FR2848351A1 - Lightning conductor with break-over device fitted with remote monitoring, uses a high voltage transformer to create a high voltage discharge to ionize the air near the lightning conductor to test its operation - Google Patents

Abstract

The lightning conductor has a test device (10,11) which generates a signal indicating operating state of the lightning conductor. A transformer (THT) sets up a high-voltage discharge (2) to ionize air in the region the lightning conductor. A sensor (C2) supplies data to a transmitter (12,14) which sends data to a receiver (17) that then passes the data to a communication network (19,20).

Description

The present invention relates to a lightning conductor equipped

  means for testing its operation remotely.

  Systems to protect yourself from lightning during a thunderstorm are not only made up of lightning rods (PTS). 5 There is also a whole range of lightning rods.

  Priming lightning conductors use physical phenomena to ionize the air in the vicinity of the tip in order to preferentially attract lightning on their tip. In this way the range of action of a lightning conductor is greater than that of a 1o lightning rod with single rod whose tip would have the same geometry.

  Priming lightning conductors are known which ionize the air in the immediate vicinity of the tip of the lightning rod. The document published by the National Institute for the Industrial Environment and Risks in October 2001 and entitled "Study of the lightning conductors with priming device" by M 15 P. Gruet, presents a study of such devices. This ionization can be achieved, for example, by an electrical discharge in the air separating two electrodes placed near the tip.

  Furthermore, document EP 0 192 000 describes a lightning rod with polarized tip. In this type of lightning rod the tip is electrically isolated from the ground by a spark gap, and connected to one of the terminals of a high voltage generator, which may be the secondary of a low voltage / high voltage transformer. Under these conditions, the point is brought periodically to a high potential.

  Next to the power electronics, making it possible to ionize the air around the tip, a starting lightning rod may include a synchronization system capable of detecting the approach of a descending tracer coming from the base of the cloud. stormy and announcing the fall of lightning, then to order the high voltage generator.

  Thus, the air in the vicinity of the point is ionized in synchronization with the arrival of a descending tracer, to create the conditions necessary for the generation and the propagation of an ascending tracer having a great probability of coming into contact with said descending tracer.

  It should be noted that the different types of lightning conductor described in these documents can be autonomous, since they can include a source of electrical power constituted, for example, by solar panels supplying an accumulator.

  In order to protect a risk area, such as an industrial installation, against the fall of lightning, a lightning rod is installed. The characteristics of this priming lightning rod will depend on the level of protection sought, the particular geography of the place, etc. In particular, the protection radius defining the efficiency of the lightning rod is adapted.

  Ignition lightning conductors include many electronic components which operate in a generally severe and even extremely severe operating environment during a lightning strike, and whose life is limited in time. Consequently, it is necessary to know whether said igniting lightning rod 20 is in working condition.

  Test devices are known which require the on-site movement of the maintenance operator. The lightning conductors are often located in high places, difficult to access, maintenance is a delicate operation to perform. In practice, it is not made.

  The object of the present invention is to provide a bootable lightning conductor equipped with means making it possible to remotely check the correct operation of said lightning conductor by a maintenance operator.

  The present invention has for its first object a lightning conductor, said lightning rod being capable of producing an ionization of the ambient atmosphere, characterized in that it comprises: - test means making it possible to develop a status signal 5 indicating the operating state of said lightning rod, from values measured by at least one sensor connected to said test means; - transmission means capable of transmitting a signal transmitted as a function of said operating state signal; - reception means capable of producing a signal received from the reception of said transmitted signal; and, - signaling means making it possible to indicate the operating state of said lightning rod from the received signal.

  According to one embodiment, the transmission means transmit a radio signal in a defined frequency band.

  Preferably, the reception means and the signaling means are located in a remote unit.

  According to one embodiment, the operating signal produced by said test means comprises a predefined identifier of said lightning rod. Preferably, the remote unit further comprises a selection means making it possible to define a selected identifier and said signaling means display the operating state of the lightning rod whose identifier corresponds to the selected identifier.

  Preferably, again, the lightning rod according to the invention is designed to switch from a standby mode to an active mode and vice versa, the active mode being engaged when a thunderstorm activity is detected, and being stopped after a period of time during which no more thunderstorm activity was detected, and said test means developing said status signal and said transmission means transmitting said corresponding transmitted signal only in the standby mode.

  In a preferred embodiment, the lightning conductor is of the polarized tip type and in standby mode, the tip is brought periodically to a nominal potential, a voltage divider bridge making it possible to take part of said nominal potential from the tip to generate a signal towards said test means in order to generate a status signal. Preferably, the distance between the transmission means and the reception means is a few tens of meters.

  The invention will be better understood, and other objects, details, characteristics and advantages thereof will appear more clearly during the following description of a particular embodiment of the invention, given solely by way of illustration and not limiting, in i5 reference to the accompanying drawings. In these drawings: - Figure 1 is a block diagram of the electronic elements of the polarized lightning rod according to the present invention; and, - Figure 2 is a block diagram of the maintenance device fitted to the polarized lightning rod of Figure 1.

  In the following description, the specific case of a polarized lightning rod is described in detail, but the remote maintenance system can equip all types of lightning rod.

  Referring to Figure 1, the lightning rod with polarized point is distinguished from a conventional lightning rod with single rod, in that the point 1 25 is electrically isolated from the earth (in dynamic regime, i.e. when lightning does not fall on the tip 1) by a spark gap 2.

  The spark gap 2 can consist of two half-spheres spaced from each other by an interval of 4 cm containing air. When lightning falls on tip 1, the electric field between the two half-spheres of spark gap 2 is greater than the threshold electric field of 27 kV / cm beyond which air is ionized and becomes current conductor. Thus, when lightning falls on the tip 1 of the lightning rod, the spark gap 2 being conductive, the current reaches the earth without passing through the various electronic devices.

  The polarized lightning rod has a high voltage polarization circuit 3 making it possible to bring the potential of the tip 1 to high values of the order of several tens of thousands of 10 volts. The high voltage bias circuit 3 is connected to a voltage / voltage converter 6. From the time-slot signal generated by a time base 7, said voltage / voltage converter 6 emits short current pulses capable of charging a capacitor C located in the high voltage bias circuit 3. When the bias circuit is triggered, by the closing of an electronic switch T, said capacitor C discharges into the primary of a low voltage / high voltage transformer THT. A potential of several tens of thousands of volts is thus generated at the secondary of said THT transformer so as to polarize the tip so that the air surrounding the tip is ionized.

  The high voltage bias circuit 3 is controlled by a control circuit 4 to which at least one sensor 5 is connected. The sensor 5 comprises a plate capable of carrying charges influenced by the charges carried by the base of the cloud. The charges carried by said sensor 5 are therefore of opposite sign to the charges at the base of the cloud. The significant variation in the load carried by the sensor 5 when a descending tracer arrives causes the appearance of a current. When the intensity of this current exceeds a predefined threshold, it constitutes a detection signal giving the indication of the arrival of a descending tracer.

  The sign of this current is also correlated with the sign of the descending tracer. The detection signal is emitted by the sensor 5 to an input of the control circuit 4. From this detection signal, the control circuit 4 generates a synchronization signal in the direction of the high voltage bias circuit 3.

  The synchronization signal is able to close the electronic switch T belonging to the high voltage bias circuit 3 io causing the discharge of the capacitor C in the primary of the high voltage transformer THT.

  On the other hand, as a function of the sign of the current of the detection signal and therefore of the sign of the descending tracer, the control circuit 4 emits, in the direction of the high-voltage bias circuit 3, a bias signal 15 capable of switching a bistable element (not shown) from one position to another. Depending on the position of said bistable, the current flows through the primary of the high voltage transformer in one direction or another, so as to apply to the tip a polarization opposite to that of the base of the cloud.

  Finally, the lightning conductor according to the invention comprises an accumulator 8. The accumulator 8 is supplied, for example, by solar panels 9ac comprising photovoltaic cells. The accumulator delivers a voltage of 6V to the various electronic devices of the lightning conductor. The latter is therefore energy self-sufficient.

  In FIG. 2, the maintenance means making it possible to know, at a distance, the operating state of the lightning conductor according to the invention are described.

  In general, it involves developing a status signal by means of the electronic devices present in the lightning rod with polarized tip, the reading of this status signal making it possible to indicate the operating state of the electronic elements and so lightning conductor.

  The lightning conductor according to the invention can switch from a standby state to an active state, when the sensor 5 detects the first descending tracer sign of a stormy activity. The active state could also be triggered when the sensor 5 detects an electric field greater than a predefined threshold value of the ambient electric field.

  io The lightning rod with polarized tip leaves active mode to switch to standby mode, for example, 45 minutes after sensor 5 has detected the last descending tracer. Obviously, this period of time is adjustable.

  In the case of a lightning rod with polarized point, in standby mode, the point 1 of the lightning rod is polarized at regular intervals.

  This interval is 90 s in the preferred embodiment of the present invention.

  The way of generating a polarization pulse of the tip 1, in standby mode, is identical to that of the polarization of the tip 20 in order to ionize the surrounding air, except that the orders of magnitude of the potentials reached are not the same. In standby mode, the tip is raised to a few thousand volts, compared to the tens of thousands of volts in active mode The tip 1 of the lightning rod is isolated from the ground by the spark gap 2 and 25 brought to a potential by the transformer low voltage / high voltage THT whose primary and secondary are shown in Figure 2.

  Two capacitors CI and C2, in series, connect the base of the tip 1 and the ground, so as to form a voltage divider bridge. The values of the capacitances CI and C2 are chosen so that the voltage across the terminals of the capacitor C2 is no more than a few volts. For a peak polarization in standby mode of 10 kV, CI can be worth 400 pF and C2 0.5 ptF, so that the voltage across C2 is 10V. The voltage taken from the terminals of C2 is applied to the input of a monostable 10. In response to a voltage variation due to the polarization of the tip 1, the monostable 10 emits, at output, a control signal of defined shape. , for example a slot between 0 and 6 V of io 240 jas of period.

  The output terminal of the monostable 10 on which said control signal is transmitted, is connected to an input of an encoder 11.

  The encoder 11 used can, for example, be a Motorola MC 145026.

  The control signal triggers the encoder 10. This emits, at output, a status signal which consists of a predefined identifier characterizing the lightning rod with polarized tip.

  In order to code the identifier, the encoder 1 1 uses a protocol based on a series of nine ternary digits. Each of the digits being coded in base 3, that is to say being able to be in three different states, for example 0, 20 3 or 6 V. The encoder 11 emits a burst comprising three times said state signal towards the transmitter 12.

  The transmitter 12 uses an available transmission frequency such as the frequency of 433 MHz. In this case the transmitter 12 used can be the HF 433 MHz TX 433 SAW transmitter module from Aurel. This emission frequency can obviously be adapted as a function of the emission frequencies available in a particular country. The operating status signal, consisting of the lightning rod identifier, is transmitted on a carrier of frequency 433 MHz by means of the antenna 14, three times in succession.

  Within a perimeter of a few tens of meters, the transmitted signal can be received by means of a portable reception device 15. The reception device comprises a parallelepipedic box 16. On the side of the box 16 is a telescopic antenna 17. The antenna 17 is coupled to a receiver. The latter is capable of receiving the electromagnetic signal emitted and of producing, at the output, a received signal.

  Said received signal enters a decoder, which, in response, generates a signal for indicating the operating state of the polarized lightning rod. If the signal received comprises at least once a series of nine ternary digits corresponding to the identifier of the lightning conductor, the indication signal makes it possible to light a diode 19 or to emit a sound signal by means of the loudspeaker 20 so to report to the maintenance operator that the lightning rod is operating properly.

  Thus, the verification of the correct operating state of the lightning rod can be carried out from the ground, very quickly.

  In another embodiment, the portable reception device 15, remote, comprises a series of selection buttons 21 20 making it possible to select a lightning rod identifier from a series of identifiers corresponding to each of the different lightning conductors present on the site. Once an identifier has been selected, the decoder of the portable reception device 15 decodes only the received signal corresponding to the selected identifier and the indication signal indicates whether the lightning rod with corresponding polarized tip is in operating state. Although the invention has been described in connection with a particular embodiment, the lightning rod with polarized tip, it is obvious that it is in no way limited thereto and that it includes all the technical equivalents of the means described as well as their combinations if these fall within the scope of the invention. In particular, the voltage divider bridge can be installed so as to take a fraction 5 of the potential difference between the electrodes of an electronic lightning conductor, these electrodes, placed near the point connected to the ground making it possible to ionize the air in the vicinity of said point. Equivalently, the voltage divider bridge can make it possible to take a fraction of the potential difference between the hollow point of a piezoelectric lightning rod and the tapered point situated inside it.

Claims (8)

  1. Priming lightning rod, said lightning rod being capable of producing an ionization of the ambient atmosphere, characterized in that it comprises: test means (10, 11) making it possible to prepare a status signal indicating the state operating said lightning rod, from values measured by at least one sensor (C2) connected to said test means; transmission means (12, 14) capable of transmitting a signal transmitted as a function of said operating state signal; - reception means (17) capable of producing a received signal from the reception of said transmitted signal; and, - signaling means (19, 20) for indicating the operating state of said lightning rod from the received signal.   2. Lightning conductor according to claim 1, characterized in that is the transmission means (12, 14) transmit a radio signal in a defined frequency band.   3. Lightning conductor according to one of claims 1 to 2, characterized in that the reception means (17) and the signaling means (19, 20) are located in a remote housing (15).   4. Lightning conductor according to claim 1, characterized in that the operating signal produced by said test means (10, 1) comprises a predefined identifier of said lightning rod.   5. Lightning conductor according to claim 4, characterized in that the remote unit (15) further comprises a selection means (21) 25 making it possible to define a selected identifier and that said signaling means (19, 20) display the operating state of the lightning conductor whose identifier corresponds to the selected identifier.   6. Lightning conductor according to one of claims 1 to 5, characterized in that it is designed to switch from standby mode to an active mode and vice versa, the active mode being engaged when a thunderstorm activity is detected, and being stopped after a period of time during which no more thunderstorm activity has been detected, and in that said test means (10, 11) generate said status signal and said transmission means (12, 14) transmit said corresponding transmitted signal only in standby mode.   7. Lightning conductor according to claim 6, characterized in that it is of the polarized tip type (1) and that in standby mode, the tip is brought periodically to nominal potential, a voltage divider bridge (CI, C2) making it possible to take a portion of said nominal potential from the tip to generate a signal in the direction of said test means (10, 11) in order to generate a status signal.   8. Lightning conductor according to one of claims 1 to 7, characterized in that the distance between the transmission means (14) and the reception means (17) is a few tens of meters.