DE1055616B - Circuit arrangement for determining electrical faults in switching networks of telecommunications switching systems - Google Patents

Description

GERMAN

PATENT OFFICE

ICL. 21a ³ 68/30

INTERNAT. KL. H 04 St.

S 50569 VIIIa / 21a ³

REGISTRATION DATE: SEPTEMBER 27, 1956

NOTICE
THE REGISTRATION
AND ISSUE OF THE
EDITORIAL: APRIL 23, 1959

The invention relates to a circuit arrangement for determining "electrical" faults in switching networks of telecommunications switching systems.

It is known to detect defects in components or to monitor components in electrical devices, in particular also in messaging equipment, one Provide test tube, for example an amplifier tube, the grid voltage level of which by the proper Operating state of the components to be monitored, voltages or currents characterizing is determined. The test tube is used to carry out the test on each individual component switched on during operation. The detection of electrical errors in coupling fields can be based on this Way not carry out ', <since in this case the switching network to be tested from its operating state in a special test condition is to be brought. The test state must be ended as quickly as possible so as not to slow down the operation noticeably.

In telecommunication switching systems, the coupling relays used generally become coupling matrices summarized. These coupling fields consist of longitudinal and cross-connections, the so-called Columns and rows, which together are referred to below as setting cores «. As a coupling relay Relays with an adjustment winding and a holding winding are usually provided. The coupling relays keep yourself in the c-core over the said Holding windings, while the setting windings of the coupling relays each with a row and a column of the Switching network is connected. So become one line and a column of a switching matrix to voltage, applied, this will energize the relay connected to these setting wires.

It has now been shown that it is inexpedient to switch field «·, which is derived from the lines described and Columns exist, to be monitored by the fact that in each individual test process generally each line and Column by itself is checked separately from the other rows and columns without being previously determined is whether there is any> fault in the relevant switching network. In this case, the check-through is required of a switching network namely a period of time that is generally not available, because yes the operation must not be noticeably slowed down by the test process.

With the switching networks described, certain errors, the cause of which is outside the switching network is, thereby lead to double assignments that a coupling relay is energized, which leads to a ready is owned by a line or column occupied by a connection. These double assignments can be caused by special Measures on the switching matrix itself or on the

Circuit arrangement to determine

of electrical faults in switching networks of telecommunications switching systems

Applicant:
Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Witteisbacherplatz 2

Dipl.-Ing. Ulrich Koerber

and Dr.-Ing. Werner Krägeloh, Munich,

have been named as inventors

the marker controlling the switching matrix recognized and eliminated will. That is> but not the subject of the invention.

However, other errors can also occur in the switching matrices, the cause of which is in the switching matrix itself lies and the z. B. as shunts and / or lack of decoupling rectifiers between the individual EinsteHadem occur. Shunted here a relatively low-resistance, unintentional connection between the decoupling rectifiers or the Setting windings of the coupling relays according to voltage or earth can be understood. Defects in the decoupling rectifier exist z. B. in losing the blocking property. It is the object of the invention to switch matrices to be able to check in such a way that it is first determined whether any of the described Error in the switching matrix itself. Only when it is certain that such an error is present should it be used started to locate it in the switching matrix. A circuit arrangement is used to solve this problem suitable with a test tube in a test circuit that can be influenced by a control circuit; in the event of a fault, a potential jump in the test circuit closes the tube, m igniting.

According to the invention, this circuit arrangement is characterized in that the test circuit consists of two There are branches, on the one hand to controllable electrodes of the test tube and on the other hand by the control circuit Contacts operated in pairs one after the other on each of the. Decoupling directional ladder summarized Lines or columns of the switching matrix can be connected in such a way that an error in the lines: or splitting the coupling network into the potential jump

509- 507/128

one or the other branch of the test circuit generated, which causes the two test branches common test tube to ignite.

The implementation of the error detection with the aid of the circuit arrangement according to the invention has the. The advantage is that all rows are sampled at the same time, followed by all columns of a switching matrix be checked at the same time. This adds up the time required for the exam. Reduced minimum size.

According to an advantageous embodiment of the concept of the invention are the lines and columns for ■ determination. the fault location via a rotary switch, a rotary selector or the like, and a resistor such can be connected to a positive test potential that the fault location of a row or column or a crosspoint between row and column is to be attributed to the fact that there is a certain resistance in the resistance Voltage drop is measurable.

The invention is shown in FIGS. 1 and 2, for example described, namely shows

1 shows the basic circuit diagram of the invention, FIG. 2 shows a table for determining the location of the fault the possible error in the circuit of FIG.

In Fig. 1, for example, two rows 1 and 2 and two columns 3 and 4 of the switching matrix are one Message switching system with the .. setting windings 5, 6, 7 and 8 of the coupling relays, and! the decoupling rectifier 9, 10, 11 - and 12 shown. Such switching matrices can be expanded as desired in practice, and the invention is not limited to that The simplified example shown is limited.

Lines 1 and 2 are set via relay contacts 131, 132 and columns 3 and 4 via relay contacts 143, 144 when the connection is established. ...

When the c-cores assigned to the individual Einsteüadern are occupied, a busy contact 151, 152, 153, 154 opens. This prevents double assignments that could be caused by errors that are located in assemblies outside the coupling network, for example in the system marker .

For detecting errors in the forward setting touring and coupling points between the wires of the branches 17 and 18 of the test circuit via rectifier .161, 162, 163, connected 164th Branch 17 contains a normally closed contact 32 of the test device controlled by a control circuit (not shown) and a switchover contact 20 of the switching network, which in its rest position applies operating potential for the switching network and, in its working days, test branch 17 via a high-resistance resistor. 19 connects to positive test potential. The rectifiers 161, 162, 163, 164, which mutually decouple the setting wires 1, 2, 3, 4, simultaneously ensure that the setting contacts 131, 132 and 143, 144 and the decoupling rectifiers 9, 10, 11 , 12 are protected from excessive induction voltages. These overvoltage protection rectifiers 161, 162, 163, 164 are used at the same time when the test circuit is switched on. If contact 33 is opened at the same time as the switching of contact -20 in branch 17, which combines lines 1, 2, etc. of the switching matrix for testing, the lines are connected to the positive test potential + U _p on one side. In the event of a shunt to earth or to minus, a negative potential jump then arises in test branch 17, which causes test tube 21 to ignite via capacitor 22 from the cathode. Thus a test relay 23 responds in the anode circuit of the tube 21, and a relay contact (not shown) triggers the alarm.

The test for the columns in the switching matrix is carried out in the same way as was described for the rows of the switching matrix. The columns are placed on one side via the resistor 25 to a negative test potential - Up , by moving the contact 24 in the test branch 18; at the same time the contact 32 is opened. In the event of a fault, a positive potential jump occurs in the test branch 18, which causes the tube 21 from the ignition electrode to ignite via the capacitor 34. The alarm is given in the same way as described above for the lines of the switching matrix.

The test procedures described are expediently carried out by a not shown in detail. Control circuit controlled, which the test branches 17 and 18 automatically switches on or disconnects at a selectable time interval through the contacts .20, 24 and 32, 33. This can advantageously be done by a Steuerfcreis which is provided with two tubes, one of which, for. B. is periodically ignited by an i? C element, while the other tube ignites only when a contact actuated depending on the triggering of the marker r switches through the control circuit. It is advisable that a relay is attracted in the test circuit during the test process, which, with its contact, blocks the marker of the switching system for normal assignments.

., Conversion now one in the manner described Festge ¹ presented Ifault on a Einstellader, so on a row or column · or on a cross-point ■ -the should here the connection between the Entkopp Lungs rectifier and the Einstellwicklung of coupling: - . To be able to locate a relay in the coupling network, the two rotary switches 26 and 27 are provided in the circuit according to FIG. With the switch 26 a positive test potential can be applied to each individual column of the coupling matrix via the positions α and b and the resistor 28, and with the switch 27 a positive test potential can also be applied to each individual row via the positions c, d and the resistor 29 will. In the event of a shunt in an adjusting wire, a certain voltage drop can be measured at the resistor 28 or 29 with the measuring device 30 or 31, which makes it possible to determine the location of the fault.

The determination of the fault location is based on the Fig. 2 in connection with FIG. 1 described in more detail.

In the circuit arrangement according to FIG. 1 ', in the illustrated section of a' switching network 'between row 1 and column 3, the fault locations can occur at the locations designated A, B and C , whereas the fault locations D, E are between row 1 and column 4 , F. The possible error locations between line 2 and column 3 are designated with G, H, I and those between line 2 and column 4 with /, K, L. From FIG Faults at points and D affect the same setting wire 1, i.e. they can be located on line 1. The same applies to faults G and / with regard to line 2. The shunts C and / influence column 3, while the shunts In the event of a fault, F and L are to be assigned to column 4. On the other hand, to determine the location of the shunts in the locations labeled B, B ₁ H and K , a crosspoint must be determined because these fault locations neither directly to a column nor directly to a cell ile belong, but with the "line and

i 055

Gaps through one component each, d. H. via a decoupling rectifier or via the setting winding of the coupling relay.

In the table of FIG. 2, the individual fault locations A to L are entered in the left column, as they are also drawn in the circuit according to FIG. In the table, the number 0 is entered for the switch positions o, b, c and d if there is no display on one of the measuring devices 30 or 31. The numeral I means that in the respective switch positions vo 'averaging a full shunt is measured directly. The number II indicates / that ^: the shunt is measured via a setting winding of a coupling ^{relay 1} , and the number III indicates that the shunt is measured via the holding windings of two coupling relays. - ^:

Is z. If, for example, the shunt is present at the fault location and has been indicated by the automatic test device via the tube 21, then the fault location determination can begin with one of the switches 26 or 27. Is initially the switch is operated 26 to 30 shows the meter in the positions α and b no deflection, as in position α of Entkopp'lurigsgleichrichter 9 and in position 10 b of the decoupling rectifier 'as the locking member acts and the incorrect current at the fault location A cannot be measured. Switch 27 is open. A If switch 26 is now opened and switch 27 is brought to positions c, d one after the other, the full shunt current must be measured in position c , since the fault location A is directly on line 1. In position d there is no deflection because the rectifiers 9 and 10 again act as a blocking element here. Accordingly, the number 0 is entered in FIG. 2 for the switch positions a, b and d in the presence of the error A and the number I is entered for the switch position c. Since the individual switch positions α to d of switches 26 and 27 are each assigned to a setting wire, it follows that the fault location is in line 1. This assignment can expediently on a scale -an; marked on the switches. In row 1 of the table, the number 1 is therefore entered in the table column for the lines of the coupling field for the error allocation.

Is z. B. the fault point C is present, then in position α there is a larger deflection on the measuring device 30 than in switch positions c and d on the measuring device 31, because in switch positions c and d the fault current through the decoupling rectifier 9 or 11 and through the winding 5 or 7 of the relevant coupling relay flows, while in position α the fault current. flows via column 3 directly to fault point C. Accordingly, the number I is entered in the table row for the fault location C in position α , the number 0 in position b and the number II in positions c and d. It follows from this that the error is in column 3, since the error must always be assigned to the row or column that produces unequal deflections. The error lies in one line if all columns show the same deflection. Conversely, the error lies in a column if the examination of all lines shows the same display. In the present case, this results in column 3 as the fault location. Faults D, F, G, I, J and L can be found in a corresponding manner, as is entered in the table in FIG. The boundary between rows and columns as a fault location is always given by the existing decoupling rectifiers.

The flaws B, E, H and K that like it. from Fig. 1 it can be seen, each associated with a crosspoint between a row and a column, can be determined as follows:

Is z. B.-the fault point B is present, there is a small deflection (current II) in switch position α , since the winding of the relay. 5 will be traversed by the fault current. In position b and any other spoke positions. if there is no deflection (current 0), in position c the full fault current (current I) flows through line 1 / and in position d and any other line positions is. there is a small deflection (current III) because the fault current flows through the windings of the two relays 7 and 5. The value of the resistors 28 and 29 is in the order of magnitude of the relay resistors; as a result, a clear difference in the deflections can be perceived, and the fault location can be determined by comparing the deflections. Most expediently, a tabular compilation of the possible displays of the measuring devices and the error determinations resulting therefrom, as shown in FIG. 2, belongs to each test arrangement. the advantage that you can detect the fault location at a glance when checking a coupling field. From the displays of the two measuring devices 30 and 31 it follows that the error is in the vicinity of line 1 and column 3, ie in crosspoint B. This is indicated in the "Crosspoint" column of the table. Correspondingly, the fault locations E, H and K , which are also located in crosspoints, can be determined. The table shows that the error D is in line 1, the error E in the crosspoint between line 1 and column 4 and the error F in column 4, while the error G in line 2, the error H in the crosspoint between Line 2 and column 3, error / in column 3, error / in column 2, error K in the crosspoint between line 2 and column 4 and error L in column 4.

The invention can be applied to arbitrarily expanded switching networks. There are then only appropriate switches that z. B. can also be designed as a rotary selector to use instead of the switches 26 and 27. It should also be pointed out that the circuit arrangement according to the invention can also be used to detect errors in the decoupling rectifiers in the coupling network by connecting one row and one column at the same time via the two rotary switches 26 and 27 to positive and negative operating potential, respectively. that the decoupling rectifiers receive blocking potential. An error display can then be read on a display device when one of the decoupling rectifiers 9, 10, 11 or 12 has lost its blocking effect. If necessary, it is expedient to carry out the supply of the potential to the switches 26 and 27 via appropriate changeover switches.

Claims (5)

Patent claims: 1. Circuit arrangement for the detection of electrical faults in switching networks of telecommunications switching systems with a test tube in a test circuit, which can be influenced by a control circuit and in which there is a fault Potentiaisprung brings the test tube to ignite, characterized in that the test circuit off two branches (17, 18), one hand to controllable electrodes of the test tube (21) and on the other hand, by means of contacts (20, 32; 24, 33) to the lines (1, 2) or scouting combined via the EntkoppelrichÜeiter (16) (3, 4) of the switching matrix can be connected in such a way that ■ that an error in the rows or columns of the switching matrix the. Potential jump in one or the other branch of the test circuit that generates • causes the two test branches (17, 18) common test tube (21) to ignite. 2. Circuit arrangement according to claim 1 for locating the detected errors, thereby characterized in that the rows and columns via a rotary switch, a relay chain or the like, and a resistor can be connected to a positive test potential in such a way that the fault location is to be assigned to a row or column or a crosspoint, that at the resistor a certain voltage drop can be measured, 3. Circuit arrangement according to claim 2, characterized in that for determining a Error in the decoupling rectifier of the coupling matrix, one row and one column each can be connected to the normal operating potential via rotary switches in such a way that the rectifiers 2Q are claimed in the reverse direction and the measuring device in the event of a rectifier fault a Indicates fault current. 4. Circuit arrangement according to claim 1, characterized in that the control circuit for periodic control of the test process is provided with two tubes, one of which is a tube by an i? C element at selectable time intervals is ignited periodically, while the other tube ignites only when a · in dependence Contact actuated by the triggering of a marker switches the control circuit through. - 5. Circuit arrangement according to claim 1 or 4, characterized in that in the test circuit a relay is picked up during the test process, which with its contact the marker of the Voting office blocks for normal occupancies. Considered publications:
German Patent No. 903 349, 1 sheet of drawings © 9OJ 507/128 4.59