DE943907C - Electrical measuring device, the transmitter of which belongs to the measuring branch of the measuring bridge of a display device operating by means of carrier frequency modulation - Google Patents

Description

Electrical measuring device, the transmitter of which is connected to the measuring branch of the measuring bridge a display device operating by means of carrier frequency modulation the known measuring bridge circuits of working by means of carrier frequency modulation Display devices are usually - when with a warming of the for one Inductive measurement specific encoder coil is to be expected, coils with temperature compensation used, d. H. Coils with one winding with partly negative and partly positive Temperature coefficient. The negative temperature coefficient can also be represented by a NTC thermistors built into the coil body can be achieved. In particular, one chooses such an arrangement in devices for measuring the clearance of internal combustion engine valves or when the measuring coil is bathed in a hot liquid. Both the However, the winding mentioned, such as the thermistor, cannot be used if the Coils are very small or if too few for the installation of the coil and NTC thermistor Space is available. In this case there was nothing else to do but the influence the coil heating on the basis of empirical values in the determination of the measurement result purely theoretically, which naturally leads to undesirable effects Inaccuracies in itself very accurate measuring device leads. This deficiency is remedied by according to the invention in the measurement branch of Carrier frequency measuring bridge besides the usual inductance an additional adjustable one Resistance with a deactivatable Wheatston: eschen bridge is arranged so that_ , the encoder resistance can be checked at any time and by adjusting the additional resistance can be adjusted to the calibration status. This makes it possible to choose accordingly if necessary Check the change in resistance of the transmitter coil at intervals and adjust it of the additional resistance to restore the calibration state of the carrier frequency bridge.

The invention is based on the drawing of an exemplary embodiment explained, namely Fig. i shows the circuit diagram of the measuring bridge by means of carrier frequency modulation working display device, Fig. z a longitudinal section through a transmitter coil in one larger scale.

In the selected embodiment, the carrier frequency measuring bridge B consists of the measuring branch a, d and the calibration branch b, b '. Either unchangeable exchangeable resistors or fixed variable resistors w, w are provided in the circuit branch, with the aid of which the bridge can be adjusted in terms of magnitude and phase. The bridge is supplied with carrier frequency by a generator G. In addition, the generator supplies a phase-correct demodulator (rectifier) with AC voltage via line c, which cannot be seen in the drawing. The line d leads to an amplifier connected upstream of the demodulator. A display device of the known type, in particular an oscilloscope, is then arranged behind the demodulator. The encoder at the measuring point consists of a double coil s, s ', which is located in the measuring branch a, a' of the measuring bridge.

In Fig. A, such a transmitter coil is drawn out on a larger scale in longitudinal section. The coils are located in a soft iron yoke e, into each of which from the outside a: likewise made of soft iron, core f, f 'is immersed. However, this core can also consist of another material that conducts the magnetic lines of force well. The coils are on their inside through a brass sleeve g and. bounded on their end faces by soft iron washers h. The soft iron parts can also be held together by tensioning screws. They enable a coherent flow of lines of force, which gives the device a high and constant sensitivity. The two plunger cores f, f 'are non-positively connected to one another by a magnetically non-conductive middle section i. The immersion depth of the cores f and f ' in the' coils s and s' caused by the measured variable results in a change in the coil induction. The latter in turn changes the AC voltage of the carrier frequency bridge B and thus also the AC voltage. to the amplifier and the demodulator. This change is displayed by the oscilloscope or other display device. The device described so far and its mode of operation are known.

If the temperature of the coils s, s' changes, such as e.g. B. in the valve clearance measurement mentioned at the beginning, where the measurement begins when the engine is cold and ends when the engine is warm, the ohmic resistance of the coil winding, which is usually made of copper, changes. This results in a zero point shift and thus a change in sensitivity. In order to be able to counteract this even if there is no automatic temperature compensation, an additional variable resistor w2, w3 each with a switch k, k 'is provided in the measuring branch sections a, ä of the carrier frequency measuring bridge B, their common line leads to a Wheatstone bridge B '. This consists in a manner known per se of a galvanometer m, a small current source n, a comparison resistor w4, a switch o and a measuring wire p. This device makes it possible to check the resistance of the coils s, s at any time by moving the switch k, k 'from the measuring bridge position to the switch position on the Wheatstone bridge and then, if the resistance has changed under the influence of heat, by a corresponding one Change in the additional resistances w2, w3 to restore the calibration status in the measuring branch of the carrier frequency measuring bridge B immediately.

To now in special cases, z. B. in the case of valve clearance measurement, in order not to let the time intervals between the individual measurements become too long, the resistance measurement of the transmitter coils with the Wheatstone bridge must be carried out in the shortest possible time. For this purpose, according to a further feature of the invention, the switches k and o or k 'and o are inevitably connected to one another in such a way that when the scUlter k or k' is switched from the measuring branch of the carrier frequency measuring bridge B to the Wheatstone bridge B 'at the same time whose switch o is closed. It is also advantageous to provide a switch from the display device at the output of the device, by means of which the display device is switched off when the Wheatstone bridge is switched on, in order to avoid overloading the display device. The actuation of the hand switch for the display device can inevitably take place at the same time as the actuation of the switches k, k ' or o. The inevitable actuation of the switch is done either mechanically by a linkage or z. B. electrically by connecting multiple contacts in parallel. The switches can also be combined on a push pin, or a collective switch is designed as a push button, which is under the influence of a return spring, such that the Wheatstone bridge is only switched on during its pressure load and after releasing it again on the Carrier frequency bridge is switched. Instead of the double coil s, s described, a simple coil can also be used within the scope of the invention. Since the change in temperature is not solely responsible for the change in resistance of the measuring coil, because the change in inductance of the coil also occurs due to a change in the coil body under the influence of heating, which also results in a zero point shift, it is advantageous in some cases to use the To produce coil bodies from a material that has practically no or only a small temperature coefficient, so that the outer dimensions of the coils always remain the same. Ceramic bobbins are particularly intended.

Claims (1)

PATENT CLAIMS: i. Electrical measuring device, the transmitter of which belongs to the measuring branch of the measuring bridge of a display device operating by means of carrier frequency modulation, characterized in that in the measuring branch (a, ä) of the carrier frequency measuring bridge (B), in addition to the usual inductance (s, s), an additional controllable resistor (w2 , w3) is arranged with a Wheatstone bridge (B ') that can be switched off, so that the transmitter resistance can be checked at any time and can be adjusted to the calibration state by adjusting the additional resistance. a. Measuring device according to claim i, characterized in that the changeover switches (k, k ') for the Wheatstone bridge (B') located in the measuring branch of the carrier frequency measuring bridge (B) are necessarily connected to the switch (o) located in the latter in such a way as to .that when the carrier frequency measuring bridge switch (k, k ') is switched to the Wheatstone bridge (B'), the switch (o) in the Wheatstone bridge is closed at the same time, and vice versa. 3. Measuring device according to claims i and z, characterized in that the display device located at the output, in particular oscilloscope, can be switched off for itself and that this switch also with the switch (o) in the Wheatstone bridge (B ') or with a the switch (k or k ') in the carrier frequency measuring bridge (B) is inevitably connected in such a way that when one of the following switches (o, k or k') is closed, the first-mentioned switch for the measuring device is opened and thus the display device for Protection against overload is switched off. 4. Measuring device according to claims i to 3, characterized by a push button or push pin collective switch under the action of a return spring. 5. Measuring device according to claims i to 4, characterized in that the bobbin or bobbins (s or s') consist of a material with a small temperature coefficient.