DE654497C - Directional counting device with photoelectric control - Google Patents

Description

Direction-dependent counting device with photoelectric control The invention relates to a direction-dependent counting device with photoelectric Control for objects moving on a fixed route. the Arrangement according to the invention works such that the objects one after the other Illumination of two closely spaced photoelectric cells affect which in turn control two counters, so that when passing the photoelectric Cells in one (main) direction both counters (main and auxiliary counter) respond, while when passing in the other (opposite) direction only the main counter comes into action. So you can z. B. by compiling the two counter information determine how many people etc. through the control body a locked one Have entered the room, how much has left it and how much is in it.

Now there is a counting device for shunting operations of railway vehicles became known that the passing cars separated in both directions allowed to count. With this arrangement, however, one is on the presence of one metallic railroad, i.e .: h. it is only for rail vehicles usable. Furthermore, the rail track must have rail sections that isolate from each other that are exposed to the weather and can therefore easily become dirty. Finally the system works with a larger number of electromagnetically controlled ones Relay and is therefore exposed to various types of interference. In contrast, the counting device according to the invention not only for counting rail vehicles, but can also be used for any other objects or people. There are no mechanical relays exposed to damage or contaminants Schin contacts necessary, rather it is an advantage of the device according to the invention, that apart from the two counters, it works without any mechanical relay.

However, a photoelectric counting device has also become known, which works independently of a railroad and by darkening two tightly neighboring photoelectric cells is controlled; however, it can only use the in Objects or people passing in a main direction count those in the opposite direction passing by, however, not. Finally she works with mechanical switching devices.

Finally there is a photo-electrically controlled counting device became known to identify vehicles or objects, the are located in the space between two passages, with their entry direction is indifferent to the two passages. However, this device can only be determined be how many people are between the two at a certain time Stopping passages, for example in a tunnel. However, she does not allow the determination of how much got into the space and how much got out of it are.

The invention now relates to a further development of a known photocell circuit, in which a photoelectric cell controls the grid of a discharge vessel in such a way that that resistors, which are in the anode circuit of the discharge vessel, with the help of different voltage drops with exposed and unexposed cells Control the grid of a gas discharge vessel so that it is released and a Relay switches or is kept blocked by a blocking potential.

According to the invention in such or a similar circuit a directional dependence obtained by a capacitance resistance coupling with a sufficiently large time constant between your anode circuit and a counter belonging auxiliary discharge vessel and the grid of a further counter (Auxiliary counter) belonging discharge vessel is provided, which causes at Blackout address both meters in one order, in the case of blackout in reverse On the other hand, the sequence is the anode current of the discharge vessel belonging to the auxiliary meter is throttled so that it does not count the darkening.

An arrangement has already become known in which the time which needs the negative charge of a capacitor connected to a control grid, to flow through an exposed photocell is compared with the time that to drain a corresponding control grid charge through a large resistor is needed. However, the known arrangement works in contrast to the one according to the invention Device so that the first-mentioned control grid is discharged via the photocell the faster it happens, the greater the illuminance of the photocell, so that the blocking time of the control grid is used as a measure of the illuminance will. So it is a completely different task, which is also supported by one of the different arrangement according to the invention is solved.

The principle of the counting device according to the invention is shown in Fig. i in the top = sees shown, for example at the entrance to a meeting room, while in Fig. z the circuit diagram of the connections from the photoelectric cells is reproduced up to the counters.

In Fig. I, i and a signify barriers between which visitors are located move in the main direction when entering and in the opposite direction when exiting. Outside at the left barrier is a light source, e.g. B. a headlight, attached, from which, in a known manner, two cones of light 4 and 5 through sections of the two Barriers at a suitable height on two photoelectric cells 7 and $ fall as long as no one crosses the barriers. When walking through in the main direction will in a known manner first light beam 4, then interrupted light beam 5, then Light beam 4 released again and then light beam 5. When going through in in the opposite direction, the light beams are naturally interrupted in the opposite direction Series. Each of the two photoelectric cells controls a counter, whereby the circuit is made so that when the cells are darkened in the order 7, 8 address both counters, while in the case of blackout in the order 8, 7, d. H. So when moving in the opposite direction, only the counter of cell 8 (Main counter) responds, while the counter of cell 7 (auxiliary counter) is unaffected remain. Thus, the main counter counts the people entering and leaving, the auxiliary counter on the other hand only the people entering. By forming the difference between the counter readings, the number of those who went out and thus also the number of those who remained in the room Identify people.

Of course, the device is not only used for counting meeting visitors applicable, it can also be applied analogously to any other counting processes will. for example on the counting of transports on conveyor belts, the passing of vehicles on roads, bridges, etc.

Fig. 2 gives the circuit arrangement between the photoelectric Cells 7 and 8 and the counters 35 and 42 controlled by these again, with 42 is the main and 35 is the auxiliary counter. Like a general overview can be seen from the circuit diagram, the arrangement shown has a special one The advantage is that no mechanically moving masses such as relays, levers or the like are required apart from the two counters themselves, of course.

A transformer io with its primary winding ii is connected to the alternating current network 12. A secondary winding 15 feeds two series-connected resistors 23 and 24, with which a grid-controlled discharge vessel 2o is connected in series. Parallel to the resistors 23 and 24 there is a photoelectric cell 7 in a manner known per se, such that its anode is connected to the cathode of the discharge vessel 2o, while its cathode is connected to the connection between resistor 2, 4 and winding 15 via a series resistor 2i lies. The grid of the discharge vessel 2o is connected to the connection point of the cathode of 7 with the series resistor 21. A smoothing capacitor 22 is located parallel to the branch 7, 21 of the photoelectric cell. A second secondary winding 16 is connected in a corresponding manner to a discharge vessel: 28, a load resistor 31, a photoelectric cell 8 and a series resistor 29 and smoothing capacitor 30 . The ends of the winding 16 are also bridged by a potentiometer 50 with sliding contact 51. The end 32 of the resistor 31 connected to the cathode of 28 is connected to the end of the adjacent resistor 24, which is connected directly to the transformer winding 15.

When the cell 8 is exposed, a strong anode current flows through the discharge vessel 28 if the proportions of the resistors 29 and 31 are correctly selected (for example capacitor 30 equals one microfarad, resistor 29 equals 10 megohms, resistor 31 equals 50,000 ohms). As a result, a relatively large voltage drop forms across the resistor 31, so that its end 33 has a strongly negative potential compared to the end 32. If the exposure of cell 8 is interrupted, the resistance of the cell becomes practically infinite, and the grid takes on a more negative potential than the cathode in discharge vessel 28, corresponding to the changed voltage distribution in branches 29, B. As a result, the passage of current through vessel 28 becomes strong throttled and depressed to a small amount. The voltage drop in resistor 31 therefore now drops to a negligible amount. This type of circuit for photoelectric cells is known per se.

Exactly corresponding conditions prevail in the circuit of the discharge vessel 20, where, for example, the resistor 21 may also have an amount of 10 megohms, each of the resistors 23 and 24 may have a value of 20,000 ohms and the capacitor 22 may have a capacitance of one microfarad. When the cell 7 is exposed, the discharge vessel 20 has a relatively strong current flowing through it, which generates voltage drops in the resistors 23 and 24 that are so great that their left ends are noticeably negative compared to the right ends. On the other hand, when the photocell 7 is darkened, the anode current is also here as a result of the lowering of the grid potential with respect to the cathode in the discharge vessel 2o. strongly throttled that the potential differences across the resistors 23, 2-. practically disappear.

The transformer i i has a further secondary winding 1.4 which the main counter .42 in series with a suitably selected resistor 4.1 and a gas discharge vessel 4o is connected in such a way that the anode of the discharge vessel on the winding 1: 4, the cathode, however, is on resistor 4.1. The grid of the Discharge vessel .4o is via a limiting resistor 49 to the sliding contact 51 connected by potentiometer 5o.

A fourth secondary winding 17 of the transformer io finally feeds Via the gas discharge vessel 36, the auxiliary counter 35, the cathode of the vessel on the winding 17 and its anode on the counter 35. The winding 17 is also bridged by a potentiometer 37,. its sliding contact 38 with the end 25 of resistor 23 is in connection.

A parallel circuit 43 is connected to the resistor 41, consisting of from a resistor 4..4 in series with a sufficiently large 'capacitor 4.5. The sizes of resistance and capacitance are chosen so that the charge circuit 43 has a sufficiently large time constant.

At the connection between resistor 4.1 and capacitor .45 is a line 46, which leads to the end 26 of the resistor 23, is connected. Finally is the grid of the discharge tube 36 via a limiting resistor .48 and Line 4.7 connected to the connection point of resistor .44 and capacitor 4.5.

The grids of the discharge vessels are provided by the connections described above 36 and 4.o in the counter circuits of the counters 35 and .42 their bias from the circles of the discharge vessels 2o and 28, so that these are referred to as the control circuits of the former can be. If the compounds mentioned are followed, the result is for the discharge vessel 36 that the cathode is at point 25 via potentiometer 37 and sliding contact 38, while the grid via the limiting resistor 48, connecting line, 47. branch '-44 - 41 is at 46 and thus at point 26. In other words, the potential difference at the ends of the Resistance a3 determines the bias of the grid, with appropriately set contact 38 on potentiometer 37. Under certain operating conditions one can also assume that the cathode has 37, 38, 25, 23, 26, 46 on the right Occupancy of the capacitor 45 is, while the grid 48 and 47 to its left Assignment is connected.

In the case of discharge vessel 40, the cathode is connected via connecting line 46 connected to point 26, while the grid via limiting resistor 49, contact 51, potentiometer 5o is at point 33. The grid bias is therefore due to the Voltage drop across resistors 3z --- 24 is determined.

Let us now examine the processes that take place when a person passes through the barrier in the main direction, these being considered in the various phases of passage for the sake of clarity. z. Section The passer-by is in the position shown in Fig. Z: light beams 4 and 5 are still undisturbed. As a result, according to what has been said earlier, both discharge vessel 2o and discharge vessel 28 let current through vigorously, so that voltage drops occur at resistors 23, 24 and 31 such that the left ends are negative compared to the right ends.

The voltage ratios of the discharge vessel 40 are therefore as follows: the cathode is positive against the grid, by the voltage increase in resistors 31 and 24, reduced by the oppositely acting voltage increase in potentiometer 5o, which is selected so large by means of contact 5 z that there are none Discharge takes place through the pipe 4o. Accordingly, the circuit in the main counter circuit is blocked, the main counter 42 is stopped. On the other hand, the voltage conditions in the discharge vessel 36 are such that the cathode is positive against the grid by the voltage increase in resistor 23, this voltage increase being increased by the amount of the voltage increase tapped in potentiometer 37. Let the contact 38 be set so that no discharge can take place through the vessel: The auxiliary counter circuit is blocked, auxiliary counter 35 is stopped the current through the tube 2o is throttled down, while 28 still lets a strong current through. The voltage conditions in discharge vessel 40 are as follows: Since resistor 24 is now practically currentless, point 26 has practically the same potential as point 32; is reduced by the voltage drop in resistor 24. The tube 4o can therefore respond and set the main counter 42 in motion.

With regard to discharge vessel 36, it should be noted that resistor 23 is practically currentless, that is to say point 25 has practically the same potential as point 26. The positive potential difference between the cathode and the grid is therefore reduced and only equal to the voltage drop across the potentiometer. Here, too, the discharge in tube 26 can start and the auxiliary counter 35 can start up. - However, this condition does not last long. The voltage drop across the resistor 41 through which current flows namely charges the capacitor 45 in such a way that its right-hand assignment is positive and its left-hand one is negative. The charging rate is determined by the branch 43 time constant. . As a result, the grid that is on the left capacitor assignment gradually becomes more negative than the cathode that is connected to the right assignment, until, after a period determined by the size of the time constant, the discharge vessel 36 blocks the current again and the auxiliary meter 35 with it comes to a standstill. 3rd section of the beam, 4 and 5 are interrupted, cells 7 and 8 are darkened. As a result, the anode currents of the discharge tubes 2o and 28 are throttled down.

The voltage ratios at discharge vessel 4o are as follows: Da the resistors 24 and 31 are practically currentless, the cathode has the potential received from point 33. The grid, on the other hand, retains the potential of contact 5 i: So it's strongly positive to the cathode. The tube 4o therefore remains in Operation and main counter 42 in progress.

The condition of the tube 36 is as follows: The voltage ratios at resistor 23 are unchanged, as are those at resistor 41 and Capacitor 45. Since its charging has now ended, the grid of the discharge vessel has 36 reached such a strong negative bias that the discharge vessel no longer works and the auxiliary counter 35 has come to a standstill. 4. Section light beam 4 is undisturbed, but beam 5 interrupted; Cell 7 irradiated, cell 8 darkened; Discharge vessel ao works fully again.

Grid bias in tube 40: Point 33 is around the voltage drop in resistor 2.4 more negative than point 26. The grid voltage is therefore positive the voltage rise at the potentiometer 5o, reduced by the voltage drop in the resistance 2d .. So it is larger than in the second section. The result is the tube 40 is still working and the main counter 42 is in motion.

With regard to the discharge vessel 36, the same voltage conditions now exist as in the first section; the tube 36 blocks the current, the auxiliary meter remains in peace. 5th section beam q. and 5 are free again, cells 7 and 8 are irradiated. The same conditions exist as in the first section. Block tubes 40 and 36 the electricity, main and auxiliary meters are at a standstill.

If one summarizes this consideration, it follows that with the beginning of the second section, the discharge vessels 36 and 4o address simultaneously. The blocking effect of the capacitor 45 on the circuit of tube 36 cannot occur immediately, but only after a certain amount of the time constant of the circle 4.3 dependent time, approximately at the end of section 2, at the latest in the course of section 3. During this time the auxiliary counter advances one step. The discharge tube 4.o, on the other hand, remains in operation considerably longer, namely until the end of the fourth Section, during which time the main counter also moves one step further counts.

However, if one reverses the irradiation processes in their order, d. H. if you let a person cross the barriers in the opposite direction, so According to the foregoing, the current in the circle of the discharge vessel 36 cannot at all first come to flow, because there is so much current in the circle of the tube has used earlier that despite the delaying time constant of the capacitor 45 is already sufficiently charged and thus exerts its blocking effect as soon as by interrupting the light beam d. the discharge tube 2o throttled down and as a result, the discharge of the tube 36 could begin.

So you can see that through the sequence of the interruption processes on the rays of light q. and 5 actually a directional dependency of the auxiliary counter is achieved, essentially through the action of the branch 43 or the Capacitor 45. The directional dependence is in fact, as it was at the beginning noticed, achieved while avoiding any mechanically moving parts. .

Claims (1)

PATENT CLAIM: Direction-dependent counting device with photoelectric Control for objects, people or the like moving on a defined path, in which these successively illuminate two closely spaced photoelectric cells and these in turn affect two counters, in such a way, that the two photoelectric cells control the grid of two discharge vessels in such a way that that resistors, which are in the anode circuit of the discharge vessel, with the help of different voltage drops with exposed and unexposed cells Grids each of a gas discharge vessel that feeds the counters when the cell is illuminated issue a blocking potential, while the voltage drops when the cells are darkened the resistances and thus the blocking voltages on the gas discharge vessels are reduced that the anode currents used can switch the counters upwards, characterized by a capacitance resistance coupling (4r, d.3) with sufficient large time constant between the anode circuit of the main counter (42) Discharge vessel (¢ o) and the grid of the auxiliary counter (35) belonging discharge vessel (36), which has the effect that when the in. the order: cell (7), cell (8), Address the main and auxiliary meters, in the case of blackout in reverse order: cell (8), cell (7), on the other hand, the anode current of the discharge vessel (36) is so throttled is that the auxiliary counter (35) does not count the darkening.