FR2822600A1 - LIGHTNING RESISTANT ECLATOR - Google Patents

Abstract

To design a spark gap resistant to lightning current with several spark gaps connected in series, this spark gap being made up of n elementary spark gaps (FS), its arc voltage being brought to the nth multiple of the arc voltage of an elementary spark gap by series connection of the elementary spark gaps (FS) and the elementary spark gaps (FS) being connected, with the exception of the first spark gap to react in the event of lightning (FS1), to capacitors in such a way that the elementary spark gaps (FS) conduct successively, the second spark gap and all the following ones (FS2 to FSN) being directly connected to a common reference potential via the capacitors, in such a way that the spark gap is triggered only in the event of an overvoltage caused by lightning, it is proposed that the sizing of the control capacitors be carried out according to the following formula: (n-1) x CE = k x CL x û/ Us , where n is the number of capacitors, CE each control capacitor, k a factor d e safety >= 1, CL the capacitance of the line between the spark gap and the source of the overvoltage, û the peak value of the overvoltage and Us the protection level of the spark gap.

Description

their memorization.

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D E S C R I P T I O N

  The invention relates to a lightning current resistant spark gap with a plurality of branehed sparkers in series, wherein the spark gap is formed of n elementary spark gaps, its arc voltage being supplied to the multiple of the spark gap voltage of an elementary spark gap. series splashing of the elementary spark gaps and the elemental sparklers being tested, with the exception of the first spark-gap to act in the thunderbolt, with impediments, especially of the actions, in such a way that the spark gaps The second spark gap and all subsequent ones are connected to a common contact potential, in particular the earth, via the impedances and the impedants used being all of the same size. Such elastomers, for example, are known from DE 197 42 302 A1 and DE 197 55 082 A1. It is known that a stirrer or multiple stirrer can be used for the transient potential compensation as well as for the extinction of the generator. current course. The function of such a spark gap can be subdivided into four basic functions:

  1. initiation of the eclator in case of lightning surge.

  2 bypass and flow of the lightning current between the earth and the eonductor and a weak

voltage drop along the are.

  3. flow and extinguishing of the current.

  4 restabilization of the eclator and resistance to the return voltage at the place of the eclator.

  o The improvement described below deals exclusively with the initiation of the spark gap in the event of transient overvoltages and overvoltages caused by major lightning strikes as well as on spark gap initiation, particularly in the event of overvoltages that appear. during secondary lightning strikes and have a steeper slope than those of

main lightning.

  Concerning the first part of the problem, it should be noted that in all the previous technical solutions, the arrester spark gap is ignited by any transient voltage, for example following pulse bursts during the disconnection of inductive loads. , fuse interruptions and switching overvoltages in the broadest sense,

  when the value of the overvoltage exceeds the starting voltage of the spark gap of the parabolage.

  o This means that a surge arrester responds whenever such an overvoltage occurs. On this occasion, depending on the moment at which the priming occurs, there appears a stream of continuation which,

  according to the lightning arrester model, will be interrupted by it or by a fuse located upstream.

  The arrester should, however, by definition, start only in case of surge caused by lightning. It would be advantageous to be able to avoid a seizure because of other overvoltages as this would save the arrester and relieve the network of falls.

  unnecessary voltage or, as the case may be, to avoid fuse tripping.

  One of the objectives of the invention is therefore to design a spark gap which is primed

  only in case of surge caused by lightning.

  Regarding the second part of the problem, it should be noted that it is known that the negative cloud-earth discharge represents, with 90%, the majority of lightning strikes. Among these negative earth-land discharges, we observe a proportion of 50% of thunderbolts

  secondary schools whose slope is significantly higher than that of the main thunderbolt.

  The spark gaps are nevertheless controlled for their response to the surge caused by the main lightning strike. The response to negative secondary lightning strokes is not verified by current standards. Since the spark gaps are still exposed, it is

  necessary to optimize their response mode from this point of view.

  The aim is to extend the level of protection of the spark gap, indicated so far only for lightning surge 1.2 / 50 1ls, at the solicitation by lightning strikes.

  side effects and to achieve the same level of protection in this case.

  This objective is attained by the invention in that the sizing of the control capacitors is carried out according to the following formula: (nl) x CE = kx CL x û / Us, we are the number of capacitors, CE each capacitor k, a safety factor> 1, (: L the capacity of the line between the spark gap and the source o of the overvoltage, û the peak value of the overvoltage and Us the protection level of the spark gap. The response mode of the multiple spark gap is thus defined in such a way that the transient overvoltages caused by switching maneuvers do not trigger the multiple spark gap while the overvoltages caused by lightning trigger the multiple spark gap when the energy of the spark gap overvoltage signal is high enough to ignite all elementary spark gaps If the signal energy of an overvoltage caused by lightning, for example caused by a very far-infrared lightning strike, is not enough to start the the whole of the multiple spark gap, the voltage remains nevertheless limited to a value lower than the level

protection.

  The reboot of the surge arrester after the extinction of the following current is made more difficult of the

  that the transient voltage in return is consumed by the control capacitors.

  Another object of the invention is to extend the level of protection of the spark gap, heretofore indicated only for the lightning surge 1,2 / 50, us, to the solicitation by

  negative lightning strikes and to achieve the same level of protection in this case.

  All the spark gaps based on gaseous discharge phenomena show a more or less pronounced inertia which has its origin in the discharge delay due to the statistics of the initial éleGtrons in the gas. This delay in discharge is therefore a disadvantage for all

  arrays consisting of a single spark gap. This effect also exists in a multiple spark gap.

  It is therefore the last elementary spark gap of a multiple spark gap to be initiated which determines the tension of rep it is. Each burst has a strong effect on the shock characteristic which indicates the relationship between breakdown voltage and breakdown time. Thus, as the slope of the shock voltage increases, the response voltage of the spark gap increases. This can lead, in case of extreme overvoltages, to exceeding the protection level which is determined by the lightning overvoltage response mode 1.2 / 50 ls. Such an overrun is possible in the event of overvoltages caused by

o Negative secondary lightning.

  In order to modify the spark gap for such conditions, it is proposed to connect the elementary spark gaps, with the exception of the first elementary spark gap, to varistors connected in parallel to the elementary spark gaps, the size of the varistors being effected according to the i5 following formula: (n-1) Ur + UA C <Us, we are the number of gaps, Ur the residual voltage of the varistor, UAK the voltage at the first spark gap FS 1, given by the voltage drop between anode and cathode

  and Us the protection level of the multiple spark gap.

  The switching on of these varistors makes it possible to ensure advantageously the level of

  protection even in case of very steep shock voltage.

  Examples of embodiments are shown schematically in the drawing and described in more detail below. It can be seen: Figure 1 a first circuit structure according to the invention and its equivalent diagram;

  Figure 2 a modified configuration of the spark gap and its equivalent diagram.

  Figure 1 shows the structure of a multiple spark gap. The overvoltage u (t) is applied across the multiple spark gap and first ignites only the first elementary spark gap FS1 capacitance C12. After the priming of the first elementary spark gap, the elementary spark gap FS2 is subjected to the voltage UFS2 (t) = U (t) U (f) because C23 << C2E

C23 + C2E

  The FS spark gap will start as well. All the following elementary spark gaps are

  o start successively for the same reason.

  But the priming of each elementary spark gap is also accompanied by taking a share of the signal energy of the pulse voltage u (t) to charge the capacitors C1E ... CNE control. If the signal energy is limited, as is the case for all transient overvoltages caused by switching maneuvers, it will be fully consumed if the CIE ... C (N-1) E control capacitors are suitably dimensioned. The nth spark gap will no longer be able to start, the tension

  residual at its terminals being lower than its starting voltage.

  o Control capacitors can also be dimensioned according to the following criteria: Linear control. All CEs are of the same size. The size of the control capacitors can be determined from the following consideration: on the spark gap side is the line capacitance CL which would be charged to U as a result of a transient overvoltage. The load on this part of the line is then Qe = CL * U. In the presence of a multiple spark gap, this charge is consumed by the control capacitors because of the ignition thereof. In order for the last elementary spark gap not to start, the charge must be distributed over only n- 1 elementary spark gaps. Once the load is distributed, it must no longer remain across the multiple spark gap that a voltage value at most equal to the level of protection. A charge Q = (n-1) * CE * U5 is then applied to the control capacitors. By equalizing the charges Q = QL and taking into account a factor of

  security, the value of the command capacity can be calculated.

  (n-l) * CE = k * CL * _ Us U = overvoltage peak value Us = spark gap proficiency level k = safety factor 21

  o CL is the capacitance of the line between the spark gap and the source of the surge.

  In the case of a thunderbolt, there appears a virtually infinite signal energy that

  in all cases causes the priming of all elementary ECIs.

  Advantageously, a response mode of the multiple spark gap is defined such that transient overvoltages caused by switching maneuvers do not trigger.

not the multiple spark gap.

  Surges caused by lightning trigger the multiple spark gap when the signal energy of the overvoltage is large enough to prime all elementary spark gaps. If the signal energy of an overvoltage caused by lightning (for example caused by a very far-off blow) is not sufficient to start the whole of the multiple eclayer, the voltage is still limited to a certain value. lower than the level

protection.

  The resetting of the parabol - late after the extinction of the current is made more difficult because the transient voltage in return is consumed by the capacitors of comand. Figure 2 shows a circuit completed by varistors. The rise in voltage due to the discharge delay of the elementary spark gap is avoided by switching on varistors. The varistors are connected in parallel to the elementary spark gaps FS2 ... FS N and keep the voltage at their terminals almost constant, at a level defined by the characteristic curve of the varistors, until the elementary spark gaps start. Since the varistors operate practically without delay with respect to an air gap, a characteristic shock curve is obtained that is almost independent of the slope of the voltage. Only the first elementary spark gap FS 1 must start with the natural gas discharge. With a multiple spark gap, it is nevertheless possible to set the first elementary spark gap FS1 to a value lower than the protection level. The sizing of the varistors is carried out according to the following formula: (n1) Ur + UA C Us n: number of spark gaps Ur residual voltage of the varistor UAK: voltage across the first elementary spark gap FS 1, given by the voltage drop between anode and cathode level of protection of the multiple spark gap The switching of these varistors makes it possible to advantageously ensure the level of

  protection even in case of very steep shock voltage.

  The invention is not limited to the exemplary embodiment and may have many variants in the context of the disclosure.

  All isolated or combined features disclosed in the description and / or drawing

  are considered essential to the invention.

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Claims (2)

R E V E N D I C A T IO N S   1. Lightening current-proof spark-gap with several spark gaps connected in series, this spark gap being constituted by n elementary spark gaps (FS), its arc voltage being supplied to the nth multiple of the arc voltage of an elementary spark gap by connection in series of elementary spark gaps (FS) and the elementary spark gaps (FS) being connected, with the exception of the first spark gap to be reacted in the event of lightning (FS1), to impedances, notably capacitors, in such a way that the elementary spark gaps (FS) lead successively, the second spark gap and all subsequent ones (FS2 to FSN) being directly connected to a common reference potential, in particular earth, via the impedances and the impedances used being all of the same size, characterized by the fact that the dimensioning of the control capacitors is carried out according to the following formula: (n-1) x CE = kx CL x û / Us, one is the number of condensate urs, CE each control capacitor, k a safety factor 1, CL the capacitance of the line between the spark gap and the source of the overvoltage, the crimp value of the surge and Us the   protection level of the spark gap.   2. A spark gap according to claim 1, characterized in that the elementary spark gaps are connected, with the exception of the first elementary spark gap FS1, to varistors connected in parallel to the elementary spark gaps (FS2 to FSN), the size of the varistors performing according to the following formula: (n-1) Ur + UAK <Us, we are the number of spark gaps, Ur the residual voltage of the varistor, UAK the voltage at the first spark gap FS 1, given by the voltage drop between