DE565626C - Arrangement according to patent 523509 for the exact determination of the exceeding of a threshold value in the case of weak, especially photoelectric currents - Google Patents

Description

Arrangement according to patent 523 509 for the exact determination of the exceedance a threshold value for weak, especially photoelectric currents In the main patent is an arrangement for the precise determination of the exceedance of a threshold value described in the case of very weak, in particular photoelectric currents, in which an electron tube operating as an electrostatic switch with a periodic working organ, the so-called clock generator. . The clock removed here the electrostatic switch at certain time intervals (so-called clock period) . periodically from its response position due to negative charging of the tubular grid (approximately the grid zero potential), while the currents to be tested in the meantime be used to bring the electrostatic switch back to its response position. The currents to be tested only have a limited amount of time available for this Available, which is to be referred to in the following as the measuring period. Only if the strength of the current to be tested is sufficient to control the electrostatic Bring the switch to the response threshold within the measuring time, so it comes to operate this switch so that its response indicates that the strength of the currents to be tested exceeds the specified threshold value. Arrangements these types work extremely precisely; however, it does as experience has shown often has certain difficulties in using mechanical relays in a reliable manner to control and a number of other, in special cases given conditions flawlessly to meet. These difficulties are eliminated by the invention.

According to the invention, the one for the creation of the critical charge transfer the available measuring time is made shorter than the clock period, that the relay circuits controlled by the electrostatic switch for a certain time be blocked directly or indirectly before the end of the clock period. This blocking is expediently carried out by the clock itself and is so vorgenomtnen that with their entry a subsequent response of the electrostatic Switch is either impossible or made ineffective. The actual measurement (Measuring time section) is therefore ended when the blockage occurs, and there is a between the end of the measuring period and the end of the clock period Intermediate periods are inserted, which are referred to below as the blocking time should and which, as the examples described later show, for Increase in operational safety, facilitate negative charging and for others Measures that require time can be used without this wasting time the measurement accuracy is impaired. Furthermore there is the blocking time, if you can make it changeable, the possibility of setting the measuring threshold as desired, an advantage of periodically working organs with a certain period (clockworks) is of great importance. The invention is explained on the basis of the figures.

In Fig. I an arrangement according to the main patent is shown. The grid i of the electron tube 2, the capacitance of which is increased by the capacitor 3 is, at the moment when the nose 4 of the in the direction of the pointer 5 is rotating Wheel 6 briefly closes contact 7, negatively charged. The charge flows via the photocell g, depending on its lighting, at different speeds, and the electron relay 2 is only able to conduct electricity for a moment if the elimination of the negative charging of the grid i takes place before the next throttling of the grid. The duration of the current flow may not be sufficient to achieve the desired To trigger switching operations, especially if that is in the anode circuit of the Electron relay 2 located relay 9 when a certain brightness value is exceeded must operate more extensive - switching arrangements.

According to the invention, therefore, as shown in Fig..2, the periodically operating organ 6 is designed so that it causes a blockage of the relay circuits a certain time before the throttling of the grid, ie before the nose 4 reaches the position shown. (The throttle circuit is not shown in Fig. 2 for the sake of clarity.) In the present example, the blocking is done by a second profile disk 1o, which sits with the wheel 6 on an axle. The profiled disk 1o actuates the spring pack 1i and causes the blocking in such a way that when the spring pack 1i falls into the cutout of the profiled disk 1o, the contact 12 is opened and the anode circle of the tube 2 is interrupted. At the same time, the relay 9 is held by closing the contact 13 in the switching position which it assumes at the moment the spring pack ii is actuated. If the relay has 9 not been addressed at the time of blocking the anode current, so its rest position is retained even after blocking and thus the - tongue 14 are at the contact i5. If, on the other hand, it has already responded at the moment of the blocking, the holding contact 16 is closed, and the closure of the contact 13, which is in series with the latter, causes the relay to stick in the response position, so that the tongue 14 on contact 17 for so long lies until the next throttling has taken place and contact 13 opens. If, according to the invention, the blocking, as shown, still exists beyond the next negative charge on the grid i, a further extension of the control time is achieved.

It goes without saying that to achieve the same threshold as in the example Fig. i the period has to be lengthened, since only three quarters of one Rotation of the disk 6 are available for the actual measurement; for that will however, a considerable amount of time was gained in order to be able to use the contacts 14, 15, 17 to carry out any switching operations and to bring them to an end.

As the previous example shows, with the invention Arrangement shortens the measuring time compared to the period duration. It runs afterwards to the throttling until the moment of blocking, and for the maintenance of a high measurement accuracy, it is only necessary to determine the time span from the Precisely define the charging of the capacitor 3 up to the beginning of the above-mentioned blocking, what practical with the help of clockworks or other timely working organs is easy to achieve. The blocking time does not necessarily need to be to stay constant. It is also not absolutely necessary that the blocking the relay circuit takes place immediately as in the previous example; they can be beneficial can also be brought about indirectly, as the following example shows.

In the example in Fig. 3, the relay circuits are blocked indirectly by switching off the photocell g. That in Ahb. 3 periodic not marked with Organ opens the contact a certain time before the grid becomes negatively charged i9, so that there will then no longer be any significant shift in the grid voltage can, what a blocking of the relay circuits and a retention of the operating state equates to the moment of blocking. The circuit mentioned is above all Things are advantageous when you work with a relatively high frequency should and the measuring time span comprises only about one second or less. The mechanical one Relay 9, which is in series with the electron tube 2, wins during the Blocking time to respond if the anode current is in the tube 2 has started at the beginning of the blocking. This increases operational safety.

According to the invention, the blocking switch is shown in the example in Fig.3 used at the same time to increase the measurement accuracy. The tongue 2o, which opens the contact i9, shifts the potential by closing the contact 21 of the grid i by a certain amount, namely by the potential difference between the points 22 and 23. The shift takes place when the grid i facing away Assignment of the capacitor 3, which via the resistor 24 initially the potential of the point a2 assumed, by closing the contact 21, the potential of the point 23 assumes. It is obviously not necessary in the arrangement according to the invention that the entire negative call charge of the grid must have flowed off via the photocell must, so that the electron tube 2 again leads electricity, but it is sufficient that only a part has flowed off and that Remaining amount less than or equal to the potential difference between points 22 and 23 must be. As a result, the actual measurement takes place in an area of tension, which is still far below the response threshold of electron relay 2. It in this way there are disturbances which are in the vicinity of the response threshold can occur due to positive grid currents and the like, since the grid potential at the moment of blocking, d. H. after completion of the measurement, by leaps and bounds a certain amount is increased and now during the blocking period of the Anode current in the tube: 2 either flows or does not flow, depending on whether the critical brightness threshold was exceeded or fallen below.

The blocking, which in the previous example was switched off the weak current to be measured, d. H. by interrupting the photocell circuit, occurred can of course also be brought about by interrupting the entry of light will. Blocking can also occur due to a negative potential shift of the grid. In many cases, however, it is beneficial to block simply by opening the anode circuit (Fig. 2) or by interrupting or To bring about closure of a secondary circuit, in particular if the negative call charge of the grid of the tube 2 is effected by induction, d. H. after a method in which a temporary positive call charge of the grid and corresponding, very brief anode current surges are unavoidable. Such only Anode current surges caused by the grid charge remain after they occur the blocking according to the invention apparently ineffective. So the invention opens up the possibility of making the call charge of the grid in any way without having to fear malfunctions caused by this.

According to the invention, it is particularly useful in cases where over- or falling below a certain threshold value switching processes in secondary circuits should be triggered, expediently, the relay circuits only briefly or immediately close before blocking. This way, it doesn't just consume a lot of electricity avoided, but also the possibility of using the arrangement according to the invention expanded, which should be explained in more detail using the following examples.

The periodic organ consists in Fig.q. again from a disk 6 with the nose q., which opens and closes the contact 25 once with each revolution. When contact 25 is opened, the assignment of capacitor 3 facing away from the grid assumes the potential of point 27 via resistor 26 and, after contact 25 closes, the potential of point 28. Since the potential of point 28 is more negative than that of point 27, thus the grid is negatively charged by influence in a manner known per se by the potential difference between points 27 and 28. In the present example, too, a photocell 8 is again provided which, as a vacuum cell, supplies a photocurrent that is independent of the operating voltage and strives to eliminate the negative call charge of the grid. In the anode circuit of the tube 2 is the relay 29, the armature 30 of which is able to play between the contacts 31 and 32. The relay circuit, which is blocked in the present case, is the secondary circuit of relay 29. However, it is only closed shortly before blocking by a pin 33, which can be inserted into the holes 34 of the disc 35, the contact 36 for a moment closes. Depending on the position in which the tongue 3o of the relay 29 is at the moment of the closure of the contact 36, either the coil 37 or 38 is excited for an instant and the lever 39 is turned over or held. (The lever 39 can move a switch, a flag, a control device o. The like.) If the closure of the contact 36 takes place only for a short time, then apparently practically no change in position of the tongue 3o of the relay 29 can occur during this period of closure; in particular, after blocking has taken place (opening of the contact 36), a change in the tongue position 3o has no effect on the relay groups 37, 38; since the secondary circuit of the relay 29 is interrupted. The short-term contact of 36 enables a high saving of switching current and the execution of two different switching processes with the help of the two contacts 3i and 32 and the magnetic coils 37 and 38: If, furthermore, according to the invention, by means of the lever 39, the circle of that magnetic coil 37 , 38, which last turned it over, can be interrupted (contacts 40 and 4i), then a current surge only flows when contact 36 closes when the previously exceeded threshold value is again undershot. It has been shown that the blocking used, beyond its original advantages, also allows the protection of contacts and thus an increase in the operational reliability of switchgear systems that are to be controlled with the aid of exceeding thresholds. The arrangement described above is particularly suitable for automatic controls, since the various switching operations can be used to bring about movements in opposite directions and the like. So she is z. B. also for controlling a diaphragm that keeps the light entry to a photocell constant, with the diaphragm movement being transmitted to the control or registration element.

Blocking of the relay circuits, which immediately closes them precedes, allows a further perfection of the arrangement in the direction that several threshold values can be detected at the same time. To explain this Invention serve the Fig. 5. To simplify this example is again a revolving disk 42 indicated as a periodically operating organ. However, it is the circuit leading to the negative. Charging the grid is used for simplicity sake 'not signed. After the negative charging of the grid of the tube 2, which may take place when the disk 42 assumes the position shown, the contacts 44 to 53 are closed one after the other by the circumferential lug 43. One pole of all these contacts is common and belongs to the secondary circuit of the in the anode circuit of the tube: 2 relays 5.4 on. Each of the contacts 44 to 53 represents a stand-alone arrangement according to the invention. It is only the Description of the operation of the contact 46 picked out. If at closing of the contact 46 through the nose 43 the electron relay 2 and thus also the relay 54 has already responded, contact 55 is closed and a current surge flows, the light bulb 56 in the field 46a, which is assigned to the contact 46, light up leaves, which is fed from the battery 57. So the light bulb only lights up then on when the discharge of the capacitor 3 takes place within a period of time, which is equal to or less than the running time of the nose 43 from the position shown to contact 46. Of course, contact 55 is when it closes of the contact 46 was just closed, also when the nose 43 continues to run remain, and the lamps contained in fields 46a to 53a also become light up. The fields 44a to 53a consequently form a scale in which a certain part of the lamps lights up, depending on how quickly the capacitor discharges 3 takes place, d. H. how big the weak current to be determined is. Each contact 44 to 53 is assigned to a certain threshold value, so that, as the example shows, there is the possibility of an arbitrarily large measuring range with one arrangement at the same time, with each field 44 to 53 forming an arrangement for itself, for which the blocking when passing the nose 43 on the associated contact 44 to 53 takes place. For the sake of simplicity, in fields 44a to 53a only Incandescent lamps indicated. It is of course also possible to use the incandescent lamps Equipping delay relays to provide permanent lighting instead of flashing lighting of the excited fields. It's also easy to set up just that the lamp that is closest to the threshold lights up or that by the device according to the invention different switching operations that are of the different thresholds (light intensity) should be controlled.

As a periodically working organs can of course also be Mechanical drives mentioned as advantageous (clockworks, synchronous motors, step holders etc.) electrical arrangements with tilting oscillation and the like can also be used.

Claims (1)

PATENT CLAIMS: r. Arrangement according to patent 523 509 for the exact determination of the exceeding of a threshold value with weak, in particular photoelectric currents, characterized in that the measuring time path is made shorter than the clock period, that the periodically acting organ (clock) a certain period of time before it the grid of the The electron tube is again negatively charged (end of the previous and the beginning of a new clock period), the relay circuits are blocked indirectly or directly and the measuring time segment is thus ended. Arrangement according to Claim i, characterized in that, during the blocking time, the relays are held in the operating state which they assume when they are blocked. 3. Arrangement according to claim i, characterized in that the blocking of the relay circuits carried out according to claim i is only released after the negative recharging of the grid, ie after the start of the new clock period. d .. Arrangement according to claim i, characterized in that the blocking duration is variable, so that a change in the measuring time path is possible with the clock generator period remaining the same. 5. Arrangement according to claim i, characterized in that the blocking takes place indirectly by switching off the weak current (interruption of the photocell circuit, switching off the light, etc.). 6. Arrangement according to claim i, characterized in that during or after the blocking, the grid potential is shifted by a predetermined amount towards positive values. 7. Arrangement according to claim i, characterized in that the closing of the circuits takes place immediately before they are blocked. Arrangement according to claim 7, characterized in that a Morse relay with two secondary circuits is connected in series with the electron relay, which are blocked together. 9. An arrangement according to claim 8, characterized in that the two secondary circuits of the Morse relay actuate a changeover switch (39) which, when it is switched, interrupts the circuit that has to switch it over. ok Arrangement according to Claim 7, characterized in that several circuits are closed and blocked one after the other during one period.