CS219882B2 - Connection of filters for the protection of duplex equipment transmitter-receiver, remotely powered by high-voltage lines - Google Patents

Abstract

The invention relates to the connection of filters for the protection of duplex transmitter-receiver devices, remotely powered by a high-voltage line against duplex interference, where the receiver is installed in a grounded housing and where the elements of the receiver circuit are placed on a printed circuit board, separated from the housing and provided with a virtual ground point formed thereon. The essence of the invention is that the receiver housing contains an insulating plate coated on both sides with a conductive foil, where the first foil of the plate is connected to the virtual ground point of the receiver circuit, while the second foil is connected to the grounded housing of the receiver and low-voltage feed-through capacitors are guided through the insulating plate, one armature of which is connected to the first foil connected to the virtual ground point, and a cutout is formed in the second foil on the other side of the insulating plate around the feed-through capacitors and all input and output connection lines of the receiver circuit are led through the feed-through capacitors.

Description

FIELD OF THE INVENTION The invention relates to the connection of filters for protecting duplex transmitter-receiver devices remotely powered by a high voltage line against duplex interference, wherein the receiver is mounted in a grounded housing and wherein the receiver circuit elements are mounted on a printed circuit board separate from the housing and provided therewith ground point.

It is an object of the invention that the receiver housing comprises an insulating plate coated on both sides with a guide film, wherein the first film of the plate is connected to a virtual ground point of the receiver periphery, the second film is connected to the grounded receiver box and the insulation plate are guided by low voltage lead capacitors. the fitting is connected to a first film connected to a virtual ground point, and a cutout is formed on the second film on the other side of the insulation board around the lead-through capacitors, and all input and output connections of the receiver circuit are routed through the lead-through capacitors.

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The present invention relates to wiring filters for protecting duplex transmitter-receiver devices remotely powered by a high-voltage line against duplex interference, wherein the receiver is mounted in a grounded housing and wherein the receiver circuit elements are mounted on a printed circuit board separate from the housing and provided thereon. virtual grounding point.

In the linear message transmission system, remote power supply has long been a long-established solution. It is based on the fact that the power supply along the line takes place at amplification stations situated at certain distances in succession above the message transmission line. With this solution, a number of stations are connected in series, depending on the capabilities of the system, from a power supply point, and a DC voltage of a corresponding amount is applied to one end of the line. The amount of remote-powered DC voltage is limited, knowing the need for line current through line losses and economy. Practically this means that, for example, assuming a current of 150 rnA in the line, the upper voltage limit of the remote supply line lies at about 700 V. From this DC voltage, the individual amplifier stations receive the energy needed for operation by inserting the Zener diodes in series. Zener diodes by constant current flowing through the line.

In the case of such message transmission systems, it is necessary in specific cases to supplement the individual stations with duplex transmitter-receiver devices in order to allow connection within the bands intended for the system also from mobile radio stations without local binding.

For reasons of economy and reliability, it also seems advantageous to keep the way of supplying the system supplemented by radio devices, since in this case the battery or network power supply may not be built and stations may also be set up unmanned.

When radio stations were deployed, the biggest obstacle for remote power supply was the so-called duplex interference. Generally, the transmitter, receiver and duplex filters of the transmitter-receiver duplex devices are arranged in a single, grounded housing, and also the internal grounding of the current circuit units is performed relative to the housing. The high-frequency interfering signals generated in the transmitter can arrive at the receiver circuit, without due suppression by the control and control lines connecting the device, and prevent it from operating partially or completely. Interference of this kind is also referred to in the art as duplex interference because they occur during the simultaneous operation of the transmitter and receiver.

Protection against duplex interference is effected in such a way that all connection lines are routed through a filter element which conducts unwanted radio frequency interference signals to the frame.

Remote power supply causes problems by supplying power to the devices with several iset volts to ground; if the power supply system is short-circuited, it is possible to detect the entire voltage of the remote power supply, since even the positive and negative branches of the supply voltage of the transmitter and receiver do not lie at the same voltage, since the two devices are connected in series.

For safety reasons, the cabinet must be earthed. This implies that the transmitter and receiver circuit units must be insulated against the chassis and that, depending on the height of the maximum remote supply voltage used, an insulation rated for about 2000 V breakdown voltage must be used.

A virtual circuit ground point is created inside the transceiver housing that is against the high voltage ground. A very difficult technical task is to achieve such high value suppression of the high frequency between the virtual ground point of the receiver and the incoming wires from outside that it can withstand the high voltage between the cabinet and the virtual chassis or breakdown voltage according to safety regulations, while ensuring effective protection against duplex interference.

The use of high-voltage lead-through capacitors has already been delivered for this purpose. However, the size of these capacitors could increase the size of the devices several times and this would also create another problem, since the distributed inductance of large capacitors could not provide high-frequency suppression with sufficient quality. Furthermore, the use of high-voltage lead-through capacitors could greatly increase the instrument's own costs.

Due to the lack of sufficient protection against duplex interference, remote-fed transmitter-receiver duplex systems have not yet been extended, and instead costly local power supply that required constant supervision or significantly higher power consumption was used instead.

These drawbacks are eliminated with the wiring of filters for the protection of duplex transceiver devices, in which the receiver housing comprises an insulating plate coated on both sides with a guide film, the first plate of the plate being connected to a virtual ground point of the periphery of the receiver, the second film being connected to grounded receiver housing and insulating plate run low-voltage lead-through capacitors, one of which is connected to a first foil connected to a virtual ground point, and around the lead-through capacitors, a cutout and all input and output connection lines are formed on the second foil on the other side The receiver circuit is led through the bushing capacitors.

It is advantageous in the connection of filters according to the invention if the grounded second sheet of the insulating plate is connected to the receiver housing via a metal grounding bar.

It is also advantageous in the filter connection according to the invention if the receiver printed circuit board and the insulating board are arranged perpendicular to each other.

The advantage of wiring the filters according to the invention is that it guarantees operationally safe protection against duplex interference when using low-cost low-voltage feedthrough capacitors, while keeping the original receiver dimensions.

An example of the connection of filters for the protection of the transmitter-receiver duplex devices according to the invention is shown in the drawings, in which Fig. 1 shows the transmitter-receiver duplex device in the assembled state in perspective view with the wall partially removed; and FIG. 4 shows a cross section of the insulating plate.

As can be seen from FIG. 1, the receiver of the duplexer is in a grounded metal box 1 of the receiver. The elements of the receiver circuit 6 are mounted on the receiver circuit board 3 separated by plastic spacers 4 from the receiver housing 1. In addition to the printed circuit board 3 of the receiver, an insulating board 2, which is lined on both sides with guide foils, is fastened to this perpendicular and the outer side of the insulating board 2 is earthed by means of the earthing strip 5 through the receiver housing 1. On the insulating plate 2 there are placed low-voltage lead-through capacitors 7, through which the receiver circuits are connected to the transmitter, to the audio frequency line and to the power supply unit.

It can be seen from FIG. 2 that between the first film 8, galvanically connected to the virtual ground point of the circuitry on the first side of the insulation board 2 and arranged on the PCB 3 of the receiver and the edge of the insulation board 2 provides a safe distance for creeping currents corresponding to a test voltage of several thousand volts. At a supply voltage of about 600 V, the insulation board 2 must be insulated to a test voltage of 2000 V. This test voltage determines the strength and also the quality of the insulation board material.

This can advantageously be made of a fiberglass-reinforced board and a film-coated board. The low-voltage lead-through capacitors 7 mounted on the insulation plate 2 are connected by one of the fittings to the first film 8.

It can be seen from FIG. 3 that in the second film 10 arranged on the other, outer side of the insulating plate 2, a cut-out 11 is formed around the lead-through capacitors 7. The cut-out 11 is so large that the distance between the edge of the second sheet 10 and the lead-through capacitors 7 It can also be seen from FIG. 3 that the earthing strip S is galvanically connected to the second foil 10 by means of rivets 12 and thus guarantees a large-area galvanic connection in the assembled state to avoid duplex interference with a secure contact between the second film 10 and the metal housing 1 of the receiver.

In FIG. 4, the insulating plate 2 is shown in cross-section through the condenser 7. On the inside of the insulating plate 2, a fastening strip 13 is brazed to the first film 8, the insulating plate 2 being fastened to the printed circuit board 3. receiver and insulating plate 2 ensures galvanic connection to the virtual receiver frame. On the other side of the insulating plate 2 is a grounding bar 5, fastened by rivets 12, which connects the second film 10 in the assembled state with the receiver housing 1.

The described circuitry realizes, by means of low-voltage lead-through capacitors 7, a high-voltage, high-frequency, as well as a broad-band filter arrangement, in which the insulation to earth is dimensioned to several thousand volts and thus provides effective protection against duplex failures. The small dimensions of the lead-through capacitors 7 used allow the receiver to be placed in a relatively small grounded housing 1. The high-voltage protection and high-frequency suppression is effected by a capacitor formed between the first film 8 and the second film 10 of the insulating plate 2.

The filter implemented in this way provides reliable protection over a significantly wider frequency range than devices solved by conventional high-voltage lead-through capacitors, as low-voltage lead-through capacitors short-circuit the interference signals in the lower frequency bands, while the "structural capacitor" 10, performs effective suppression in the higher frequency bands.

In the circuit shown, the insulating plate 2 coated with the first film 8 and the second film 10 is arranged perpendicular to the receiver printed circuit board 3 and also separates the so-called "interference" and "clean fields" electrically from each other and contributes in this way to further reduce interference.

Claims (3)

Subject 1. Wiring of filters to protect the transmitter-receiver duplex devices remotely powered by the high-voltage line against duplex interference, where the receiver is mounted in a grounded cabinet and where the receiver circuit elements are mounted on a printed circuit board separated from the cabinet and provided thereon a virtual ground point, characterized in that the receiver housing (11) comprises an insulating plate (2) coated on both sides with a guide film, the first plate film (8) being coupled to the virtual ground point of the receiver circuit (6), the second film (10J) being connected to a grounded housing (1j of the receiver and the insulating plate (2) are led low-voltage lead-through capacitors (7), one armature of which is connected to the first inventive film (8) connected to a virtual ground point, and around the lead-through capacitors {7} a notch (11a and 11b) is formed on the second film (10) on the other side of the insulating plate (2) all input and output connection lines of the receiver circuit are routed through the bushing capacitors (7j. Filter connection according to claim 1, characterized in that the grounded second film (10) of the insulating plate (2) is connected to the receiver housing (1) via a metal grounding bar (5). 3. The filter arrangement according to claim 1, wherein the receiver printed circuit board (3) and the insulating board (2) are arranged perpendicular to each other.