HU180027B - Circuit arrangement for telecommunication apparatus,for ensuring optimum operation of switching to line - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement which enables a telecommunication device, preferably a tele-speaker device, to be connected to a line even under optimum operating conditions, even when additional constraining conditions exist in the plant, e.g. in areas exposed to high-voltage interference in the course of supplying cs / or social traffic.

The invention can be advantageously applied e.g. in telephone networks along railway lines, in particular where there is interference from inductive coupling of the telephone circuits to the telecommunication circuits due to the overhead traction current.

Telephones operating in such a network require that each device be threaded to the telephone network without reflection, without significant level reduction, and that the power supply of the device should not be provided from a local power source, but should be centrally powered, and the telephone device should remotely while allowing both direct-to-device and centrally-initiated, where appropriate, one-to-one calls. A further requirement is that the acoustic signaling (call signaling) intensity is not affected by the distance of the device from the power source or line damping conditions.

The low input resistance of known CBs does not allow multiple loops to be fed from a common power bridge; therefore, the use of such a CB device in a corporate business requires a local power source. The social application of the known CB devices is further complicated by the impedance of the device, which is comparable to the line impedance, due to which the devices attached to the loop have a strong damping effect, the speech energy is significantly reduced and the matching and reflections occur. It is also a common feature of known devices that their input impedance is on the one hand power dependent and on the other hand its f / sequential path does not follow the frequency impedance of the line impedance. The line used in the device does not help this shortcoming; its effect is only in reducing the echo, and practically no line plays a role in aligning your device with the line. Equivalent attenuation of known devices is also dependent on current, strongly influenced by line length and resistance, and the expensive call signal used requires high call power. For LB systems, it is precisely because of this high call power demand that the device's inductor does not provide the ability to call multiple devices at the same time, but with a bell transformer connected to the lighting network.

Various solutions have been developed to improve the fit of the device to the line, but even solutions that otherwise have a favorable improvement are not capable of providing optimal operating conditions under the aforementioned tightening conditions. It is used to serve social traffic eg. No. 155,500; a switching arrangement according to a Hungarian patent. The total current-1180027% 4 of the loop-mounted devices is complicated by such a solution, because e.g. at the insertion point of each device, three of the patented switching arrangements are required to achieve the required small insertion damping. The application of these multiple amplification circuits results in excitement and instability; the purpose of this known solution is only to eliminate reflection and to obtain a better fit with the known device solves only one of the problems.

At the same time, the solutions to the problems listed so far must be achieved so that we can meet the specific requirements of standard, centrally powered service links along the lines (emergency, work control).

None of the state-of-the-art solutions allow the development of a centralized power telephone network capable of voice communication, which allows both selective calling of devices and connection of multiple devices to the network at the same level (conference call) without the need for line amplifiers.

The circuit arrangement of the present invention provides, at least in part, if not completely, the disadvantages of the prior art, and provides a telecommunication device capable of communicating with one another;

- powering a plurality of devices connected to the telephone loop from a central common power source with locally identical parameters, including excluding any change in device equilibration;

- galvanically disconnecting the speaker set from the line;

- protection against high-voltage interference;

- minimum insertion damping and thus no reflection;

- providing a four-wire junction with the possibility of further switching;

- issuing a ring signal of equal intensity, preferably through the handset of the device, without the ringing of a ring signal;

- the cost-effective deployment of a telephone network capable of handling both centralized and decentralized calls;

- simpler design of call origination circuits in the case of an electronic telephone exchange;

- simple implementation of line matching;

- the ability to adapt to a portable handset;

- providing a reflective non-reflective four-wire branch to either central or local power networks;

- the deployment of all these services, which can also be incorporated into existing networks.

In general, we aim for a design that eliminates the need to break up the line with telephone booths and other fixtures; the line shall be continuous DC, directly testable and, if necessary, remotely powered, and failure of any device shall not interfere with the operation of the line or line.

The present invention is based on the discovery that with a centralized power supply of multiple telephone loops, identical and optimal local operating conditions can be achieved if the local device is powered by a local power supply from the central power source that provides high input to the power line. impedance, but with low internal resistance, and through dual-to-alternate-current conversion, it ensures that the energy supplied to the local consumer can be stabilized independently of the incoming form of the energy, while dual conversion also allows it to be performed at desired locations galvanic isolation from the line without hindering the coupling of energy from the line to the local consumer. However, the design of the power supply unit with high input impedance does not prevent the receiver unit and transmitter unit from being fitted to a reflection-free audio frequency line. An advantage of the invention is that the device so designed can also be used when power is drawn from a local power source.

Accordingly, the circuit arrangement according to the invention, as in some prior art solutions, has a power supply unit and, preferably, an acoustic signal transmitter and a fork circuit between the line terminals and the receiver side of the device and the transmitter terminal of the device.

According to the invention, the input stage of the power supply unit is a direct current transformer stage, briefly an E / V stage, an output stage rectifier stage, the input of which is connected via an E / V stage separator transformer, at least one output terminal of the rectifier stage. and the DC input terminals of the E / V stage and thus of the power supply unit, preferably via line terminals, are connected to a DC power source.

The invention is not limited by the specific design of the fork circuit. The fork circuit may be e.g. any type of AC bridge circuit, and may include a single transformer between the line and the device, or two or more transformers, one per side or more. The balancing impedance of the fork circuit may be at the point of symmetry between the receiving side and the transmitting side, or it may be inserted differently so long as the resulting arrangement has the equilibrium required for self-deconstruction.

The circuit may comprise a transformer, formed by line or device side coils, having a device side coil having a symmetrical design, one terminal to the receiving unit, the other terminal to the transmit unit, and its center branch indirectly to the common potential point of the switching arrangement. and an equalizing impedance, preferably a line, is connected between the common potential point. In this case, a second capacitor is inserted into the circuit branch between the first capacitor between the equalizing impedance and the common potential point, one of the transformer line terminals and one of the output terminals of the rectifier stage to the common potential point and the other output terminal of the rectifier stage. is connected to one of the impedance terminals as a power input.

The invention will be explained in more detail by the description of preferred embodiments, which are shown in block diagrams. It will be apparent to those skilled in the art from 2180027 that the circuit arrangement of the present invention allows for multiple variants for both corporate and selective traffic, allows local power instead of central power, allows for the synchronization of traffic on different lines, and provides additional line serialization. instead.

Fig. 1 shows a block diagram of a telephone line which can be connected to a line according to the circuit arrangement according to the invention, and Fig. 2 shows a line connection implemented through an auxiliary polarity change unit. In the embodiment of Figure 3, the microphone and the earpiece are arranged in a portable handset which can be plugged into a circuit of a local line station. 4-6. Figures 4 to 5 show embodiments implemented with local amplifiers, with the possibility of various ancillary services.

As shown in Figure 1, the coupling device of the filament circuit 12 is a TR transformer and one of its line-side terminals 2 is connected to the corresponding line terminal V2 by a circuit branch which can be opened or closed by operating signals. In this exemplary embodiment, the breakable short circuit 11a is bridged by a branch having a contact 11 for generating a dashed call signal. If all contact is controlled by the dial, the short circuit 11a must be broken. The device side winding of the TR transformer is symmetrical. One of its terminals is connected to the receiving terminal 4 and the other terminal is connected to the transmit terminal 3. The receiving side terminal 4 is connected to the input of the receiving unit B in this embodiment. The transmitting terminal 3 switching contact is connected to the moving contact of the set OFF, the stationary contact is connected to the acoustic signal transmitter D, the operating stationary contact is connected to the transmit unit A. The center branch 5 of the device coil is indirectly connected to the common potential point 6 of the switching arrangement by providing a compensating impedance Z1 between the center branch 5 and the common potential point 6. In this embodiment, a second capacitor 82 is coupled to the circuit branch between the impedance line Z1 and the capacitor 81 between the impedance Z1 and the common potential 6, one of the line terminals 2 of the transformer TR and the corresponding line terminal V2. The input stage of the local power supply unit C is comprised of a stage for converting direct current to alternating current, briefly an E / V stage, to which a circuit separating transformer 91 and a rectifier stage 10 are connected. One terminal of the DC input of the E / V stage 9 - in this embodiment - through the switching device (s) to the circuit branch between the second capacitor 82 and one of the line terminals V2, the other terminal either directly or via the line side winding of the transformer TR. connected to another line VI terminal. In this case, one of the switching devices is a diode 7 which level-wise or switches one of the input terminals of the E / V stage 9 to a circuit branch connected to one of the line terminals V2 and the other switching device is the contact K2 which bridges the diode 7.

The output terminals 10a and 10b of the rectifier stage 10 are connected to a circuit branch between the center branch 5 of the transformer device side coil 5 and the common potential point 6 by enclosing the first capacitor 81, i.e., galvanically separated at two points of the circuit branch.

Essentially, the known elements shown in Figure 1 are intended for those skilled in the art. The device is connected to the L line through the terminals VI and V2. The transformer TR performs the function of the fork circuit 12 and also galvanically disconnects the talking set, i.e. the receiving unit B and the sending unit A, from the L line. The self-sounding immunity is provided by the application of the balancing impedance Zl. The DC circuit of the power supply unit C is terminated towards line L either via diode 7 or contact K2. Thus, the E / V stage 9 is of course not galvanically isolated from the L line, but by means of a separating transformer 91 inserted between the 9 E / V stage and the rectifier stage 10, it is ensured that the 10 stage coupled to the speaker set is already isolated DC L line. Transmission The unit thus receives power from the 10 stages connected to the first capacitor 81 and, if applicable, the impedance Zl. When the call signal is received, the voltage is applied to the acoustic transducer D through the dc contact of the toggle contact OFF set, but when the earpiece is lifted, the toggle contact switches to deactivate, the microphone is turned on. However, the AC signal superimposed on the DC voltage is received by the receiving unit B, e.g. results in the student speaking. Contact K2 provides a short circuit to bridge the diode 7 to permanently turn on the E / V stage 9. In addition to proper sizing, the K2 contact can trigger ring stop by switching on the appropriate battery polarity by operating the 9 E / V stage at a higher frequency. The acoustic signaling can also be triggered by the short-circuiting of the diode 7, for example, when the changeover contact kit is at rest. by issuing a tone signal. Otherwise, the mode of operation of the device is the same as that of known telephones, so it will not be further elaborated. In the case of a social enterprise, the receive unit B and the transmit unit A, which are coupled by the fork circuit 12 to the audio line L, are preferably high impedance using amplifiers, which we return to in Figures 4 and 5. The level of the signal output to the L line and the impedance value Zl depend on the impedance of the L line and the transmission ratio of the TR transformer. A suitable amplifier used in the receiving unit B amplifies the signals coming from the telephone line L.

Contact K2 closes when lifting the listener; the 9 E / V stages will then operate, providing power to the A and B units, especially the microphone power supply. When the call is received, the 7 diodes start the 9 E / V stages; if necessary, the polarity of the L-line signal must be reversed. The trigger signal can also be generated by an operating receiver for the audio signal received from the line terminals VI and V2. The AC signal on the impedance Zl returns to the telephone line L according to the balancing and acknowledges the call signaling.

The power supply unit input C is designed and sized for high-voltage drive, low power consumption, and provides proportional power output to the output at the appropriate voltage or current rating. Due to its high DC internal resistance, it can also be connected directly to the line to avoid passing current through the TR transformer. The internal resistance measured at the terminals VI and V2 of the line can be reduced by ohmic bridging of the second capacitor 82, thereby allowing a larger line in the telephone exchange network3.

-3180027 and can also neutralize the pre-magnetization of the TR transformer.

The input impedance of the device, measured from the line terminals VI and V2, can be formed for both line termination and party operation by appropriate training and dimensioning of the receiving unit B and the transmission unit A. Of course, the fork circuit 12 may be designed in other ways, e.g. two or more transformers, however, care must be taken to have independent line-connected coil sides.

Referring to Figure 2, the line terminals VI and V2 of the device 19 of Fig. 1, not shown in detail, are coupled to a polarity switching stage 20 having a line side formed by terminals 15 and 16 that can be connected to wires La and Lb. When stage 20 is part of the apparatus, terminals 13 and 14 are preferably connected by fixed connection to line terminals VI and V2 and terminals 15 and 16 are formed as plug-in connections; when terminals 15 and 16 are connected to the L line by a fixed connection; the terminals 13 and 14 may be designed as a socket and the terminals VI and V2 may be a connection plug. The output signal of the audio signal receiver 17 coupled to the device 19 or to the line L operates the relay 18, with a terminal 14 connected to one of the line terminals V2 via a corresponding switching contact and one terminal Lb of the other line via terminal 16. and - by means of the terminal 13, the corresponding resting contact and the terminal 15, it is connected to another La conductor of the line L; when the relay 18 is energized, the connections are reversed.

Figure 3 shows an embodiment in which the transmitting unit A and the receiving unit B, or at least their Al microphone and B1 listening device, are arranged in a portable handset known per se; one of the terminals of the microphone Al and of the student B1 is the plug-in terminal 3 'and 4' which is to be connected to the device-side terminals of the TR transformer via terminals 3 and 4, and their common terminated terminal 6 ' . Such an arrangement may be used in the case of the already mentioned, e.g. for additional services along the line, when a person traveling along the line for the purpose of checking, repairing, requesting assistance or operating instructions for a line, the "patrol" wants to enter line L at a particular point. It can enter at points where an interface unit 26 is formed which is ultimately formed by the functional building blocks shown in Figure 1, i.e. the transformer TR, first and second capacitors 81 and 82, impedance Z1, line terminals VI and V2. The portable handset is actually a connector unit 27, which allows the "patrol" to connect to the adapter unit 26. In unit 26, the other DC input terminal of the power supply unit C, and thus the unit C, is not directly connected to the line connecting the other terminal 1 of the transformer TR to the corresponding line terminal VI, but via the line side coil. the wire between one of the line terminals V2 is interrupted at one point and a socket is provided at each of its terminating ends, through which the two ends of the short circuit K3 arranged in the connector unit 27 can close the current path of the conductor; is connected to the L line when the connector unit 27 is plugged into the adapter unit 26. The terminal of the device side coil of the transformer TR to be coupled to the receiving unit B is also interrupted by a further capacitor 25 inserted therein. Thus, the receiver B1 of the receiving unit B receives only a tone signal superimposed on the tension voltage, which can also be used to indicate a call when the vibration generator of the power supply unit C is set at a lower frequency. In addition to a defined polarity, a separate oscillator can be used in the power supply unit C to trigger the call signal via the listener B1.

When the connector unit 27 is plugged into the adapter unit 26, the transmission unit A microphone A receives the required microphone current from the power supply unit C; the central unit 21 can then be used to call the units 26 and 27. line device through the ski jeh set with the selected bursting change. The polarity / reversal is implemented by the switch control stage 22, the interior design of which may be designed by one of ordinary skill in the art, as described herein. In addition to the polarity reversing relay, stage 22 also includes a DC signal receiver for signaling line start, line 27, through line S2. The signal line S2 is galvanically independent of the power supply line, optical coupling or relay isolation can be used, etc. The L-line can be connected via the central device 21 to various additional Li (i = 1,2, ...) lines, so that the connection can be further connected to them. For local appliances, eg. the power supplied to the adapter unit 26 via the L line is provided in this embodiment by a power supply unit 23 located at the site of the central unit 21, which is ground independent. The line L is thus galvanically isolated from the ground potential and from the central apparatus 21 via the line VT transformer. The L line calling signal can be transmitted not only from the central unit 21 but also from the L line through the S1 signal line to the central unit 21. The signal from the L-line can also control the polarity reversal at 22 degrees, if desired. In this way, the usual acknowledgments are also made in the known manner, the control panel being informed that the connecting unit 27 has been connected to the connecting unit 26, that a call, signaling, etc. has taken place. The services and signals may, of course, be further expanded, as represented by the S3 signal leads, without the need for any specific extension to be made within the scope of possible requirements.

Generally speaking, in this embodiment, the L line is connected to the central device 21 via a line VT transformer having a line-side coil © coupled to switch control stage 22 and the switch control stage 22 actuator © S1, S2, S3 signal line (s). connected to the appropriate circuit (s) of the central device 21. One of the pairs of polarity reversing stages that are part of the 22 stages, not specifically described, e.g. the terminals of the line-side coil (s) of the line transformer VT are connected to the moving contacts of the alternating contact sets, to the other pair of terminals of the polarity reversing stage - e.g. properly connected upright contacts - 23 power supplies connected.

Figure 4 illustrates the already mentioned embodiment in which the transmission stage E1 is received and the stage E2 is received B unit, so that the wave impedance of the line L can be measured from the terminals VI and V2 of the device.

-4180027 has an input Zbe impedance of at least an order of magnitude. Loops can be connected to local devices in parallel so that the parameters of the L line are not significantly altered by the connection of the local devices, and the devices do not burden the network significantly. Transmission to the line A unit outputs a signal amplified to the required level by amplifier stage E and receiving unit B outputs the signal received from line L to amplifier B1 appropriately amplified. The gain can also be adjusted level-wise, amplifying weaker incoming signals to a greater extent, so that even larger distances will not cause significant differences in traffic. In order that the impedance of the A and B units to an order of magnitude greater than the impedance of the L line does not affect the matched line closure, which may result in unwanted reflections, the telecommunication device of the present invention is not interleaved between terminals VI and V2. it can be terminated by the impedance Z2 corresponding to the wave impedance of the L line. However, this is not necessary. If the output impedance of the amplifier stage E1 is low, then the input impedance across the terminals VI and V2 is given by the value of the balancing impedance Z1 modified by the transformer TR, which can be suitably scaled to the line impedance L. If an additional line L1 is inserted into the fork circuit 12 instead of a line to which the line L can be switched, the two lines L and L · are connected in series. When a low output impedance amplifier is used, the fork circuit 12 is single-balanced, passing between the two series L and L lines without attenuation. Preferably, operational amplifiers are used, and it may be advantageous to connect the output of the power supply unit C to a power input formed in or around the amplifier circuit, rather than to one of the output impedance Z1.

Detailed description of the specific embodiment of the embodiment of Figure 4 is provided in Figure 5. In this embodiment, the not-shown but marked Al microphone adapter TI is connected to a symmetrical input coil of the transformer and the asymmetric output coil to an operational amplifier E1 and its output to an impedance adapter 31; the output of this stage 31 forms the terminal 3 connected to the terminal of the transformer TR. Similarly, TR. a 4 level terminal regulator coupled to a transformer terminal is connected to an E2 stage input of an operational amplifier, and an E2 output is connected to an asymmetric input coil of an adapter T2 and a level regulator 32 stage input; the symmetrical output coil of the transformer T2 is connected to a student B1 not shown but marked. The inverter input of the amplifier stage is connected to a voltage divider branched between the output of stage E2 and a 6-point common potential, preferably fixed.

Further details of the mode of operation and the construction will be apparent to those skilled in the art from the foregoing, and that with such an arrangement, the power supply may be varied, either through the L line or from a local power source. This design is also varied in that, by inserting an impedance Z1 as an additional line Lj rather than a line, the switching arrangement allows for two lines of traffic, and by leaving the impedance adapter 31, a unit can be formed.

If two lines are received, i.e. the line L · is connected in series as impedance Z1 instead of the line, the fork circuit 12 generally comprises two transformers.

The embodiment of Figure 4 is also a variant of the embodiment of Figure 6. No adapter T1 and T2 transformers or level control 32 steps are used here. In the transmission unit A, the output of the operational amplifier E1 is connected to the fork circuit 12 via an impedance adapter stage 31, the microphone A1 is connected to the direct input of the operational amplifier stage E1, and its inverse input is connected to a transponder 33. The device-side terminal of the transformer TR, through its terminal 4, connects to the line input E2 and signal receiver input 34 of the operational amplifier connected to the student B1, and the output of the signal receiver 34 to the inverse input of the amplifier stage E and the output of the amplifier stage E2. connected to the common potential 6 points of the arrangement - 35 potentiometer moving contacts.

The transponder 33 can be controlled from the dial or push button according to the desired mode. The signal receiver 34 may be configured according to the desired selective mode.

It will be appreciated that the switching arrangement of the present invention provides simple means for solving various functions associated with transmission and interference suppression. The device according to the invention can be installed along the line and can be easily switched to the different operating mode desired at each installation site. The terminal 30 shown in Fig. 6, which is the output terminal of the operational amplifier stage E1, can be connected to a branch 3a of the device side winding of the transformer TR if the device is to be applied at the end of the line. Such a connection may also be used when, by means of said serial insertion, the Z1 line is occupied by an additional L line. It has already been mentioned that the power supply unit C can be connected to a local power source instead of the L line.

The symmetrical portions and ground-independent power supply of the circuit arrangement of the invention also allow to avoid other interferences: increased crosstalk protection, no additional noise due to crosstalk, and avoidance of life-threatening voltage levels.

Complemented with the appropriate transducer, we make the device suitable for selective selection while maintaining the opportunity for social networking. It can also be used in dispatcher mode, complete with a receiver or with associated reception automation.

The line reinforcement according to the invention is not provided by line amplifiers which cannot be satisfactorily stabilized, but in the device when needed; the level of the lines can be independent of the number of devices it currently charges, and the level of the lines can be ensured even during conference calls.

The invention makes it possible to avoid high-level ring signals, to reduce the noise level of cables, and to make electronic exchanges more advantageous than known. Thus, the application of the invention is advantageous not only in the case of a social enterprise, but also generally for optimizing the operation of telephone exchanges.

-5, .....,, .11., .... _; ....... ¹⁸⁰⁰²

It is a special advantage that the level of the acoustic signal can be controlled completely independently of the line conditions and the location of the given device.

Claims (16)

1. Circuit arrangement for multiple telecommunication, e.g. a telephone tree - co-operative and / or selective - for establishing a telecommunication network 10 for optimum operating conditions when connecting the device to a line, having a fork circuit and current between the device terminal terminals and the receiver side of the device and the transmission side of the device - 15 supply units, characterized in that the input stage of the power supply unit (C) is a stage for converting direct current to alternating current, briefly an E / V stage (9), an output stage for rectifying stage (10); 9) connected via a separating transformer 20, connected to at least one output terminal (10b) of the rectifier stage (10) at the device-side power input and the DC of the E / V stage (9) and thus the power supply unit (C) input terminals, preferably via line terminals (VI, V2), DC connected to a power source. An embodiment of a switching arrangement according to claim 1, characterized in that the device side winding of one of the transformers (TR) of the fork circuit (12) has a symmetrical design, one terminal to the receiving side terminal (4) and the other terminal and the center branch (5) is connected indirectly to the common potential point (6) of the switching arrangement, the tip being connected to the common potential point (6), the first capacitor (81), the central branch of the capacitor (81) and the device side winding 35 And (5), a balancing impedance (Z1), preferably a line, is inserted and a second capacitor (82) is inserted in the circuit branch between one of the line-side terminals (2) of the fork circuit (12) and the corresponding line terminal (V2). 40 An embodiment of a circuit arrangement according to claim 2, characterized in that one terminal of the DC input of the E / V stage (9) is connected directly or indirectly to a circuit branch between the second capacitor (82) and one of the line terminals (V2). . 45 The embodiment of the circuit arrangement according to claim 3, characterized in that the other terminal of the DC input of the E / V stage (9) is connected directly to the other terminal terminal (V1) directly through the line winding of the transformer (TR), 5. An embodiment of a switching arrangement according to any one of claims 1 to 6, characterized in that v'Önal (L) is coupled to a central device (21), to which additional lines (Li, where i = 1, 2, ...) are also varied. '') To an embodiment of a circuit arrangement according to claim 6? VAT? 5? '; characterized in that it is connected to the central unit (21) via a line (L) line transformer (VT). '~ L' '*' ' YA Signature Switch 6 Selector Signature 6 *; noting that 'the Vopali Tphari-phosphorus? (VT) line-side coil with switch control stage (22) varied. '', * ' ^I! '8. A'7. Embodiment of a switching arrangement according to the invention, characterized in that the switching controller 6 is connected to a switching arrangement. . ... 12 - for a pair of terminals of a polarity reversal stage forming part of unit (22) - eg. to the moving contacts of the inverter supply kits - the terminals of the line transformer (VT) line-side coil (s) are connected; properly connected to the common-ground contacts — the power supply (23) is connected and the signal (s) (S1, S2, S3) of the actuator (22) of the switching control stage (22) are connected to the appropriate current circuit (21). í) attached with. 9. Figures 1-8. An embodiment of a circuit arrangement according to any one of claims 1 to 3, characterized in that a polarity reversing stage (20) is connected between the line terminals (VI, V2) and the lines (Ea, l.b) of the line (L). An embodiment of a circuit arrangement according to claim 9, characterized in that the device-side terminals (13, 14) of the polarity-change stage (20) are fixedly connected to the line terminals (VI, V2) and the line-side terminals (15, 16) are plug-in. are designed as a connector. An embodiment of a switching arrangement according to claim 9, characterized in that the line-side terminals (15, 16) of the polarity-changing stage (20) are fixedly connected to the lines (La, Lb) of the train (L), the device-side terminals (13, 14). ) and are designed as plugs. 12. An embodiment of a switching arrangement according to any one of claims 1 to 5, characterized in that at least the microphone (A1) and the receiving unit (B) of the transmitting unit (A) are arranged in at least a connector (27) formed as a portable handset speaker; one end of the microphone (Al) and the earpiece (B1) terminates in a plug connector, the other terminal of the microphone (Al) and the earpiece (Bí) terminates in a plug-in connector and forms part of the device in a fixed connection the adapter (26) is formed with sockets which are respectively connected to the receiver terminal (4), the transmit terminal (3) and the common potential point (6) and the line terminal of the second capacitor (82) and the corresponding line terminal (V2) ) is interrupted and the two ends generated during the interrupt are one additional socket which sockets are arranged in the connector unit (26) in accordance with plugs formed at the end of the arrangement short-circuit (K3). 13. Figures 1-12. An embodiment of a circuit arrangement according to any one of claims 1 to 5, characterized in that in the transmitting unit (A), an operational amplification stage (E1) is inserted between the microphone (A1) and the transmitting side terminal (3). 11. An embodiment of a switching arrangement according to any one of the preceding claims, characterized in that in the receiving unit (B), an operational amplification stage (E2) is inserted between the listener (Bt) and the receiving side terminal (4). 15. An embodiment of a switching arrangement according to claim 13 or 14, characterized in that an impedance alignment stage (31) is inserted between the transmission side amplifier stage (E1) and the transmission side terminal (3). An embodiment of a circuit arrangement according to claim 15, characterized in that the microphone (A1) is connected to a straight input of the operational amplifier stage (E1) and a signal transmitter (33) is connected to its inverse input. 17. Embodiment of the kap-6180027 loop arrangement according to any one of claims 1 to 4, characterized in that the receiving side terminal (4) is connected to the straight input of the operational amplifier stage (E2) and the input of the signal receiver (34). connected, and the output of the signal receiver (34) and the movable contact of the variable resistor (35) are connected to the inverse input of the amplifier stage (E2). 18. An embodiment of a circuit arrangement according to claim 15, characterized in that a level control stage (32) is inserted between the receiving terminal (4) and the operational gain stage (E2), the output of which is a straight input of the gain stage (E2), its input is connected to the output of the amplifier stage (E2) and the inverter input of the amplifier stage (E2) is connected to a branch of a voltage divider coupled between the output of the amplifier stage (E2) and the common potential point (6). 5 19. An embodiment of a circuit arrangement according to claim 18, characterized in that between the microphone (A1) and the transmit-side operational amplifier (E1) and between the listener (B1) and the reception-side operational amplifier (E2). an adapter transformer (TI, 10 T2) is registered. 20. Figures 1-19. An embodiment of a switching arrangement according to any one of the preceding claims, characterized in that the balancing impedance (Z1) is constituted by an additional line (L ·) connected in series to the network.