DE810433C - Method and device for determining the mean deviation of a variable size from its mean value, in particular for determining the mean deviation of the substance cross-section of fiber strands, roving yarns and yarns - Google Patents

Description

(WiGBl. P. 175)

ISSUED AUGUST 9, 1951

Z 263 IXb / 42 d

Textile technology already knows a large number of mechanical and, more recently, also electrical ones Process (see Swiss patent 249 096) for measuring and registering the unevenness the substance cross-section of the slivers, rovings and yarns produced in the textile industry.

In the electrical measuring process, the substance cross-section causes the with constant speed Test specimen moved through the measuring system with the help of an electrical device an electrical one Value gained, the size of which is a measure of the substance cross-section of the test item. By Continuous graphical registration of this value gives an image of the cross-sectional fluctuations of the test item.

There are also devices that only display the cross-section of the test specimen at regular intervals determine individual points.

Numerous conclusions can be drawn from the character of the recorded diagrams, for example on the operation of a spinning machine with different mechanical settings or with different numbers of revolutions, then on the influence of doubling number and delay factor the unevenness of the textile product. These conclusions can be subjectively based on

distinctive periodic or aperiodic diagram progressions, from the absolute width, within it the diagram moves or, due to other things, when comparing the diagrams, it is more noticeable different Draw features.

However, there is very often the need, also the unevenness of two yarns, rovings or ribbons, the difference in unevenness of which may be small, with each other compare objectively. Furthermore, there is a need for standardization in textile metrology of mean unevenness to make the limits for good, mean, and to determine bad qualities. In such a case, assessment by the naked eye is sufficient mostly nothing more, objective evaluation methods have to be used. With help of a With a planimeter, it is possible to use known methods to determine the mean linear deviation from the diagram to be determined as a percentage. However, the evaluation of diagrams with the planimeter requires very time-consuming and conscientious work.

The mean linear deviation can also be calculated in a known manner by averaging can be determined from individual values, the individual values at regular intervals can be taken from the substance cross-section diagram.

Since the determination of the average value requires a great deal of addition work, it is computational In most cases, the method is even more time-consuming than the evaluation with the planimeter.

The disadvantages of these evaluation methods are eliminated by the present invention.

It relates to a method for determining the mean deviation of a variable value from its mean value and consists in the fact that of the variable quantity initially an equivalent electrical Size is obtained and the mean value of this electrical variable by means of an electrical frequency-dependent Siebes is separated from their deviations from the mean, whereupon the deviations rectified, averaged in a second frequency-dependent sieve and then in an electrical indicating instrument are displayed.

The present invention also relates to a device for carrying out the invention Method and is characterized by a device for obtaining an equivalent electrical Size from the variable size, through a frequency-dependent electrical sieve, which this equivalent electrical variable in their mean value and their deviations from the mean value separates, as well as through a rectifier for rectifying the time-variable electrical signals representing the deviations Size, also through a second frequency-dependent sieve to obtain the mean value of the rectified size and a display instrument to display this mean value.

An embodiment of the method according to the invention is based on FIGS. 1, 2 and 3, the one Represent device according to the invention, for example, explained.

Fig. Ι shows three diagrams that explain the principle of determining the mean deviation to serve;

Fig. 2 shows the block diagram of an embodiment of the device according to the invention;

Fig. 3 shows the complete circuit diagram of this device.

In FIG. 1, curve 1 in diagram A shows the value of an electrical measured variable χ as a function of time t. The curve runs from point 5 to point 6. The mean value χ of the electrical measured variable χ is represented by line 15. Above the center line 15, the areas 9, 11 and 13 delimited on the one hand by the curve i and on the other hand by the center line 15, and below the center line the corresponding areas 8, 10, 12 and 14 are formed.

The calculation of the mean linear deviation is based on the following commonly used calculation formula:

whereby

α = - I χ - χ dt,

x = ~ I χ dt.

(2)

i - X,

J = I

whereby

-IiS--

i = ι

In these formulas: α = mean linear deviation, T = duration of the evaluated measurement (corresponds to the length of the diagram strip), χ = electrical measured variable that is a function of time, χ = average value of the measured variable, dt = differential of time t.

The evaluation of a diagram according to this formula is mostly done by using a planimeter, namely in two operations: The area F determined by a first bypass 4-5 course of the measured variable -6-7-4, divided by the length T, gives the Average value ~ x of the measured variable x. This is shown as line 15 in the diagram. Then the sum f of the area contents of the horizontally and vertically hatched areas 8 to 14 is determined and the sum area f obtained in this way is divided by the total area F. This gives the mean linear deviation α to:

α (in percent) = - 100. (3)

The mean linear deviation can also take place through arithmetic processing of individual values. The formula for the linear deviation determined from individual values is:

. N

In these formulas: a = mean linear deviation, TV = number of measured values included in the calculation, *; = Instantaneous values of the electrical measured variable, measured at equal time intervals, χ = average value of the instantaneous values.

The mean square deviation is mostly determined by the computational processing of individual values. These can either be taken as individual measured values can be determined or from the continuous diagram at regular intervals be taken.

In FIG. 2, 30 denotes an electrical measuring apparatus which derives an equivalent electrical measured variable χ from a variable size of a test item, from which the mean value of the absolute values of the deviations (x - x) from the mean value χ is to be determined. The measured variable χ is applied to an electrical, frequency-dependent sieve 31. A first display device 32 is used to display the size which is produced at one output of the electrical frequency-dependent filter element 31 and is proportional to the mean value size χ. This measured variable χ is advantageously registered by a registering ammeter 33. The measured variable arising at the other output of the frequency-dependent electrical sieve 31 is (x - x) proportional and arrives at the rectifier 34, through which the measured variable {χ - χ), which has positive and negative values, is rectified. In the exemplary embodiment, this rectification takes place linearly; it could also take place as a square or according to an arbitrarily defined characteristic. At the output of the rectifier a quantity proportional to (x - x) "occurs, the η being dependent on the characteristics of the rectifier.

In Fig. Ι the diagram B shows the resulting after rectification at the rectifier 34 measured variable (x - x) as a function of time t . The curve 20 represents the deviations of the electrical measured variable χ from its mean value χ , and the curve sections higher than the center line 15 as well as the curve sections lower than the center line 15 now appear with the same sign. The rectified measured variable (x - x) is not displayed directly, but is sent to a second frequency-dependent sieve 35. This forms the mean value (x - x), since in practice a mean value of the absolute values of the deviations (x - #) over a certain period of time is more useful than the display of (x - x).

Diagram C in FIG. 1 shows the course of this mean value in curve 26, as it results at the output of filter 35 as a function of time t . The mean value of the deviations is displayed by the second display instrument 36 and can be registered by a second recording ammeter 37. The display instruments 36 and 37, which display and register the mean value 26 of the deviations, are advantageously calibrated in such a way that the mean deviation can be read off directly as a percentage. In Fig. 3, 30 denotes an electrical measuring apparatus which obtains an equivalent electrical measured variable χ from a variable size of a test item, whose

mean deviations from the mean value χ are to be determined.

The electrical measured variable, which may, for example, have the course of curve 1 in diagram A of FIG. 1, reaches an electrical frequency-dependent sieve 31 and 45. The series resistors 40, 42 and 44 can also be replaced by induction coils. The circuit acts as a low-pass filter, so that the relatively rapid fluctuations in size x (t) cannot reach the output terminals 52, 53. Practically only the mean value ~ x appears at these terminals. At the series resistors 40, 42 and 44, i.e. at the terminals 53 ', 54, on the other hand, there is only one changing variable corresponding to the deviations (x - x) of the measured variable χ from its mean value χ , since the mean value χ itself is the Capacitors 39 and 45 can not happen. The alternating voltage generated at the terminals 53 ', 54 thus has positive and negative instantaneous values, the positive instantaneous values corresponding to the positive instantaneous values and the negative instantaneous values corresponding to the negative deviations of the measured variable χ from its mean value χ. This alternating voltage corresponding to the deviations (x - x) of the measured variable χ reaches a rectifier 34. This consists, for example, of the rectifier elements 46, 47, 48 and 49, which are arranged according to the known Graetz circuit. At the output terminals 55, 56 of the rectifier 34 there is an (x - x) proportional voltage.

In order to obtain a mean value from these deviations (x − x) , a second frequency-dependent electrical screen 35 is used, which can consist of a resistor 50 and a capacitor 51, for example. A voltage then occurs across the capacitor 51 which corresponds to the mean value of the variable (x - ~ x) . This mean value (x - x) is displayed in the following display instrument 36. It can also be registered in a registering ammeter. An ammeter could also be used to display the root mean square value (rms value) (x - x ² ) V ₂ of the squares of fluctuation (x - x) ^2.

As already mentioned, the frequency-dependent electrical filter 31 is electrically dimensioned so that it only allows very slow fluctuations (for example fluctuations with a frequency ¹ J _n ^ per second) of the mean value χ of the measured variable χ at its output terminals 52, 53. In this case, the display instrument 32, which displays the mean value χ of the measured variable χ , has a practically constant display value x.

When using the device according to the invention with measuring devices that gain a measured variable χ corresponding to the substance cross-section of ribbons, rovings and yarns in the textile industry, it is advantageous to dimension the frequency-dependent electrical sieve 31 so that only fluctuations in the mean value χ are displayed that are one correspond to the tested test material length of at least 8 m.

The frequency-dependent electrical sieve 35, which derives the mean value (x - Ic) from the deviations (x - x) of the measured variable χ from its mean value *, is advantageously also dimensioned so that only fluctuations in the mean value 26 of the deviations are displayed which correspond to a test material length of at least m.

It is clear that for other areas of application

electrical sieves F ₁ and F _{2 must} expediently be dimensioned for other cutoff frequencies.

Claims (3)

PATENT CLAIMS: i. Procedure for determining the mean deviation of a variable size from its mean value, characterized in that from the variable Size an equivalent electrical variable is obtained for the time being and the mean value of this electrical quantity by means of an electrical frequency-dependent sieve of their deviations is separated from the mean, whereupon the deviations are rectified, in a second frequency-dependent Averaged sieve and then displayed in an electrical display instrument. 2. Device for performing the method according to claim 1, characterized by a device to obtain an equivalent electrical quantity from the variable quantity by a frequency-dependent electrical sieve that shows this equivalent electrical quantity in its mean value and their deviations from the mean value, as well as by a rectifier to rectify the Time-variable electrical quantity representing the deviations, furthermore by a second frequency-dependent one Sieve for obtaining the mean value of the rectified variable and, through a display instrument, for displaying this mean value. 3. The method according to claim 1, characterized in that the frequency-dependent sieves are low-pass filters be used. 4. The method according to claim 1, characterized in that that the linear mean value of the deviations of the measured variable is displayed. 5. The method according to claim 1, characterized in that that the root mean square value of the deviations of the measured variable is displayed will. 6. The method of claim i, wherein the variable The size of the substance cross-section of slivers, yarns or rovings is characterized by that the mean value of the substance cross-section is also displayed and that the time constant of the first frequency-dependent sieve is chosen so that at the test speed used only fluctuations in the mean value of the measured variable are displayed which correspond to a test material length of at least 8 m. 7. The method according to claim 1, wherein the variable size of the substance cross-section of slivers, Yarns or rovings is characterized in that the time constant of the second electrical Sieves is chosen so that only fluctuations in the test speed used Mean value of the deviations of the measured variable from its mean value are displayed, that of a test material length of at least 8 m. 8. Device according to claim 2, characterized in that a rectifier with a linear Characteristic is used to rectify both positive and negative deviations the electrical quantity of its mean value. 9. Device according to claim 2, characterized in that a rectifier with a square Characteristic is used to rectify both positive and negative deviations the electrical quantity of its mean value. 1 sheet of drawings 984 8.