DE974507C - Measuring and testing device for contact rectifiers - Google Patents

Description

With a mechanical precision rectifier, the accuracy of the measurement result depends on the Switching accuracy of the mechanical rectifier. Switching accuracy is compliance with the switching duration to understand, which should be exactly half a period of oscillation. Understood by the switching duration error one can find the difference between the actual switching duration and half the oscillation duration.

The switching duration error depends on mechanical and electrical inaccuracies in the switching capacity of the controlled rectifier. It is known that with a mechanical rectifier one has to check the switching duration error from time to time and, if necessary, readjust the mechanical rectifier. In this known device, the mechanical rectifier is switched into an external test circuit, consisting of a direct current voltage source, a controllable series resistor and a direct current instrument, with bridging tabs, one of which bridges the measuring instrument and one bridges the synchronous contact, opened or closed in a predetermined order. need to be closed. To test, the rectifier contacts are first short-circuited and a certain current intensity with full deflection of the direct current instrument is set. If the short-circuit of the rectifier is then removed, exactly half the current value is displayed if the switching duration error is zero. One division of this difference corresponds to a switching duration error of 2 ° / ₀ (half-value method) if the scale has 100 parts or the deflection when the rectifier was short-circuited was set to 100.

009 685/10

This known method is unsuitable for operational use because it is extremely time-consuming; because in order to pass from a circuit suitable for a measurement to the test circuit a plurality of switch operations must be carried out in the correct order.

In the case of a test device built into a mechanical precision rectifier to test the Switching duration and switching phase by means of a switching device which simultaneously separates the measuring circuit and an auxiliary voltage, according to the invention, the auxiliary voltage is divisible in the ratio ι: 2, and the Switching duration test is carried out by means of a switching device that can be operated with just one movement, whereby by actuation of the one changeover switch both the short-circuit and subsequently the switch-on of the rectifier contact and thus half or all of the voltage of the auxiliary power source is switched on so that the switching duration error can be read off as a percentage on a display instrument, and that to control and adjust the switching phase, a special auxiliary AC voltage to the half-wave or full-wave circuit of the rectifier is switchable.

Details of the invention are explained using exemplary embodiments. The working examples but allow modifications that remain within the scope of the invention, so that the invention is not should be limited to the exemplary embodiments and the details shown therein.

In Fig. Ι is a measuring and testing device according to the invention

■ Figure shown for a circuit with full-wave rectification. The display device used for both the measurement and the test is designated by M. The rectifiers used in the circuit are G ₁ and G ₂ . The control winding of this rectifier is not shown. The two connection terminals A are used for a measurement. One of these terminals leads to a point N, the common zero point. The other connection terminal leads to two resistors r _x and r ₂ , one of which is in series with the rectifier G ₁ during the measurement and the other with the rectifier G _2.

The display device M is connected to the resistors and the rectifiers in a bridge circuit.

A rotary switch with seven contact positions and four switching levels is provided for the switchover from the measuring position to different test positions for the switching duration and for the test the switching phases of the rectifiers. The individual contact positions are 1 ... 7 or 11 ... 17, 21 ... 27 and 31 ... 37.

A direct current source E with a voltage of 1.5 V and an alternating current source W for generating an alternating voltage of 2 V are provided for the test. _{A protective resistor S 1} and S _{2 is connected} in series with the two current sources in order to avoid a short circuit between the current sources.

To understand the mode of operation, the different switch positions must now be considered: man has to keep in mind that the four switching levels of the switch differ from the schematic Drawing lie on a common axis, so that the further switching in all four switching levels always be carried out consistently. "

The position 4 or 14, 24 and 34 is, for example, the middle position of the switch, in which it is not checked but measured. The power connections to the two test power sources are then switched off. The measurement voltage that is applied to the terminal ends, on the one hand, leads to a measurement current through the resistors Y ₁ and r ₂ and the rectifier G ₁ or through the resistors T ₁ , r ₂ and the rectifier G ₂ and, on the other hand, through the zero point Λ ^Γ of the two rectifiers G ₁ and G ₂ . The work of the two rectifiers G ₁ and G ₂ then results in a direct current through the measuring device M.

If the changeover switch is moved from position 4 to position 3, the measuring circuit just described is interrupted, namely at contacts 4, 14, 24 and 34. For this purpose, a connection to the test current source E is established via the protective resistor S ₂ , with which a controllable resistor S _{3 is} in series. A current is now generated from the current source E via the resistors S ₂ and S ₃ , the switch contact 3, the measuring device M, the contact 13 to the zero point N of the rectifier and back to the battery E. The rectifiers are therefore passed over in this switch position, so that an instrument deflection of "100" can be set with the aid of the control resistor S _3. If the switch is turned by a further step, a circuit now arises from the test current source £ via switch contact 2, measuring device M, switch contact 32, rectifier G ₂ to zero point N and back to power source E. In this switch position, therefore the one of the two rectifiers switched on, whereby the current in the measuring device M must be reduced to exactly half if the switching duration of the rectifier G _{2 is} exactly half a switching period.

The rotary switch can be turned one step further, in which case the direct current source E is switched off and the alternating current source W is switched on. A circuit then arises via switch contact 1, measuring device M, contact 31 and rectifier G ₂ , zero point N to power source W. In this position of the test switch there is a certain deflection on measuring device M. The next step of the rotary switch is contact 1 is interrupted and contact 7 is established. This in turn leads to a circuit via the measuring device M, which is still routed via the contact 27, and via the rectifier G ₁ to the AC voltage source W. At the transition from position 1 to position 7, which are next to each other on the rotary switch, is switched from rectifier G ₂ to rectifier G ₁ . You can now observe on the measuring device whether this changeover has resulted in a change in the deflection size of the measuring device. This would then be an indication that the two rectifiers G ₁ and G ₂ do not have the same phase setting.

The switch positions 5 and 6 are still to be explained. In the switch position 5, the direct current source E is switched on, so that a direct current through the switching

contact 5 of the measuring device M, the switching contact 15, the zero point N to the power source E flows. Again, this is a switching position that bypasses the two rectifiers. In this case, it is recommended to set the current intensity up to the measuring device deflection »100«. If the switch is then switched from position 5 to position 6, the stop on the test current source E remains, but the measuring device M is connected to the rectifier G ₁ via contacts 6 and 26, so that this rectifier G _1, the same test can be carried out as was previously described for position 2 for rectifier G ₁ , in that measuring device M in switch position 6 shows exactly half the current intensity compared to the current intensity in switch position 5.

With the switching device indicated schematically, it is thus possible to test the rectifiers G ₁ and G ₂ both with regard to the switching duration and with regard to their mutual phase position.

In the arrangement described, the test for switching duration is carried out by means of a current intensity which, when the rectifier is short-circuited, should have exactly twice the value as when the rectifier is switched on. It is now more favorable if the deflection of the measuring device is the same in both cases, ie when the rectifier is short-circuited and when the rectifier is switched on, because this gives you the absolute certainty that the test is independent of any display errors on the display instrument. Such an arrangement is shown in FIG. In accordance with FIG. 1, the measuring device or display device is designated by M. The resistors r _x and r _% used in the same circuit as well as the test current sources E and W and the rectifier _{symbols G 1} and G ₂ are also used again. In this further embodiment of the invention, the changeover switch has five switching levels, and the voltage source E is equipped with a voltage divider T ₁ and T ₂ and thereby enables half the test voltage to be used once and the other time exactly the entire test voltage. In order to increase the clarity of the figure, the positions are only indicated for the top switching level of the switch, namely with the numbers from 41 ... .51. This switching level is adjusted in exactly the same way in all other switching levels.

The operating position, ie the switch position for carrying out a measurement, is established in switch position 46. From the terminals A the left then leads via the contact position 46, the two resistors r _x and r ₂ via the measuring device M and the two rectifiers G ₁ and G ₂ to the right terminal A in the known full-wave rectifier switch.

If the switch is moved one step to the left on contact 45, the measuring circuit is interrupted; but a circuit is prepared from the middle of the voltage divider TJT ₂ via the one rectifier G ₁ . Since the back connection of the lower end of the voltage divider T ₂ to one pole of the test battery E is still missing, the direct current source is not yet switched on. Only after the second switching step is the partial voltage on the voltage divider T ₂ switched on via the contact 44 in the top switching level ScH ₁ and the corresponding contact in the switching level Sch ^ In addition, the lower end of the voltage divider resistor T ₂ is through the corresponding contact in the switching level Sch _s connected to the battery pole. A current intensity flows through the measuring device M , which can be set to the deflection "100". In the next step of the switch, the switch position 43 is reached. The upper connection end of the voltage divider T ₁ is then connected to the supply line to the resistors r _x and r ₂ via this. At the same time, the rectifier G ₁ is switched on again via the corresponding contact of the switching level ScH ₃ , and the lower terminal end of the voltage divider resistor T _{2 is} connected to the battery in the switching level Sch _s. There is now twice as high a voltage on this test circuit as in the previous switch position, in which the rectifier G _{1 was} short-circuited. Since the rectifier G ₁ is now switched on, the result is exactly the same pointer deflection as before, if this rectifier has the correct switching duration.

For the phase test, the switch is set to position 42. There is then an alternating voltage from the transformer W via the contact 42 on the lead to the resistors V ₁ and r ₂ . The rectifier G _{1 is} switched on via the corresponding contact position in the switching level Sch _s , and the further course of the current leads from the zero point N back to the transformer W. In this position, the rectifier G ₁ disconnects a half-wave from the alternating current of the transformer W. This results in a certain pointer deflection on the measuring device M, which must not change if, when the switch is switched to position 51, a half-wave of the same alternating current occurs through the other rectifier G ₂ .

A contact position 41 is also provided for the changeover switch, via which the measuring device M can be used as a sensitive direct current measuring device. The direct current to be connected and measured to terminals A then runs via contact 41 and closes via the corresponding contact in switching level ScA _4. The rectifiers are short-circuited.

In Fig. 2, the same circuit is indicated again in the right half of the figure for the assumption that it is an apparatus for performing two different measurements. The same assumption is made in the illustration in FIG. 3, which roughly reproduces the appearance of a measuring and testing device according to the invention. The device has two measuring circuits I and II or pairs of terminals for connecting two display devices. A rule resistor Dj and Z) _n and an oscillating contact rectifier set Gj or G $ belong to every measuring device. For the requirement that two measuring circuits with the associated rectifier sets can be connected to the measuring and testing device, the changeover switch U is also built, which has switching positions for measuring circuit I as well as for measuring circuit II.

A simplified switchover device for a half-wave rectifier arrangement is shown schematically in FIG reproduced. A check of the mutual phase position is in the case of a half-wave circuit with only one rectifier works, not possible. The test is therefore limited to the switching duration. Only one DC power source is required for this test.

Assuming that the measuring device should be usable for four measuring circuits, each with a rectifier, four such measuring circuits I ... IV are indicated in FIG. Each of the measuring circuits has a rectifier G ₁ and a display unit M. A common battery B is provided for the test. In series with this there is a protective resistor S and a control resistor R. The changeover switch has two switching levels with the contacts a _x , B ₁ and C ₁ as well as a _z , δ ₂ and C ₂ . In the position c, the contact _{bridges C 1} and C ₂ are set so that the measuring circuit via the instrument M and the rectifier G _{1 is} closed. If the changeover switch is brought into contact position b , the battery B is switched on via the measuring instrument and the regulating resistor R while the rectifier G _{1 is} short-circuited at the same time. A certain deflection of the instrument M can be set with the aid of the resistor R.

In the third switching position α , the contacts a _{x are}

and a ₂ closed, so that if the position of the variable resistor R remains unchanged, the deflection of the device M is reduced by half as a result of the rectifier G _{1 being switched on again.}

In this circuit, too, similar to the circuit according to FIG. 2 in both test positions α and b, one can work once with half the voltage with the rectifier short-circuited and once with the full voltage with the rectifier switched on, so that the deflection of the instrument M in both Cases remains the same.

As can be seen from FIG. 5, the changeover switch U is divided into four equal sectors in this arrangement, so that the test can be carried out by means of one and the same changeover switch for each of the four measuring circuits provided. This one changeover switch then includes four rotary resistors D ₁ and D ₁ , D ₁₁ I, DiY in order to be able to set the deflection values of the measuring instrument for each measuring branch and for each rectifier to be tested independently of one another.

Claims (13)

PATENT CLAIMS: i. A test device built into a mechanical precision rectifier to test the switching duration and switching phase by means of a switching device that simultaneously separates the measuring circuit and an auxiliary voltage, characterized in that the auxiliary voltage is divisible in a ratio of 1: 2 and the switching duration test is thereby carried out by means of a switching device that can be operated with just one movement takes place that by actuating the one changeover switch both the short circuit and subsequently the activation of the rectifier contact and thereby half or the entire voltage of the auxiliary power source is switched on, so that the switching duration error can be read in percent on a display instrument, and that for checking and setting the Switching phase a special auxiliary AC voltage can be switched to the half-wave circuit or full-wave circuit of the rectifier. 2. Test device according to claim 1, characterized in that that for the switching duration test in a known manner rectifier and direct current instrument can be combined with three fixed resistors to form a bridge circuit, the Resistors are chosen so that the switching period is equal to half the period of oscillation the measuring frequency the instrument shows zero adjustment. 3. Test device according to claim 2, characterized in that a measuring circuit voltage for phase comparison is used. 4. Test device according to claim 1 and following, characterized in that the direct current instrument and each contact rectifier is assigned a double-pole switching level on a common axis. 5. Test device according to claim 1 and following, characterized in that the contact rectifier unipolarly connected to each other and directly connected to the zero pole and that a switching level of the common changeover switch is assigned to each of their free connections. 6. Test device according to claim 1 and following, characterized in that on the switch position "Measurement" the half-wave or full-wave circuit is switched through in the measuring state. 7. Testing device according to claim 1, characterized in that that on the switch position "switching duration" either the test bridge circuit or the test series connection with the direct current voltage source is created. 8. Test device according to claim 1 and following, characterized in that on the switch position "0" in the test circuit, the test voltage source is switched off and that by means of the phase shifter Any deflection of the galvanometer brought to position "0" due to interferences will. 9. Testing device according to claim 1 and following, characterized in that on the switch position »100« the test circuit with the short-circuited rectifier is in operation and by means of the series resistor the deflection of the instrument is regulated to exactly 100 divisions. 10. Test device according to claim 1 and the following, characterized in that in the switch position "50" the test circuit with the released Rectifier is in operation, so that when the rectifier is properly adjusted the instrument goes back from the reading "100" to the reading "50". 11. Testing device according to claim 1, characterized in that that on switch position "phase" the half-wave circuit or the full-wave circuit with only one rectifier to the control alternating voltage or to the measuring alternating voltage is placed, in which case the phase equality is then established in a manner known per se by means of the oscillation rectifier controlling phase shifter is set. 12. Test device according to claim i, characterized in that that the resistance sets of the half-wave and full-wave measuring circuit and the bridge and series test circuit each from one Carrier plate worn and expedient in the immediate vicinity of the switching level on the same switch frame are arranged. 13. Test device according to claim 1 and the following, characterized in that the connecting lines to the switch levels are below one another twisted and the resistance sets are put together so that the smallest possible winding areas for the purpose of the smallest possible interference. Considered publications:
German patent specification No. 851 382. 1 sheet of drawings © 009 685/10 1.61