DE1064573B - Device for the optional connection of a common connection line with one of two other lines - Google Patents

Description

GERMAN

The invention relates to a device for • the optional connection of a common connection line with one of two other lines, using at least three magnetically actuated Changeover switches that are connected to one another in such a way that, in the switched state, the common Connection line is placed via the first switch to that of the two other switch that is connected to the desired one of the two other lines, with simultaneous earth connection of the unused connections of all changeover switches.

Devices of the aforementioned type are required, for example, in order to connect a high-frequency device, for example a transmitter or a receiver, to a corresponding replacement device as quickly as possible in directional radio systems. So far, this object has mostly been achieved in such a way that the inner conductor of a coaxial line is made flexible and made of magnetic material and switched between two stationary contact arms by means of appropriate magnetization. The disadvantage of this arrangement can be seen in the fact that the respective open connection is only inadequately disconnected via the stray capacitances. This disadvantage is largely remedied in practice in that the entire switching device in the above-mentioned manner consists of at least three interconnected changeover switches in such a way that the respective unused connections are grounded. Here, however, it turns out that just when it comes to maintaining a uniform wave resistance over the train of the entire switching device, the fulfillment of this requirement is relatively difficult because of the sometimes considerable length of the individual unused tongues of the switch. One has therefore switched to keeping these tongues relatively short and largely eliminating the increased risk of bruises caused by mercury-wetted contacts during the switching process. However, this leads to spatially very complex arrangements, and moreover, the entire
Sensitive to shaking and position.

The invention has for its object to provide a way in which it is possible, among other things precisely the difficulties listed above with a particular intended for high-frequency purposes To fix switching device. According to the invention, starting from a Switching device of the type described in the introduction, solved in such a way that each of the changeover switches consists of two protective gas contacts designed in a manner known per se as working contacts, each of which is supplemented by means of a metallic outer jacket to form a coaxial line, and that this outer conductor

Switching device Device for optional connection

a common connection line
with one of two other lines

Applicant:

Siemens & Halske Aktiengesellschaft,
Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Ernst Welz, Munich,
has been named as the inventor

of all protective gas contacts are also directly connected to one another in a known manner and form the pole that is common to all connections of the switching device. A protective gas contact is understood to mean a known arrangement in which two, preferably about the same length, resilient and about ^a 5 band-shaped metal tongues made of ferromagnetic material are melted into a glass tube, from the ends of which are fused in such a way that their adjacent ends meet with little mutual Overlap the distance. By applying an external magnetic field in such a way that it closes over both resilient tongues, the contact can be closed or, if the contact is closed by means of a corresponding premagnetization, can be opened.

The invention is illustrated below with reference to exemplary embodiments, the essential details of which are given in the drawings are reproduced, explained in more detail. In the drawings shows

1 shows a known embodiment of a protective gas contact,

2 shows the basic circuit diagram of a known switching device with "intermediate earth" of the unused one Connections,

Fig. 3 shows a known development of the circuit of FIG. 2, in such a way that each free line is completed without reflection,

4 shows the front view with partial section of a switching device according to the invention,

FIG. 5 is a plan view of the switching device of FIG. 4,

6 shows a basic circuit diagram of the switching device shown in FIGS. 4 and 5,

7 shows a further development of the switching device according to FIGS. 4, 5 and 6,

909 610/277

8 shows a further embodiment of a switching device according to the invention,

9 shows a structural design of the arrangement according to FIG. 8,

10 shows a device equivalent to the switchover device according to FIG. 7 with a smaller one Number of protective gas contacts using the embodiment according to FIGS. 8 and 9,

11 shows, in a further development of the invention, the use of the new switching device in equivalent circuit technology a radio link using units according to FIGS. 4, 5 and 6 or 8 and 9,

12, 13, 14 and 15 show a specific application example of the new switching device using of units according to FIGS. 8 and 9 and

FIGS. 16 and 17 show advantageous designs of the magnetization devices.

In Fig. 1, a protective gas contact of known design is shown [see. z. B. Bell System Technical Journal, Vol. 35 (1956), p. 253], which consists of two contact springs 1, 2 of magnetic material which, slightly overlapping, face each other at a small distance and which are in a preferably gas-filled tube 3 from Glass or other suitable material are melted in a known manner. The ends 4, 5 of the fusible conductors are led to the outside of the protective vessel 3 either in the manner of a strip conductor or in the form of a stiff wire. If a magnetic field is brought into effect on the contact springs 1, 2 in such a way that the magnetic flux tries to close through these contact springs 1, 2 made of magnetic material, the two contact springs 1, 2 attract each other at the overlap point, and it occurs for making electrical contact between these parts. When the acting magnetic field is canceled, the contact parts 1, 2 move away from one another. The relay 1, 2 can be closed either by means of a permanent magnet or by means of an electromagnet.

In the switching technology for high-frequency purposes, however, such normally open relays have not been used so far used, but, as mentioned in the introduction, changeover relays that have an additional contact spring, which, in cooperation with the overlapping contact tongue, forms a break contact.

In order to reduce the capacitive coupling in such changeover switches to a minimum, high-frequency changeover devices work in such a way that the unused connections are grounded or connected to the other unswitched line pole. A schematic sketch of this type of circuit is shown in FIG. 2, in which AIB means the common feed line to the switching device, which optionally establishes the connection with one of the two further lines ^ or B. Er denotes the earth connection, which in the case of lines AlB, A and B as coaxial lines means nothing else than the connection to their outer conductors, while the inner conductors of these coaxial lines to the points of the circuit marked A / B, A and B to lead. In the switching position shown, the line AIB is connected to the line A , which is coupled at the same time to the free connection of the first changeover switch I via the harmful coupling capacitance Ck. The energy flowing out of this, however, is led to ground potential via the switch II, which also applies to the free connection of the switch III. The other connection of the switch III is with the connection A.

connected, likewise the still free connection of the changeover switch II with B. The changeover of the common line AIB to one of the lines A or B is done by simultaneous changeover of all changeover switches I, II and III.

If in practice the requirement arises to terminate the connection line not connected to the common line - in the exemplary embodiment in FIG. 2, the connection line B - without reflection,

This can be implemented in a manner known per se in the manner shown in FIG. For this purpose, at least four changeover switches are required, of which the changeover switches I 'and I "initially lead to a kind of preselection of the desired connection, while the changeover switches II and III then establish the final connection to the desired connection line. OA and OB are the two the respective line branch reflection-free final termination resistors, respectively. Similar to the embodiment of FIG. 2 is here the common line AIB with the further line ^ through-connected, while the other line is switched B to which they reflection-free final terminator OB. is in case of simultaneous switching of all switch the Line B connected to AIB , while line A is connected to the non-reflective final resistor OA intended for it.

The required in the known arrangements switch-over can be avoided in the subject invention because thereby the \ ^r are achieved on the one hand dvantages that the two parallel connections of a changeover switch, which, as the inventors have underlying shown lying investigations, result in a relatively strong coupling, and the contact bruises occurring at the break contact of changeover switches are avoided. On the other hand, the working contacts can advantageously be supplemented much more easily than switching contacts to form a coaxial line which has an at least almost constant wave resistance over its length, and in this way relatively simple switching units can be achieved, in which there is the additional advantage that a great freedom of movement with regard to the location of the connections to be connected to the lines is gained.

In Fig. 4, a switching device is shown in approximately natural size with essential structural details, which is formed according to the teaching of the invention. The circuit of this arrangement is shown in FIG. The switching device consists of six protective gas contacts 7, S ₁ 9 , 10, 11 and 12, each of which is supplemented by means of a surrounding metal sleeve H to form a coaxial line section. The protective gas contacts (7 to 12) are clamped with their associated metal sleeves H between two end pieces 13 and 14, in such a way that these metallic end pieces 13, 14 are connected to the outer conductors Ii of the individual protective gas contacts in a high-frequency manner with good conductivity. At one end of the protective gas contacts, which are parallel to one another and arranged in a row, the connections of the protective gas contacts are connected to one another via bracket 15 in such a way that the first three and the second three connections - as shown in FIG. 4 - with one another be short-circuited. An intermediate wall of the end piece 13 is drawn between these two groups of connections short-circuited to one another in order to suppress undesired coupling. At the other end of the protective

gas contacts, the connection of the protective gas contact 7 merges into the inner conductor of the connection line A, which is designed in coaxial design, and the connection of the protective gas contact 12 merges into the inner conductor of the connection line B, designed as a coaxial design. The connections of the protective gas contacts 9 and 10 are short-circuited to one another in the manner shown in the drawing and are connected to the inner conductor of the common connecting line AIB, which is also designed in coaxial construction. The connections of the inert gas contacts 8 and 11 that are still free are short-circuited against their associated outer conductor, for example by means of two spring clips 16. The actuation of the individual relays or protective gas contacts takes place by means of magnetic coils 17 which are pushed onto the metal sleeves H forming the outer conductors. In order to ensure the best possible closure of the magnetic circuit, a side part 18 made of ferromagnetic material, for example soft iron, enclosing the row of protective gas contacts (7 to 12) is provided. The connections of the individual magnet coils 17 are, for example, as shown in FIG. 4, on the narrow side of the side part 18 to connection solder lugs 19 or the like.

FIG. 5 shows a plan view of an arrangement according to FIG. 4 using the corresponding designation, so that a further discussion of this figure with regard to the execution of the Fig. 4 is unnecessary.

As can be seen from FIG. 6, the actuation of the individual magnetic coils 17 in an arrangement according to FIGS. fourth and sixth inert gas contact are closed. In this case, either line A or line B is connected to the common line AIB , and at the same time the unused line is practically completely decoupled via an earth connection. In the schematic diagram of FIG. 6, each protective gas contact is represented by a circle which contains two smaller circles indicating the contact springs, of which the one on the side (connection side) of the end piece 14 is marked by ticking the corresponding circle. The highly distinctive connections within the inert gas contacts 7 to 12 emphasize the inert gas contacts that are closed in one of the two switching states.

The arrangement shown schematically in FIG. 6, of which an embodiment is shown in FIGS. 4 and 5, can be developed in a very simple manner in such a way that, in addition to the so-called intermediate earth, the reflection-free termination of the respective unused line ^ or B is ensured . This is enforced in that two of the rows of contacts shown in FIG. 6 are combined in the manner shown in FIG. Each of the protective gas contact rows is indicated by a dashed box 20, 21 ι. The inert gas contacts 7 of the rows of contacts 20 and 21 are also connected to one another by an external line, as are the inert gas contacts 12 of both rows of contacts. The intermediate earths of the contact row 20 remain, while in the contact <row 21 the intermediate earths are replaced by reflection-free terminations OA and OB for the respective associated line. In one switching state, the inert gas contacts 7, 9, 10 and 11 in the row of contacts 20 are closed. If necessary, it is recommended 7

In addition, in the switching state shown, the inert gas contact 12 of the row of contacts 20 must be closed so that exposed line sections are avoided. In the other switch position, the contacts of the two rows of shielded gas contacts appear mirrored with respect to closing and opening around a center line passing through the common connecting line AIB compared to the switch position shown.

In Fig. 8 a further embodiment for a switching device according to the teaching of the invention is shown, which is characterized in that it avoids two of the six inert gas contacts of a row of contacts while eliminating the absence of earth faults in the respective unswitched line. The device consists of four inert gas contacts, which in turn are arranged in metal sleeves H , which are clamped between two end pieces 13, 14 with the simultaneous application of the magnetic yoke 18 already shown in FIGS. 4 and 5. The rest of the training is essentially similar to that according to FIGS. 4 and 5, so that there is no need to go into this further. Identical reference numerals have been selected for parts that are identical to the arrangement according to FIGS. 4 and 5. In order to keep all line connections directed to one side, the common connection line AIB is led through a short piece of coaxial line in the middle between the four inert gas contacts to the common connection side.

With such a basic unit - as shown in FIG. 10 in the basic circuit diagram - can also Develop a circuit analogous to FIG. 7 which, in addition to the "intermediate earth", also includes the non-reflective one Ensures termination of each unswitched line by placing two rows of contacts according to FIG. 8 and 9 correspondingly interconnected by external connection or structurally combined in one unit will.

In cases in which the response and release time of the individual protective gas contact is as short as possible, precautions known per se can be taken, such as avoiding any short-circuit winding, especially through external components and the like In individual cases it may be expedient to provide the metal sleeves H forming the outer conductors with a longitudinal slot and to avoid a short circuit through external components. A solution that is roughly equivalent electrically to this and is also structurally advantageous consists in constructing the metal sleeves H from a metal of sufficiently high resistance. This can also be done, for example, in that the sleeves H are made of an insulating material and only coated on the inside with a thin metal layer that is sufficiently low-loss because of the skin effect only for the high frequency, for example vaporized.

In Fig. 11, the use of a toggle

> o device according to the invention reproduced in a radio relay system. One end point “sending” (Se), one “intermediate point” (Z) and one end point “receiving” (Em) are assumed. In the »Send« terminal, for example, five individual

'5 channels a, b, d, d and e each into the associated channel modulator M and from there, with the interposition of switching devices, to the associated transmitter output stages S, which are either directed to different directional antennas or via a corresponding connection

o branch circuit to a common antenna RA,

Claims (1)

preferably a directional antenna, are connected. At some distance therefrom, the intermediate point Z is arranged, which receives the individual channel frequencies via an antenna system RA 'in a corresponding manner and transmits them to the receivers Es, which they transfer to the corresponding transmitter 5 "^ via switching devices for transmission to the receiver, which is also located at a greater distance Give Ee to the terminal »Receive«, where the individual channels a to e are routed via switches to the corresponding demodulators D, from which the individual channels a to c can then be taken Static investigations have shown - as advisable, both in the "Send" terminal as well as in the "Intermediate point" and in the "Receive" terminal is denoted by ο in Fig. 11. For example, falls in the middle telleZ the receiver Ez of the channel d, the transmitter Ss of the channel d is switched to the receiver Eso of the substitute channel ο by appropriate signaling of the "intermediate point", while at the same time the modulator M of the channel d is switched to the transmitter at the terminal point "transmit" .So the substitute channel ο is switched on. All other switch positions are retained. A great advantage of the subject matter of the invention with this switching principle is that switching can take place in the low-frequency, high-frequency and intermediate-frequency levels of the frequencies to be switched. In the exemplary embodiment, it is assumed that the circuit takes place in the intermediate-frequency level, so for example with high-frequency voltages whose frequency is in the order of magnitude between z. B. 30 to 150 MHz. In order to make the overview of the switching principle significantly easier, the "intermediate point" is marked with dash-dotted lines indicating which part of the switching device is encompassed by two of the protective gas contact rows shown in FIGS. 4, 5 and 6. FIG. 12 shows the use of switching devices according to FIGS. 8 and 9 in an equivalent circuit system in which, for example, one of three operating channels a, b, c can be replaced by the common equivalent channel ο. FIG. 12 shows the undisturbed circuit of which the basic circuit diagram in FIG. 13 is reproduced. Since it only depends on the principle of the arrangement, only switching between the intermediate frequency output (Eo, E I, £ 11, £ 111) of the receiver and the associated demodulation stage (Do, DI, DU, DIU) is shown for each channel. It can be seen from FIG. 14 (disturbed operation) together with the basic circuit diagram of FIG. B. to switch over in the event of failure of the receiver £ I only its demodulation stage DI has to be switched to the substitute receiver Eo, which can be done in a simple manner in that from the switching position shown in FIG In the two uppermost protective gas contact rows, the normally closed contacts are opened and the contacts that are otherwise open in these two rows are closed. In the other rows, the contact positions remain unchanged. If the receiver £ 11 is exchanged for the replacement receiver Eo, the same type of exchange is only to be carried out in the two middle rows of contacts. If the receiver £ 111 fails, the swap should only be used in the two lower rows of contacts. This leads to a significant simplification with regard to the magnetization of the individual inert gas contacts. In this case, a constant premagnetization can be applied in each row of contacts, e.g. by means of a coil common to a row of protective gas contacts (22 in FIGS. 16 and 17), which is only sufficient to hold the individual protective gas contacts, but not to close or open them . Each protective gas contact is then also assigned an individual coil 17 which, with subtractive superimposition, serves for premagnetization to open and, with additive superposition, serves for premagnetization to close the respective protective gas contact. The circuit is expediently made in such a way that (cf. and in the same way the magnetizing coils of the inert gas contacts of the second and fourth columns. In this way, a substantial reduction in the total number of connections for the magnetizing coils is obtained. Instead of individual coils when using structural units according to FIG. 8, the arrangement according to FIG. 12 can also be implemented in such a way that two rows of contacts are combined to form one structural unit, and that (cf. ) a common closing or opening winding 23 is assigned to two protective gas contacts lying one after the other in a column. Viewed as a whole, this type of circuit essentially corresponds to a coordinate principle. The aforementioned bias, which only has the purpose of holding the closed contacts, is expediently chosen approximately in such a way that it covers half, e.g. B. 30 ampere turns, the magnetization, z. B. 70 ampere turns, which is given by the coil provided for opening and closing the contacts for the individual protective gas contact. If it is important to keep the reflection in the course of the switching device particularly low, it is advisable to compensate for stub lines in the connected power train in a manner known per se. A stub line is given, for example, in the arrangement according to FIGS. 4, 5 and 6 for the switching position shown in FIG. In the other switch position, the same applies to the equivalent connection of the protective gas contact 11. The compensation is particularly useful if a larger number of switching devices is connected in series (see FIGS. 11 to 15) and it is important that the total reflection has a certain value, z. B. 1% does not match. Patent claims: 1. Means to choose wise connection of a common connection line with one of two further lines using at least three magnetically operated changeover switches that are connected to one another in such a way that