DE1766245B1 - ARRANGEMENT FOR THE CENTRAL REQUEST OF COUNTER STATUS FOR CONSUMPTION METERS - Google Patents

Description

The invention relates to an arrangement for central interrogation of counter readings in the case of consumption meters via a trunk line that is used several times, in which the selection the measuring point via two tone frequencies to be transmitted simultaneously by the control center he follows.

When reading consumption meters remotely via a common line the problem is to transfer the individual meters from a central station to initiate its counter reading. It is necessary to use the meter with a To provide the identifier so that it can be called up from the control center. One The possibility of marking is to give each counter a certain frequency to be assigned, when they are sent by the control center, the transmission of the counter status is initiated. With such a marking, however, difficulties arise insofar as than the polling frequencies must be within the audio frequency band, so that accommodate a maximum of fifteen to twenty different frequencies in this band permit. A larger number of meters to be queried would have to be in districts, groups and subgroups be divided, with a group corresponding to the possible frequencies only fifteen can include up to twenty counters. A larger number of counters can be recorded if two frequencies can be used for identification at the same time.

In a known arrangement for interrogating counter readings, as described in German Auslegeschrift 1259 743, coded switch positions are scanned. The measurement results are thus available at the measuring point in the form of switch positions which are interrogated one after the other with the aid of a measuring point switch, each switch position being communicated to a central measuring point by one of two audio frequencies. The correct transmission of the measured values is checked by a double pulse of both frequencies at the end of the interrogation process.

The aim of the invention is to make the interrogation arrangement mentioned at the beginning to design that a constant control of the measured value transmission is possible, so that every fault is detected immediately and the further transmission of measured values is prevented can be. This is achieved in accordance with the invention for the transmission of measured values a query generator arranged centrally or in a substation is used by gradually turning a selected memory counter forward to reset it causes the memory counter in turn a direct current pulse at each step to the interrogation point and each DC pulse with the help of one at the measuring point provided, operated by the memory counter, the one on a Control part registered current increase on the line causes, can be generated.

At each measuring point there can be several meters for different consumption counts be provided that are to be queried one after the other, each of these consumption meters a memory counter is assigned, which is provided by a counter located at the measuring point, by the two frequencies operated switch from the consumption meter the long-distance line is switchable. The contacts operated by the memory counters is always one that is closed when the counter is reset and when it is in the closed position second contact in parallel causing a strong increase in current on the long-distance line switched. A test facility is provided in the control center or the substation, the line for interference voltages and / or short circuits before interrogation of the first measuring point examined ..

The invention will be explained in more detail with reference to the drawing.

A transformer station 1, which is connected to a measuring center (not shown) via long-distance lines 10, contains a program unit P, a query generator AG, a control part K, a line testing device LP, a tone generator TG, a gate T and a group selector GW with rotary magnets D. .

The program unit P, which can be started by calling frequencies sent out by the control center, controls the individual phases of the query. The query generator AG is switched on by the program unit P and switched off by the control part K. It generates square-wave pulses with a repetition frequency of about 20 Hz, which run on the one hand via gate T and a switch k., And via the group selector GW to measuring point 2, and on the other hand are fed to the measuring center via an amplifier V1 and a switch k1. The control part K controls the impulse transmission while the query is running and monitors all stages involved. This part ensures that, in the event of a fault, the query is interrupted and the tone generator TG is switched on, which reports the fault to the measuring center in the form of a tone frequency signal. The control center is connected to the individual groups of the transformer station 1 via the group selector GW. The line testing device LP has the task of monitoring all group lines of the transformer station 1 for external voltages and line breaks during the time in which there is no query. Monitoring is only carried out when the group selector GW is in the zero position. Group lines lead from the group selector GW to the individual measuring points, of which the measuring point 2 connected to the group selector via a group line 9 is shown in the drawing. At the measuring point 2 there is a gas meter 3 and an electricity meter 4 with a counter 4 a for low tariff and another counter 4 b for high tariff. The counter of the gas meter 3 is assigned a contact y1 to be operated by the counter, while in the electricity meter 4 only one contact y. The tariff changeover takes place with the help of a time switch 5. Each counter of the gas or gas meter. A storage counter Z 1 or Z2 or Z3 is assigned to the electricity meter. The storage counters are formed by ratchet counters or the like, and their excitation coils are located in an electric circuit via contacts y1 or _v12 and changeover contacts u1 or u .. or u. The contacts u, to u. Belong to contact blocks I, 1I and III, which also contain the working contacts a1 and a, or a.3. The contact y., Can optionally be connected to the memory counter Z2 or Z3 via a contact 6 actuated by the timer 5. The contact blocks I to III belong to a measuring point switch MU and are operated by a switching magnet SM . With the help of the working contacts a1 to a. parallel branches to the excitation coils of the storage counters Z1 to Z3 can be established. The parallel branches contain pulse contacts il and i, or i3, respectively, in series with one resistor Ri each, actuated by the memory counters. Resistors Rn are parallel to these branches in series with contacts n1 and n and ya3, respectively. The contact il or i .. or i3 is closed when the armature of the memory counter Z1 or Z2 or Z3 has attracted. The contacts to n3 are only closed when the memory counters Z1 to Z3 are in the zero position.

The switching magnet SM of the measuring point switch MU is connected to the output of an amplifier V., whose input E 1 receives voltage from two audio frequency receiving stages TF1 and TF2 via an AND gate UG. A second input E2 of the amplifier V is connected to the resistor Rn assigned to the memory counter Z3. The audio frequency receiving stages TF1 and TF2 are connected to the group line 9 via a capacitor C.

The query of the measuring point 2, the two specific call frequencies f; and fk are assigned, proceeds as follows. Nine dialing pulses are sent from the measuring center to the transformer station 1, whereby the group selector GW is switched to position 9. In this position, the line testing device LP is switched off and the group line 9 is connected to the facilities of the control center via the switches k1 and k. The measuring center now sends out the double frequency call with the frequencies fi and fk, which reaches the group line 9 and, via the capacitor C, influences the frequency switching stages TF1 and TF2, which are matched to the frequencies f1 and fk. These frequency switching stages operate the switching magnet SM via the AND gate UG and the amplifier V for the duration of the audio frequency call . As a result, the contact block I of the measuring point switch is actuated, that is, the contact u1 changes from position 2 to switch position 1, and the normally open contact a1 is closed. The storage counter Z 1 is now separated from the contactor y1 of the gas meter 3 and connected to the group line. The measuring point 2 is now prepared for the query.

The double frequency call also started the program unit P in the transformer station 1, which initially switches the contacts k1 and k to position 2. The amplifier V1 controlled by the query generator AG and the tone generator TG are thus connected to the line 10 leading to the control center. In addition, the gate T is connected to the memory counter Z 1 via the contact k1 and the group line 9. The program unit P starts the query generator AG, which opens the gate T and closes it. When gate T is open, a circuit is closed from the positive pole of the voltage source via control part K, gate T, changeover contact k. " Contact arm of group selector GW, group line 9, changeover contact u1, storage counter Z1 to ground. The current flowing in this circuit pulls The armature of the storage counter Z1 closes. This closes the contact il, which connects the resistor Ri in parallel with the magnet of the storage counter Z1 If the current increase is absent, control part K immediately switches off the query generator AG and prevents the next and all subsequent counting steps. In addition, control part K then switches on the tone generator TG , which reports the fault to the control center by emitting a tone frequency signal. If a line break occurs during the query , no current flows when gate T is open . This malfunction also leads to the abortion of the transmission with a subsequent malfunction report to the control center. In both cases of malfunction, no pulse is lost because the query is interrupted immediately. This secure transmission of measured values is only possible because the measuring point 2 has a passive character as a result of the central query generator AG.

The voltage pulses generated by the query generator AG , which on the one hand control the gate T, are on the other hand fed to the amplifier V1, which amplifies them and converts them into current pulses. These current pulses reach the receiving device of the control center via the telecommunication line 10, from which they are counted. The memory counter Z 1 is switched forward to zero, so that the number of transmitted pulses represents the complement of the true counter reading. The true totalizer reading is obtained by taking the complement of the transferred value. The complement formation in the control center can be done, for example, by running the counting levels backwards.

The first pulse generated by the query generator AG and arriving at the control center is a pre-pulse which confirms to the control center that the memory counter Z1 has been called up for interrogation. The pre-impulse opens a gate connected upstream of the counter in the control center. The pre-pulse is important in the event that the memory counter is in the zero position, i.e. no transmission takes place. The control center would have no confirmation as to whether the memory counter Z 1, Z 2, Z 3 was called and is in the zero position or a fault, e.g. B. line short circuit exists. Only the second and all further pulses are counted.

When the memory counter Z1 has reached its zero position, the contact n1 is closed as a result. The resistor Rn is connected in parallel to the magnet of the memory counter Z1 by the contact closure of n1. The resistor Rn is dimensioned so that the current flowing through the group line rises sharply when this resistor Rn is switched on. In the control part K, this strong increase in current is registered as a counter zero setting. The control part K thereby switches off the query generator AG . Then the program unit P returns to the starting position and switches the contacts k1 and k back to position 1. The device is now ready to query memory counter Z2. The central station again sends out the call frequencies f1 and fk, which move the measuring point switch MU to another switch position. In this switching position, the switching magnet SM in contact block II has switched the contact uz to position 1 and closed the normally open contact a2. The memory counter Z2 is queried in the same way as that of the counter Z1. If the counter Z2 has reached the zero position, then by repeated transmission of the frequencies f; and fk counter Z3 brought to the query. If this has reached its zero position, the contact n3 is closed, whereby the input E2 of the amplifier V2 is connected to the group line. The still following last interrogation pulse controls the amplifier V2 via the input E2, whereby the measuring point switch MU returns to the zero position and separates the memory counter Z3 from the group line. The query of the measuring point 2 consisting of the three memory counters is thus completed.

Claims (6)

Claims: 1. Arrangement for central interrogation of meter readings in consumption meters via a multiple-use trunk line, in which the selection of the measuring point takes place via two tone frequencies to be emitted simultaneously by the central unit, characterized in that a centrally or in a substation (1) is arranged for the transmission of measured values Inquiry generator (AG) is used, which causes a selected memory counter (Z 1, Z 2, Z 3) to be reset to zero by step-by-step forward rotation, the memory counter (Z1, Z2, Z3) in turn sending a direct current pulse to the interrogation point at every step and every direct current pulse with With the help of a contact (il, i2, i3) provided at the measuring point (2) and operated by the memory counter (Z1, Z2, Z3), which causes a current increase on the line registered at a control part (K). 2. Arrangement according to claim 1, characterized in that at each measuring point (2) several counters (3, 4) can be provided for different consumption counters, which are to be queried one after the other, each of these consumption meters (3, 4) having a queryable memory counter ( Z1, Z2, Z3) is assigned, which can be switched from the consumption meters (3, 4) to the long- distance line (10) by a switch (MU) located at the measuring point (2) and operated by the two frequencies. 3. Arrangement according to claim 1 and 2, characterized in that that in each case the contact actuated by the memory counter (Z1, Z2, Z3) is on Zero setting of the counter closed, in the closed position a strong increase in current Second contact (n1, n2, n3) acting on the long-distance line connected in parallel is. 4. Arrangement according to claim 1 to 3, characterized in that a test device (LP) is provided in the control center or the substation, which examines the line for interference voltages and / or short circuits before interrogating the first measuring point. 5. Arrangement according to claim 1 to 4, characterized in that a tone generator (TG) is provided which is switched on in the absence of an increase in current on the line. 6. Arrangement according to claim 1 to 5, characterized in that the first pulse supplied by the query generator (AG) serves as a pre-pulse not counted in the center (acknowledgment pulse) which opens a gate (T) connected upstream of the counter present in the center, and that the last pulse of the query generator (AG) counted in the control center serves as a test pulse for the closed position (zero position) of the n-contact (n1, h2, n3) in the measuring point (2).