SE439988B - ELECTRICAL TENDON INCLUDING A LEADING PYROTECHNICAL TENDING COMPOSITION PARALLEL WITH A STABLE RESISTANCE - Google Patents

Description

? 907ä86I'0 2 Experiments, on the other hand, have shown that the energy range for an initiation of These igniters are very extensive. For some weak voltages can the igniter exceptionally operate with some microjoule energy, while one can find clicks or failures for other igniters when ignited with an energy of the order of joules.

Most of the above disadvantages can be explained by the circumstance the electrical resistance of the conductive pyrotechnic the composition varies in the function of the electrical energy that one applies to the composition. This is actually due to the fact that they the conductive particles (generally graphite) are distributed on a non- uniform manner in the pyrotechnic composition of the igniters. During a rela- weak voltage circulates the current between the conductive particles following long and winding paths. learn the igniter is exposed for a sufficiently high voltage, on the other hand, the mentioned currents the paths through the microwaves so that the igniter works with a dynamic resistance with a value clearly lower than its static resistance below .weak voltage. It is therefore understood that under these conditions the ignition can be effected at a very low energy threshold.

The object of the present invention is to provide an igniter with a pyrotechnic composition, which igniter exhibits a functional security and reliability that are clearly better than those known igniters.

The electric igniter referred to in the invention comprises a leading pyrotechnic ignition composition, which is placed in contact with a useful pyrotechnic charge, and two electrodes arranged in electrical contact with said conductive pyrotechnic composition.

In accordance with the invention, the two electrodes are connected a stable electrical resistance connected in parallel with the conductor the pyrotechnic composition.

Thanks to this stable electrical resistance, which is connected in parallel with the conductive pyrotechnic composition, the ignition energy is distributed between this parallel resistor and the pyrotechnic composition.

Consequently, a functional constancy of the igniter is obtained which is superior to that obtained in the known embodiments. '7907h86-0 3 Incidentally, the parallel arrangement of the said stable resistor stand with the conductive composition. which varies greatly in function of the applied energy, a considerable desensitization of ignition w .. as far as the click-through thresholds are concerned without: or dan skulï appreciably affect the specific function of the igniter The invention is advantageously applicable to electrical igniters which one of the electrodes consists of a round metal dot nal the other the electrode consists of a metal body having a flat surface on a parallel with said washer.

According to a preferred embodiment of the invention, said tray is separated from the flat surface of the metal body by means of a round washer of an electrical resistance material, which is the electrical parallel the resistor, the cavity formed by said tiles being filled with the leading pyrotechnic composition. This washer or pad of electrical resistance material consequently replaces those of the known ones electric igniters utilized the discs of dielectric material. According to a preferred embodiment of the invention, it has electrisk the parallel resistor an ohm value suitably included between 0.8 and 2 times that of the resistance of the conductive pyr0g¿kh_. the composition.

This is connected in parallel with the conductive pyrotechnic composition resistors may be made of a thermoplastic material shipped with graphite, which allows easy achievement of a resistance exhibit an ohm value of the same order of magnitude as that of the: ledanue comp- sitionen.

Other features and advantages of the invention will become apparent the following description. On attached drawing given givencg out not limiting example, Fig. 1 is a longitudinal view of an electric igniters according to the invention and Fig. 2 a diagram to illustrate the function of the electric igniter according to the invention.

As shown in Fig. 1, the igniter according to the invention comprises: wL a substantially non-cylindrical, outer metal nozzle 1,: if iunæwlutcr rigid technical pyrotechnic charge 2 and the standard composition tion 5. The useful pyrotechnic charge 2 is neparated from the outer metal casing 1 by means of a cup A ua metal, viluonu 3oLLfJ : ttifa pyroteknjaku liid- ür provided with a central opening H. Den the ring 2 is covered by a metal shield 2a, which compresses it charge 2 against the leading pyrotechnic composition j. The ledaidc clvsovaas-o 4 the composition 5 is in contact with the useful charge 2 through it insulating cup 4 central opening 5.

The conductive composition 5 is placed in electrical contact with two electrodes 6 and 7) The electrode 6 consists of a metal body, which is shows a flat surface 8 in contact with the conductive composition 5. the root 7 is a round metal washer or metal disc arranged below the metal cup 4 parallel to the flat surface 8. The disc 7 and the metal body 6 is electrically insulated with respect to the exterior the metal casing 1 by means of an insulating cup 9 surrounding this roundel 7 and the body 6.

Otherwise, the flat surface 8 of the body 6 is separated from the roundel 7 by means .another round washer or roundel 10 of substantially dimensions identical to those of roundabout 7. This roundabout 10 has a determined electrical resistance, which is stable as a function of it energy applied to, the same. The one of the openings'a and 10a of the discs 7 and 10 formed, the cylindrical cavity is filled of the conductive pyrotechnic charge 3.

The disc 10 forms an electrical resistor connected in parallel with the resistance of the conductive composition 5.

The resistance of this roundel 10 is advantageously comprised of essential between 0.8 and 2 times the actual resistance of the conductor the pyrotechnic composition 3.

The resistor 10 may be made of a thermoplastic material or a rubber made conductive by graphite particles. ß med The graphite weight content is advantageously comprised between 3 and 10 with regard to the total weight of the roundabout 10. At the time of manufacture of the resistor pad 10, it is compressed under a pressure in the order of 1,000 bar. Under these conditions, this exhibits roundel 10 a resistivity comprised between 500 and 2,000 ohm.cm due to the graphite content.

To ensure a good electrical contact between the resistor the part 10 and the electrodes consisting of the disc 7 and the body 6, this resistor 10 is compressed between the two electrodes 6 and 7 under the influence of the pressure exerted by the useful charge ~ ningen 2. '7907486-0 5 With reference to fi? 2 now comes the function of the electric ski Ä. the igniter according to the invention to be described.

In accordance with the diagram in Fig. 2, it can be seen that the disc 10 is arranged between the electrodes 6 and 7 is equivalent to a resistor ap connected in parallel with the resistor Rs constituted by the conductive pyramid technical composition 5. Under these conditions, the the point of ignition of the igniter the ignition energy between the composition 5 and its parallel resistance consisting of roundel 10. Starting from that the electrical resistance of the conductive compositions 5 varies much in function of the energy applied to electrodes 6 and 7 allows the parallel arrangement of a fixed resistor with the resistor of this composition 3 that the igniter is desensitized considerably in terms of the threshold without this significantly affecting the specific of the igniter function threshold.

This result can be displayed using the following calculations: In the case of one between the electrodes 6 and 7 of the igniter, in static condition, applied voltage H = 1 (unit) is that in the ignition used the energy W equal to (1 / Rs + 1 / Hp) t the relation, in which Rs is static resistance of the conductive composition 5, up rondelleos 10 stand and t time.

The ratio w fifi / W between that consumed in the conductive composition 5 the energy and the total energy W are equal to: (1 / ns) t (1 / RS + 1 / Rp) t Rs are generally of the same order of magnitude as Rp; to simplify assuming that Rs = Rp. Consequently, WRG / W is equal to å.

In the dynamic state, the dynamic resistance of the conductive composition 5 is equal to 1 Rs, where k can vary between 2 and 10 in the risk energy field contemplated by the present invention.

In this case; wßd / w = k / (1 + k) For k = 2 w fl á / w = 2/3 For k = 5 wRd / w = 5/6 For k e 10 w fi å / w = 10/11 _ 7907486-0 The calculations above show that in the static state the conductor dissipates the composition 5 only half of the applied energy, while the composition sition diverts a much larger fraction of it as soon as it the dynamic resistance Rd becomes very different from the static one the resistance Rs.

The difference between the voltage called the safety voltage and the voltage called functional voltage significantly amplifies the difference in terms consumed energy in the igniter with the corresponding threshold value.

In practice, the voltage is called the operating voltage equal to about 2 to 5 times the safety voltage. The corresponding voltage step favors very current input in a resistor with dynamic behavior oßh i in that case much weaker. In this case, the probability of functioning increases with equal energy, as evidenced by low initiation energies for the igniter, while at low voltage it passes through the igniter according to the finding greatly reduced probability requires a huge amount of energy tet.

The total electrical resistance consisting of the internal resistance Rs of the composition 3 and the fixed resistance Rp of the roundel 10, which former resistor is connected in parallel with the latter, is consequently more precise than for a known igniter. The coordination of two given precision resistors lead to a certain compensation of static defects superior to their dispersion.

The electrical resistance of the igniter according to the invention varies in addition, much less with time than with the known igniters. The measure to provide a fixed resistance parallel to that of the conductive composition 5 resistance relatively reduces the resistance variation.

Hereinafter, comparative characteristics are given as comparative examples and performance of a known igniter and an igniter according to the invention. which differs from the known igniter by the fact that it includes a resistor pad 10 located between the electrodes 6 and T instead of an electrically insulating disc.

Known igniter w- »ww-» Qw M3 m _ š 79Û7485_0 'EšÃ¿Ä¿§Wš¿ii¿f0 the invention , Definite voltage for : non-function Functional energy is unavoidable 10 volts (safety voltage ning) ~ at 99 ß click - via 99% functions mwwwegmwwewwu fl w in z 5 to 4 volts E 5 to 10 microjoules . «». 1 ............. 4. . 200 à 1 ooo mikr ° j ° u1 @ § Diameter 8 mm I 3 mm Processed h0S I0nå91 ~ cellulose acetate É rubber loaded with len included between å graphite electrodes à ' in Thickness of this 0.10 mm § 0.20 mm roundabout ; eWw "m_wW.-¿-H» TYPE of tä fl dl fi ddninë B1ytrinitroresorcinate, š potassium chlorate, barium- 1 nitrate, calcium silicon- 2 ditto compound, graphite É in É Average resistance 70 ohms É 48 ohms Typical deviation with É with respect to means- g resistance r 35% f 25 ß g å Resistance variation after one month aging »15 to 20% É 2,000 to 5,000 micro- jouie 50,000 to 400,000 microjule Functional energy below 18 volts (functional voltage) - at 99% kmickning _ at 99% function 5 to 10 microjoules 160 to 400 microjoules - hrs... -, w ». I _.

Operating time for ignition donated below normal Lenergy for ignition << šO microseconds » 40 to 100 microjoules 300 to 1,000 micro- joule in * NA <: §O eíkeoeekuedee i _ ,. vsovuss-o 8 When comparing the numerical data given in the table above it appears that the igniter according to the invention has a pyrotechnic behavior close to that of the known igniter. On the other hand, ignition the device according to the invention has a resistance which is slightly more constant and in time clearly more stable.

The voltage threshold that gives absolute clicking also exceeds in average about 3.5 to Y volts. With 10 volts, at safety threshold, is the igniter in accordance with the invention is about 1,000 times smaller sensitive to the known igniter, which is considerable. üed 18 volts voltage, ie at the function threshold of the igniter, is nevertheless the grounding device according to the invention only 2 times less sensitive than the known the igniter, which is predictable in practice.

The igniter according to the invention consequently provides a functional safety which is clearly increased in relation to the known igniter.

The invention is of course not limited to the example which just has been described without numerous modifications being made to the igniter without leaving the scope of the invention. Thus, the invention is applicable as well on igniters that work with low voltage (10 to 20 volts) as on igniters that operate at medium voltage (eg 200 volts).

The igniter according to the invention is likewise applicable to detonators. to withstand significant accelerations.

Incidentally, the shape of the electrodes 6 and 7 and the shape of the resistor 10, which is connected in parallel with the conductive pyrotechnic composition. tion 5, may be different from that shown in the figures.

In addition, the resistor 10 can be made of any suitable material such as exhibits a resistivity comparable to that of the conductive composition. provided that this resistance is sufficiently stable in function of the energy applied to the resistor.

Claims (6)

vsovass-o Patent claim An electric igniter comprising an electrically conductive pyro-technical igniter composition (3), which is placed in contact with the useful pyrotechnic charge (2) of the igniter, and two electrodes (6, 7), which are arranged in electrical contact with the conductive the pyrotechnic composition and which are connected by means of an electrical resistor (10) connected in parallel with the conductive pyrotechnic composition, characterized in that the electrical resistor (10) has a stable resistance value. Electric igniter according to claim 1, wherein one of the electrodes is constituted by a metallic annular washer (7) and the other electrode is constituted by a metal body (6) having a flat surface (8) parallel to said washer, characterized therefrom , that the washer (7) is separated from the flat surface (8) of the metal body by means of a second annular washer (10) which is made of electrical resistance material and which constitutes said parallel resistance, and that the cylindrical cavity provided by the two washers is filled with the conductive pyrotechnic composition (3). 3. An electric igniter according to claim 1 or 2, characterized in that said electrical parallel resistor (10) has an ohm value which is comprised substantially between 0.8 and 2 times the ohm value of the static resistance of the conductive pyrotechnic composition (3). . Electric igniter according to one of Claims 1 to 3, characterized in that the electrically connected electrical resistor (10) is made of a thermoplastic material loaded with graphite. 5. An electric igniter according to any one of claims 1-3, characterized in that the parallel-connected resistor (10) is made of rubber or rubber containing between about 3 and about 10% graphite. Electric igniter according to claim 4 or 5, characterized in that the electrical resistance material of the resistor (10) has a resistivity comprised substantially between 300 and 2,000 ohm.cm.