FR3072507A1 - ELECTROMAGNETIC AGGRESSION PROTECTION SYSTEM FOR RADIO FREQUENCY TRANSMISSION CHANNELS - Google Patents

Abstract

The present invention relates to a protection system (10) against electromagnetic aggression intended to equip an electromagnetic wave emission system (100) provided with an emitter placed in a faradisé enclosure, at least one antenna, and coaxial connections, inside (20) and outside (30) to said faradise enclosure, connecting said At said antenna, said protection system comprises, along said coaxial links, a primary protection (12) at the foot of said antenna and a wall-through protection (11) at the input of said enclosure. faradised between the inner coaxial link and the outer coaxial link, said primary shield having at least one primary splitter and said wall crossing shield having a secondary splitter, a filter and a © crêteur. The invention also relates to an emission chain equipped with such a protection system.

Description

Electromagnetic aggression protection system for radio frequency transmission channels

FIELD OF THE INVENTION

The present invention belongs to the field of the transmission of electromagnetic waves and more specifically of radio frequency emission chains, it relates more particularly to a system of protection against electromagnetic aggressions of high amplitude and of impulse nature for high frequency emission chains.

STATE OF THE ART

The chain to be protected includes equipment located outside, such as the antenna and the coaxial line and equipment located in a faradized enclosure to protect this equipment against the direct field generated by electromagnetic aggression.

The impulse electromagnetic aggression induces, on the external elements of the chain, electrical stresses, which propagate to the transmitter via a coaxial link.

The strongest sources of stress result from the coupling of the field with the structures exposed to direct radiation, that is to say the antenna and the portion of coaxial line outside the faradized enclosure.

The transmitting antennas considered are large structures with no dissipative charge, the size of which is related to the lowest frequency wavelength. One of the difficulties is that part of the spectral energy content of the aggression occupies the useful band and can therefore only be partially filtered in frequency.

The coaxial link between the antenna and the faradized enclosure is exposed to the direct field. The stress developed along the line results from the diffusion of the field through the shield of the coaxial.

However, this collected stress can be made negligible compared to that collected by the antenna by choosing a cable with low linear impedance of transfer in the pulse band.

Another constraint to be taken into account is the compatibility of the device with the radio signal to be transmitted, which can be of high power.

There are solutions to protect a reception chain.

On the other hand, there is no device to protect a high-power broadcast chain made up of standard equipment, notably the transmitter.

PRESENTATION OF THE INVENTION

The present invention relates to a system for protection against electromagnetic attack intended to equip an electromagnetic wave emission chain provided with a transmitter placed in a faradized enclosure, at least one antenna, and coaxial connections, interior and exterior. to said faradized enclosure, connecting said transmitter to said antenna.

This protection system is remarkable in that it comprises, along said coaxial connections, primary protection at the foot of said antenna and protection for crossing the wall at the entrance to the faradized enclosure between the internal coaxial connection and the external coaxial link, said primary protection comprising at least one primary spark gap and said wall crossing protection comprising a secondary spark gap, a filter and a clipper.

According to one embodiment, the primary spark gap and the secondary spark gap are gas spark gaps.

Advantageously, the primary spark gap has a static ignition voltage greater than a maximum peak voltage of the useful signal from the transmitter.

Likewise, the secondary spark gap has a static ignition voltage between the maximum peak voltage of the useful signal from the transmitter and the static ignition voltage of the primary spark gap.

According to an advantageous embodiment, the filter of the wall passage protection is a band pass filter.

Preferably, the bandwidth of the bandpass filter corresponds to the emission band of the antenna.

For example, the bandwidth of the bandpass filter is 2 MHz to 30 MHz.

According to one embodiment, the clipper of the wall crossing protection has a threshold independent of the pulse form and slightly higher than the maximum peak voltage of the useful signal of the transmitter.

Advantageously, the secondary spark gap, the filter and the clipper are arranged in this order, starting from the outside towards the inside of the faradized enclosure.

The invention also relates to a transmission chain comprising a protection system as described, said transmission chain having for example a useful band of frequencies between 2 MHz and 30 MHz.

The fundamental concepts of the invention having just been exposed above in their most elementary form, other details and characteristics will emerge more clearly on reading the description which follows and with reference to the appended drawings, giving by way of 'nonlimiting example an embodiment of a protection system and an emission chain in accordance with the principles of the invention.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 represents a block diagram of a program chain provided with a protection system according to the invention.

DETAILED DESCRIPTION OF EMBODIMENTS

In the following description, the radiated electromagnetic aggression is a high amplitude pulse signal characterized by its time profile. By coupling with the antenna structure, the aggression is collected by the antenna and generates, at the foot of the antenna, a high level signal with significant instantaneous variations in voltage.

FIG. 1 represents an exemplary embodiment of a transmission chain 100 of radiofrequency waves (abbreviated as RF) mainly comprising a transmitter, an indoor coaxial link 20, an outdoor coaxial link 30, and a transmission antenna, said transmission chain incorporating a protection system 10 against electromagnetic attack according to the invention.

Overall, the radio channel 100 includes, in addition to the elements mentioned, other elements not shown and which participate in the emission of RF waves.

The emission chain 100, according to the illustrated exemplary embodiment, operates in a usual high frequency band (abbreviated as HF) which corresponds to frequencies between 2 MHz and 30 MHz, and which is commonly used in radiocommunications.

According to the exemplary embodiment illustrated, the transmitter of the emission chain 100 has a power of 10 kW.

The transmitter is the equipment in the emission chain most vulnerable to electromagnetic attack, so it is placed in a faradized enclosure which limits its exposure to direct radiation and which isolates it from external RF signals which could impair its functioning.

In addition, the faradized enclosure has a faradization class compatible with its susceptibility to electromagnetic radiation.

Among the elements not shown in the transmission chain, signal distribution and switching equipment located immediately downstream of the transmitter are also protected as the transmitter, their conduction and radiation susceptibilities being taken into account.

The transmitter of the transmission chain 100 feeds the transmission antenna via distribution equipment not shown and the coaxial, short indoor 20 and outdoor 30 links.

The HF transmitting antenna, according to the illustrated exemplary embodiment, has a wide frequency band between 2 MHz and 30 MHz, said transmitting antenna being a structure without dissipative load, having dimensions which are linked to the lowest frequency wavelength.

The protection system 10, delimited by a broken line in FIG. 1, comprises two parts, a primary protection 12 at the base of the transmitting antenna and a protection for crossing the wall 11 of the faradized enclosure, said protections being placed along the coaxial connections.

When a pulsed electromagnetic attack reaches the emission chain 100, it induces electrical stresses, in the form of induced currents, in the elements of the chain. These electric currents propagate in the coaxial links between the various pieces of equipment in the chain.

The protection system 10 then makes it possible to sufficiently weaken the currents induced by the electromagnetic attack so that all the elements of the emission chain 100 remain operational during the attack and after its disappearance.

During an electromagnetic attack, the strongest induced electrical stresses result from a coupling between the field of the attack and the elements of the emission chain exposed to direct radiation, i.e. the antenna. and the portion of the coaxial connections located outside the faradized enclosure.

The antenna of the emission chain 100 works in a wide useful band which can contain part of the energy spectrum of electromagnetic aggression, which can therefore only be partially filtered in frequency.

According to the example illustrated, the external coaxial link 30 which connects the antenna to the faradized enclosure, and which is thereby located outside of said faradized enclosure, is exposed to direct radiation as pointed out above. The electrical stress generated along this external coaxial connection 30 results from the diffusion of the field of aggression through a shielding of said external coaxial connection. The diffusion of the field of aggression towards the interior of the faradized enclosure is characterized by a linear impedance of transfer of the shielding Z _T (in Ω / m). This impedance depends on the material constitution and the geometry of the coaxial connection, and varies according to the frequency. The electrical stress collected can be made negligible compared to that collected by the antenna by choosing for example a link with low linear impedance of transfer in the frequency band of the aggression.

Primary protection

The primary protection 12, according to the illustrated exemplary embodiment, comprises a primary spark gap placed at the base of the antenna between said antenna and a ground.

Indeed, the electromagnetic aggression collected by the antenna induces the most energetic electrical stress due to the exposure of said antenna to direct radiation. This electrical stress induced at the antenna has significant instantaneous variations in voltage, greater than the variations in voltages produced in the rest of the transmission chain, it is therefore capable of damaging the coaxial supply link of the antenna, that is to say the external coaxial link, by a breakdown of the dielectric of said coaxial link.

The primary spark gap, which is a gas spark gap according to the exemplary embodiment illustrated, then makes it possible to clip the impulse stress generated by the attack at the head of the external coaxial link 30 which supplies the antenna, said primary spark gap being intentionally placed there.

The primary spark gap has a static ignition voltage greater than the maximum peak voltage of the wanted signal from the transmitter so that the wanted signal from the transmitter is never clipped in the absence of disturbance. Especially since the static ignition voltage of a spark gap is always lower than its dynamic ignition voltage.

In addition, the primary spark gap is capable of draining the short circuit current from the antenna upon attack without damaging its own electrodes.

The amplitude of the residual electrical stress at the terminals of the primary spark gap is limited and divided over time into several pulses of small amplitudes generated at each ignition of said primary spark gap.

Thus, the peak amplitude and the total energy content of the residual stress are considerably attenuated compared to the electrical stress collected at the foot of the antenna.

Wall crossing protection

The wall crossing protection 11, according to the example embodiment illustrated, comprises in order, from the outside to the inside of the faradized enclosure, a secondary spark gap, a band pass filter and a clipper. All of these elements are placed at the wall of the faradized enclosure crossed by the coaxial connections.

The secondary spark gap has a static ignition voltage between the maximum peak voltage of the useful signal from the transmitter and the static ignition voltage of the primary spark gap.

The secondary spark gap makes it possible to reduce the residual pulses from the primary spark gap, which propagate in the external coaxial link 30 between the antenna and said secondary spark gap and which add to the electrical stress collected by said external coaxial link.

The choice of an external coaxial link 30 with low linear transfer impedance makes it possible to considerably limit the electrical stress collected by said external coaxial link with respect to the residual stresses of the primary spark gap.

The bandpass filter has a bandwidth identical to the useful band of the transmission chain, namely 2-30 MHz in the example illustrated, and has the role of reducing the energy content outside the useful band of the residual pulses of the secondary spark gap.

In addition, the bandpass filter is sized to pass the transmit signal from the transmitter into the wanted band with very little loss.

The clipper is a solid-state clipper (Solid-state in English terminology) with a threshold independent of the pulse form and slightly higher than the maximum peak voltage of the useful signal of the transmitter.

The clipping of the wall crossing protection 11 thus makes it possible to limit the amplitude of the residual stress, at the output of said wall crossing protection, to a value close to a nominal value of the useful signal of the chain transmitter. .

The protection system as described thus makes it possible to obtain a hardened emission chain, without modification of the transmitter, and comprising mainly:

- A primary protection at the foot of the antenna protecting the coaxial link which feeds said antenna by a clipping operation, and making it possible to reduce the stress induced by the aggression into narrow residual pulses of considerably reduced amplitudes, in particular in the case of strong coupling;

- An external coaxial link, the shielding of which is dimensioned so that the stress collected in said coaxial link remains negligible compared to the stress collected by the antenna;

- A class-wide enclosure compatible with the radiation susceptibility of the equipment in the chain it protects;

- A wall crossing protection formed by a spark gap, a band pass filter and a clipper allowing to limit the stress at the entry of said protection, to filter it outside the useful band of the chain, then to limit it in amplitude so as to obtain a residual stress at the output of said peak value protection close to the nominal value of the useful signal of the transmitter.

The various protective elements thus make it possible to preserve the functional integrity of the emission chain, and this for any level of aggression less than or equal to that prescribed in the standard which governs said emission chain.

Claims (10)

1. Protection system (10) against impulse electromagnetic attacks of high amplitude intended to equip an emission chain (100) of electromagnetic waves provided with a transmitter placed in a faradized enclosure, with at least one antenna, and coaxial connections, interior (20) and exterior (30) to said faradized enclosure, connecting said transmitter to said antenna, characterized in that it comprises, along said coaxial connections, a primary protection (12) at the foot of said antenna and a wall crossing protection (11) at the entrance to said faradized enclosure between the internal coaxial connection and the external coaxial connection, said primary protection comprising a primary spark gap and said wall crossing protection comprising a secondary spark gap, a filter and a clipper. 2. Protection system according to claim 1, wherein the primary spark gap and the secondary spark gap are gas spark gaps. 3. The protection system as claimed in claim 1 or claim 2, in which the primary igniter has a static ignition voltage greater than a maximum peak voltage of the useful signal from the transmitter. 4. The protection system as claimed in claim 3, in which the secondary spark gap has a static ignition voltage comprised between the maximum peak voltage of the useful signal of the transmitter and the static ignition voltage of the primary spark gap. 5. Protection system according to any one of the preceding claims, in which the wall-crossing protection filter (11) is a bandpass filter and in which the passband of said bandpass filter corresponds to the emission band. of the antenna. 6. Protection system according to claim 5, in which the pass band of the band pass filter is from 2 MHz to 30 MHz. 7. Protection system according to any one of the preceding claims, in which the wall crossing protection limiter (11) has a threshold independent of the pulse shape and slightly higher than the maximum peak signal voltage. useful from the transmitter. 8. Protection system according to any one of the preceding claims, in which the secondary spark gap, the filter and the clipper are arranged in this order, starting from the outside towards the inside of the faradized enclosure. 15 9. Transmission chain (100) characterized in that it comprises a protection system (10) according to any one of the preceding claims. 10. Transmission chain according to claim 9, characterized in that it has a useful band of frequencies between 2 MHz and 30 MHz. 1/1