DE636467C - Uniform load calibration counter - Google Patents

Description

Uniform load calibration counters The development of the counting process has taken a technical turn in the last few years. Whereas in the past calibration was carried out with a wattmeter and stopwatch, jetfit has gradually switched to the uniform load calibration procedure. This method uses the uniform load calibration counter as an essential component and works as follows: The uniform load calibration counter and the counter to be tested are switched on at the same time, for example under full load of the counter to be tested. A number of revolutions are counted on the test item. Count 7: write off which is dimensioned in such a way that the pointer of the calibration counter moves to the zero point of the error scale while the test item is running. When the previously determined number of revolutions of the test item has expired, the calibration counter is switched off. If the test item is OK, the pointer of the calibration counter on the error scale must point to zero. If the test specimen runs too quickly or too slowly, the calibration counter has accordingly traveled too long or too short a distance during the running time of the test specimen, so that its pointer does not come to rest at zero, but at another point. The error can then be identified directly on a scale. read off in percent. In practical calibration, the distance covered by the calibration counter is approximately one revolution. Depending on the constant, nominal current and nominal voltage of the test item, the calibration counter's target paths vary between about 70 and 130 ob) of a revolution. Strictly speaking, one would therefore have to use a special error scale for each target path. Since this is not feasible in practice, the various target paths have been combined into six groups and a mean error scale is used for such a group, which includes, for example, 80 to 90% of a full revolution. It can be seen that the use of six different error scales very easily leads to confusion and requires the careful attention of the calibration staff.

Another known calibration meter does not work with constant torque, but with a constant pointer path. This is achieved by using the calibration counter system not with constant, but with variable voltage. With that one is but switched from the uniform load calibration counter to the uniform calibration counter and has forfeited one of the most important advantages of the balanced load meter. One uses the calibration counter is no longer always on same point of his Characteristic, so that the calibration meter system is special for the entire voltage range calibrated and very carefully checked at several points at certain time intervals must become.

The invention is a, uniform load calibration counter, which for all target paths manage with a single error scale and still always on the same Point of its characteristic is operated. This is achieved through changeable Target pointer travels and a single scale adjustable in its division, with the Setting of the target pointer travel at the same time and necessarily the correct width the scale division is set.

An example of the invention is shown schematically in the accompanying drawings: The pointer z of the calibration counter is driven via a slip clutch 2 by the system of the calibration counter, which is not shown. By means of a heart-shaped return curve 3, which is known per se, the pointer i can be set to the starting position again and again. This is done by turning the knurled knob 4, which moves the slide 6 against the heart curve 3 via the eccentric 5. The pointer i .. plays about a seventh of individual segments in the manner of a known iris composite scale If the Sollzeigerweg happened to ioo% of a revolution, so there are the individual components in the - shown in the figure able to target other hand, the Zeigerweg deviate from oo ° / a, the entire return device mounted on the support arm 8 is pivoted about the center point by a certain amount. The support arm can be locked in the new position by means of a button g. If the feedback device is now actuated, the pointer is no longer set to the zero mark on the scale, but to a new starting point. The changed pointer path corresponds to a changed width of the error scale. In order to inevitably achieve that the scale division fits your chosen target path of the pointer at any time, the scale, which can be adjusted in the manner of an iris diaphragm, is coupled to the support arm of the return device by the bolt io. If the support arm is pivoted to a. To achieve larger or smaller pointer travel, the scale division is simultaneously narrowed or expanded in the correct manner.

If the knurled knob is used very skilfully, especially too quickly 4, the pointer may bruise or the pointer axis may be damaged. Appropriate one therefore does not connect the eccentric 5 rigidly with his. Axis but about a suspension. In this way. it is achieved that the carriage 6 is independent of the rotation of the round button 4 is always advanced with the same force.

The operation of the eccentric 5 does not have to be done by hand a knurled knob. Especially when the calibration meter is permanently installed in the An electric remote drive of the eccentric shaft can be advantageous for the calibration station.

You can also use a heart curve instead of returning the pointer axis any other known means, e.g. magnetic type, is used will.

In all types of feedback, it is possible that through the dead gear in the drive gears errors arise. You can make these mistakes' by doing this Make it harmless that you briefly the voltage during the pointer return to the calibration meter system. In this way, the dead gear in the transmission is switched off. This activation is expediently done automatically by the device, which is operated by the pointer return is controlled.

If one wants to examine the test specimen not only at cos @ g9 = i, but also at cos (p = 0.5, then in the second case twice the observation time would result. In a manner known per se, this disadvantage can be eliminated by equips the calibration meter with two systems, one of which is used at cos p = i - and both are used together at cos T = 0.5. This gives you the same torque at cos cp = 0.5 as with cos 99 = i, see above that one gets the same torque and the same observation time as well as the same target path on the calibration counter and that the same scale can be used in both cases.

Claims (7)

PATENT CLAIMS i. Uniform load calibration meter, identified by a adjustable scale division, which can be adapted to the respective pointer path: 2. Uniform load calibration meter according to Claim i, characterized in that the individual Scale divisions can be adjusted against each other in the manner of an iris diaphragm. 3. Uniform load calibration meter according to Claim i, characterized in that the setting of the target pointer travel necessarily coupled with the setting of the scale division is. . 4. pointer return for uniform load calibration counter according to claim i :, characterized characterized in that .the return by a spring arrangement always in the same Way done. 5. Pointer return for uniform load calibration counter after Claim i, characterized in that the return is not carried out by hand, but is remote controlled. 6. Equal load Eiclizähler according to claim i, characterized in that that 'during the pointer return automatically voltage to the calibration meter system is placed in order to eliminate errors caused by dead gear. 7. Uniform load calibration counter according to claim i, characterized in that in a known manner in the Calibration under cos (p = 0.5 two systems can be used.