DE966594C - Relay chain arrangement for telecommunications, in particular telephone systems - Google Patents

Description

ISSUED AUGUST 22, 1957

19453 VIII a J 2i a *

The invention relates to a relay chain arrangement for storage, counting or the like, in which the individual chain relays each have one Rectifiers are connected to fixed, graduated potentials, and. to the control line to operate the individual chain links ■ each different potentials are applied, in telecommunications, in particular Telephone systems ,.

Relay chains of this type have already become known, which, in contrast to the pure contact chains, which have a large number of contacts need to work with different potentials. Here are the windings of each Chain relay on the one hand placed via a rectifier each to staggered fixed potentials and on the other hand connected to a common control line, the rectifiers each conducting, if the control line carries a potential that is higher than the fixed potential connected to the relevant chain relay Potential is. With such an arrangement, a large number of are required for the switching necessary. Contacts saved, but at least one more normally closed contact is required, so that the subsequent chain relays, to which there are upwardly graded potentials, are disconnected will.

The advantage of a chain arrangement with differentiated There is potential in the fact that such

709 64175

Chains can be advanced not only in pulses, but also by marking if necessary of a specific relay are to be set.

The invention is now based on the object of avoiding any contact between the individual chain relays, that is to say to create a completely contactless relay chain arrangement and to avoid the associated potential for malfunctions. The elimination of all electromechanical ίο contacts and ¹ the associated increased operational security is particularly important because Reilaiskettenanierungen in switching systems are often in central organs, such. B. storage, application and there are exposed to heavy use. Precisely because central organs have far-reaching consequences for the functioning of a switching system in the event of a fault, a reduction in the susceptibility to faults for memories made up of relay chains, for example, means a technical advance.

The implementation of a relay chain arrangement without the use of incremental contacts is according to the invention achieved in that the response windings of the individual relays on the one hand each at staggered fixed potentials and on the other hand each via a feed rectifier and with this series resistor connected to a common control line and these rectifiers each conduct when the control line a higher one. Potential leads than the fixed, at the concerned; Chain relay lying potential, and that in each case, the response winding of a Chain relay is connected to the shedding winding of the preceding chain relay, and that in each case Limiting rectifier on the one hand on one between ^ the fixed potentials of the relevant and following chain relay and potential on the other hand at the connection point of the relevant Series resistor with the rectifier connected in series, and that this limiting rectifier conduct 'if the potential applied to the control line is higher than that with the relevant Limiting rectifier permanently connected ■ 45 is potential.

The details of the invention are explained in more detail with the aid of the figures. Here shows

Fig. Ι an embodiment for a two-part Memory chain,

Fig. 2 a first example for a multi-link storage chain,

3 shows a second example of a multi-link storage chain,

55 * Fig. 4 a third example of a multi-link Memory chain,

5 shows a first example of a four-link storage chain,

6 shows a second example of a four-section .60 storage beds.

Returning to FIG. 1, the right winding of the relay ^ _{1 is connected} between the terminal T of the control line and the DC voltage terminal V _x . The other pole of this terminal is grounded in a manner not shown. The winding of the relay S ₂ is in series with a rectifier G ₂ between the terminal T and the voltage source V ₂ . This voltage source is grounded at the other pole in a manner not shown either. The potential of the source V ₂ is higher than that of the source V ₁ , the rectifier G ₂ being polarized so that, as shown, it prevents current from flowing through the windings of the relays S ₁ and S _2. The relay ^ ₁ has a second winding which is parallel _{to the winding of relay JT 2!} is switched. If a suitable potential, which is not higher than the voltage source V ₂ , is applied to the terminal T , the relay, S ₁ , responds, whereas the relay JT _{2 is} not energized. If a potential which is higher than the source V _{2 is applied} to the terminal T, the relay JT _{2 is made} to respond, since the rectifier G _{2 is} now conductive. If the latter potential is denoted by V ₃ , then the resistances of the right and left windings of, relay, S _{1 are} equal to the values - a _x and b _x , whereas the number of turns of this relay is assumed to be P ₁ and ^ _1.

Beijler relationship

• η * η I / . . ι /

.τ 1 1 τ 2

the relay S _{1 is} not energized when the two windings are directed in opposite directions.

If one tries to use the arrangement shown in Fig. Ι for more than two relays and to provide all relays with the exception of the last with two windings, the second winding being connected in parallel to the first winding ioo of the next relay and each If the relay has a higher bias voltage than the previous one, it can be determined that it is impossible to switch only one relay at a time when a certain potential is applied to terminal T. If z. B. three relays are used and the potential F _{4 is applied} to the terminal T, which is high enough to cause a current flow in the winding of the third relay, there is no condition for the non-disconnection of relay S _{1 when the latter relay responds} . In this case it is

Pi-

V ₁ -V ₂

(2)

Since both equations, (1) and (2) must be satisfied at the same time, the desired result cannot be achieved since solving these two equations at the same time requires that either V _{1 be} equal to V ₂ or F _{3 be} equal to F ₄ . These conditions contradict the principle of this arrangement.

Fig. 2 shows one way of overcoming this difficulty, namely on a relay chain circuit, of which three relays are shown.

The right winding of. Relay S ₁ is still between the control terminal T and the voltage source V ₁ , but in series with the resistor; R ₁ . The connection point with the right winding of relay. ^ Is connected to an additional voltage source V ₁ via a rectifier G ₁ . AUe relays are switched in the same way, and the voltages at the individual sources are defined as follows:

V ₁ <V ₂ <V ₂ '<V ₃ <

(3)

Each relay, with the exception of the last relay, not shown, has a second winding

t5, which is parallel to the first winding of the following relay. The rectifier G _1, G _2, G _2, G _3, G ₃ ... are used for decoupling of the individual voltage sources, so that in the absence of the. Control potential, the terminal T no

ao current flow arises. If a suitable potential, which is not greater than V _2, is applied to terminal T , the relay,, S _{1 can} respond, whereas the other relays remain idle. If a corresponding potential that is higher than V ₂ but not greater than. V _{3 is applied} to terminal T , relay S _{2 can} respond, whereas the other relays, starting with relay ^ ₃ , are de-energized and therefore remain idle. Current flows through both the left and right windings of relay ^ ₁ ', and since the two rectifiers G ₂ ' and G _{1 are} now conductive, the potentials at the lower ends of the resistors R ₂ and R _{1 are} applied to the Voltages V ₂ and V _{1 are} limited, regardless of which voltage is applied to control terminal T. That means the relationship

Pi'

should be fulfilled so that the currents in the two windings of, relay S _{1 are the} same, and since the two windings are directed in opposite directions:, the relay S ₁ remains unactuated.

4-5 If a potential is higher than V ₃ , but not higher than V _i , a bias potential for the right winding of the relay _{VS "4,} not shown, is applied to the control terminal T. Here, the relay S _{3 is} actuated, but the Potential differences across the left and right windings of relay S ₁ remain the same as V ₂ -V ₂ and V ₁ -V ₁ , since rectifiers G ₂ and G ₁ 'act as voltage limiters, which means that relay S _{1 works} for all Voltages, with the exception of those between V ₁ and V ₂ , which are applied to terminal T. The same conditions exist for all relays, with the exception of the last one, which has only one winding. This arrangement allows one relay to respond at a time at a point in time at which a voltage of a certain level is applied to the terminal T. All relays, with the exception of the last one, have the same design with regard to their windings and resistances using a single relay with two windings, one obtains:

V 'V —V' V = V ' V = = V (<\

V ₁ V ₁ v ₂ v ₂ V ₃ V ₃ ...— v ₀ ($)

Here, the voltage V _{0 represents} the same amount by which the potentials V ₁ - V ₁ , V ₂ ' - V ₂ , V ₃ - V ₃ ... differentiate. Although this is not necessarily important, the levels between Spainnunigsources V ₂ . - V ₁ , V ₃ - V ₂ ... can also be made equal to the voltage V ₀ . The various control voltages are preferably designed in such a way that a specific relay operates in each case. If you pull z. If, for example, the control potential at terminal T has the value V ₂ , this ensures that the rectifier G ₁ becomes conductive, a potential V ₁ - V _{1 being applied} across the right-hand winding of S ₁ while the; right winding of relay. .S ^ is not energized, regardless of the effect of the, rectifier, G ₂ , since the potentials at both ends are the same.

Instead of applying different control voltages, the same potential V can be applied in all cases, but each time via a series resistor with a special value. If such an arrangement is used, one should consider potentials such as B. V ₂ , V ₃ ... , Apply to the control terminal T. The series resistance R ' _m , not shown, which corresponds to the response value' this relay S _m , is given by:

V-V.

m + l

(6)

M))

where η is the number of chain relays. The resistors R ₁ , R ₂ , R ₃ ... can be chosen in any desired manner, e.g. B. in such a way that you get the fixed separation for the series resistors, not shown. Each resistor ¹ corresponds to the response of a certain relay, and thus the power consumption can be reduced. * ·

Although both embodiments in Figs. 1 and 2 show that the left winding of each relay, with the exception of the last one, connected in parallel with the right winding of the next relay, it is useful here that the windings are connected to one another.

Fig. 3 shows e.g. B. an arrangement which is similar to that ia Fig. 2, but in which the left Winding of each relay, with the exception of the last relay, m row with the right winding of the next relay is switched. In this case equation (4) becomes:

q ₁ a ₁

P ₁ (ß ₂ + O ₁ )

-V ₉

(40

However, the principle of this arrangement remains the same.

Fig. 4 shows how a chain with two relays · according to Fig. 2 in a more effective arrangement can be trained. The individual sources of potential are defined as follows:

(7)

While the rectifiers G ₁₁ , G ₁₁ ', G ₂₁ , G ₂₁ . ■. with their cathodes are directly connected to the voltage sources, the rectifiers G ₁₂ , G ₁₂ ', G ₂₂ , G ₂₂ ' ... are connected to the corresponding voltage sources with their anodes. The source V ₁ is used jointly for the relays, S ₁₁ and S ₁₂ , and these relays are jointly connected to the common control terminal T via the resistor, R ₁ . The an-order works in the same way as shown in FIG. If. z. B. a potential; V _{21 is applied} to the control terminal T !, only the relay S _{11 can be} operated, since all rectifiers, with the exception of G ₁₁ 'and G ₁₁ , are blocked. This anao order has the advantage that only half of the resistors are required as in the arrangement in FIG. 2. There can be two. Potential sources are saved and two relays are used instead of one with only one winding. If, furthermore, the various potentials to be applied to the control terminal are taken from only two fixed potentials, one of which is greater than all of the pre-voltage sources and one is smaller than all the others, only half the number of series resistors is necessary in order to to obtain the required potentials at control terminal T. This is possible because the same series resistance can be used to obtain a potential, such as V ₂₁ at the control terminal T, from the highest of the two fixed voltage sources or a potential. F ₂₂ from the lowest potential source. The fewer resistance resistors are required *, the easier it is to make the necessary excretions between them. reach.

'The fig. 5 shows that counting chains with two relays according to FIG. 1 after the assembly · of Fig. ¹ 2 and circuits can be made as shown in FIG. This arrangement can advantageously be compared with a four-link counting chain according to FIG. 2, since the latter requires three relays, each with two windings, one relay with only one winding, four resistors, six rectifiers and seven voltage sources, whereas the arrangement according to FIG. S only two; relays with two windings each, two relays with one winding each, four rectifiers and three fixed voltage sources required.

The arrangement according to FIG. 5 can also be operated by two fixed potential sources, not shown, in series with one of two different resistors. In all cases, one of these resistors can be replaced by a short circuit. If it is advantageous to use more relay windings So, it should be noted that in all cases each winding which is connected to a certain bias voltage ¹ can in any case be replaced by two windings which have the same number of turns. These windings ^ ₀ are connected to one another at one end and lead at their other ends to a fixed DC voltage source with values such that the unloaded potential at the common end corresponds to the particular bias voltage. In this case, then the two windings do not work as resistors, and if they are respectively wound, the flows occurring in these windings are of equal magnitude, but opposite, so that the relays remain unacknowledged, wena the chain is not used g _0th

Such a case is shown in a Ausfübrungsbei game in Fig. 6, which represents a four-link counting chain of the type shown in Fig. 5, but in which series connections between the, Wick boys as in, Fig. 3 are used and the relays .S ₂₁ and: .S ₂₂ (Fig. 5) with only one winding now have two windings! (Fig. 6). In each relay, the two windings are connected at one end, while their other ends are connected to a negative voltage ¹ , which is grounded at the other pole. When using oppositely directed windings with the same number of turns, the resulting flux for each relay is equal to 0 if no expensive voltage is applied to terminal T. With a suitable definition of the resistances of the windings, the potentials at the common ends can be made equal and brought to any desired value. If z. B. the left winding of relay JT _{21 has} three times the resistance of the right winding and the battery voltage is -48 volts, the cathode of the rectifier G _{21 is} biased to -12 volts. If, on the other hand, the right winding of relay .S _{21 has} three times the resistance of the left winding, the anode of rectifier G _{22 is} biased to -36 volts. If: on the other hand, the resistors R ₁₁ and i? _{12 are the} same, the cathode of rectifier G ₁₁ and the anode of rectifier G ₁₂ , which are connected to one another, have a bias voltage of -24 volts. If, for example, ground potential is applied to control terminal T , the relay can. .S ₂₁ respond, while ReIaISr ₁ S ₁₁ remains in the rest position, namely by defining the number of turns of its winding and its resistance, so that an equally large, but oppositely directed flux is created. If a potential of -12VoIt is applied to the control source T, ReIaIS ₁ S _{11 can} respond alone, while when -36 volts and -48 volts are applied, the relays S ₁₂ and S ₂₁ can be triggered.

The resistors, such. B. R ₂₁ , which are connected in parallel across each winding of relay .S ₂₁ and 5 " ₂₂ , are designed so that a temporary excitation of the relay (z. B. .S ₁₁ ) is prevented if, that

Response of relay S _{2i is} desired. If such a temporary excitation of the relays is undesirable, ParaHel resistors can be applied to avoid this. These shunt resistors can be determined to be on the order of twice the resistance of the corresponding winding, and the ratio between the resistor and the associated winding should be substantially equal to the ratio between the other resistors and their windings. Suitable vacuum tubes can also be used in place of the relays.

Claims (8)

PATENT CLAIMS: i. Relay chain arrangement for storage, Counting or the like, in which the individual chain relays each via a rectifier to each, fixed staggered potentials and to the control line for actuation of the individual ao nen chain links each different potentials are applied, in telecommunications, especially telephone systems, characterized in that the individual relays (S ₁ to S ₃ in (Fig. 2), arranged in a contactless chain circuit, each have a response and a drop winding and that the response windings of the individual relays are on the one hand each at staggered fixed potentials (V ₁ to V ₃ in Fig. 2) and on the other hand via a supply rectifier (G ₂ and G ₃ in Fig. 2) and with this in series · series resistor (R ₁ to · R ₃ in Fig. 2) lie on a common control line (T in, Fig. 2), and these rectifiers each conduct when the control line carries a higher potential than the fixed one on the relevant chain relay lying potential, and that in each case the response winding of a chain oreliais (right winding from S ₁ to S ₃ in Fig. 2) with the discharge winding (left ♦ o winding of S ₁ to S ₃ in Fig. 2) of the preceding chain relay is connected, and that in each case Limiting rectifier (G ₁ to G ₃ ) on the one hand at a potential between the fixed potentials of the relevant chain relay and the following one (e.g. . B. V ₁ in FIG. 2) and on the other hand lie at the connection point, this · Vorwidenstandes concerned with the 'switched in ¹ row of the rectifier, and that this limitation rectifiers conduct when the at S applied potential fire control higher than that with the respective limit rectifier is firmly connected potential. 2. relay card arrangement according to: claim 1, characterized in that the first chain link does not contain a feed rectifier. 3. Relay chain arrangement according to claim 2, characterized in: that the individual Chain relays through different, specific, to the common control line (T in Fig. 2) applied potentials become effective. 4. Relay chain arrangement according to claim 3, characterized in that by applying; from Intermediate potential no chain relay responds. 5. Relay chain arrangement according to claim 4, characterized in that the connection a discharge winding with the response winding of the following chain relay through parallel connection (Fig. 2) or by series connection (Fig. 3). 6. Relay catenary arrangement according to one of the claims 2 to 5, characterized in that the chain ireliais, together with their associated supply and limiting rectifiers, combined in pairs and beginning in the middle of the chain and via the individual series resistors (R ₁ to R ₃ in Fig. 4) are placed on the control line and that all rectifiers of a relay chain half (S ₁₂ , S ₂₂ and S ₃₂ in Fig. 4) and all of this relay chain half associated fixed potentials (F ₁₂ ' V ₂₂ , V ₂₂ V ₃₂ and F ₃₂ 'in Fig. 4) are reversed. 7. Relay chain arrangement according to claim 5 or 6, characterized in that with Impuls.-control the individual pulses applied to the control line continuously staggered potentiates be assigned,. 8. Relay chain arrangement according to claim 5 or 6, characterized in that when marking processes o a certain chain relay becomes effective by applying a certain potential assigned to it to the fire line. Considered publications:
German Patent No. 833 369;
U.S. Patent Nos. 1,593,993, 1,982,290, 058 170. 1 sheet of drawings © 609 619/162 9.56 8.57)