DEP0052880DA - Method for evaluating one or more sequences of electrical impulses in relays controlled by these, in particular in use for counting purposes, for example for axle counting in railway safety systems - Google Patents

Description

The invention is based on a method which involves evaluating one or more sequences of electrical pulses in the setting of electrical relays brought about by these pulses. This method, carried out with the aid of relays, is intended to be carried out in contrast to an evaluation of such pulses in stepping mechanisms or other actuating mechanisms of a mechanical nature, which are more or less subject to inertia with regard to their response time. Among other things, it is important to avoid this inertia by using sensitive and quickly responding relays as setting elements, so that pulses of high frequency can be detected and no larger masses need to be actuated, which also require an increased setting force .

It is already known per se to record series of pulses in relay memories. In the simplest type of relay memory of this type, a special relay is required for each individual pulse to be evaluated, which leads to an uneconomical relay effort with a large number of pulses. For this reason, it has already been proposed to build relay memories in which the relays are combined into groups. This results in a considerable saving in relays, because such a group-wise multiple use of the re- lais becomes possible. If, for example, the relays are combined in p groups of a elements each, then a (exp) p pulses can be recorded or counted, while with a simple relay arrangement, as already mentioned, as many relays are required as the pulses are evaluated or counted should.

In contrast, the object of the invention is now to further reduce the need for relays in comparison to the group-based relay combination, and indeed to an actually minimal relay outlay. This is achieved according to the invention in that the relays are switched in such a way that their successive response takes place using all mutually possible combinations of the positions of the relays, so that by means of x relays at n different positions, n (exp) x pulses with just as many resulting different Record relay position combinations and have them evaluated (0 position of the relay arrangement, namely pulse 0, included).

The relay circuit required for this method is expediently set up in such a way that each relay that responds in the pulse sequence repeats the previous relay position combinations for the following pulses before another relay in the relay series responds again. An increase in occupational safety can also be achieved in that the alternating switching of the main relays, which detect the series of pulses in a specific combination of settings, is effected by means of auxiliary relays assigned to these relays.

The invention is explained with its further details and their possible applications in the following on the basis of exemplary embodiments, specifically when using relays with only two operating positions, namely the rest position and the working position. Show it

Fig. 1 shows the circuit structure of a relay arrangement of the invention when, for example, only four relays are used.

FIG. 2 is a tabular representation of the mode of operation of the relay arrangement according to FIG. 1,

3 shows the circuit structure of an arrangement likewise consisting of four relays using auxiliary relays assigned to the main relays,

Fig. 4 shows the application of the relay arrangement according to FIG. 2 for automatic comparative counting evaluation, e.g. for axle counting in railway safety systems.

In the figures, A, B, C and D denote the main relays, which are referred to as counting relays because the circuits shown are intended to be used for counting purposes, for example. i is a pulse contact that sends the pulses to be evaluated in the circuit or the incoming series of pulses to this circuit. This contact i is controlled by any pulse generator (not shown) located at the counting point. The small letters a (sub) 1, a (sub) 2, b (sub) 1, b (sub) 2, b (sub) 3, c (sub) 1, c (sub) 2, c (sub) 3 and d (sub) 1, d (sub) 2, d (sub) 3 are the contacts associated with relays A, B, C, D.

The circuit according to Fig. 1 now works as follows:

When the 1st pulse is triggered, the contact i closes the circuit l (sub) 1 coming from the positive pole. Relay A receives voltage via contact a (sub) 2. It attracts and then holds itself with its closed contact a (sub) 1, which also leads to the positive pole via line l (sub) 2. Contact a (sub) 1 and contact a (sub) 2 are follow-up contacts that work in such a way that contact a (sub) 2 is only actuated after the self-holding contact a (sub) 1 has closed. In the meantime the pulse contact i has opened again. Contact a (sub) 2 is a changeover contact and changes its position accordingly when relay A responds. This prepares the circuit of relay B for the 2nd pulse. After the 1st impulse, relay A has picked up.

When the 2nd pulse is triggered and contact i closes again, relay B receives voltage via the transferred changeover contact a (sub) 2. It picks up and in turn holds itself again via the self-holding contact b (sub) 1. The changeover contact b (sub) 2 automatically prepares the circuit for the next pulse. The contact b (sub) 3 also brings the relay A to drop out again during its switching time. After the 2nd impulse, relay B picked up.

The processes described are then repeated accordingly for the subsequent pulses, ie after the 3rd pulse, relays A and B have picked up, after the 4th pulse only relay C has picked up, after the 5th pulse relay A and now has again relay C picked up, etc.

In FIG. 2, the relay operating diagram, as it corresponds to FIG. 1, is shown in tabular form for four relays A, B, C, D, starting with the pulse 0. The number of pulses is noted in the first horizontal column. In the vertical column below that corresponds to each pulse, it is also indicated which of the existing relays is under current i t for the pulse in question and which is not. The energized relay in the attracted position is indicated by a diagonal cross and the relay in the rest position, i.e. not energized, by an empty table field. 2 clearly shows that all possible relay position combinations occur one after the other with a certain regularity and a new relay in the relay series only responds when all previous relays have previously carried out all possible response combinations with each other, with the Relay series all previous relays have been switched off. Since the relays are assumed to have two working positions, namely the rest position and the response position, there are 16 relay position combinations according to the table in FIG (the pulse 0 and the 0 position of the overall combination are included). With just four relays, 16 pulses can be evaluated or counted according to the formula n (exp) x given above, where n = 2 means the number of positions of the individual relays and x the number of relays available. In this way, for example, with just 10 such relays in no less than 1024 different relay position combinations that can be achieved, just as many pulses can be recorded and evaluated or counted; because 2 (exp) 10 = 1024. With a simple relay arrangement one would need 1024 relays for this purpose and with a group-wise relay combination of the type already proposed one could at least record 32 to 36 counting pulses with 10 relays depending on the selected group subdivision. In contrast, the invention brings a relay saving that exceeds all expectations.

The practical implementation of the circuit according to FIG. 1 makes special demands on the closing and opening times of the relay contacts and their timing of actuation. This sensitivity can be avoided if the circuit according to FIG. 1 is supplemented in such a way that an auxiliary relay is assigned to each main relay acting as a counting relay. In this case, follow-up contacts and certain defined pulse times can be dispensed with.

One of the circuit arrangements possible in this way is shown in FIG. In this circuit, the contact i (sub) e controlled by the pulse generator is now a changeover contact that is switched from the rest to the working side with each pulse, which is there for a certain time and then returns to its rest position. In the circuit according to FIG. 3, the relays A, B, C ..... are the main relays known as counting relays, while the relays A (sub) h, B (sub) h, C (sub) h .... . the auxiliary relays are. L (sub) a, L (sub) b, L (sub) c are lamps that are used as series resistors in the holding circuit of the counting relay. They also serve to display the counted pulses. If one quantifies the lamps as follows, for example: L (sub) a = 1, L (sub) b = 2, Lc = 4 ....., then the sum of the lamps lit directly indicates the number of pulses to be counted that are on the circuit can be brought into action. In detail, the circuit according to Fig. 3 works as follows:

First of all, all relays have dropped out. When the 1st pulse is triggered, the contact i (sub) e moves to the working side (left position in FIG. 3). The auxiliary relay A (sub) h receives voltage from the positive pole. It picks up and holds itself through its normally open contact a (sub) h2 and its holding winding. Furthermore, it prepares the counting relay A with its contact a (sub) h1. After the pulse contact i (sub) e has been returned to its rest position, as shown in FIG. 3, the relay A receives voltage. It now also picks up, holds itself through its holding winding and its changeover contact a (sub) 1 and thereby causes its auxiliary relay A (sub) h to drop out. During this switching process, contact a (sub) 2 of counter relay A also prepares the response for the next auxiliary relay B (sub) h. After the 1st impulse, relay A has picked up.

With the 2nd impulse, the contact i (sub) e is switched back to its working position. This means that the auxiliary relay can now

Address B (sub) h. It holds itself again via its holding winding and holding contact b (sub) h2 and prepares the counting relay B with its contact b (sub) h1 and also causes relay A to drop out. If the pulse contact i (sub) e then resumes its illustrated rest position, the relay B can now respond. It holds itself through its holding winding and its contact b (sub) 1 and causes its auxiliary relay B (sub) h to drop out and also prepares the auxiliary relay C (sub) h for the next pulse with its contact b (sub) 2. After the 2nd impulse, relay B is activated.

As with the 1st pulse, the auxiliary relay A (sub) h picks up again with the 3rd pulse and then its main relay A. As a result, the auxiliary relay A (sub) h drops out again, so that after the 3rd pulse both Relay A and relay B are energized. In the manner shown, the switching processes repeat themselves analogously with each further pulse. The response sequence of the main relays A, B, C ..... takes place exactly as it corresponds to the table of FIG.

The circuits according to Figs. 1 and 3 can be used, for example, for simple counting of the number of pulses in a series of recorded pulses. However, it is also possible to use the inventive method with the circuits for an automatic count comparison, in particular in such a way that it is determined whether two or more pulse trains have the same number of individual pulses or not, without the number of pulses being important to be recorded in their absolute value in detail. The last-mentioned task exists, for example, when it comes to determining whether certain individual elements pass two or more places in the same number or whether there are differences in this regard. This can be important for automatic production controls, e.g. in assembly line production. But this comparison method is also important for any other cases.

For these purposes, the circuit according to the invention is of particular importance not only because of its independence from strongly changing pulse frequencies, but above all because with a very large number of pulses due to the utilization of all combinations of the possible relay positions with an extraordinarily minimal relay effort gets by. As a particularly preferred area of application for the method according to the invention is to be called axle counting in railway safety systems. In this case, a block vacancy message may only be issued if the same number of carriage axles that entered the opposite station have left the block section again, whereby the absolute number of axles is irrelevant. This automatic counting comparison can be achieved if an identical relay memory of the specified type is assigned to each counting point, which has already been proposed for relay memories with group-wise relaying. If you place a contact of the relays used in a dependency circuit, you can trigger a display on which this method is based if the pulses counted at two or more points, which are electrically triggered by each passing carriage axle, do not match, in the manner explained below .

The principle of such a circuit arrangement emerges from FIG. The relay circuits serving as counting-in memories EZ and the counting-out memories AZ correspond to one another and are to be constructed, for example, analogously to the arrangement shown in Fig. 1 or 3. The lower circuit part VZ includes those additional circuit elements from the two relay memories EZ and AZ, which are used to trigger the comparison display. These switching elements are essentially relay contacts which, in series or parallel to one another, control a circuit in such a way that a special display trip relay C or a relay H is excited or not.

The contacts a (sub) 3, b (sub) 3, c (sub) 3 ..... in the circuit part VZ of the circuit according to FIG. 4 which carries out the count comparison are contacts of the relays A, B, C .... in the counting-in memory EZ or counting-out memory AZ; the contacts a (sub) h3, b (sub) h3, c (sub) h3 ..... are contacts of the auxiliary relays A (sub) h, B (sub) h, C (sub) h ..... , also in the count-in and count-out memory EZ or AZ. These contacts of both memories are connected in series in the display circuit in such a way that display relay C is activated when all relays are in the rest position. At the start of counting, the first counting pulse, as explained above with reference to Fig. 3, causes the relay A (sub) h of the count-in memory to pick up, depending on where the counting pulse is output. is resolved. By opening the corresponding contact a (sub) h3 of the counting-in or counting-out memory, the relay G then drops out and this relay remains dropped out as long as the counting continues. It should be mentioned that it is possible to count in both counting points simultaneously and independently of one another. Only when the count values recorded in the count-in memory and those in the count-out memory match, the relay H receives voltage, picks up and thereby causes the display relay G to respond with its contact h (sub) 1. The contact h (sub) 2 de-energizes the count-in and count-out memories. The relay C holds itself through its contact g (sub) 1. The relay H has dropped out again by switching the contact g (sub) 1 and prepares the counting-in and counting-out memory for a new one by closing its contact h (sub) 2 again Compliance check before. Depending on its position, contact g (sub) 2 provides information about the respective operating status of the two counter values to be compared at the existing counting points.

Claims (6)

1.) Method for evaluating one or more sequences of electrical impulses in relays controlled by these, which are actuated in succession according to the number of impulses according to a certain regularity, in particular in use for counting purposes, for example for axle counting in railway safety systems, characterized in that the relays ( A, B, C, D, .....) are switched in such a way that their successive response takes place using all mutually possible combinations of the positions of the relays, so that by means of x relays at n different positions n (exp) x pulses with the same number of resulting different relay position combinations can be recorded and evaluated (including the 0 position of the relay arrangement, namely pulse 0). 2.) Arrangement for performing the method according to claim 1, characterized in that the relay circuit is constructed in such a way that each newly responding relay in the pulse train can repeat the previous relay position combinations for the following pulses before another relay in the relay row responds again (Fig . 2). 3.) Arrangement according to claim 1 and 2, characterized in that the alternating circuit of the main relay (A, B, C, D .....) detecting the pulse series in a certain setting combination by means of these relays assigned auxiliary relays (A (sub) h, B (sub) h, C (sub) h, D (sub) h, .....) is effected (Fig. 3). 4.) Arrangement according to claim 1 and 2 for comparing different series of pulses for correspondence, characterized in that two or more identical relay circuits (EZ, AZ) operating according to the combination principle according to claim 1 or 2 are used, in which contacts are in the Relays corresponding to individual circuits are combined to form a common circuit system (VZ) in such a way that a test circuit is only closed in this circuit if the relay circuits are set to match (FIG. 4). 5.) Arrangement according to claim 1 to 4, characterized by the use of relays working with two working positions (a rest position and a response position), so that x relay 2 (exp) x pulses in as many different relay positions Record and evaluate solution combinations (including pulse 0 and the rest position of the relay arrangement). 6.) Arrangement according to claim 1 to 4, characterized in that each main relay of the relay series (A, B, C, D .....) in a holding circuit is assigned a contact of the next main relay or its auxiliary relay so that it is only When this next following or one of the following main or auxiliary relays is triggered, it drops out, but remains when it is triggered again, if the next following relay or relays remain energized, and that there is also one in the course of the series of pulses A new main relay that has not yet been actuated, possibly with associated auxiliary relays, only responds when all previous relays that have already been actuated are energized at the same time, this newly energized main relay then making all previously actuated relays de-energized.