DE822996C - Circuit for automatic signal systems for selective testing of the value of characteristic resistors - Google Patents

Description

Circuit for automatic signaling systems for selective testing of the value of characteristic resistors The 1? Rfindting relates to a circuit for s.cllisttätige signal systems, e.g. 13. an automatic Telephone system for selective checking of the value of characteristic resistors. Germ \% resistances are used to display on educational triscliein ways of certain properties or of the outputs with dialers, connection Training lines or the like. Used. Different Properties or textures are made of Characteristic resistors with different nendeil values indicated. I? S are z. 13. In known systems, voters «Titei- help @ -on characteristic resistors set, the finite: marking contacts of the outputs are connected and their resistance «@ value for this Digit of the digit of the output is characteristic. The Steuervor right of a voter checks during the l @ e. @@ egung one the resistance values of the successive outputs, e.g. B. by these values in a bridge circuit are finite Marking resistance set in a register corresponding to the desired digit can be compared. As soon as an output is reached whose characteristic resistance is in a certain ratio to the marking resistance, e.g. B. corresponds to ili.m, the voter is stopped.

Characteristic resistors can be used to make a different distinction to do between different output groups. It can e.g. 13. the @ 1us.gang by call seekers or en, d dialers are marked by characteristic resistors, the one Modification of the condition of the lines connected to the terminals yell, so z. B. the indication that a line is assigned to a PB1 group, that a telephone booth or a payphone is connected to the line is that in a certain traffic direction there is the possibility of a desired one To effect connection via a detour, etc. Such selective markings are in the general checked after the voter has been stopped. Even a bridge circuit can be used in which the tested characteristic resistance is successively compared with different comparison resistors. As a criterion can e.g. B. apply that the tested characteristic resistance is equal to a certain comparison resistance is <xler that the sum of the characteristic resistance and comparison resistance is a certain Assumes value. : Whichever way the check is carried out, it is anyway required that a current is passed through the resistor to be tested, whose Value is checked directly or indirectly by the test circuit.

The known test circuits do not work particularly reliably. Because the output contacts of a selector multiple times with corresponding output contacts other voters are connected, the same characteristic resistance is simultaneously for several Test devices accessible. It can therefore happen that the same characteristic resistance is tested at the same moment by two or more test devices. Of the The test current flowing through the characteristic resistor is then distributed over the test devices. The current flowing through the test devices can then assume a value that coincides with the nominal value, which corresponds to another characteristic resistance, so that the test devices would react incorrectly. This can e.g. B. affect it, that a voter is set to an undesirable outcome.

The test circuit according to the invention overcomes this disadvantage and is characterized in that the test circuit contains an electronic ticker, which can be in two different., electrically stable positions and the is equipped with at least one discharge tube, which is in the first electrical Layer locked and conductive in the second electrical layer and its discharge path during the test in the test circle between the multiple point and a point second potential is switched on, and that the ticker before testing in the first electrical position is brought and remains in this position when in the multiple point a potential is found, its difference with the second potential is smaller is than a certain threshold value, but the discharge tube becomes conductive when a potential is found in the multiple point, its difference with the second Potential is greater than the specified threshold value, so that the ticker second electrical layer passes over and such a test current the characteristic resistance to be tested flows through, @ that the difference between the potentials of the multiple point and the second potential is brought down to a value smaller than that certain threshold is.

With this circuit it is not possible that the test current spread over two or more test fixtures.

The discharge tube contained in the test circuit can be used as a gas-filled tube be designed, which has such an ignition and burning voltage that the tube only ignites if no other test device is passing a test current through the test device Sends characteristic resistor.

A circuit can also be used that has two vacuum tubes contains, in each of which a control electrode is galvanically connected to one such point Output circuit of the other tube is coupled that when the first tube is conductive the other is blocked and vice versa.

One of the tubes in this circuit is so in the during the test Test circuit inserted that the cathode of this tube is connected to your characteristic resistor is.

It should be noted that it is already known to use gas-filled tubes Circuits for checking the vacant or occupied position of exits from voters and that a circuit for the same purpose has already been proposed is, in which two vacuum tubes are used, their control electrodes with such are coupled to a point of an output circuit of the other tube that when the one tube is blocked, the other is conductive and inverted, and then the cathode one of the tubes is connected to the selector's test arm. The purpose of these circuits is completely different than in the present case, and a selective check of the value of characteristic resistors is not carried out.

The invention is illustrated below with reference to a number in schematic form and simplified form of the embodiments shown in the drawing explained.

FIG. I shows in schematic form an example of a circuit according to the 1? Rhn (hung to the number setting of selectors, only those elements are shown which are necessary for understanding the invention. K i, K2, K3 denote three voters, a Of the selectors K i, K 2 and K 3, only the test arms 0, 41, 0A2 and 0A3 with the marking contact sheets IICi,: LIC2 and MC 3 and the rotary magnets 1) i , D 2 and D 3 are shown.

The marker contacts of corresponding outputs. Of the selector are connected to one another several times in a known manner by 111 i, M2, etc. Between. At multiple points _Il i, 1112 and the voltage source hi, the Kenawid devices Rx i, Rx 2 are switched on, the values of which are kenini-drawing for the number of the assigned outputs. The number setting of the selector K i or K2 is controlled by the test devices 01 1 and 012.

After the selector K i has been occupied, a test circuit is formed from the test arm 0A i via marking contacts and test arms of voters in any previous selection stages, the discharge path of the gas-filled discharge tube B i, the winding T i of the 1) ifferenitial relay T to the voltage source V2. The tube B i can, for. Be a neon tube. : IIS designates a marker switch in a register, which is indicated by e.g. B. number disc signals sent by a subscriber has been set in a certain position, whereby the switch of the selector 1IIS has come into contact with a certain marking contact, which is connected to the voltage source V via a marking resistor Rm, the resistance value of which is characteristic of the number to be dialed r is connected. The switching arm of the selector 111S is, on the other hand, connected to one of the 1? Iitleli of the winding T2 of the relay 7 ', exercising contact b of a relay (not shown) of the test device 011. The other end of the winding T2 is connected to the voltage source V2. The winding of the rotary magnet D i of the selector K i is inserted into a circuit from earth via the winding of the magnet D i and the normally open contact t of the dilterential relay T.

The mode of operation of the circuit is as follows: When contact b closes, a circuit from V 2 via winding T 2, contact b, the switching arm and the marker contact of the selector AIS, the marker resistor Rm to V i closed. The strength of the current in this circle is determined by the marking resistance Rm and is therefore characteristic of the number to be used. The relay T now picks up. As the normally open contact t closes, the rotary magnet D i is excited, whereby the selector K i is engaged and the switching arm 0A i moves along the XI arkierungskontakte 111C i.

It is assumed that the output corresponding to the multiple point M i is occupied because the selector K 3 is set to this output in an existing voice connection. The multiple point! 11 i is then connected to earth via the test arm 0A3 of the switch K3 and the contact r. The potential difference between V 2 and earth is lower than the ignition voltage Vo of the gas-filled tube 13 1. If the test arm 0.4 1 of the switch K i comes into contact with the multiple point M i, the tube B i will not ignite, the N \ There will be no current flowing through the winding T i of the relay T , and the voter will continue to move. The test arm then comes into contact with a marking contact which is connected to the multiple point .11I2, the associated output of which is assumed to be unoccupied. The potential difference between V2 and V i is somewhat greater than the ignition voltage Vo of the tube B 1. At the moment of contact there is therefore a voltage on the gas-filled pines 13 i which exceeds the ignition voltage. The gas-filled tube thus ignites, and a circuit is formed from V i via the characteristic resistor Rx 2, marker contact and test arm of selector K i, discharge path of tube B 1, winding T i to voltage source V2. The voltage across the gas-filled tube B i now drops to the burning voltage Vb.

The current intensity in the mentioned circuit is determined by the value of the characteristic resistor Rx 2. The values of the characteristic resistances Rx are chosen such that, when the test arm finds a desired free exit, the currents flowing through the windings T i and T 2 correspond to one another. The relay T then drops out and the normally open contact t opens, whereby the excitation circuit of the rotary magnet D i is interrupted and the selector stops at the desired output. If the marker contact of the multiple point M i is not assigned to a desired output, the currents flowing through T i and T 2 do not correspond, and the relay T remains energized, so that the selector moves on. During the transition of the test arm 0A i to the next marking contact, the test circuit opens and the gas-filled tube goes out.

It can now happen that at a moment in which the characteristic resistor Rx2 of the multiple point M2 is checked by the test device 01 1, the selector K i reaches the same output and the test arm 0A2 thus comes into contact with the multiple point M 2. At this moment @, however, a current flows through the resistor Rx 2 and the test circuit of the test device 01 1, whereby such a voltage drop occurs at the resistor Rx2 that the difference between the potentials of the multiple point M2 and the voltage source V 2 is lower than the ignition voltage of the gas-filled Tube in test device 012. This gas-filled tube does not ignite, and test current does not flow through test device 012.

The test by the test device 01 1 is therefore not disturbed by the parallel connection of the test device 012, and therefore no faulty voice connection can result.

The connection circuit between the test arm 0A r and the test device 01 1 can run over several selectors in previous selection stages. Since the contacts of these voters are connected several times to contacts of other voters, a relatively large earth leakage can occur, which is illustrated by the leakage resistance R i. An earth conductor can also be present between your multiple points of the selector K i and earth. During the test, these bleeder resistances are parallel to the characteristic resistance, which can cloud the display. The circuit is preferably set up in such a way that the potential of the test arm (point i) has at least almost earth potential during the test. The bleeder resistors then carry a current. In the circuit according to FIG. I, this can be achieved in that the potential of V 2 is approximately matched to the operating voltage of the gas-filled tube B i and the resistance values of the characteristic resistors are selected to be large compared to the resistance of the winding T i.

The circuit according to Fi: g. i can be changed in several ways. It can e.g. B. the winding T i and the gas-filled tube B i are exchanged against each other. The test circuit via T i and the comparison circuit via T 2 do not need to be fed from the same voltage sources.

In the circuit according to FIG. I, the test current flowing through T i is compared with a test current flowing through T2, the magnitude of which is changed by comparison resistors Rm. However, it is also possible to use a marker selector to switch the comparison resistor Rm in series with the test circuit running via T i, the gas-filled tube and the characteristic resistors, and to allow a constant comparison current to flow through the comparison circuit via T 2. The relay T will drop out when T i and T 2 have the same current flowing through them, ie when the sum of the switched-on comparison resistor Rm and the characteristic resistor Rx reaches a certain value. In this case, the values of the comparison resistors Rm must therefore be taken complementary to the values of the characteristic resistors Rx. The supply voltages hi and h2 are preferably selected in such a way that the point i has ground potential when the desired output is reached, so that the test is not disturbed by any earth leakage.

The disadvantage of not having two or more test devices in the same Can test the same characteristic resistance at a moment, the circuit according to Fig. 2 not on.

In this circuit, one of the characteristic resistors forms R with the series circuit the gas-filled tube B i and the fixed resistor R i, the fixed resistor R2 and the switched on according to the number to be dialed by the marker selector _lIS Comparative resistance Rm a Wheatstone bridge, which h i and V2 is fed. In the diagonal of the bridge is between points i and 2, a voltage comparison device NW with a high input resistance is switched on. This voltage comparison device can, for. B. from an already proposed Be kind.

If the test arm 0A i of the selector K i reaches a marking contact of a free output, the characteristic resistance of which is not checked by another test device at this moment, the gas-filled tube B i ziirises and a circuit is created from hi to Rx; Marker contact and test arm of selector K, point i, tube B i, resistor R i to h2. The potential of point i is determined by the value of the characteristic resistor Rx. As soon as a desired free output is reached, the potential of point i becomes equal to that of point 2, whereby the response device NW reacts and the sensor is blocked as a result of the opening of the excitation circuit of the rotary magnet. If another selector reaches a corresponding output during the testing of a characteristic resistor by the testing device of the selector K i, the gas-filled tube in the testing device of this other selector will not ignite, since the current flowing through the gas-filled tube B i causes the Potential difference z \\ - isclien l-2 and the lx- hitting multiple point is lower than that Ignition voltage. About the other testing device So no electricity flows. \ - (> i-exposed that the interior resistance of the voltage test device @ 1iW forward is sufficiently high. The testing of the Kenmvid Resistance by the The test device of the selector K i is therefore not disturbed; the voltage testing device .the other However, voters can use the potential of --multiple- point with the comparative potential in the Putikt 2 compare this tester. The germinal resistance flowing through test current is in in this case not de; other voter himself, but from the test device of the selector K i supplied. The clamping device of the selector K i is in a variant of the circuit according to Fig.2 instead of point i with point 3 bound. A simultaneous examination by several Testing equipment is natural in this case not possible. In the circuit according to Fig. 3, the Mar- marking selector MS in series with the gas-filled Tube B2 inserted into the test circuit, and that The potential of point 3 is determined by the voltage test device NW with the fixed potential of the Point 4 compared. After the gas-filled When reaching a free tube, do not go through a other test device tested output has ignited, the potential of point 3 is through the values of the characteristic resistance lt and the through MS switched on comparison, resistance Rin it's correct. The values of these `resistances are like this chosen that in achieving a desired Output the potential of point 3 equal to that of point 4 becomes. If the comparison sw-id is: rst: inde in series with be placed in the test circle, as (read in Fig. 3 is shown, the funneling device may be used YW not with point t instead of point 3 be connected because the potential of the point i also depends on the value of the resistance 1- # rra, so that the control device of another currency lers when reaching a corresponding exit would react incorrectly. With the circuit according to 11 ig. 3 shows the gas filled tube a cathode k, an anode a and a control electrode; on. This has the advantage that the ignition voltage of the 1Zölii-e by change of the potential of the control electrode in certain Limits set to a desired value can be. The circuits of Fig. I to 3 have the following part that -the resistance Rr flowing through Test current more or less of your value of the Burning voltage of the gas-filled lZÖlii-e is dependent. This disadvantage adheres to the circuit according to Fig..I not on. In this circuit, the 2 'marking selector MS, similar to the circuit after Fig. 3, placed in series with the test circuit. The gas filled tube B 2 is from the voltage divider R 5, R 6 bridged. Between your tap 5 on (lein Voltage divider and the point of fixed potential h3, the voltage testing device NW is switched on. The tap point 5 is on the voltage divider in such a way that the ratio between the resistors R, 5 and R6 is equal to the ratio between a comparison resistor Rin and a characteristic resistor Rx corresponding to the same number. Are z. For example, if the comparison resistances and characteristic resistances assigned to one another are below #, itiati; cler equal, then the point P lies on the = middle of the reference divider R5, R6. In this case, the Spanaiung G'3 is equal to half the sum of the voltages V i and h2 selected overall. The total resistance of the voltage divider R5, R6 must be large compared to the highest of the comparison and characteristic resistances.

The mode of operation of the circuit is as follows. As soon as the test arm hits a free output that has not been tested by another device, the gas-filled tube ignites. The voltage of point -5 is then equal to h3 + '/ 2 (Rx-Rm) 1, where 1 denotes the current flowing through the test circuit. ! Voltage of the point 5 is h3, the Spannungsprüfvorrichtungspricht, and the voters will be stopped - is the characteristic impedance of the Rx audited @ us, gangs equal to the reference resistor Rm, sc, that is. In this case, the voltage of point 5 is independent of the current flowing through the test circuit, i.e. does not depend on the burning voltage of the gas-filled tube Comparative resistance, which are assigned to one another, there is a fixed ratio.

The supply voltages h i and V2 are preferably selected in such a way that that during the test the point i has practically earth potential, and will continue the voltage V3 is taken from a voltage divider connected between hi and V2, whereby the difference between V 3 and the potential of point 5 at bridge equilibrium independent of the supply voltages. h i and, V2 is.

If the tested characteristic resistance is not equal to the comparison resistance Rm, this is how the device responds: VW does not respond and the voter continues to move. If the resistances are unequal, the voltage at point 5 is of the test current 1 depends, but this is not a hindrance as long as it is ensured that I is sufficient is large in order to produce the required voltage deviation at point 5.

If there is a simultaneous test of the same characteristic resistance by two Test devices 0I i and 012, the gas-filled tube in the device is whose test arm first strikes the relevant marker contact, e.g. B. 0I i ignite. The gas-filled tube on the other test device remains extinguished.

Since the resistance of the voltage divider R 5 ', R 6' in the device 01 2 is large compared to the characteristic resistance Rx, the device 012 can only have such a small current that the test by the device 011 is not influenced . The potential of the point 5 'in the device 012 is then practically equal to half the sum of the potential b'2 and the potential of the multiple point. Since the potential of the multiple point is not equal to hi, the potential of point 5 'cannot be equal to h3, since V3 is equal to half the sum of hi and h2.

As a result, none of the devices 011 and 012 can fail speak to and put a voter on a missed number.

The supply voltages h i and 1l2 are preferably chosen in such a way that that during the test point i has practically ground potential.

By the current flowing through the device 012 all the way to the value Reducing zero becomes a resistance between point i 'and point h i Rc 'switched on, the value of which is such that the potential of the point i 'in the non-conductive state of the gas-filled tube and glue lack of electricity over the test director is practically equal to the potential of a multiple point for which Case that a desired resistance is tested. The potential of the point i ' is only slightly dependent on the size of the marking resistors Rm, since the resistance value of the voltage divider R 5 ', R 6' large in relation to the highest marking resistance is. In the circuits described, the ticker was designed as a gas-filled tube. There may be several disadvantages associated with the use of a gas-filled tube at. The ignition and burning voltages are not always the same for different tubes Values and can change over time, even with the same tube. The difference between the ignition voltage and the burning voltage cannot be made arbitrarily large will. Once a gas-filled tube has ignited, the current cannot or be seriously influenced by a control electrode. Another disadvantage is that the deionization time is relatively long, whereby disturbances occur can. If, e.g. B. after the gas-filled tube has ignited during a test, the test arm of the selector passes over to a marking contact with a characteristic resistor is connected, which just happened to be tested by another test circuit it can happen that during the transition from one contact to the next, the gas-filled tube is not sufficiently deionized, so that the ignition voltage is lower than the nominal value and the tube ignites again.

In the embodiments of the invention to be described below, the ticker is equipped with two vacuum tubes, a control electrode of each of the tubes being galvanically coupled to an output circuit of the other tube in such a way that, when one tube is conductive, the other is blocked and vice versa . In the circuit mach Fig. 5, a battery Ba i is connected between the control grid, the tube B3 and the anode of the tube B 4 , whereby the control grid of the tube B3, in the conductive position of the tube B 4, has a potential of e.g. B. assumes -40V. The control grid of the tube B4 is similarly connected via battery Bat with the anode of the tube B3. The anode of the tube B 4 is fed via a resistor R8 from a voltage source V 2, while the anode circuit of the tube B3 contains the series circuit of a resistor R7 and the winding T i of the differential relay T.

In the rest position, the cathode circuit of the tube B 3 is open, so that this tube is blocked. The potential of point 3 is then relatively high and tube B4 is conductive. When the test circuit is engaged, the cathode of the tube B 3 is connected to the test arm of the selector K i in an unspecified manner, and the selector is; actuated. The marker contacts of the selector K i are connected to the voltage source V i with a potential of -6o V via the characteristic resistors Rx i, Rx 2. The potential of the marker contacts of occupied outputs and of outputs that are tested by another test device is, as will be shown below, higher than -4o V; it can be seen that the occupancy criterion can optionally also be given via separate marking contacts.

If the test arm now encounters a marking contact of one of these Output on, the potential of the cathode of the tube B3 is higher than the potential of the control grid and the tube remains locked. However, it becomes a marker contact a free one. or untested output is hit, then the potential of the control grid of tube B 3 positive with respect to the cathode, so that tube B 3 becomes conductive. If the control grid now had a fixed potential of -4o V, then as a result of the The potential of the cathode of the tube B3 via the characteristic resistance of the current flowing increase to a value several volts higher than -4oV. In this case would the tube B 3 of a control device of another selector, the corresponding Marking contact reached, also become conductive and would thus be a simultaneous, but incorrect testing take place. By making the tube B3 'conductive, however, it sinks the potential of point 3 goes down, whereby tube B4 is blocked- As a result the potential of the cathode of the tube B 3 rises to approximately earth potential. The whole The process of conduction of the tube B 3 takes place within a special short period. If another voter now reaches a corresponding exit, so the test arm finds a potential on the marking contact that is strongly positive with respect to that of the control grid of the tube B 3 of the associated test circuit is, so that this tube remains blocked and this test circuit no current transfer can cause via the characteristic resistor and the test by the first test circuit is not disturbed.

The value of the current flowing through the characteristic resistor Rx is equal to the potential difference between the cathode of the tube B3 and V i, divided by the value of the characteristic resistor. The same current flows through the winding T i. If this is equal to the current flowing through the winding T 2 of the transformer T , the relay drops out and the movement of the selector is ended. If it turns out that the checked outcome is not the desired one, the voter moves on. During the transition of the test arm to the next contact, the cathode circuit of the tube B3 is interrupted and B3 is again blocked.

By appropriately choosing the supply voltages and the potential of the cathode of tube B4, it is possible to omit one of the batteries Ba i or Ba 2 and to connect the control grid of one of the tubes directly to the anode or to a point in the anode circuit of the other tube. Using batteries to create the required voltage differential between the control grid and anode is impractical because the batteries are floating and separate batteries must be used for each test fixture.

A circuit such as that shown in FIG. 6 is therefore preferably used to 8 shown. Next to it is the control grid of the pipe B 3 to the tap 7 of the voltage divider connected between the anode of the tube B4 and the feed point V 4 R i i, R 12 connected. The point V 4 has a negative potential. The one at the resistance R i i generated voltage drop replaces the voltage of the battery Ba I of FIG. 5. Appropriate choice of the tapping point 7, the potential of the tube B 3 to the desired value can be set.

The control grid of the tube B4 is correspondingly connected to the tapping point 8 of the voltage divider R9, R io connected. How the ticker circuit works is completely analogous to that of the circuit according to FIG. 5.

The testing of the characteristic resistances takes place in the circuit according to FIG. 6 in a manner which corresponds to that according to FIG. The anode of the tube B3 is connected to the switching arm of the register mark selector MS . The register marking resistors Rm are on the one hand connected to the contacts of the marking selector, on the other hand connected via the point 9 together via the resistor R 2o to the voltage source V2. The purpose of resistor R20 will be found below. The tube B3 is bridged by the voltage divider R5, R6. The total resistances of the voltage dividers R9, R io and R5, R6 are preferably high in relation to the highest values of the series connection of the resistors Rm and the resistor R20, so that almost the same current flows through a marking resistor Rm and a characteristic resistor Rx.

The voltage test device. # 'W compares the voltage of point 5 on the voltage divider R5, R 6 with the fixed potential V3. This device reacts when, when a desired output is reached, the potential of point 5 comes to stand in a certain ratio to potential V3, e.g. B. becomes equal to him.

The point 5 is further chosen such that the potential of this point is independent of the current flowing through the tube 5 when the switching arm of the selector K is in contact with the marking contact of a desired output, ie the relationship must be fulfilled, when Rm and Rx represent values of the marking resistance and the characteristic resistance associated with one another.

The potential h3 must be equal if, with the correct setting of the switch KI, V 3 is equal to the potential of point 5.

Fig. 6 further illustrates a measure that may also in association with the circuits according to FIGS. 5, 7 and 8 are carried out could. This measure is intended; the disruptive effect of any leakage resistances (R i in Fig. I) to reduce the test conductor to earth completely to the value zero, by the cathode line of the tube B3 in the conductive position on the most perfect Earth potential is held.

For this purpose, the circuit contains the tube B5, in which a control electrode is connected to the point io of the voltage divider R I5, R I6 switched on between Odem point 9 and the voltage source h [. The anode of tube B 5 is fed through resistor R I7. The control grid of the tube B3 is further connected via rectifier g I to the tapping point 12 on the voltage divider R 18, R 19 connected between the anode of the tube B 5 and h4.

The rectifier g I is non-conductive in the rest position of the circuit and, becomes conductive as soon as the circuit changes to the second electrical layer, d. H. in a position in which tube B 3 is conductive.

If the value of the resistance Rx contained in the cathode circuit is reduced, this increases the current flowing through the test lead and the resistor R2o. Consequently the potential of the point I o 'drops, and the potential of the point 12 and of the control grid of tube B3 rises. When the control grid of the tube B3 a had a fixed potential, if the cathode resistance was reduced, the The potential of the cathode of the tube B 3 will drop. The feedback on the grid the tube B 3 is now adjusted so that the decrease in the cathode potential just removed from the influence of the increase in the potential of the control grid. Of the (Differential) input resistance in the test circuit is then just zero, i.e. H. a change in the current flowing through the circuit has no change in the potential in point I. A calculation shows that under these conditions that of the regenerative circuit formed by the tubes B 3 and B 5 in the absence of a resistor in the cathode circuit of the tube B 3, z. B. with direct connection of point I. with earth, must be adjusted to the edge of self-oscillation.

In the presence of a characteristic resistor in the cathode lead is the circuit. then naturally stable.

The point 12 is further chosen so that the cathode of the tube B 3 has earth potential.

The wiring capacity together with the test director <(point 1) C forms a disruptive factor in the event that characteristic resistances occur particularly quickly one after the other should be checked, e.g. B. with fast circulating voters. This capacity can have a relatively high value, e.g. B. of the order of magnitude j04 pF, assume if the exam is about voters in a number of preceding, cascaded Voting stages takes place because the multiple points of this voter with the test lead connected (stay.

The capacitance delays the transition of the ticker from the first electrical one Location in the second. At the moment when the tube B 3 becomes alive, the Point I has a negative potential, and the capacitance C is thus negatively charged. Because the tube B 3 becomes conductive, C is over the discharge path, the tube B 3 and the resistors Rm and R20 are discharged. The presence of the proportionate high resistance in this circuit limits the discharge current.

On the one hand, there is consequently the possibility that the process takes place so slowly that the device NW responds incorrectly, while on the other hand it remains possible that a simultaneous test by two test circuits takes place with an incorrect result. Furthermore, the time remaining for the voltage test by the device NW is shortened.

Fig. 7 shows a circuit by means of which the interference the capacitance C can be reduced significantly.

The ticker circuit is set up in a manner similar to that of the circuits according to FIGS. 5 and 6. The tube B3, however, is provided with a screen grid. The anode circuit of the tube B 3 contains the resistor R7. Otherwise, the control grids of tubes B3 and B4 are coupled to the anode of the other tube in a similar manner with the aid of voltage dividers R 11, R I2 and R9, RI o, as in the circuit of FIG. 6.

The circuit also includes the auxiliary tube B6, which, similarly like the tube B3, is designed as a screen grid tube. The cathode K6,; the control grid g61 and the screen grid g62 of the tube B 6 are connected to the cathode K 3, the control grid g 31 and the screen grid g 32 of the tube B 3 connected.

The anode of tube B 6 is connected to earth. The discharge paths between the cathode and the screen grid of the tubes B3 and B6 are connected in parallel to each other in the actual test circuit, ie, as will be seen below, almost the entire test current flows through these switchgear during the test. The voltage divider R5, R6 is switched on between the cathodes and the screen grids. The sl> rinnungsprüfvorrichtung NW compares, similar to the circuit according to Fig. 6, the potential of the point 5 on this voltage divider with the fixed potential V3 of the voltage divider R3, R4-The screen grids are also switched on by the marker selector MS comparison resistor Rrn connected to the feed point V 2. The resistor Re is connected between the cathodes of the tubes B3 and B6 and V i, the purpose of which corresponds to that of the corresponding resistor in the circuit according to FIG.

During the test, point i has almost earth potential, because of the characteristic resistance Rx, and the capacitance C of the test conductor is therefore uncharged the tubes 133 and B6 .blocked and B4 becomes conductive, so that the ticker circuit B3, 134 goes into the first electrical position.

After the test arm; the selector K i with the following marking contact has come into contact, the capacitance is increased by the switched-on characteristic resistor Rx negatively charged until point i has such a potential with respect to control grid g3i of the tube B3 has "that the tubes B3 and B6 become conductive. As a result of the decrease in savings the anode of the tube B3, the tube B4 is blocked, and the potential of the control grid the tubes B3 and B6 is raised to approximately ground potential, i.e. H. to a value which is strongly positive in relation to that of the cathodes.

The tubes B3 and B6 are therefore traversed by a strong current, that quickly discharges the capacitance C.

The greater part of this current flows through the anode of the tube B6 during this period, since the currents through the anode circuit of the tube B3 and the screen grids of the tubes B3 and B6 are limited by the resistors R7 and Rm contained in the supply circuits.

After the potential of the point i is at approximately earth potential : has increased, the current through the anode of tube B6 drops to zero, since the potential of the anode becomes lower than (read the cathode. The potential of the point i then increases slightly until the final value is reached.

Almost all of the test current flowing through the characteristic resistor R_r now flows through the screen grids of the tubes B3 and B6. The resistor R7 contained in the anode circuit of the tube B3 has such a high value that the potential of the anode only approximately exceeds the cathode potential. The current flowing through this resistor is particularly small and also practically independent of the switched-on characteristic resistor Rx (the potential of the cathodes of tubes B3 and B6 fluctuates only slightly), so that this current can be compensated for by the current flowing through resistor Rc. The switching elements «-ground in such a way measure that, as already shown on the basis of FIG. was put together, in the first -electrical Position of the ticker circuit as a result of the voltage divider R5, R6 and \ Viderstaild Rc occur- the voltage division the potential of the point i practically equal to the potential of point t rend the test is so that the test circuit does not will be traversed by electricity when with is connected to the multipoint, which is one Characteristic resistance is assigned to that in this Moment just from another circuit is checked. The resistor Rc also has: in some other advantages part, (la, if the resistance was dropped in the first electrical layer of the ticker that The potential of point i can increase to V2 would. After the test arm has passed a marking konta, kt, e: liedcutencl would be longer take time before the capacitance C is on .ein such a way negative value charged lliitte, dala the IZölire f3, would lead. Fig. 8 shows a circuit for internal input place of a \ @ \ 'ühlers, z. I>. of a Vitd voter, which makes it possible to use a]), - standing, e speaking to enter, i.e. the vain @ ennwid @ r- Check the status of an occupied @usgailgs zii, where the busy marking of the same i \ Iarking- contact is given like the iltiiner \ Vider- stand marking. The control grid of the tube 1,3 is here above one. Rectifier g 2 with (! Ein: \ nzal>fl> unht 7 of the span voltage divider R ii, R 12 left> un (len. On the other hand, the control grid in the position .S i of the switch S via the resistor R 13 with the voltage source V5 and in position S2 of switch S. the resistor R 13 with the voltage surge V6 tied together. The coupling of the control grid with the Points 7 and 13 is such that the control grid assumes the highest of the potentials of these points. Z. B. the potential of Pt111ktes 7 over that of the 13, the rectifier is conductive and forms a low resistance to via R 13. If, conversely, the potential of the point tes 7 lower than that of point 13. so d -, - r Rectifier has a high resistance to- via R13. The same purpose is achieved, @ i, -eiln der Rectifier g2 and the resistor R13 against be exchanged for each other. The potential of the voltage sources V 5 is z. B. -40 N 'and the potential of the voltage source l' 6 equal to -2o V. Able for the circuit in which the tube B4 is conductive, is the potential of the Point 7 -4o V. In the rest position (read Potential of the control grid of the tube B 3 through the of point 13 conditional. The rectifier g4, the is switched on between point 7 and earth, is in locked in this location. The switch S is normal in the position S i. If the test arm 0.-l1 hits a V (arkierungs- contact of a free output, the the way described above, the tube B3 tend and the tube B4 blocked. The same Richter g 2 is now conducting, and the potential of the control grid of tube B3 is determined by that of point 7. The potential of the point 7 increases in such a way that the rectifier 94 also becomes conductive. The potential of the control grid of the tube B3 is therefore equal to earth potential and is not influenced by any divergences in the values of the resistors R8, R ii, R 12 or by changes in the potentials of the voltage source V2 or h4.

The voltage testing device NW compares the potentials (point 3 in the test circuit and point 2 in the comparison circuit R 14, Rm. As soon as a desired output is hit, the device NW responds. It is now assumed that a voice connection exists, which extends over the output U i of the selector K2. The multiple point 111 of this output is then via the 3 # marking contact and test arm 0A2 de, S selector K 2, the rectifier g3 and the closed contact 2 of a relay, not shown connected to the voltage source P7, the potential of which is e.g. 13. -25 V. If the test arm 0.4 i of the selector K i reached this output, the tube B 3 would become non-conductive because the control grid has a potential which is 15 V lower as <read potential of the cathode. So the voter moves on.

If the operator wishes to connect to the existing connection, she sets the switch S to position S2, as a result of which the control grid of the tube B 3 assumes a potential of -2oV. The threshold value of the ticker is lowered in this way. If the test arm 0A 1 now reaches the occupied output, the potential of the control grid of tube B3 is higher than that of the cathode, tube B3 becomes conductive, and the ticker changes to the second electrical, stable position.

The potential of the cathode of the tube B 3 increases then to a little above ground potential, so that the rectifier g3 is blocked and the busy marking circle of the selector K2 forms no load on M i. The test of the Ketitiw # resistance Rx i therefore continues like 1> ei an unoccupied exit.

Claims (7)

CLAIMS: i. Circuit for automatic signal systems, in particular Telephone systems, for selective testing of the value of characteristic resistors, on the one hand connected to a point of first potential, on the other side connected to a multiple point that is connected to the test circuit during the test and that at the same time a number of L'rüfschaltungen so accessible that the test of a resistor with the help of one about the liriife # nt (lei) resistance and the multiple point flowing direct current, characterized in that the test circuit has a Elektroiiisclien contains ticker, which consists of two different electrical, stal> ilezi Layers can be located and with at least one discharge tube (B i in Fig. I and 2, B 2 in Figs. 3 and 4, B 3 in Fing. 5, 6, 7 and 8), which in locked in the first electrical layer and conductive in the second electrical layer and its discharge path during the test in the test circuit between the multiple point (M 1, M2) and a point (V2) of the second potential is switched on, and that the Before the test, the ticker is brought into the first electrical position and in this If a potential is found in the multiple point, its difference remains with the second potential is less than a certain threshold value, the E. discharge gsröhre becomes conductive if a potential is found at the multiple point, its difference with the second potential is greater than the specific threshold value is, so that .the ticker goes into the second electrical layer and one such Test current flows through the characteristic resistance to be tested that the difference between brought down the potentials of the multiple point and the second potential to a value which is smaller than the certain threshold value. 2. Circuit according to claim i, characterized in that in the second electrical layer of the ticker the The potential of the multiple point is equal to the earth potential, at least during the Checking a desired characteristic resistance. 3. Circuit according to claim i or 2, characterized in that a discharge path of a first vacuum discharge tube in the test circuit (B3) is inserted, the cathode of which is inserted during the test with the resistance to be tested associated multiple point is connected and in which a control electrode, e galvanically coupled to a point (6) of an output circuit of a second discharge tube (B4) is, in which a control electrode is galvanically connected to a point (3) of an output circuit the first discharge tube is coupled such that when the first tube is blocked, the second tube is conductive and vice versa. 4. A circuit according to claim 3, characterized in that the first discharge tube (133) is equipped with a screen grid (g32 in Fi.g. 7) and the cathode (K3), the control electrode (931) and the screen grid (932) of this Tube with corresponding electrodes (K6, g61, g62) of a third tube (B6) are connected in such a way that the anode of the third tube is connected to a point (earth) of such a potential that during the (Tl) erganges of .the ticker of From the first to the second electrical layer, the anode of this tube is live, but in the second electrical layer of the ticker, the entire emission current flows to the screen grid and the discharge paths of the first and third tubes formed between the screen grid and cathode are mutually parallel inserted into the test circuit and the anode of the first tube is passed over such a high resistance (R7) that in the second electrical layer of the ticker the current through the anode of the first tube is opposite to the Current flowing through the test circuit is low. 5. Circuit according to one of the preceding claims, characterized in that the control electrode the first discharge tube (B3) with a point (earth) of constant potential a rectifier (94 in Fig. 8) is coupled which is conductive when the second Tube is locked. 6. Circuit according to one of the preceding claims, characterized characterized in that a control electrode of a further discharge tube (B 5 in Fig. 6) with a point (9) of an output circle of the first tube and a control electrode the first discharge tube via a rectifier (g) with a point (i i) one Output circuit of the further discharge tube (B 5) is coupled and the multiple point, when the first tube is conductive, at least close to earth potential, and the feedback is set so that when the first tube is conductive, the impedance of the Test device is at least zero. 7. A circuit according to claim i, characterized in that the discharge tube inserted into the test circuit is designed as a gas-filled tube (B i, B2) which has such an ignition voltage that the tube only ignites when no other test device causes .the resistance to be tested is traversed by a test current. B. Circuit according to claims i to 7, characterized in that the means (T in Fig. I) are provided for testing the current flowing through the discharge path or paths inserted in the test circuit. 9. Circuit according to claims i to 7, characterized in that the end facing away from the multiple point (3 in Fig. 8) of the discharge path of the discharge tube inserted into the test circuit via a resistor (R i in Fig. 8) with the point of second potential is connected and means (NW) are provided for testing the potential of a point of this resistance. ok Circuit according to claims i to .4, 5 and 8, characterized in that d @ aß in series riding in the. Test circuit inserted discharge tube a constant resistance (R i in Fig. 2) is switched on and means (: 'N' W) for testing the potential of the multiple point (mi, m2) are provided. i i. Circuit according to Claims i to 5, characterized in that -means are present through which the end of the discharge path, facing away from the -multiple point, of the discharge tube inserted in the test circuit with the second point of constant potential via a comparison resistor (Ryn i, 2m 2 in Fig . 4, 6 and 7) is connected, the value of which is in a certain fixed ratio to the value of the desired core resistance (Rx i, 2x 2) and that the first discharge tube is bridged by a voltage divider (R 5, R 6) whose Resistance value is high compared to that of the resistors to be tested, and means are available by which the voltage of a tapping point (5) of the voltage divider is checked, which divides the voltage divider in the specific ratio and in the order of the comparison resistance and the desired characteristic resistance. 12. A circuit according to claim 11, characterized in that the end to be connected to the multiple point (i in Fig. 7) of the voltage divider is connected via a resistor (Rc) to a point (hi) of constant potential and this resistor has such a value that in: the first electrical position of the ticker the current flowing through the resistor is at least almost equal to the current flowing through the voltage divider, if the mentioned end is given a potential which is equal to the potential of the multiple point. 13. A circuit according to one of the following: gehmdeii claims. For the numerical setting of a selector, characterized in that an output of a selector is marked occupied by the multiple point of this output, which has a numerical characteristic resistance with the point -first potential, and it is connected via a rectifier (g3 in FIG. 8) to a further point (V7) of such a potential that the difference between this potential and the second potential (V2) is smaller than the specific threshold value of the ticker, but is larger as the difference between the second potential and the potential of the multiple point in the second electrical layer of the ticker, and that further means (S) are present through which in; the first electrical layer of the ticker is supplied with such a potential of a control electrode of the discharge tube (B3) inserted in the test circuit that the threshold value of the ticker is reduced to a value which is smaller than the difference between: the second potential and the potential of the further Point.