DE1011935B - Circuit arrangement for the magnetic storage of electrical switching orders in saturation chokes - Google Patents

Description

GERMAN

The invention of the main patent application is that for magnetic storage electrical Switching jobs in saturation chokes special saturation transformers, which can be optionally used with the saturation chokes can be connected to generate the current or voltage surges to be stored and provided for converting the stored switching orders into series of elective current impulses are. The first saturation transformer has the task of generating the voltage pulses for magnetization to supply the saturation reactors during storage; the latter must have smaller voltage pulses Generate amplitude for the gradual demagnetization of the saturation chokes during withdrawal. So now the number current impulse series to be saved corresponds to the saved switching order corresponds to a very precise adjustment of the two saturation transformers with regard to the field change required during a magnetization reversal process. Without this, the conversion is easy to ■ fakes. As a result of the manufacturing fluctuations in the band ring cores used for the saturation chokes this comparison is difficult to achieve.

The condition of an exact adjustment of the two saturation transformers can be avoided if one According to the invention, the magnetization of the saturation chokes when storing the switching orders Serving saturation transformer also for the gradual demagnetization of the saturation chokes Used when the switching orders are saved and mutually dependent switching means provides, which also with simultaneous or almost simultaneous storage and retrieval of the Switching orders ensure an interference-free transmission of the voltage surges in the shared saturation transformer Secure transmission circuits running to the saturation reactors.

In this way, the correct proportionality of the two voltage circuits is achieved without any special adjustment achieved. In addition, a saturation transformer is saved.

It is already known to design the saturation reactor itself as a saturation transformer, but it is required on the one hand iron cores made of different magnetic material for the chokes, on the other hand at least three windings per choke. Of these windings, one forms in conjunction with one Set of matched resistors to store the saturation transformer, the second winding the withdrawal saturation transformer and the third winding the actual saturation reactor. These The solution is to have a larger number of saturation chokes, as is the case with key-controlled number dialing inevitably involves a great deal of effort.

Circuit arrangement for the magnetic

Storage of electrical
Switching jobs in saturation chokes

Addition to patent application S 37853 VIII a / 21 a ³

Applicant:
Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dipl.-Ing. Kurt Fischer, Munich,
has been named as the inventor

The invention avoids this expense in that, on the one hand, it uses saturation chokes in a known manner with uniform core material and only one single winding, plus special saturation transformers is used, and according to the invention, the input and output saturation transformer is combined is and. it is ensured by mutually dependent switching means that the inputs and Withdrawal processes, which partly use the same switching paths, cannot interfere even with simultaneous injection and withdrawal. Using the In contrast, known saturation chokes allow a completely independent one from the start Separation of the injection and withdrawal circuits so that switching orders can be entered and removed at the same time there is no risk of mutual interference from the saturation reactors. pre-condition It is, however, necessary that the same saturation choke is switched on and off at the same time is prevented.

1 shows an exemplary embodiment of the invention, omitting all circuit details that are not required for understanding the invention. With the SÜ for generating both of the inputs also serving as the Withdrawal surges transformer saturation is indicated. It has a primary winding PW, a secondary winding SW and a reset winding RW. In the primary winding

709 587/156

1 Oil 935

are the current or ·. Voltage surges generated in that the core is remagnetized from one saturation remanence to the opposite saturation remanence. This is effected in that a certain-saturation remanence is forcibly set after each surge by the "reset winding RW in the saturation transformer. At the secondary winding SW DES Sättigungsübertragers be correspondingly by the keys Tl to TlO

When relay E responds, magnet De is also switched on:

3. +, e5, De, -. ■ -

produced:
4. +, RW, e3, ab4k, -.

5 The Einspeicherwähler takes a step T || IAE ^'

does the next saturation choke switch to the Übai? - "

scope of responsibility. After relay E has dropped out, the: ^ transmission circuit to the saturation choke at Kontailiv e 4 is interrupted, the circuit of the primary winding ':,;*'

the digits to be keyed in when dialing the number I io PW at the contact el interrupted and the circuit f to 0 partial voltages for the magnetization of the reset winding RW at the contact e3 again; Saturation chokes - tapped .. A smaller partial voltage is applied to the secondary winding via the
Contact from 1 tapped to generate the demagnetizing voltage surges. When the 15 through this last-mentioned circuit is keyed in, the

Digits are returned to a specific,? 'By the common key Tg2.

lais E switched on for a short time, which on the one hand is worth the saturation remanence, z. B. the negative Remä ¹ ^ I circuit for the primary winding of the saturation nenzwert, remagnetized. ;, | ;! ||

Transmitter closes, on the other hand, for the reset The timing of the above-described; p l ||

winding RW opens. In addition, the primary 20 switching processes can be seen on the basis of the diagram;,; Follow the winding PW also through the relay Ab in FIG. 2. The Tg button is a certain 1 ¹ I storage via contact from 3 briefly switched on, for example for about 100 ms, pressed. Depending on the date, the reset winding is pronounced by contact a & 4, relay E responds for about 10 to 15 ms. ; D ^ r

switches. Relay Ab in turn is triggered by contact i 1 rotary magnet De is dependent on it after about 7 Äs,

of a one-relay self-breaker / switched on. 25 excited. The curve X shows the course of the Magneii-:;,. ■ IJ The saturation chokes Zl ... Z10 are on the one hand sierungsstroms partly in the saturation chokes, telfe,: ,,, on the contact banks del, de2 of a storage in the saturation transformer. In the time χ the :; «! Selector with the magnet De, on the other hand to the saturation choke due to the voltage surge from the contact banks dabl, dab 2 of the withdrawal selector saturation over carrier is magnetized. This Mamit the magnet Dab .._ About the contacts of the re- gnetisierungsstrom 30 ms has subsided after about 5, relay E or Down is the transmission path between After about 7 ms, the rotating magnetic De off his Wählerdem saturation transformer and Zähldrosseln arms around moved one step further. As a result, the saturation choke Zl is switched off alternately via the store selector or off and the next store selector is established. The scanning path contains a saturation choke on the transmission path ^J: "'Söge toggle relay P, which switches the end of a stored 35. ■ ■'

Numbered current surge series. In this way, the simple,

FIGS. 2 and 3 show diagrams of the temporal keyed digits as voltage surges in the saturation curve of the actuation, the switching means stored during throttling. ! ^; and save the dialed digits. To blank out the stored voltage surges Let us first consider the simplest case, at 4 ° the start button 6 * is pressed. In this way, Rewelchem will switch on the injection and withdrawal separately according to Λ: 'takes place each other. First, all 5 ± r, 5 c »_ borrowed digits are keyed in by pressing the appropriate keys T ■>> -, *, · , then the start key 6 * is bridged to contact st 2 as a precautionary break contacts'ö.

Print out. Of course, the relay / is switched on: K: ^:: f ^: '

Instead of the start button, also a start criterion for 6 + stl ϋ2 J j3

step at any time. When pressing '''''

one of the number keys, e.g. B. T 2, the relay / is interrupted by means of its contact / 3

common key Tg pressed. The capacitor Co 1 is released by contact Tg 3 working as a self-interrupter in the cycle of Num. Due to Kon- 5 ° mern current surges, ie in a ratio of 60: 40 ms, its clock Tg2 is relay E briefly through a Kon-own circuit. Relay / gives by opening his

Contact ] 2 releases the capacitor Co2. Relay Down is briefly energized by contact / 1:

7. +, jl, e2, Co2, Ab, -. " . ■ /,.,

capacitor surge excited:
1. +, Tg2_, ab2, Col, E, -.

Relay E interrupts at contact e2 as a precaution 55

the circuit for relay Ab. At contact el , relay Ab is interrupted by opening its p

the primary winding PW of the transformer SO clocked from 2 as a precaution the circuit of the Eintasfe

switches; by opening the contact e 3, the relay E. At contact from 3, the primary winding

Reset winding RW of the saturation transformer off - PW on, by opening the contact ab4t

switched. The reset winding RW of the saturation over-

ization of the core is switched off in the secondary winding. The saturation transformer will

of the transformer SÜ induces a voltage surge. thereby in turn remagnetized, whereby a Spaii ^

The Γ 2 key induces a corresponding splitting surge in the secondary winding SW

voltage is tapped and on is withdrawn via contact e4. This arrives during the excitation of the Re ^

Speaking voltage surge on the choke Zl relays Ab to the counting choke Z1: "" * ■■ '.

^{wear; en:} 8. +, ab8, dab2, Zl, dabl, P, ab6, abl, SW ₁ ψ.

2. +, abl, de2, Zl, del, ab5, ei, T2, SW, +. 7th

This voltage surge of smaller amplitude and

As a result, the saturation reactor Zl is magnetized in an opposite direction, the SätM-

magnetized at a certain remanence point. At 70 flow throttle in one direction opposite to the

1 Oil

Infeed voltage surges. This reduces the remanence in the saturation reactor. After the relay Ab has dropped, the primary winding of the saturation transformer is switched off again and the reset winding RW is switched on again. As a result, the saturation transformer is remagnetized again. These processes take place at the beginning of the first excitation of the relay /. As can be seen from the diagram in FIG. 3, they repeat themselves with every further current impulse given by the relay /. This transmits the pulses in some way as number pulses on a line. The relay Ab stores the characteristic field value of the saturation choke step by step. As soon as the magnetic remanence reaches the saturation range - according to the example chosen after two current surges ■ - ■, the resistance in the scanning circuit suddenly decreases, whereby the toggle relay P is energized, which marks the end of the numbered current surge series sent. Relay P interrupts the circuit of the relay / through contact ρ 2 and thereby terminates the current impulse. Relay P also switches on the selector magnet Dab :

9. +, p \, Dab, -.

The withdrawal selector takes one step and switches on the next saturation reactor. The relay P is also reset and the relay / is switched on again. Relay / turn briefly switched on a relay from. The game starts all over again. In this way, all counting chokes are scanned and the stored voltage surges are converted into numbered current surge series corresponding to the entered digits.

If digits are keyed in during the removal process, a distinction must be made between several cases:

1. The inputting process occurs in the pause between two series of numbered current impulses to be passed on. In this case, the start of the new series of current impulses to be stored is triggered by the drop in the push-button relay E ₁ d. Ii. made dependent on the end of keying. Tapping relay Ab can therefore only respond via the normally closed contact e 2 of the relay after it has dropped out. In the worst case, this has the effect of shifting the start of the series of numbers to be stored by 15 ms. This slight shift does not affect the free selection time, which is secured by an auxiliary relay (not shown).

2. The keying-in process coincides with a scanning pulse from the relay Ab that has already been initiated. In this case, the excitation of relay E must be made dependent on the drop in relay Ab. This is done by the normally closed contact from 2 in the circuit of the relay E. In this case, a minimum actuation time of the numeric keys must be prescribed, which is determined by the sum of the release time of the relay from and. Response time of relay E, that is a maximum of 30 ms, a time that can be easily reached even if the button is pressed quickly.

3. The keying-in process is already in progress when a new pick-up pulse starts. In this case, the keying-in process is completed and the response of relay Ab is delayed by contacts 2 until relay E drops out. Since the response time of both relay E and relay Ab is short compared to the duration of a transmitted pulse and the saturation reactors are magnetized in an even shorter time, there is no distortion of the transmitted pulse series.

As the above cases show, small temporal shifts between the entry and withdrawal permitted, but which are limited to the much larger times of the number pulses and Free election times are without influence.

The above embodiment shows an application of the invention on keyboard choice. If the invention is to be used for pulse repeaters, where the saturation chokes step by step through the individual pulses, each characterized by equal voltage surges, are magnetized, the incremental advancement of the storage selector must by a relay dependent on the end of each pulse train, e.g. B. by a bridging pulse series Delay relay, can be made dependent.

Claims (5)

PATENT CLAIMS: 1.Circuit arrangement for the magnetic storage of electrical switching orders in saturation chokes, in which special saturation transformers, which can optionally be connected to the saturation chokes, are provided for generating the current or voltage surges to be stored and for converting the switching orders stored in optional current surge series, according to patent application S 37853 VIII a / 21 a ³ , characterized in that the saturation transformer (SÜ) serving to magnetize the saturation chokes when storing the switching orders is also used to demagnetize the saturation chokes when removing the switching orders and mutually dependent switching means (E, Ab) also when simultaneously or almost simultaneous storage and retrieval of the switching orders ensure a trouble-free transmission of the voltage surges in the transmission circuits running from the common saturation transformer to the saturation reactors. 2. Circuit arrangement according to claim 1, characterized in that the generation of the current or voltage surges for magnetizing and reversing the magnetization of the saturation chokes in the common saturation transformer is controlled by relays (E, Ab) which are actuated briefly by capacitor surges themselves. 3. Circuit arrangement according to claim 2, characterized in that the switching on of the saturation transformer when the digits are keyed in relays (E) when it is actuated the circuit of the relay (Ab) controlling the saturation transformer when the digits entered are released and vice versa makes the release relay ( Ab) makes the push-button relay (E) ineffective when it is actuated. 4. Circuit arrangement according to claim 1, characterized in that the saturation chokes (Z 1 ... Z10) have two poles each via two switching arms (del, de2) of a selector (De) which is incremented during storage and via two switching arms (dab 1, dab2) a selector (Dab), which is incremented after a digit has been saved, and corresponding contacts (f4, abl, from 5 ... from 8) of the storage and withdrawal relay (E, Ab) are connected to a secondary circuit of the saturation transformer. 5. Circuit arrangement according to claim 4, characterized in that the Einspeicherwähler (De) by switching on the saturation transformer 1 Oil push-button relay (E) or a control relay that is dependent on the end of a pulse series, the withdrawal selector (Dab) by the end of a stored numbered current series in the blanking circuit of the saturation choke the toggle relay (P) in the drawing is switched step-by-step. References considered: U.S. Patent No. 2,430,457. ,,, 1 sheet of drawings © 709 587/156 7.