DE853476C - Electrical measuring device - Google Patents

Description

Electrical measuring device The invention relates to an electrical Measuring device, consisting of a mechanical, driven by a synchronous motor and a pressure contact connected as a rectifier upstream of a direct current meter. One Such a device for measurements on toroidal cores is already in the archive for electrical engineering, 1944, pp. 141 to 156, specifically for determining the magnetization characteristics been, the pressure contact by a synchronous switch designed as an oscillation rectifier is formed.

The invention consists in this known measuring device to use to measure alternating currents by rotating the contact compared to the phase position of the synchronous motor, the phase position of the alternating current variables to each other and by the measuring device the alternating current values are measured itself. This creates a vector meter with which it is immediately possible to determine phase angles to measure without the aid of other devices besides those mentioned. The exact However, measurement of vectors is only possible with a contact device in which the scale the contact rotation exactly angularly with the rotation of the contact closing time is. The invention therefore further relates to adaptation, simplification and improvement of the known synchronous switch for the present purpose. His Training is described using an exemplary embodiment.

In Fig. I of the drawing, a leaf spring ii is shown in side view, which can have an approximately trapezoidal shape perpendicular to the plane of the drawing. At one end it carries the moving contact 12, and its other end is attached to the support frame 13. Below it is a damping spring 14 which slides back and forth a little when the leaf spring ii moves. A second leaf spring 15 carries the stationary, unspecified counter-contact for the movable contact 12, which can be adjusted by the adjusting screw 16 corresponds, carries a crank pin ig directly at one end, which makes 3000 revolutions when the synchronous motor, assumed to be two-pole, is connected to an alternating current network with a frequency of 50 Hz and causes the periodic opening and closing of the contact 12 by lifting the leaf spring ii. If the crank pin rotates ig, it presses the leaf spring ii down with each rotation and opens the contact 12. If it moves away from the leaf spring, the contact 12 closes. The shaft 17 is moved as close as possible to the contact 13, to achieve bounce-free opening and closing of the contact. For the same reason, the leaf spring ii must have as high a natural frequency as possible, ie it must have the smallest possible mass for a given suspension. The support frame 13 can be rotated precisely centered and free of play about the axis of the shaft 17, whereby the phase position of the contact closing time can be regulated. The eccentricity of the crank pin ig is about 0.5 to 1 mm. The contact pressure is about 5 to 10 g. The torque of the driving synchronous motor must be about ig / cm. So that the fluctuation in the contact resistance does not have a greater influence than 0.1% on the measurement result, the resistance of the measuring circuit must be at least 20 ohms. If the spring is made of silver or silver-plated steel and the crank pin is made of polished steel, the coefficient of friction between the two materials is particularly low. The leaf spring ii can then also be used directly as a contact, and if the circumferential crank pin ig also rubs off some material from the leaf spring ii over time, this means no risk of worsening the contact. By means of the adjusting screw 16, the contact closing time before each measurement can be adjusted to the desired value with an accuracy of ± 0.1%, e.g. B. also set to i8o °. This setting can take place, for example, in that an auxiliary direct current voltage of a few volts is applied to the moving coil measuring device 20 via a large resistor and via the pressure contact. If the resistance is regulated in such a way that the measuring device deflects fully when the contact is permanently closed, then when the contact is working, the fraction of the full deflection of the measuring device is equal to the fraction of the contact time, based on permanent contact closure. For example, the meter shows half a deflection at 180 ° contact time.

Thus, when the support frame 13 is rotated, the phase of the contact closure time corresponds exactly to the angle of rotation, the driving synchronous motor must be sufficient be strong and have sufficient flywheel mass on the shaft.

If you want to determine the phase shift between the current and voltage of the in Fig. I determine the alternating current network shown, so one sets first with the one described without the necessary series and shunt resistors, DC circuit sets the contact closing time i8o °. The moving coil measuring device is then switched on However, via an appropriately dimensioned series resistor, which is shown in FIG is unspecified, to the alternating voltage to be examined, turns the Support frame 13 with the synchronous motor running until the measuring device 20 does not deflects, and marks the position of the support frame 13. Then you switch the Moving coil meter on the other. Comparison alternating current magnitude around and repeated the same measurement method. Fig. I shows only the circuit for voltage measurement. The difference in angle between the first and the second position of the support frame 13 gives the phase shift between the two alternating current quantities.

In FIGS. 2 to 4, further configurations of the contact device described are shown schematically. According to FIG. 2, the bearing of the rotor 21 of the synchronous motor and the bracket 22 of the contact spring ii and the contact spring, which is not visible in FIG. 2 and denoted by 1s in FIG , a sliding seat 24, which always involves an inevitable backlash. This avoid the embodiments according to FIGS. 3 and 4, in which the bearings of the rotor are mounted in the same housing part 25 21 as the holder for the contact springs ii and 1 5. The sliding of the housing part 25 on its supporting arms 26 inevitable with his game here has no influence on the mutual position of the crankshaft 23 in relation to the contact. However, when the housing part 25 is rotated, the contact time cannot be influenced here because the housing part rigidly connects the rotor bearing and the contact spring of the holder to one another. The scale for the contact rotation can then be attached to the holding arms 26 of the housing part z5 and the mark for reading the phase position can be attached to the housing part 25 itself. According to FIG. 3, one bearing of the motor shaft is held by means of support arms reaching through the air gap of the synchronous motor, while according to FIG. 4 the rotor 21 of the synchronous motor is arranged overhung. In all the cases shown, the pressure contact is driven directly via the motor shaft 23, which is designed as a crank. The embodiments according to FIGS. 2 to 5 show that it is advantageous for the construction of the contact device to attach the contact arrangement above the synchronous motor.

Fig.5 shows the practical design of such a contact device recognize in the cut if two pressure contacts, preferably for special Circuits, are to be used.

Fig. 6 shows the top view.

This contact device, like the devices according to FIGS. 2 to .4, symmetrical to the motor shaft with an eccentric arrangement of two pressure contacts 27 and 28 built. The stator iron 29 of the synchronous motor carries the field winding 3o. The shaft 31 of the rotor supported according to FIG. 3 is supported at 32, 33 and 34. Two eccentrics 35, 36 rotate with this shaft. These move the eccentric to Central axis lying contact leaf springs 37 and 38, which in the figure only strongly are visible in a shortened form, as their longitudinal extent is perpendicular to the image plane lie. They correspond to the leaf springs ii in the previous figures.

The fixed contacts are made with the help of the adjusting screws 39 and 40, the are led out to the side of rotary handles', also adjustable during operation.

The contact leaf springs 37 and 38 with their adjusting screws 39 and 4o are supported on the rotatable parts 41 and 42, of which the rotatable part 41 has a 360 ° scale 43 and the rotatable part 42 has a mark 44 (see FIG. 6). At its edge, the rotatable parts 41 and 42 are designed as rotary handles, such as 6 shows this. Another rotatable part is located around the rotatable part 41 45, who in turn owns a mark 46. The connection of the pressure contacts 27 and 28 takes place via slip rings 47 and appropriately mounted brushes. The corresponding Connecting lines are not shown. Two locks 48 and 49 allow it to determine each one of the rotatable housing parts 41 and 42, so that only the others can be rotated.

The pressure contact 27 is used to measure in the following way: The rotatable Part 41 with the scale 43 and the leaf spring 37 is brought into such a position that the DC meter 20 in the circuit according to FIGS. i and 2, in which the AC output current magnitude at the measuring device does not deflect after previously has been adjusted in the manner already described to a contact closing time of i8o ° is. This zero point of the scale 43 is with the mark to be rotated in this position 46 recorded. Then that alternating current quantity becomes its phase shift to be measured against the output alternating current quantity (phase comparison quantity), placed on the measuring device and rotated the rotatable part 41 again until the Measuring device no longer deflects. The angular amount from the second zero of the Scale up to mark 46 corresponding to the first zero point of the scale gives the measured value Phase angle, in Fig. 6 z. B. 71.5o.

The measurement with the one associated with the rotatable part 42 and the mark 44 Pressure contact 28 proceeds accordingly. First, in the zero position of the Measuring device brought the zero point of the scale 43 with the mark 44 to coincide, then the rotatable part .42 with the mark 44 is rotated during the second measurement and read off the angular amount of the current position of the mark 44 on the scale 43, in Fig. 6 e.g. B. 6 °. The pressure contacts are used to measure the alternating currents themselves set to the largest deflection of the measuring device. The meter then shows the arithmetic Mean value of the half-wave of the measured variable. All rotating parts of the contact devices 5 and 6 are by elastic springs against unwanted twisting secured.

With the device described, the phase positions can also be determined the two mutually rotatable pressure contacts 27 and 28 determine in the Make sure that one and the same amount of alternating current is applied once to contact 27, then to the contact 28 is placed. The angular positions of the contacts, the marks etc. must must be read beforehand. After that, when the alternating current quantity is applied, one Contact, e.g. B. 28, rotated until the same rash occurs as before when measuring at contact 27. The angular amount by which contact 28 is at this Opportunity had to be rotated starting from the position read at the beginning, is a measure of the phase difference between the contacts.

The contact device formed in this way can be compensated as Unit built into the DC current meter or assembled with other measuring devices will.

The described measuring device can be used to investigate alternating current resistances, Transformers, transducers and alternating current or three-phase machines in otherwise per se known circuits are used. No-load currents, fundamental and harmonics, Iron losses, number of turns, short-circuit voltages, efficiencies, transmission ratios, Voltage drops during operation, increase in resistance of windings due to eddy currents and measure the errors of voltage and current transformers with this device without With the aid of ammeters and voltmeters, wattmeters, oscilloscopes and vibration galvanometers. The measuring device (vector meter) according to the invention is used for alternating current measuring technology a measuring device of the highest accuracy and general usability created.

Claims (1)

PATENT CLAIMS: i. Electrical measuring device, consisting of a mechanical pressure contact (contact device), driven by a synchronous motor and connected as a rectifier upstream of a direct current measuring device, characterized by its use for measuring alternating current variables according to phase and size by rotating the pressure contact relative to the phase position of the synchronous motor to change the phase position of alternating current variables to each other and by the measuring device the alternating current values are measured itself. 2. Measuring device according to claim i, characterized in that on the contact device holder of the bearing of the synchronous motor and holder of the pressure contact are rigidly connected to one another. 3: Measuring device according to claim 2, characterized in that one bearing of the motor shaft of the synchronous motor is held on the contact device through its air gap. 4. Measuring device according to claim 2, characterized in that the rotor of the synchronous motor is overhung on the contact device. 5. Measuring device according to claims 2 to 4, characterized in that the actuation of the pressure contact takes place directly on the contact device by the motor shaft designed as a crank or as an eccentric shaft. 6. Measuring device according to claim 5, characterized in that the contact device of the crank pin or eccentric made of polished steel and the contact spring made of noble metal, for. ß. Silver, is made or is silver-plated. 7. Measuring device according to claims 2 to 6, characterized in that the contact arrangement is attached to the contact device above the synchronous motor. B. Measuring device according to claims 2 to 7, characterized by a symmetrical arrangement of the contact device with respect to the motor shaft with an eccentric arrangement of the pressure contact. G. Measuring device according to Claim 8, characterized in that the contact is rotated on the contact device by means of a rotary handle and is read off from an associated circular scale. io: Measuring device according to claim 1 or the following, characterized in that the contact closing time can be set on the contact device during operation from the outside without opening the device. i i. Measuring device according to Claims 2 to 10, characterized by the installation of the contact device as a unit in the direct current measuring device. 12. Measuring device according to claims 2 to ii, characterized in that two mutually rotatable pressure contacts are actuated by a common shaft on the contact device.