DE1101523B - Circuit arrangement for connecting an inductor to a connecting line - Google Patents

Description

Circuit arrangement for connecting an inductor to a connecting line The invention relates to a circuit arrangement for switching on an inductor to .a connection line after switching off the speech equipment from , this connection line in telephone stations, @ especially in field telephones.

Several circuit arrangements of this type are already known. With these, the inductor is automatically connected to the connection line by switching contacts switched on and the speech device switched off from the connection line, when the inductor crank is operated. The movement of the switch contacts is here either directly from or from the rotary movement of the inductor crank or from (its rotational speed derived. The inductors of the first-mentioned switching type include all embodiments, in those who actuate the switching contacts by shifting the crank axis is effected or in which the actuation of the switching contacts via a mechanical Transmission link is derived directly from an angle of rotation (German Auslegeschrift 1033 719).

Embodiments are provided as inductors of the second type of switching Centrifugal contacts known (Swiss patent 239648).

Inductors of both one and the other kind have disadvantages, which are conditioned by the principle of switching. While with inductors, with those who switch directly from the rotary motion of the inductor crank is, .the crank can in principle not be made smoothly and also a watertight execution is not possible, inductors have the switching is derived from the speed of rotation of the inductor crank, the disadvantage that with these a Morse code is not possible.

In the case of inductors; the first-mentioned type of switching is namely for Resetting the changeover contacts in any case an automatic return movement the inductor crank necessary. The restoring force required for the return movement generally provides a spring which must be dimensioned so strong that it overcomes the frictional force that opposes a movement of the inductor crank. When turning the inductor crank, on the other hand, the RÜGkstellkraft must first the spring must be overcome before the rotor can be set in rotation can to enable the desired switching.

Accordingly, the greater the restoring force of the spring, the greater it is also the continuously effective counter-torque on the inductor crank when cranking. While , under favorable climatic conditions the frictional force between the inductor crank and whose storage is usually still small enough, it reaches with bad climatic conditions, conditional. through; the toughness of the lubricant, already a considerable size, the frictional force would be even greater if the inductor housing would be made watertight by a sleeve around the inductor crank. In this In the event of a safe switchover, the inductor could only be unreasonable with one difficult inductor crank are executed.

With inductors, where the switching from the rotational speed the inductor crank is derived, there is no need to reset the changeover contacts Return movement of the crank required. The restoring force is therefore omitted. Such Inductors can run smoothly even if they are watertight. For this, however, the switchover only occurs after a specified rotational speed has been reached so that it depends on the acceleration of the inductor crank after which angle of rotation is switched. Thus, with inductors of this type, the conditions cannot be met meet, which are known to be linked to an inductor crank. Also is in the previously known inductors of this type, in which one for switching Centrifugal switch is used because of the space required for the switching device the rotational speed of the rotor limited by the desired inductor frequency - still very big.

Of the known inductors, one type has the principle one Disadvantage that the crank is difficult to turn and a waterproof design is not possible, and the other has the disadvantage # that it is expensive and for Morse code operation Is unsuitable. In addition, both types have a disadvantage in common, which is due to the fact that the actuation of the changeover contacts in all cases through a mechanical transmission link from the movement of other inductor parts is derived. The - changeover contacts can not be encapsulated and through a .tight housing protected. But it is precisely the contacts that are used in inductors particularly failure-prone parts.

The aim of the present invention is a mode of switching for a universal one Inductor, with which a Morse code operation is possible, which is independently waterproof can be executed and in which the changeover contacts are protected for themselves can.

This goal is: by a circuit arrangement for turning on a Inductor to a connection line after switching off the speech equipment from this connection line in telephone stations, especially in field telephones, achieved in that a changeover relay, .das by turning tthe inductor generated current is excited, connects the inductor to the connecting line.

FIGS. 1 to 7 show exemplary embodiments of the invention. None of them The details required to explain the invention are provided for a better overview because of being omitted.

The fing. 1 shows the changeover relay U, with its voltage winding I connected in parallel with the winding of the inductor T and its current winding II in series with the inductor winding I. When the inductor is actuated, the alternating current generated is rectified by the Graetz rectifier Gr 1 and causes the changeover relay U to respond via its winding I. As a result, the voice wire of the connection line TAL is switched off from the voice wire a2 leading to the not shown voice station Spst by opening the contact u1: and by closing the contact u2, the inductor is connected to the voice wire a 1 of the connection line TVLL. As a result of the load, the voltage: of the inductor .T drops, and there is a risk that the relay U via its winding I would no longer be held in the event of a heavy load. However, relay U is now held via its winding II by the current flowing through it. The winding II of the changeover relay U is also in a cross arm of a Graetz rectifier. If alternating current relays are used instead of the direct current relays shown here, the rectifiers Gr 1 and Gr 2 are not required.

2 shows a modification of FIG. 1, which consists in that two rectifier cells of the Graetz rectifier Gr4 for the rectifier Gr3 be related to.

While in Figs. 1 and 2, the examples of the so-called "open circuit or Morse code" of an inductor should be the inductor winding and d'ie windings of the switching relay U between the two wires a 1 and b 1 of the connecting line VL and the line leading to the call station is interrupted when the inductor is actuated, are shown in FIGS. 3 and 4, which are intended to be examples of the so-called "short-circuit circuit" of an inductor, the inductor J and the windings of the switching relay U in the longitudinal branch of the speech wire type .the inductor winding is short-circuited in the idle state of the inductor for speech currents. The wires leading to the call station are short-circuited via contact u1 when the inductor is actuated. When the relay U responds (via the winding U II), the short circuit of the inductor and the winding UI of the relay U is canceled by opening the contact u2, and the inductor is connected to the voice wire via the then closed contact 7z 1 b switched on.

FIG. 4 shows a variant of FIG. 3. As in Fig. 3 also here the inductor started in short circuit. For inductors with greater power but it is difficult to crank the inductor in this short circuit. Therefore is, as shown in Fig. 4- is shown, a capacitor Ko in .den short circuit switched on. This capacitor is dimensioned so that: it for the alternating speech current has a low resistance, while its resistance for the low ringing frequency is high. As a result, the inductor is cranked practically when idling.

In the arrangement shown in FIG. the changeover relay U is excited by the current generated in a secondary winding (JII) of the inductor. It a second winding of the changeover relay is avoided.

FLg. 6 also shows an arrangement for a changeover relay with only one winding. This lies as a voltage winding parallel to the winding of the inductor J. An undesirable drop in voltage when the inductor is loaded by the connecting line is avoided by keeping a PTC thermistor KZ, for example a metal filament lamp, in the circuit.

7 shows how FIGS. 3 and. 4 an inductor which is short-circuited is left on. Opposite Eig. 3 and 4, however, FIG. 7 shows the use of a Changeover relay with only one winding. This is also, as in Vig. 6, as Voltage winding parallel to the inductor winding @ g J. An undesirable drop the voltage when the inductor is loaded by the connecting line is determined by .the capacitor Ko, which is in series with the inductor, is prevented from approximating is tuned to resonance with the inductor winding. Therefore, with this arrangement just as in the embodiment according to FIG. 6, a special current winding .des Changeover relay U not required.

The use of a PTC thermistor as a current-limiting element, accordingly Fig. 6 is not tied to an "idle circuit", as is the other hand Use of a current-limiting capacitor according to Fig. 7 not only for the »short circuit« is possible. Both elements are equally for one »Idle <or a» short circuit «are suitable.

FIG. 8 shows an arrangement of an inductor which is also started in a short-circuit circuit. Through the resistance. Wi a complete short-circuit of the inductor is prevented and this enables easier cranking: the switching relay U picks up the current generated by the winding I of the inductor T and switches one end of the winding I of the inductor via its contacts u2 and u4 J to voice line b 1. The changeover relay U is held by the current flowing over the line. In the case of very high-resistance lines, however, the following is sufficient: the current is not sufficient to excite the relay U. In order to prevent the relay from becoming obsolete in these cases, the auxiliary winding II of the inductor J is provided, which then supplies the required holding current for the relay U. When relay U responds, resistor wi2 is short-circuited via its account file u2 so that it is no longer switched on in the circuit ades inductor.

Claims (1)

PATENT CLAIMS: 1. Circuit arrangement for connecting an inductor to a connecting line after the intercom equipment has been disconnected from this connecting line in telephone stations, in particular in field telephones, characterized in that a switching relay (U) which is excited by the current generated when the inductor (J) rotates , connect the inductor to the connection line (VL) (using u2). 2. Circuit arrangement according to claim 1, characterized in that the changeover relay (U) responds via a first winding (UI) lying parallel to the inductor winding and holds itself via a second winding (UII) lying in series with the inductor winding during the current transmission (Fig . 1 and 2). 3. Circuit arrangement according to claim 2, characterized in that the windings of the changeover relay (U) are in the shunt arm of a bridge rectifier (Graetz circuit). 4. Circuit arrangement according to claim 1 and 2, characterized in that the inductor (J) and the windings of the switching relay (Ü) are in a shunt of the connecting line (VZ) and in the idle state of the inductor by an open contact (u2) of the switching relay from the connection line are switched off (Fig. 1, 2, 5 and 6). 5. Circuit arrangement according to claim 1 and 2, characterized in that the inductor (J) and the windings of the changeover relay (U) are in a series branch of the connecting line (VL) and are short-circuited in the idle state of the inductor by a contact (u2) of the changeover relay (Figures 3, 4, 7 and 8). 6. Circuit arrangement according to claim 5, characterized in that a capacitor (Ko) is switched on in the short circuit of the inductor (J) (Fig. 4). 7. Circuit arrangement according to claim 1, characterized in that the changeover relay (Ü) has only one winding, but the inductor (J) has an additional winding (JII) in whose circuit the changeover relay (U) is excited and held (Fig. 5 ). B. Circuit arrangement according to claim 1, characterized in that the changeover relay (U) has only one winding and also the inductor has only one winding, in the circuit of which the changeover relay (Ü) is excited and held, and that a PTC thermistor in series with the inductor winding (Metal filament lamp KL) is connected (Fig. 6). 9. Circuit arrangement according to claim 1, characterized in that the changeover relay has only one winding and also the inductor has only one winding, in the circuit of which the changeover relay (U) is excited and held, and that a capacitor (Ko) in series with the inductor winding which is tuned to resonance with the inductor winding (Fig. 7). 10. Circuit arrangement according to claim 1 and 4 or 5, characterized in that in a short circuit of the inductor (J) in the short circuit, a resistor (Wi) is switched on and that the inductor has an additional winding (J I1) which is parallel to the changeover relay (U) is connected in series with the main winding (JI) of the inductor (Fig. 8). Considered publications: German Patent Specifications Nos. 926 969, 203 141; German Auslegeschrift No. 1033 719; Swiss Patent No. 239 648; "Feinwerktechnik", 1957, issue 2, pp. 62/63.