CH679888A5 - - Google Patents

Description

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CH 679 888 A5

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description

The invention relates to a method for measuring the material hardness of a test specimen according to the preamble of claim 1 and a device for carrying out the method according to the preamble of claim 6. Such methods and devices are used in particular in the textile industry for simple and quick manual measurement Measure the winding hardness of warping and warp beams, spools of thread or fabric wraps. The measuring principle used in these devices is based on the fact that the indenter in the form of a ball or a tip is pressed into the winding by means of degressive spring force until the inner winding forces of the spring force keep the balance. The equilibrium force corresponding to a certain penetration depth is measured and displayed as a measure of the winding hardness.

Devices of a comparable type are already known in which the measuring device has a microprocessor, and the measured value determined via a position transmitter can be displayed directly digitally. Practice has now shown that a single measurement on the test specimen results in inaccurate values due to various influencing factors and that it is therefore necessary to carry out a series of measurements of at least two individual measurements on the test specimen, preferably at different points on the test specimen. An average value can then be formed from the different values of the individual measurements, which is more precise than the values of the individual measurements.

With the devices known to date, such a series of measurements could only be carried out in such a way that the values of the individual measurements were recorded and that the mean value was then calculated separately. However, reading and noting down the individual values already contains a source of error and also represents a considerable amount of work. It is therefore an object of the invention to provide a method of the type mentioned at the outset, with the aid of which accurate mean values from a series of errors can be made without any significant additional time Individual measurements can be read. This object is achieved with a method which has the features in claim 1. In terms of the device, the object is achieved by a device having the features in claim 6.

The method and the associated device allow individual measurements to be carried out quickly on a test specimen in succession, the ultimately desired mean value being displayed immediately. The measured value memory eliminates the need for intermediate results to be recorded in writing, and the counter reliably ensures that the mean value is always determined from the correct number of measurements. Finally, the operational safety of the device is also increased by the fact that only the mean value that has already been calculated is visible on the display device. This prevents a measured individual value from being inadvertently regarded as the end result of an entire measurement series.

Further advantages can be achieved if the maximum possible number of individual measurements per measurement series is limited by the counter. Depending on the application, the measuring device on the meter can be set to a certain number of individual measurements, which allows an optimal average to be expected. A further measurement exceeding this predetermined number remains without influence and is no longer registered. Before starting a new series of measurements, the counter must be reset to zero or the measured value memory must be deleted.

The ease of use can be increased if a tone generator is activated for each individual measurement and if the tone generator generates a tone when the last possible single measurement is reached that differs in tone and / or duration from the tone that is generated in the previous individual measurements. The tone generated after each individual measurement signals to the operator that the individual measurement has ended and that the corresponding measured value has been processed in the computer. At the last possible measurement determined by the counter, another signal sounds, which indicates to the operator that the measurement series has ended and that the mean value can now be read off.

The end of a measurement series can also be signaled optically by the measurement values being displayed digitally and by the display having at least one element which, when the last possible individual measurement is reached, differs optically from the display of the previous individual measurements. The digital display can e.g. be provided with an interrupter which can switch off the whole display or e.g. flashes even a decimal point as long as the displayed mean values are not yet binding. The digital display only appears permanently when the last individual measurement is reached, thus signaling the binding end result. Of course, the measured values do not necessarily have to be displayed digitally. An analog display would also be conceivable, e.g. the end of a measurement series could be indicated by a light emitting diode or the like.

The implementation of the method and the handling of the device is facilitated if the measuring device is activated via a switch and if the last measured value is displayed on the display device regardless of the measuring position as long as the switch is switched on. In this way, the device can be easily removed from the test object in order to read the measured value. On the other hand, switching off the switch causes the stored measured values in the measured value memory and the display on the display device to be deleted.

The single figure shows an embodiment of the invention in a greatly simplified and schematic representation. The measuring device 1 has a schematically represented, preferably

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drisches housing 4, which can be held comfortably with one hand. In the housing 4, a spindle 5 is linearly displaceable. At the end of the spindle an indenter 3 is attached, which is spherical, but which also has a different shape, e.g. could have a spike. The indenter 3 or the entire spindle 5 is under the pretension of the compression spring 6, in such a way that the indenter 3 protrudes from the front face of the housing.

For the hardness measurement of a textile roll 2 or any other test specimen, the measuring device 1 is pressed in the direction of the arrow X as far as possible at right angles to the surface of the roll 2. Pressure sensors on the front of the housing can ensure that a measurement is only possible if the measuring device is pressed against the winding 2 in the correct position. When the measuring device 1 is pressed on, the indenter 3 is pushed back out of its rest position, but on the other hand also penetrates the winding 2 by a certain amount. The compression spring 6 is pressed together, and the spindle 5 travels a certain distance relative to the housing 4. Since the spring characteristic of the compression spring 6 is known, a certain spring force can be assigned to each spring travel. This spring force forms the measure of the hardness of the winding 2. The smaller the depth of penetration of the indenter 3, the greater the spring travel and, obviously, the greater the hardness of the winding.

The spring travel is measured in the measuring device 1 via a position transmitter 9. Positioners of various types, e.g. Optical, electromagnetic or inductive position transmitter known. A particularly high resolution and thus a high measuring accuracy is achieved with optical / incremental position sensors, such as those e.g. are also known for length measuring devices.

A switch 7 closes the circuit to a power source, not shown, in the form of a battery. The switch 7 is operated on the one hand by a pressure switch 8 which is arranged on the housing 4 and which must be pressed by the operator so that a measurement is possible at all.

In accordance with the specified spring characteristic of the compression spring 6, the spring travel in millimeters determined on the position transmitter 9 is converted in a converter 10 into an analog spring force in Newtons. The measured force is stored in a measured value memory 13, the sum S of the individual measurements already taken being formed in each case. At the same time, the number N of individual measurements is counted in counter 11. The maximum possible number of individual measurements Nmax can e.g. can be set on a selector switch 12. When the maximum possible number is reached, switch 7 is activated and a further individual measurement is no longer possible.

The respective mean value M of the previous measurements is determined in a computer 14 from the sum S of the stored individual values and the number N of individual measurements. After the first measurement, it is evident that only the actually measured value S: 1 = S is displayed.

The computer 14 is operatively connected to a display device 15 and to a tone generator 16. The display device is a digital display with e.g. 3 digits and with a decimal point 17. The digital display can be a liquid crystal display or another display system. An interrupter, not shown, ensures that at least the decimal symbol 17 flashes until the maximum possible number of individual measurements Nmax is reached. Only then will the decimal point appear permanently, indicating to the user that a series of measurements has now been completed.

The tone generator 16 also signals the measuring process in the same way. After each individual measurement, a constant acoustic signal sounds, e.g. a short beep. After the last possible single measurement, a different signal sounds, e.g. a long beep, which also indicates to the operator the end of the measurement series without the display device 15 having to be observed during the intermediate measurements. The individual measurements are preferably triggered or completed by sensors which are arranged on the housing 4 and which also ensure that the measurement is independent of the force in the direction of the arrow X with which the measuring device 1 is pressed onto the winding 2.

A measurement process is then explained using an example. It is assumed that a maximum of 3 individual measurements are possible per measurement series. Accordingly, the selector switch 12 is set to 3 measurements. Instead of the selector switch 12, the maximum possible number could of course also be permanently entered into the counter 11.

At the beginning of the measurement series, the pressure switch 8 is actuated so that the various electronic components are supplied with current. The pressure switch 8 remains switched on during the entire measurement series. The measuring device 1 is now pressed against the winding 2 in the direction of the arrow X. If the relative position is correct and the contact pressure is sufficient, the sensors (not shown) trigger the measuring process. A short beep on the tone generator 16 indicates the end of the first measurement. The first measured value appears at the same time, e.g. 60 Newtons in the display device 15, the decimal symbol 17 flashing.

The measuring device 1 is now set down, the measured value remaining on the display device. The measuring device for the second individual measurement is then pressed, again offset, against the winding 2. Another short beep sounds and counter 11 counts the second measurement. The second measured value, e.g. 75 Newtons is not displayed on the display device 15, but is added to the first measured value in the measured value memory 13. From the sum, namely 135 newtons, the mean value, 67.5 newtons, is calculated and displayed on the display device.

The mean values are not saved because they are used for the subsequent individual measurements and mean

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valuations are not to be considered. However, it would be conceivable that the mean values are also stored in a separate memory, so that the associated mean value can be called up for each individual measurement.

The measuring process is repeated for the third and thus last possible individual measurement of this series of measurements, e.g. a value of 63 Newtons is determined. This value is added up again and the mean of the total of 3 measurements, namely 66 Newtons, is calculated and displayed from the total of 198 Newtons. During this measuring process, a long beep sounds on the tone generator 16 and the decimal symbol 17 appears permanently. The operator now knows that the value of 66.0 Newtons must be read. A further measurement is now only possible if the pressure switch 8 is switched off, with all components in turn being reset to the starting position.

The digital display can also be used to indicate that the battery is exhausted.

Of course, the various components shown in the drawing, such as the measured value memory 13 or the computer 14 are not separate components. Rather, practically all functions can be solved by a microprocessor, which e.g. is controlled by a quartz. However, alternative solutions are conceivable.

Claims (11)

Claims 1.Method for measuring the material hardness of a test specimen, in particular a textile roll (2), an indenter (3) under spring preload being pressed against the test specimen and the penetration depth or the pressing force corresponding to the penetration depth measured with a measuring device and on a Display device (15) is displayed, characterized in that the measuring process is repeated on the test specimen and that each measuring process is counted with a counter, that the sum of all measured values of the individual measurements is stored in a measured value memory (13) and that after the second and after each further measurement from the sum (S) of the measured values and from the number of measurements (N) in a computer (14) the mean value of all previous measurements is calculated and that only the first measured value or only the one measured on the display device (15) Average of all previous measurements is displayed. 2. The method according to claim 1, characterized in that the maximum possible number of individual measurements (Nmax) per measurement series is limited by the counter (11). 3. The method according to claim 2, characterized in that a tone generator (16) is activated for each individual measurement and that the tone generator generates a tone when the last possible individual measurement is reached, which differs in tone pitch and / or duration from the tone used in the previous individual measurements is generated. 4. The method according to any one of claims 2 or 3, characterized in that the measured values are displayed digitally and that the display has at least one element which, when the last possible individual measurement is reached, differs optically from the display of the previous individual measurements. 5. The method according to any one of claims 1 to 4, characterized in that the measuring device is activated via a switch (8) and that the last measured value on the display device (15) is displayed regardless of the measurement position as long as the switch ( 8) is switched on. 6. Device for measuring the material hardness of a test specimen, in particular a textile roll (2), with a spring-loaded indenter (3) that can be pressed against the test specimen, and with a measuring device for measuring the penetration depth of the test specimen or the corresponding one Contact pressure and with a display device (15) for displaying the measured values, characterized by a counter (11) for counting successive measurements, a measured value memory (13) for storing the sum of the measured values of all individual measurements in a series of measurements, a computer for calculating the mean value after each Individual measurement from the sum of the measured values and the number of measurement processes and by means of a display device which is connected to the computer in such a way that it only displays the result of the first measurement and the calculated mean values of the subsequent measurements. 7. The device according to claim 6, characterized in that the counter (11) can be limited to a maximum possible number of individual measurements per measurement series. 8. The device according to claim 6 or 7, characterized in that the computer (14) is connected to a tone generator (16) with which at least two tone signals can be generated with respect to pitch and / or duration and which generates a tone after each individual measurement. 9. Device according to one of claims 6 to 8, characterized in that the display device has a digital or an analog display and a signal element which optically indicates the completion of a measurement and / or the completion of a measurement series. 10. Device according to one of claims 6 to 8, characterized in that the display device (15) is a digital display with an interrupter, wherein at least one element of the display is either flashing or permanently displayable. 11. The device according to any one of claims 6 to 10, characterized in that it has a switch (8), the measuring device can be activated when it is switched on and when it is switched off, the stored measured values in the measured value memory (13) and the display on the display device (15) can be deleted. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65