DE974727C - Circuit arrangement for devices that are subject to the same temperature influence, for button-controlled selection in telecommunications, in particular telephone systems - Google Patents

Description

Saturation chokes can be used as a time element, as a counting element or as a storage element will. In the Siemens magazine, 1952, issue 3, pp. 140 to 144, there is, among other things, an arrangement described, in which a saturation reactor is operated as a time element. In doing so, according to Figure 2 of the above-mentioned article shows a saturation choke lying in series with an indicator variable winding taps at a fixed voltage or connected to a variable voltage.

With reference to this arrangement it is stated in the article that a precisely working time element is obtained with the basic voltage kept constant, since the properties of the material are influenced by external influences, e.g. B. the temperature, are largely independent. The temperature coefficient α of a throttle is generally around 10 ~ ³ , so that when the temperature δ changes by 20 ° C, the response time of the indicator is α · Αδ = 2 · το ~ ² , that is to say by 2% - that is to say a little Amount · - ■ is changed.

However, the situation is fundamentally different in the case of one used as a storage element Saturation reactor, in which several, z. B. ten, memory states are to be distinguished that thus serves as a multi-stable storage element. Corresponds to a change of 2% of the total field stroke in such a memory element a

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Change of 20% of a single stroke if ten storage states are to be distinguished, and 60% of a single stroke if thirty storage states are to be distinguished. For the simple case of differentiating between ten memory states, however, this means that if the ^{temperature has risen by 20 0} C when reading a "ten", a response current for the indicator already flows during the tenth pulse and not only at the eleventh pulse, or vice versa, that at um 20 ⁰ C lower temperature when reading a "ten" the response current for the indicator, which should be fully available during the eleventh pulse, is shortened by 20%. This in turn requires greater reliability of the indicator's response, which cannot even be mastered with electronic components, especially in the case of larger temperature differences and / or when more than ten pulses are stored. There is therefore a need to reduce the influence of temperature in arrangements in which saturable chokes are used as storage elements.

U.S. Patent 2430457 shows an arrangement in which storage elements are used, the cores of which are made up of several different ones Assemble magnetic materials and are provided with several windings. The storage the values to be saved. B. act to ranks current surge, takes place according to the number of current surges to be stored and one for each Storage element individually assigned storage winding. It is saved over two further individual windings and a complicated tube circuit through which the individual impulses be measured. Apart from the expense, which is disproportionately large and for storage facilities in telecommunications, in particular telephone systems, is not portable, this well-known is also liable Arrangement of the disadvantage of a temperature dependency, as has been proven, for storage elements at.

One might assume now that the temperature response of the known arrangement would fix in a simple manner in that instead of normal Einspeicherwiderstände resistors would be used, which are wound from constant and therefore only have a temperature coefficient of about io ~ ^5th In fact, this does not improve the situation, since the temperature dependency of an arrangement is always based on the weakest link in this arrangement. As such, however, in the arrangement known from the cited patent specification, the storage elements themselves and the discharge elements, such as tubes, capacitors and the like, are to be considered.

The invention now relates to a circuit arrangement for devices which are the same The influence of temperature are subject to button-controlled choice in telecommunications, in particular Telephone systems in which saturation chokes act as multi-stable storage elements by actuation by selection buttons with a current or voltage surge, each of the series of pulses a dialing number that is formed when the data is withdrawn. The object of the invention is to avoid the temperature dependence of the known arrangements and at the same time the necessary Reduce effort. This is achieved with the invention in that the storage and retrieval of the dialing digits shared across several saturation chokes, the one or saturation transformer measuring the pulses to be stored is made and the Storage - serving transformer is provided with partial taps, via which the corresponding the individual dialing digits measured current or voltage surges can be tapped.

With the invention, the temperature dependency is reduced to zero, since all elements of a store, namely the storage elements, the storage elements themselves and the discharge elements, have the same temperature coefficient. Even when using a memory according to the invention as a long-term memory, the temperature dependency is equal to zero, since after storing a value in a throttle and after changing, e.g. B. lowering the temperature by z. B. 20 ⁰ C not only change the properties of the discharge transmitter so that the single pulse with a total storage volume of ten pulses and a temperature coefficient of io ~ ³ is 2% smaller, but also the remanence point of the storage choke by a corresponding Value is shifted, namely by the fact that the total storage volume is reduced by 20% of an original single pulse.

At the same time, however, with the invention of the ioo The effort of the known arrangements is significantly reduced. Instead of ten resistors high quality and accuracy for the storage in the arrangement according to the said USA patent occurs in the invention, a single transformer with taps. The storage elements only need to be provided with a single winding and with a core consisting of only one Material exists because the dimension of the values to be saved is determined by the dimensioning of current or voltage voltage pulses in the invention is determined directly by the transformer and not by dimensioning a current through resistors, which have a special storage winding in each storage element would assume.

Also compared to a counting arrangement used as a memory according to Figure 6 of the above-mentioned article the Siemens magazine would result in considerable savings in effort. Apart from this, that the transmitter in the known arrangement the counting element individually and in the invention is assigned to a plurality of memory elements in common, are essential in the invention Savings made possible by the fact that the winding taps the transformer and not the Storage elements are assigned. Among other things

it is also possible to use the key set for keying in the switching orders together for all Provide storage elements on the transformer.

The withdrawal via a transmitter in the arrangement according to the invention has the obvious one Advantage of the cost savings compared to tubes and complicated measuring members the arrangement known from the United States patent. With the ones from Siemens magazine

ίο known arrangements is one in this regard Comparison not possible at all, since it is a matter of counting arrangements or timing arrangements, where only counted or stored up to an end value, but never queried will.

The invention is explained below with reference to FIGS.

Fig. Ι shows a keyboard number generator as an embodiment. In the figure, circuit details are shown only to the extent necessary for the Understanding of the inventive concept is required.

Fig. 2 shows various characteristics of the switching elements used Hand of the electrical and magnetic that take place during storage and retrieval Operations are described.

The keypad number transmitter according to FIG. 1 has ten dialing keys T 1 to To assigned to the numbers 1 to ο. Of these, only the keys Ti, T5, T6 and Γο are shown in detail in the figure. The key T 1 is a dummy key, its contacts are not connected. The keys T 2 to Tg are, as shown for the keys Tζ and T6 , with partial taps of the secondary winding II of the saturation transformer Üi, the key To connected to one end of this winding. The common key contacts 1 tg and 2 tg close when each of the selector keys T τ to To is actuated.

For example, the selection key T6 corresponding to the number 6 may be pressed. The common key contact 2tg closes a circuit for the reset winding III of the transformer Ü ι and the relay A with the contacts 3 α to 6 α and together with contact 1 tg for the saturation choke currently provided via the switching arm d 1 of the selector D ι, for example the saturation choke Zi. The transformer Ü 1 and the choke Z1 were brought before the reversal of the contact 5 α by the direct current flow through contact 2 ig in their initial magnetic state, such that after interruption of the current flows through the contacts 3 α and 5 α the remanent Inductions of the transformer and the choke core assumed one of their respective two saturation remanence values.

Fig. 2 a schematically shows the hysteresis loop of the core material for the transformers UEI, Fig. 2b, the core material of the saturable reactors, particularly including the throttle Zi. In Fig. 2a, the magnetic induction decreases Bü 1 of the transformer U ι after moving of the contact 3 α the remanence value —Rüi, according to FIG. 2b that of the throttle Z1 (Bz) after switching over the contact 5 a the remanence value —Rs .

Contact 4a switches on relay B with contacts yb to 10 &. Relay B binds itself for the duration of the button press via its contact 8 b, which at the same time switches relay A off again. Relay A drops off delayed due to a short circuit in its winding I through contact 3 α. Contact 7 b closes a circuit for the primary winding I of the saturation transformer Üi. The core of this transformer is now saturated by the current flowing in the opposite direction. The magnetic induction assumes the value corresponding to the point sü 1 on the positive saturation branch of the hysteresis loop according to FIG. 2a. The position of the point sü 1 is determined by the magnitude of the current IU 1 established via contact 7b after the saturation.

The change in induction during unsaturation results in the occurrence of an induction current in the secondary winding II, which is appropriately referred to as a voltage surge when the secondary winding is weakly loaded and as a current surge when the secondary circuit resistance is low. A measure of the magnitude of this induction surge is its voltage or current-time integral, which has a known, lawful relationship to the change in induction in the primary circuit. 2c shows schematically the voltage-time integral corresponding to the magnitude of the induction surge as a rectangular area I in the voltage-time diagram. U means the voltage occurring at the secondary winding II, t the magnetization reversal time. The size of the integral is only dependent on the change in induction caused by the primary winding. This can, as Fig. 2a shows, be made practically independent of the current flowing after the saturation or of the voltage applied to the primary winding if a core material with a sharp saturation kink is used, in which the saturation branches of the hysteresis loop as parallel as possible to the The abscissa axis. Such core materials are known and used for saturation transformers. The size of the voltage integral occurring in the secondary circuit can therefore be made largely independent of voltage fluctuations in the primary circuit.

Using the selection key T 0, as indicated in FIG. 2 c, the full induction surge is tapped, and fractions of this induction surge are tapped via the keys T 2 to T 9 connected to partial taps of the secondary winding II. The induction surge picked up via one of the selection keys causes a change in the magnetic induction of the switched-on saturation choke. The transformer U 1 and the chokes are matched to one another in such a way that, for example, the magnetic induction of the core material of the choke assumes the value + Rs after pressing the selection key To (FIG. 2 b). If the key T 6 is pressed, the ascending branch of the hysteresis loop in FIG. 2b is, for example, up to

go through to point ί 6. After the induction shock has subsided, point / 6 is reached.

The one triggered by pressing the selection button Γ 6

Induction surge is therefore stored in the form of a change in the remanent induction of the reactor core from - Rs in / 6. This process takes place during the release time of relay A.

After the relay A has dropped out, the drive magnet of the selector is via the contacts 6 α and gb

ίο D ι and the relay V with the contacts 11 ν to 14 w switched on. The next saturation choke Z 2 is made available for subsequent storage via the selector arm dl. Contact 11 ν switches on winding I of relay X with contacts 15 λγ to 17 χ . During the response time of the relay X, the winding I of the toggle relay P is energized via the contacts 12 ν and ijx , which then places its contact 18 ^ in the Z position. Ν contact 13 completes a circuit for the secondary winding II of Sättigungsübertragers U2, which is thereby brought in an analogous manner as described above for the transmitter T 1 in its magnetic initial state. Contact 14 ^ closes, for example, a line loop for forwarding the dialing pulses to be sent out subsequently.

Contact i8p switches on the self- interrupting pulse relay / with contacts 191, 20 i and 22 i to 24 j. Contact 20 i takes over the further excitation of the relay V, since its switch-on circuit is interrupted after releasing the selected button on contact 9 b. Contact 22 i sets a pulsed manner, the secondary winding II of the transformer Ü'2 via the winding II of the latching relays P to the respectively via the switching arm d.2 of the selector Ό 2 turned-saturable reactor, here the choke Zi. Contact 23 i closes during the pulse, a circuit for the primary winding I of the saturation transformer Ü2. Contact 24 i sends pulses, for example in the form of loop interruptions on the line L.

The magnetic induction Bü 2 of the core of the transformer £! 2 oscillates under the influence of the contacts 22 i (in the rest position) and 231 (in the working position) between the two saturation points + sÜ2 and -sü2 of the hysteresis loop shown in FIG. 2d Values. For example, while the relay / is in the rest position, the ascending branch of the hysteresis loop is passed through from - sü2 to + sü 2 , while the descending branch is passed through between the same points in the operating position of the relay. During the saturation in the working position of the relay / a voltage or current surge proportional to the change in induction is induced in winding II of the transformer, the corresponding voltage-time integral of which is indicated schematically in FIG. 2 c as a rectangular area II. Each such induction surge causes a proportional change in the magnetic induction of the respectively connected saturation choke, in such a way that it is gradually returned to its initial value in the region of negative saturation.

According to FIG. 2 b, starting from the storage value / 6 of the magnetic induction of the choke Z i, the curve s'6-i-i'-2-2 ^r -2) -2) '- A'A' ~ S ~ (~ Rz) - 6 - (- Rs) run through. Points 1 to 6 of this curve are taken in the working position of the relay /, points 1 'to 4' and - Rz in the rest position of this relay.

The magnetic induction Bz is shown in Fig. 2b as a function of the current Jz flowing through the saturation reactor. The response current value of winding II of the flip-flop relay P is denoted by Jp. As can be seen from the figure, this value is reached or exceeded for the first time when the hysteresis loop is passed through on the sixth response of the relay / the curve piece (-Rz) -6. The relay P then responds via its winding II and puts its armature contact 18p back into the separating layer T. The circuit for the relay / is thereby interrupted and the pulse transmission is ended. Relay V and subsequently relay X drop out. Your fall times determine the voting pause between two series of voting impulses. The drive magnet of selector Ό 2 is excited via contacts 18 /> and 15 χ , the switching arm d2 of which adjusts to the next saturation throttle.

The selector Ό 2 has two contacts 25 d 2 and 26 ^ 2. After the relay X has dropped and during the time the drive magnet D 2 drops, a circuit for the winding I of the toggle relay P is established via the contacts 17 χ and 25 ^ 2, the switching arm d2 and the saturation choke that is switched on, which then returns its armature contact 18 p in the character position Z and thus initiates the storage of the following series of dialing impulses. The current flowing here is so small that under its influence the magnetic induction of the saturable choke is not noticeably influenced and its stored value is therefore not falsified.

As described above, selector D 1 is advanced by one step with each storage or each key press. The voter D 2 hurries after him by being advanced by one step after each withdrawal, as shown. If the voter Ό 2 catches up with the voter Di so that the switching arms d 1 and d 2 are on the same output, this is the sign that all the stored series of dialing pulses have been sent out. After the relay X has dropped and during the dropping time of the MagnetaiD2 there is a circuit for the windings I and III that runs through the contacts 17 x, 2 $ d2, the switching arms d2 and d ι and the contacts 5 a, 26 d 2 and ι6λγ of the toggle relay in which the excitation of winding III outweighs that of winding I. Under the influence of winding III, the armature contact i8p is held in the separating layer Γ, thus preventing the relay / from being switched on again.

As shown in the present example, the saturation over-

tragers Ü2 induced current or voltage surges, the induction changes of the saturation reactors caused by the storage are reversed. The arrangement could also be made so that under the influence of these induction surges, the magnetic induction of the saturation chokes is changed in the same sense as in the storage, so that after a certain number of pulses, for example

ίο value + Rz in Fig. 2b is reached and with the next pulse a point on the positive saturation branch of the hysteresis loop is reached, then the toggle relay P is again excited in the sense shown via its winding II. The connections of the selection keys Tx to To to the secondary winding II of the transformer Ü 1 would then have to be exchanged. The arrangement shown here, however, has the advantage that the magnetic core values of the chokes are eliminated by the back-magnetization of the saturation chokes to their initial magnetic state which takes place during the withdrawal. Since the magnitude of the induction surges generated by the saturation converter Ό 2 can be made largely independent of fluctuations in the operating voltage under the aspects already mentioned for the saturation converter U 1, based on the arrangement shown in the exemplary embodiment, the circuit arrangement according to the invention is largely independent of external influences, which other known arrangements do not have.

If the number "1" is selected by pressing the selection key T 1, since this key is not connected, the magnetic induction of the saturation choke to be stored is not changed, but rather retains the initial value - Rz (Fig. 2 b). When the relay / is released for the first time, the response current value of winding II of the flip-flop relay P is reached or exceeded and the relay / is switched off again immediately. So there is only one voting impulse to be sent.

Claims (6)

Patent claims: i. Circuit arrangement for devices that are subject to the same temperature influence, for button-controlled dialing in telecommunications, especially telephone systems, in which saturation chokes are stored as multi-stable storage elements by pressing selection buttons with a current or voltage surge, which each characterizes the pulse series of a dial number, which at The storage is formed, characterized in that the storage and retrieval of the dialing digits is carried out via several saturation chokes jointly assigned saturation transformers (Üi, Ü2) measuring the pulses to be stored and removed, and the storage transformer (Ü 1) with partial taps is provided, via which the current or voltage surges measured according to the individual selection digits are tapped. 2. Circuit arrangement according to claim 1, characterized in that the saturation chokes with the help of the further saturation transformer gradually to the end of the withdrawal characteristic value of their magnetic induction are to be brought about in such a way that they are determined by the value of the magnetic Induction at the beginning of the withdrawal, a certain number of steps required for this is in a fixed connection with the dialing digit identified by this value. 3. Circuit arrangement according to claim 2, characterized in that the withdrawal via the withdrawal transmitter via a pulse transmission relay (/). 4. Circuit arrangement according to claim 1, characterized by a one-armed selector (Di, D 2), through which the two saturation transformers are connected to the saturation chokes. 5. Circuit arrangement according to claim 4, characterized in that the same selector arms (dl, d2) switching means (PIII) can be influenced, which mark the end of the transmission of all keyed dialing digits. 6. Circuit arrangement according to claim 3, 4 and 5, characterized in that both the pulse transmission relay and the drive magnet (D 2) are dependent on at least one of the two rotary selectors from one and the same switching means (P). Considered publications:
German Patent Nos. 888268, 914393; German patent application T 1250 VIII a / 21 e ³
(published July 12, 1951);
U.S. Patent No. 2,430,457;
Siemens-Zeitschrift, 1952, issue 3, pp. 140 to 144; "Electronic" magazine, 1953, pp. 146 to 149; Publication "Proceedings of the National Electronics Conference", Vol. VII, Chicago, 22./24. X. 1 sheet of drawings 109 56OT 4.61