FR2932561A1 - MICRO INITIATOR SECURE - Google Patents

Abstract

The subject of the invention is a micro-initiator 1 comprising a pyrotechnic initiation means 3 that can be initiated by a first ignition means 13 and is itself intended for igniting a charge 5. This micro-initiator is characterized in that the pyrotechnic means 3 is formed by an energetic composition placed on a first layer 2 of a substrate and able to be connected to the charge 5 via an ignition channel 6 which is closed off by a movable screen 8, which is located on a second substrate layer 7 incorporated in the initiator, which screen 8 can be moved from a safe position to an armed position through the action of the gases generated by a first pyrotechnic generator 9 which is itself incorporated into the micro-initiator 1 and initiated by a second ignition means 14.

Description

The technical field of the invention is that of pyrotechnic primers or initiators, such as igniters or detonators. These components generally comprise a pyrotechnic initiation means, for example a primary explosive composition (for a detonator) or an inflammatory composition (for an igniter). This pyrotechnic means is itself capable of being initiated by an ignition means, for example a heating resistor connected to an electric generator. Pyrotechnic components are the first floor of an initiation chain. When the component is a detonator, it ensures the detonation of an explosive charge, for example a munition.

When the component is an igniter, it ensures the ignition of another composition, for example a propellant charge or a device. These pyrotechnic components are extremely sensitive, especially to shocks, temperature rise or static electricity. It has always posed the problem of the security of their implementation. Generally it is proposed to use a safety and arming device which comprises mechanical means ensuring the interruption of the pyrotechnic path between the initiating component and the load that it must initiate. These devices are however complex and bulky. Their overall volume is of the order of ten cubic centimeter. Most often the component is carried by a movable flap which positions it opposite the charge to be initiated or it provides a chain interruption flap which is driven by motor means and is interposed between the component and the load . A significant source of energy is required to move such a flap, whether or not it carries the component.

This energy source must also have a secure operation to avoid inadvertent arming of the component that would be detrimental to safety. It has been sought for some time to miniaturize the safety and arming devices by realizing all or part of them in the form of chips incorporating micro-machined or micro-etched electro-mechanical elements, either in an element deposited on a substrate, or directly on the substrate itself. This technology known under the name of MEMS (Micro Electro Mechanical System) makes it possible today to achieve micro mechanisms by implementing a technique similar to that for producing electronic integrated circuits. US6964231 discloses such a micro machined safety device comprising a flap carrying a pyrotechnic charge and sliding by the action of the centrifugal force. This shutter itself is immobilized by a lock that is erased by the acceleration of firing of the projectile. The patent FR2892810 describes another safety device implementing a micro machined screen which is interposed between a conventional pyrotechnic component and the explosive charge that it must initiate.

Electromechanical actuators equip safety and arming devices when used in applications that do not implement environmental forces sufficient to move the moving parts and arm the device.

Even if the dimensions of these new devices have been reduced (volume of the order of 2 to 5 cm3), the control means they implement are electromechanical means for which it is necessary to provide sources of significant energy, which limits the possibilities of reducing their size. In addition, they use conventional pyrotechnic components whose size is not reduced and which must be integrated into the safety device by means of specific interfaces.

Finally, it should be noted that the solutions in which it is sought to incorporate a pyrotechnic component to a movable flap (patent US6964231) are difficult to implement. The pyrotechnic mass is indeed extremely reduced and the mobility of the flap must not be disturbed by the addition of this composition. It is the object of the invention to provide a pyrotechnic component of reduced dimensions but nevertheless ensuring high implementation safety. The invention thus proposes to make a micro initiator that incorporates all the means to ensure the desired security. It is then unnecessary to add a security and additional arming device. Finally, the micro initiator according to the invention requires only little electrical energy to ensure both the arming functions and those of initiation. Thus, the subject of the invention is a micro initiator comprising a pyrotechnic initiation means capable of being initiated by a first ignition means and itself intended to initiate a charge, a micro initiator characterized in that the pyrotechnic means is formed by an energetic composition set up on a first layer of a substrate and connectable to the charge by a priming channel which is closed off by a movable screen which is arranged on a second substrate layer incorporated in the initiator, the screen being movable from a safety position to an armed position by the action of the gases generated by a first pyrotechnic generator also incorporated in the initiator and initiated by a second ignition means. The first pyrotechnic gas generator may be placed on the first substrate layer and will be placed in communication with one face of the screen via a gas reservoir chimney. The screen will be held in the security position by at least one lock. The screen may include a transverse hole which will be positioned next to the priming channel when it is in the armed position. When the initiator micro is intended to equip a munition fired by a weapon, it may include a bolt erased by inertia when firing the ammunition. 3 The lock can be housed in its locking position in the transverse hole of the screen. According to another embodiment, the micro initiator may comprise at least one electromechanical lock.

The electromechanical lock may be supported by two conductive beams of different dimensions and will pivot by the effect of a differential thermal expansion of the two beams. The micro-initiator may include a second pyrotechnic gas generator which will be positioned so that the pressure of the generated gases will push the screen to its safety position. The second generator, the volume reserved for the gases that it generates and the surfaces of the screen subjected to the pressures will advantageously be dimensioned so that the effort resulting from the action of the second generator is greater than that resulting from the action. of the first generator. The second generator may be initiated by a rise in temperature, its autoignition temperature being chosen lower than that ensuring self-ignition of the pyrotechnic initiation means. The second generator may be initiated by a third ignition means.

According to one embodiment, the different ignition means are integral with a third substrate layer which is applied to the first layer carrying the pyrotechnic ignition means and the gas generating compositions.

The third layer of substrate may comprise switch means for controlling the ignition means. The third layer may incorporate electronic control means switches and / or ignition means. The third layer will advantageously be connected to a fourth layer which will incorporate electronic means for controlling switches and / or ignition means. The invention will be better understood on reading the following description of particular embodiments, a description given with reference to the accompanying drawings and in which: - Figure 1 is a schematic sectional view of a micro initiator according to a first embodiment of the invention, the micro initiator being in the safety position, - Figure 2 shows the same initiator in the armed position, - Figure 3 shows the initiator in the sterilized position, - Figure 4 is a view schematic of a second exemplary embodiment of the micro initiator according to the invention, - Figure 5 shows an embodiment of the third layer of substrate incorporating switch means ensuring the securing of the ignition means, - Figure 6 shows a diagram of a second embodiment of the third substrate layer incorporating switch means ensuring the securing of the ignition means 20, this diagram being a 4a and 7b show another embodiment of a lock for immobilizing the screen, FIG. 7a showing the locked screen and FIG. 7b showing the locked screen. unlocked screen. Figure 1 shows a first embodiment of a micro initiator 1 according to the invention. This component 1 is made in the form of a stack of several layers of substrate. A first layer 2 of substrate is a silicon layer which receives a pyrotechnic initiating means 3 disposed in a cavity 4. This pyrotechnic initiating means is here an energy pyrotechnic composition, for example a composition that can be activated. detonation or combustion / deflagration depending on the type of component involved (detonator or igniter). For example, it is possible to use a composition based on lead azide. The composition 3 is intended to initiate a pyrotechnic charge 5 which is for example a relay explosive disposed in a casing 5a represented here schematically. Relay 5 will for example be associated with a munition. The energy composition 3 is connected to the charge 5 by a priming channel 6 which passes through the different substrate layers. The micro initiator 1 comprises a second substrate layer 7 which is formed of three parts: a lower part 7a, an upper part 7b and a middle part 7c. These three parts 7a, 7b and 7c will be made for example of silicon (or aluminum). This second substrate layer 7 encloses a movable screen 8 which will be made either of silicon or of a ceramic having a coefficient of expansion similar to that of silicon in order to avoid any jamming. The mobile screen 8 is able to move in a housing 27 which is arranged in the middle part 7c of the second layer 7. It can be seen in FIG. 1 that the first substrate layer 2 also carries a first pyrotechnic gas generator 9 which is disposed in a cavity 10. The cavity 10 of the generator 9 is connected to a chimney 11 arranged in the upper part 7b of the second substrate layer 7. The first pyrotechnic generator 9 is constituted by a pyrotechnic composition generating gas. The chimney 11 forms a reservoir for the gases generated by the generator 9. The pressure of these gases will be exerted on a rear face 8a of the screen 8. A layer 12 of a dielectric membrane (for example made of silicon oxide ) is applied to the rear face of the first substrate layer 2. This membrane makes it possible to isolate the pyrotechnic compositions 3 and 9 from the electrical control circuits to ensure their initiation. These electrical circuits comprise ignition means 13 and 14 which are formed by conducting wires 6 intended to be heated by the Joule effect by means of an electric generator (not shown). The ignition means 13 and 14 are integral with a third substrate layer 15 (made for example of silicon) which is applied to the first layer 2. Advantageously, the ignition means 13, 14 will be associated with means for control of these ignition means. FIG. 5 shows an example of a control circuit 16 which comprises the ignition means 13 and 14 as well as a certain number of switches. A first branch 13a, 14a of each ignition means 13 and 14 is connected to a contact pad 17 which is also connected to the electrical ground of the various control circuits. A second branch 13b of the first ignition means 13 (which ensures the initiation of the pyrotechnic means 3) is connected to a control pad 18 via a normally closed switch 19. Another normally closed switch 20 Moreover, this second branch 13b connects to the earth stud 17. Thus, in the state of electrical safety which is represented in this FIG. 5, the first ignition means 13 is short-circuited, its two branches 13a and 13b being all Two connected to the ground. A normally open switch 21 also makes it possible to connect the second branch 13b to the ground stud 17. This switch architecture constitutes a means for electrically securing the first ignition means 13. Such an architecture is described by the patent FR2884602. By short circuit means 13, the switch 20 provides electrical safety. The current transmitted by a control means (not shown) through the pad 18 can not heat up the first ignition means 13. To lift this electrical safety is controlled opening of the switch 20. It becomes possible to order the initiation of the primary composition 3 by the first ignition means 13. 7 If it is desired to sterilize the ignition means to prohibit any subsequent operation, it suffices on the one hand to open the switch 19 and to on the other hand to close the switch 21 which runs the means 13 and again ensures electrical safety. The switches have been shown schematically in FIG. 5. They will advantageously be in the form of electrothermally controlled micro-switches and without moving parts which will be produced by micro-etching according to the MEMS techniques. Such micro-switches normally open or normally closed are described by the patent FR2884602 and it is therefore not necessary to describe them here in more detail. It is also possible to mount switches using static electronic switches. These components will either be incorporated in the third layer 15 or incorporated in a complementary hybrid circuit 40 which is attached to the third layer and in electrical contact (links 41 and 42) with it. The third layer 15 will then carry only the ignition means 13 and 14. The hybrid circuit 40 will also carry the electronic control means (micro controller or microprocessor) and the energy source (elements not shown).

It can be seen in FIG. 5 that the ignition means 14 of the first pyrotechnic generator 9 is connected by its second branch 14b to a control pad 22 which is like the pad 18 connected to an electronic control means (not shown).

FIG. 5 does not show means for electrical securing by switches associated with the initiation means 14. It is of course possible to provide a set of switches similar to that previously described for securing and sterilizing the means of initiation 14.

It can be seen in FIG. 1 that the mobile screen 8 has a transverse hole 23 in which a latch 24 is positioned. The latch 24 is an inertia lock which is held in its locking position by a compression spring 25. lock slides in a hole 35 arranged in the lower part 7a se the second layer 7. It has a diameter sufficient to ensure the maintenance of the screen 8 in the safety position in case of accidental initiation of the gas generator 9. The compression spring 25 is defined so as to be deformed only when the latch 24 is subjected to the inertial forces following the firing of a munition carrying the micro initiator according to the invention.

Of course the architecture of the ammunition will be such that the micro initiator 1 is properly oriented so that the firing acceleration can effectively erase the latch 24. The latch 24 may be made of silicon, ceramic or metal. A locking means 26 is disposed at the hole 27. This means is intended to ensure the immobilization of the latch 24 in its erased position. The locking means 26 is shown schematically here as a finger integral with a flexible blade, finger can be erased radially to let the lock and then positioned to prevent the return of the lock. It is understood that this means may structurally have a different shape that can be obtained with MEMS micro etching techniques.

As can be seen in FIG. 1, the housing 27 encloses a second pyrotechnic gas generator 28 which is disposed at its end opposite to that where the chimney 11 opens. The pressure of the gases generated by this second generator 30 will be exerted. on the face 8b of the screen and will have the effect of pushing the screen 8 to its safety position. The micro-initiator itself and the second gas generator 28 will be dimensioned so that the force resulting from the action of the second generator 28 is greater than that resulting from the action of the first generator 9. To size the micro initiator can be used in particular the volumes reserved for the gases generated by the first generator 9 and the second generator 28, and 9 that the values of the surfaces 8a and 8b of the screen 8 which are subject to pressure. According to the embodiment shown in FIG. 1, the second generator 28 is initiated by an increase in the ambient temperature. The generator gas composition of this generator 28 will be chosen so that its autoignition temperature is lower (of the order of 100 ° C.) than that ensuring the self-ignition of the initiation pyrotechnic means 3.

Figure 2 shows the micro initiator 1 in the armed position. The acceleration due to the firing of the ammunition which contains it caused the erasure of the latch 24. At the same time, the electronic control means commanded the initiation of the first gas generator 9. The pressure of the gases generated made the screen pass 8 to his armed position. We see that in this armed position the hole 23 of the screen 8 is positioned next to the ignition channel 6. With such an arrangement, a relatively small stroke of the screen 8 ensures the passage of a position security to an armed position. Such an arrangement reduces the size of the micro initiator and increase its reliability. Indeed a reduced stroke for the screen 8 reduces the risk of jamming of the latter in its housing 27. is shown schematically in Figure 2 a means 29 ensuring the locking of the screen 8 in its armed position. This means is here a flexible tongue carrying a locking finger. It may also be constituted by a pin pushed by a spring and which will cooperate with a piercing of the screen 8. It is shown in Figure 3 the position of the micro initiator 1 when a rise in ambient temperature caused the initiation first 9 and second 28 gas generators. Such a situation is encountered for example in storage phases of the micro initiator or the ammunition which incorporates it. A rise in temperature (related to a fire) can cause the initiation of the first gas generator 9 thus the passage of the device to its armed position while no electrical signal controlling such armament has been given.

The risk is then to see the micro initiator be in the armed position while the heat will also cause the initiation of the ignition means 3, that of the ammunition. According to a particular embodiment, the invention therefore proposes to incorporate the second gas generator 28 which has a self-ignition temperature lower than that of the ignition means 3. The sizing has been chosen so that the pressure of gas supplied by the second gas generator 28 generates a force on the screen 8 which is greater than that generated by the action of the first gas generator 9. Of course the device will be dimensioned so that the locking means 29 is also broken. Thus, even if the continuation of the heating of the micro initiator 1 causes the initiation of the ignition means 3, no critical effect is to be feared, the screen 8 being in the safety position. Note in Figure 3 that the gas pressure has pushed the screen 8 slightly beyond the initial safety position. The screen 8 however ensures in this position (called sterilization) an interruption of the priming channel 6. There is shown in Figure 3 a stop 31 which limits the stroke of the screen 8 pushed by the gases of the second generator 28 It is indeed essential that the screen remains in a position ensuring the interruption of the priming channel 6. This stop will be made by micro machining of the second layer 7 of the substrate. FIG. 3 also shows a means 30 for locking the screen 8 in its sterilization position. This means may be structurally analogous to the locking means 29. From a manufacturing point of view, the different substrate layers 2, 7, 15 are produced according to the techniques of integrated circuits incorporating MEMS. This will start from a first silicon substrate in which holes 4 and 10 will be made and the dielectric membrane 12 (silicon oxide) will be produced by oxidation of this substrate. According to the MEMS technologies, the third substrate layer 15 carrying the ignition means 13 and 14 will also be produced, as will the switch means for controlling the ignition means and, optionally, the electronic control means for the switches and the means of ignition. 'ignition. The first substrate 2 and the third substrate 15 will be fixed by gluing. The first substrate 2 can then receive pyrotechnic materials 3 and 9. In addition, MEMS micro-etching technologies will also perform the second substrate layer 7. For machining conveniences, the upper part 7b of the second layer 7 will be made by micro etching of the chimney 10 and the ignition channel 6. During this machining, the stop means 31 and the various latches 29 and 30. The lower and middle portions 7a, 7b of the second layer 7 are also made. The micro-etching of the hole 35, the ignition channel 6 and the housing 27 are carried out for this purpose. 'screen. The ceramic screen 8 is made according to a different technology. The inertial lock 24 and its spring 25 are put in place, then the gas generating composition 28 and the screen 8 and the upper part 7b and the lower and middle parts 7a, 7c are bonded together. Lastly, the first substrate 2 and the second substrate 7 are bonded together by bonding the fourth layer 40, which incorporates electronic control means for the switches and ignition means. From a dimensional point of view it is thus possible to produce a micro initiator whose overall volume is less than 1 cubic centimeter. The total thickness of the micro initiator will be of the order of 5mm and the other dimensions (width and length) will be less than 10mm. Such a micro initiator has dimensions comparable to that of a conventional pyrotechnic component but incorporates all the electrical and mechanical safety of a complex device. It is therefore no longer necessary to provide a complementary security and arming device. It is of course possible to incorporate in the micro initiator a second inertial lock which will be arranged to fade as a result of a rotation of the ammunition carrying the initiator. One can thus provide a pin engaged in a hole of the screen, the axis of this pin being oriented perpendicularly to the axis of the latch 24. Figure 4 shows another embodiment of a micro initiator according to the invention .

This mode differs from the previous one in that the second gas generator 28 is disposed in a cavity 33 formed in the first substrate layer 2. The cavity communicates with the housing 27 of the screen 8 by a chimney 32 which is machined in the upper part 7b of the second substrate layer. The function performed by the second generator 28 is identical to that described above. When it is initiated, the pressure of the gases generated pushes the screen 8 to its sterilization position which ensures the safety of the device. Thus, again for the second gas generator 28, a pyrotechnic composition having a self-ignition temperature lower than that ensuring the self-ignition of the pyrotechnic initiation means 3 will be chosen. A first advantage presented by this embodiment is that the Placing all the pyrotechnic compositions 3, 9 and 28 is done on the same substrate layer 2. It is thus easier to mount the micro initiator, 13 all the pyrotechnic steps of the process being performed on a single and same substrate layer. Another advantage of this embodiment is that it becomes possible to provide at the level of the third substrate layer 15 an initiation means 34 specific to the second gas generating composition 28 (third ignition means 34). It suffices to give the cavity 33 a depth substantially equal to that of the other cavities 4 and 12, ie such that the composition 28 is separated from the third ignition means 34 only by the thickness of the membrane 12. It then becomes possible (in addition to the thermal self initiation of the composition 28) to provide a possibility of controlling the sterilization of the micro initiator. Such an arrangement is particularly useful when it becomes necessary for safety reasons to prohibit the operation of an already armed micro-initiator, for example in response to a failure of a means for guiding or detecting the ammunition incorporating the micro initiator. By way of example, FIG. 6 shows an example of a control circuit of a control circuit 16 which comprises the ignition means 13, 14 and 34. Also shown in this figure are the switches 19, 20, 21 securing the first ignition means 13 and a set of switches 36, 37 and 38 securing the second ignition means 14 of the first gas generating composition 9). Switches 36 and 37 are normally closed switches. Switch 38 is a normally open switch. The switch 37 ensures the short circuiting of the ignition means 14. The opening of this switch allows the operation of this means. The opening of the switch 36 and the closing of the switch 38 makes it possible to electrically sterilize the ignition means 14. No electrical safety is provided for the third ignition means 34 whose action leads, not to arming, but to the sterilization of the micro initiator 1. 14 A first branch 34a of the third ignition means 34 is connected to the ground contact pad 17. A second branch 34b of the third means ignition 34 is connected to a control pad 39.

A detonator micro initiator has been described here. As a variant it is of course possible to produce a micro initiator of the igniter type. It suffices for this to choose as a pyrotechnic initiation means 3 an inflammatory pyrotechnic composition.

It is also possible to define a micro initiator according to the invention wherein the locking of the screen 8 is ensured, not by inertial means, but by at least one electromechanical lock. Such a variant is more particularly adapted to the case of munitions that are not fired by gun and for which the inertial forces are therefore insufficient. By way of example, FIGS. 7a and 7b show an electromechanical lock 43 which comprises a rod 44 which is in the locking position in a lateral bore 47 carried by the screen 8. The micro initiator is shown here so very schematic and only the screen 8 is visible in plan view in its housing 27 arranged in the second layer 7. The transverse hole 23 carried by the screen is also visible in the figures.

The rod 44 of the electromechanical lock 43 is supported by two conductive beams 45a and 45b which are of different dimensions and each connected to a contact 46a, 46b. The contacts 46a, 46b are connected to an electric generator (not shown) which will be integral for example with the hybrid circuit 40. When the beams 45a, 45b are traversed by an electric current, the heating causes a thermal expansion of these two beams . The difference in surface area between the two beams causes a differential expansion which leads to the pivoting of the rod 44 with respect to the screen 8. With appropriate sizing of the rod 44, its housing 47 and the beams 45a, 45b the rod 44 can effectively disengage from its housing 47 and release the screen 8 which can then move (as described above) by the action on the face 8a of the screen 8 of the gases generated by a generator of gas (not shown). 16

Claims (16)

REVENDICATIONS1. Micro initiator (1) comprising a pyrotechnic initiation means (3) capable of being initiated by a first ignition means (13) and itself intended to initiate a charge (5), micro initiator characterized in that the pyrotechnic means (3) is formed by an energetic composition placed on a first layer (2) of a substrate and which can be connected to the charge (5) by a priming channel (6) which is closed off by a screen (8) movable which is disposed on a second layer (7) of substrate incorporated in the initiator, the screen (8) being movable from a safety position to a position armed by the action of the gases generated by a first pyrotechnic generator (9) also incorporated in the initiator (1) and initiated by a second ignition means (14). 2. Micro initiator according to claim 1, characterized in that the first pyrotechnic gas generator (9) is placed on the first layer (2) of substrate and is placed in communication with one side of the screen (8). ) via a chimney (11) forming a gas tank. 3. Micro initiator according to claim 1, characterized in that the screen (8) is held in the safety position by at least one latch (24). 4. Micro initiator according to one of claims 1 to 3, characterized in that the screen (8) has a transverse hole (23) which is positioned opposite the priming channel (6) when in the armed position . 5. micro initiator according to claim 3 and intended to equip an ammunition fired by a weapon, characterized in that it comprises a latch (24) erased by inertia when firing the ammunition. 6. micro initiator according to claims 4 and 5, characterized in that the latch (24) is housed in its locking position in the transverse hole (23) of the screen. 7. Micro initiator according to claim 3, characterized in that it comprises at least one electromechanical lock (43). 17 8. micro initiator according to claim 7, characterized in that the electromechanical lock (43) is supported by two conductive beams (45a, 45b) of different dimensions and pivots by the effect of a differential thermal expansion of the two beams. 9. micro initiator according to one of claims 1 to 8, characterized in that it comprises a second pyrotechnic gas generator (28) which is positioned such that the pressure of the generated gases pushes the screen (8) to its position of security. 10. Micro initiator according to claim 9, characterized in that the second generator (28), the volume reserved for the gases it generates and the surfaces of the screen (8) subjected to pressure are dimensioned so that the stress resulting from the action of the second generator (28) is greater than that resulting from the action of the first generator (9). 11. Micro initiator according to one of claims 9 or 10, characterized in that the second generator (28) is initiated by an increase in temperature, its autoignition temperature being chosen lower than that ensuring self-ignition of the pyrotechnic means of initiation (3). 12. micro initiator according to one of claims 9 to 11, characterized in that the second generator (28) can be initiated by a third ignition means (34). Micro initiator according to one of claims 1 to 12, characterized in that the different ignition means (13, 14, 34) are integral with a third substrate layer (15) which is applied to the first layer (2). ) carrying the pyrotechnic ignition means (3) and the gas generating compositions (9, 28). 14 micro initiator according to claim 13, characterized in that the third layer (15) of the substrate comprises switch means (19,36) for controlling the ignition means. 15. Micro initiator according to claim 14, characterized in that the third layer (15) incorporates 18means electronic control switches and / or ignition means. 16. micro initiator according to claim 14, characterized in that the third layer (15) is connected to a fourth layer (40) incorporating electronic control means switches and / or ignition means. 19