and supplying electric signals proportional to the displacements and have a size which permits their fastening to the standard tensile test specimen 1 by means of a suitable gripping attachment.The signal transmitters 2 and 3 are connected to an apparatus 4 according to the invention comprising amplifiers 5 and 6 connected to the signal transmitters 2 and 3. The amplifiers 5 and 6 are one or multistage linear amplifiers containing transistors or integrated circuits, the amplification of which can be varied between wide limits according to the type of signal transmitter used. The input signal is amplified to the required level with a torsion coefficient of less than 0.5%. The amplifier 5 is connected to the comparator and switching unit 7. The unit 7, using semiconductors, generates temperature stabilised direct potential reference signals corresponding to longitudinal changes of dimension. The characteristics of the material being tested are preselectable in advance, for example by means of a push button switch.

When the difference between the output signal of amplifier 5 and the selected reference signal is zero, or has a certain defined value by the circuitry, the temperature stabilised trigger circuit with cut off biasing threshold potential transfers an interlock signal to the switching unit 9 and to the decoding unit 10.

The trigger circuit generally consists of transistors or integrated circuits (e.g. Schmitt-trigger, comparator etc.) Thus the apparatus does not register further changes of dimension on the test piece 1 once cut off has occurred. The signal transmitter 3 is connected via amplifier 6, to the comparator unit 8. In comparator unit 8, reference signals are generated, for example using a presettable press button, proportional to changes of dimension in the lateral direction belonging to the individual discrete rvalues according to the change of dimension in longitudinal direction. These reference signals are compared in the comparator unit 8 via amplifier 6, with the electric signals coming from the signal transmitter 3.

A reference signal corresponding to the signal coming from the signal transmitter 3 on the output side of the comparator unit 8.

The switching unit 9 comprises temperature stabilised trigger circuits with cut off biasing direct potential, having transistors or integrated circuits. One trigger circuit belongs to each discrete rvalue, thus only one circuit will trigger during the course of the measurement up to the appearance of the interlocking signal supplied by the unit 7, corresponding to the preselected longitudinal change of dimension.

The comparator unit 8 supplies the direct voltage which is necessary for the trigger. Due to the effect of the interlock signal, the measuring apparatus will not register further dimensional changes and will fix the value of r.

The expression of the value of r in decimal numerical system is provided by the decoding unit 10 connected to the switching unit 9, comprising suitable gate circuits and SCO decimal decoders. The decoding unit 10 is connected to the indicator unit 11. The indi cation can be digital or analogue. In view of the design of the circuitry, digital indication is preferred which also ensures more accurate readings of values. The required stabilised direct potential for the individual units is supplied by the supply units 1 2 and 13, which can operate from mains or battery, or expediently by application of integrated circuits.

The apparatus according to the invention indicates the rvalues with an absolute accuracy of 0.85%. It is advantageous if the r values are determined without using a recording co-ordinatorgraph or a computer.

Claims (4)

1. A method of determining the anisotropy value of the normal direction, of sheet metals during tensile testing which method comprises measuring the change in dimension in the longitudinal direction for a reference specimen and calculating the corresponding lateral changes in dimension for preselected anisotropy values, measuring the change in lateral dimension in a test specimen for the same predetermined change in dimension in the longitudinal direction as for the reference specimen, and determining the nearest anisotropy value for the test specimen from the measured lateral dimension.

2. Apparatus for determining the anisotropy value changes in the normal direction in sheet metals, which apparatus comprises a signal transmitter to determine and convert longitudinal changes in dimension into electric signals, a signal comparator to accept one or more predetermined reference signals corresponding to predetermined anisotropy values and compare them with signals from the signal transmitter, a switching unit operable by the signal from the signal transmitter, identical with or showing a known difference from one of the predetermined reference signals to pass a signal to a display unit to show the appropriate an isotropy value corresponding to the anisotropy value of the predetermined reference signal which operates the switching unit.

3. A method as claimed in claim 1 substantially as hereinbefore described with particular reference to the accompanying drawings.

4. Apparatus as claimed in claim 2 substantially as hereinbefore described with particular reference to the accompanying drawings.