DE1059086B - Arrangement for the automatic control of a relay - Google Patents

Description

GERMAN

For the automatic control of a relay, arrangements are known that have a variable resistance, For example, photocell or photoresistor, an ion tube with a cold cathode, main anode and auxiliary anode and a relay located in the main discharge circuit of this tube. Such an arrangement is shown in Fig. 1 and described below with a photoresistor as the variable resistor.

The photoresistor 1 is connected in series with the constant resistor 2 to a sinusoidal alternating voltage. The series connection of the main cathode-main anode is still connected to this voltage of the ion tube 7 and the relay 9. The auxiliary anode of the ion tube is via the resistor with the connection line between the photoresistor and the resistor 2 is connected. Also is parallel to the auxiliary section cathode-auxiliary anode of the ion tube the capacitor 6 switched. This arrangement works as follows:

The photoresistor 1, together with the resistor 2, forms a voltage divider. Will the photo resistor reduced by lighting, the voltage on the auxiliary section increases. Once the Peak value of this voltage or - in the case of discontinuous Change in the lighting of the photoresistor - the instantaneous value of which is the positive ignition voltage reaches the auxiliary section, it is ignited.

The resulting charge carriers cause the main line to ignite with little delay. Since the arrangement is fed with AC voltage, both the auxiliary and the Main discharge after about a quarter period of the supply voltage again by applying the voltages to the Discharge paths drop below their extinguishing voltages. As long as the voltage on the auxiliary line is in each period of the supply voltage reaches at least the auxiliary anode ignition voltage, repeat themselves these operations in the same way from period to period. The relay operates with pulsating direct current excited and remains attracted. If the peak value of the voltage on the auxiliary section falls due to darkening of the photoresistor falls below the auxiliary anode ignition voltage again, ignition can no longer occur and the relay drops out. This representation is the ignition of the ion tube with positive auxiliary and Main anode voltage is used as a basis, while the additional possible, but practically inadmissible Ignition with negative electrode voltages was not taken into account.

The capacitor 6 facilitates the initiation of the main discharge. When it is discharged, from the ignition voltage of the auxiliary section to its chip arrangement for automatic control
of a relay

Applicant:

LICENTIA Patent-Verwaltungs - G. m, b. H. _r Hamburg 36, Hohe Bleichen 22

Dr. rer. nat. Werner Bräuer, Kettwig / Ruhr,
has been named as the inventor

It briefly increases the amperage in the auxiliary section and thereby increases the number of for the initiation of the main discharge available charge carriers. The resistor 3 is used to limit the current in the auxiliary path, which, like all such discharge paths, has a negative resistance characteristic Has.

However, the arrangement described shows the possibility of impermissible ignitions negative electrode voltages is excluded, which is achieved by a positive bias in the auxiliary discharge circuit can be achieved conditionally, two major disadvantages. One of them is that the auxiliary anode ignition voltage is subject to statistical fluctuations, and the other is that the supply voltage is always more or less inconsistent. This results in the following in practice :

If the photoresistor is just illuminated for a few periods of the supply voltage - or longer - that the peak value of the voltage at the auxiliary section in the fluctuation range of the auxiliary anode ignition voltage the ion tube ignites irregularly and the relay flickers. This condition occurs inevitably in all such applications of the described arrangement in which the value of the photo resistor changes only slowly. Act in the same way under the given condition Fluctuations in the supply voltage, even if the fluctuation range of the Auxiliary anode ignition voltage is very small. In the arrangement shown in Fig. 2, an extension of the Arrangement according to FIG. 1, the ignition irregularities described above are eliminated and the The sensitivity to changes in the supply voltage is greatly reduced. It also contains the Rectifier 8, the capacitor 5 and the variable

909 530/311

Resistance 4. The relay is between the cathode of the ion tube and a connection of the Supply voltage switched. The following is caused by the additional switching elements: When there is an ignition the ion tube begins. the work winding of the Relay 9 a voltage on the. on the. Rectifier 8 charges the capacitor 5, in such a way that the negative pole of the capacitor voltage on the relay, the positive pole on the rectifier. After ignition, the Ion tube from a positive DC voltage component. The arrangement is dimensioned so that this DC voltage component 'within a period of the supply voltage to a maximum of the value of the Fluctuation range of the auxiliary anode ignition voltage drops. For re-ignition of the ion tube in the. The following period is then, even with unchanged conditions at the photo resistor, a at least the range of fluctuation of the auxiliary anode ignition voltage greater than that of the first Ignition available. In this way, the fluctuation range is passed upwards so quickly that that the ion tube ignites perfectly for a long time. On the other hand, the arrangement is in the extreme case to be dimensioned so that the DC voltage component in the auxiliary discharge circuit without intermittent ignition falls within a maximum of two periods of the supply voltage by at least the fluctuation range of the auxiliary anode ignition voltage. Of the The fluctuation range becomes as soon as the ion tube darkens the photoresistor remains unignited during a period, so quickly passed through that the ion tube without undesired Reignition remains permanently extinguished. Because of the "permanent extinguishing of the ion tube a greater reduction the lighting of the photoresistor is required than without the one that is newly generated with each ignition DC component, the arrangement has a marked difference in the response and Sensitivity to waste. Because of this difference, it is considerably less sensitive to it Fluctuations in the supply voltage than the arrangement according to Fig. 1. He can with the help of the resistor 4 taking into account the rate of change of the photo resistor within certain Limits can be varied.

Prevention of ignitions of the ion tube with incorrect polarity can be achieved with the arrangement according to Fig. 2 also achieve only conditionally.

According to the invention, such an arrangement "with double half-wave voltage (commutated sinusoidal AC voltage) and points between the main anode and auxiliary anode of the ion tube "The series connection of a capacitor and a resistor. Capacitor and resistor are dimensioned so that depending on whether the ion tube is ignited for 'continuously periodically or for continuously periodically is to be deleted, an additional DC voltage component of in the auxiliary discharge circuit such direction and magnitude arises or is reduced that the fluctuation range of the auxiliary anode ignition voltage is passed through so quickly that even with the slowest change as a sensor Serving resistance ensures a perfect ignition and extinguishing behavior of the ion tube and that due to the variable difference in the response that is impressed on the arrangement and drop sensitivity the sensitivity to fluctuations in the supply voltage is strong is reduced.

The invention will be explained using an exemplary embodiment according to FIG. 3 of the drawing. The order partially corresponds to that of FIG. 1; Corresponding switching elements are identical .Specifications provided.

The auxiliary anode of the ion tube 7 is across the current limiting resistor 3 is connected to a voltage divider formed from the variable resistor 1 and the constant resistor 2. This

ίο Voltage divider is at the outputs of the rectifier arrangement 10 in the form of a Graetz bridge circuit. To the outputs of the rectifier arrangement the ion tube 7 is also connected in series with the relay 9. Parallel to the auxiliary line of the The ion tube is the capacitor 6. Between the main anode and auxiliary anode of the ion tube is the capacitor 11 connected in series with the variable resistor 12. The capacitor is parallel to the relay 13. The arrangement works as follows:

ao After the supply voltage has been applied, a direct voltage builds up on capacitor 11, the more positive of which Pole on the resistor 12 and whose negative PoI is on the auxiliary anode. Forms on the capacitor 6 A DC voltage is also produced, with its positive pole on the auxiliary anode and its negative pole on the Cathode lies. When the ion tube is ignited, this is initiated by reducing the resistance 1 is, on the one hand on the relay 9 with the parallel capacitor 13 forms a DC voltage, whose positive pole on the rectifier and its negative pole on the main anode. On the other hand, the am The DC voltage component lying on the capacitor 11, namely stronger than the value of the DC voltage component, which arises at the relay with parallel capacitor. As a result of these two opposites When the voltage changes, the DC voltage component increases of the capacitor 6 by dividing the DC voltage component of the supply voltage as fourth DC voltage in the cathode-rectifier circuit 10 — relay 9 with capacitor 13 — resistor 12 and capacitor 11 and capacitor 6 — cathode remains constant. If the resistor 1 is increased so much that during a half-wave of the supply voltage If the ion tube is no longer ignited, the arrangement falls in the direction of the initial state return.

If the capacitor 11 and the resistor 12 are dimensioned according to the guidelines given in the explanation of the inventive concept are indicated, ensures the inventive arrangement in in the same way as the arrangement according to FIG. 2, a perfect ignition and extinguishing behavior of the ion tube even with the slowest changes in the controllable resistance. The arrangement according to the invention also has a difference in the response and drop sensitivity and is therefore against fluctuations relatively insensitive to the supply voltage. A change of this difference within certain Limits can also be set using the variable resistor 12.

Compared to the arrangement according to FIG. 2, however, the arrangement according to the invention has the following advantages on:

An ignition of the auxiliary line with wrong polarity ruled out because the auxiliary anode is positive at all times with respect to the cathode of the ion tube. Also a very strong exaggeration of the vertex value the voltage across the resistor 2 via the auxiliary anode ignition voltage cannot become impermissible Lead ignitions. This makes it possible, too

in the case of a very large range of change in the supply voltage, still at the minimum value of the supply voltage to work with a large ignition voltage reserve. An ignition of the main line with a wrong Polarity cannot occur either, since on the one hand the supply voltage does not become negative and on the other hand to extinguish the main discharge and deionization of the main line only a slightly negative one Voltage pulse from capacitor 13 is required. ίο

Furthermore, with the double half-wave feed, the peak value of the main anode current is the same arithmetic mean value only about half as large as with the supply with sinusoidal alternating voltage, Assuming the same gating ratios of the ignition characteristic, since with her in the time unit twice as many main anode current pulses of the same shape as in the comparison case. This condition has a beneficial effect on the life of the ion tube. Such a favorable relationship between The peak value and arithmetic mean value of the main anode current can be determined with sinusoidal Supply voltage even with ignition with phase-shifted voltages on the two discharge paths Hardly realized because of the relatively high operating voltage of the main discharge path.

In addition, the double half-wave feed has the advantage that the ripple of the relay current at parallel capacitor of the same size is considerably lower than when feeding with sinusoidal alternating voltage is.

Claims (1)

Claim: Arrangement for the automatic control of a relay by means of a variable resistor, the serves as a measuring sensor in a bridge circuit, and an ion tube with a cold cathode, main anode and auxiliary anode, characterized in that the arrangement with double half-wave voltage (commutated sinusoidal alternating voltage) works and between the main anode and. Auxiliary anode the ion tube the series connection of a capacitor (11) and a resistor (12) is of such a dimension that depending on whether the ion tube is ignited periodically for a long time or is to be permanently extinguished, an additional DC voltage component of such direction and size in the auxiliary discharge circuit such a speed arises or is reduced that the fluctuation range of the auxiliary anode ignition voltage is passed through so quickly that even with the slowest change in the resistance serving as a measuring sensor, a faultless result Ignition and extinguishing behavior of the ion tube is guaranteed, and that by the arrangement impressed, changeable difference in the response and drop sensitivity Sensitivity to fluctuations in the supply voltage is greatly reduced. Considered publications:
German Patent No. 372,415;
U.S. Patent No. 2,372,104. 1 sheet of drawings © 909 530/311 6.59