The invention generally relates to insensitive munitions safety. Embodiments relate to using electronic means to vent rocket motors.
Embodiments of the invention were the result of extensive modeling work to determine options for implementing a trigger device for a thermally-initiated venting system using standard or emerging electronic technologies. Options for implementing an electronic trigger device for a thermally initiated venting system (E-TIVS) include commercial-off-the-shelf (COTS) based electronics, a semi-custom hybrid module, and a fully custom integrated circuit fabricated using one of two available manufacturing technologies.
It is to be understood that the foregoing general description and the following detailed description are exemplary and explanatory only and are not to be viewed as being restrictive of the invention, as claimed. Further advantages of this invention will be apparent after a review of the following detailed description of the disclosed embodiments, which are illustrated schematically in the accompanying drawings and in the appended claims.
Embodiments of the invention relate to using electronic technology to improve insensitive munitions safety in rocket motors. Embodiments provide added safety in the form of actual temperature sensing and multiple, sequenced, arming energy locks.
Although embodiments of the invention are described in considerable detail, including references to certain versions thereof, other versions are possible. Examples of other versions include performing the orienting electrical components in alternating sequences or hosting embodiments on different platforms. Therefore, the spirit and scope of the appended claims should not be limited to the description of versions included herein.
At the outset, it is helpful to describe various conventions, parameters, and terminology associated with embodiments of the invention.
E-TIVS: Electronic Thermally Initiated Venting System Trigger Mechanism.
SCO: Slow Cookoff, consisting of conditions where the temperature of the munition is raised slowly, such as when the munition is in a bunker that is being heated by an external fire. A representative test raises the temperature of the munition at a rate of 3.3° C./hour. The slow cookoff test puts the munition in a thermal chamber and slowly increases the temperature inside the chamber. This subjects the munition to extreme temperatures with little to no temperature gradient within the munition. When the energetic materials within the munition reach a critical temperature, they begin to chemically decompose, increasing the pressure within the case of the munition. If subjected to this intense heat for enough time, the energetic materials loaded into the munition may explode.
FCO: Fast Cookoff, consisting of conditions where the temperature of the munition is raised rapidly, such as when the munition is suspended over a fuel fire. A representative test suspends the munition over an enveloping fuel fire with a temperature of at least 870° C. The fast cookoff test also imparts a large thermal stress to the munition. The temperature, however, is increased at a very high rate. To conduct the fast cookoff test, the munitions under test are suspended over a pool of burning jet fuel, and are subjected to extreme levels of heat and thermal flux. The fast heating rate associated with this test results in a large temperature gradient between the energetic materials closer to the case of the munition and those loaded nearer to the center of the munition. As in the slow cookoff test, when energetic materials reach their critical temperature, they also begin to chemically decompose. However, the large temperature gradients experienced in the fast cookoff test means that only a portion of the energetic materials loaded into the munition undergo this decomposition. Like in the slow cookoff test, the energetic materials may explode when subjected to the conditions of the fast cookoff test.
Upper Static Switch: One of the switches in the WSESRB approved Three-Switch Inline Fuze architecture is the Upper Static Switch which interrupts the flow of power to the fuze until its control signal is asserted. The Upper Static Switch is located between the power supply rail and the high voltage transformer.
Lower Static Switch: One of the switches in the WSESRB approved Three-Switch Inline Fuze architecture is the Lower Static Switch which interrupts the flow of power to the fuze until its control signal is asserted. The Lower Static Switch is located between the Dynamic Switch and the ground rail.
Dynamic Switch: One of the switches in the WSESRB approved Three-Switch Inline Fuze architecture is the Dynamic Switch which rapidly switches states as controlled by a dynamic signal driver to generate high voltage using a specialized high voltage generation transformer. The Dynamic Switch is located between the high voltage transformer and the Lower Static Switch.
WSESRB-Approved Three-Switch Inline Fuze Architecture: The preferred method for implementing the safety architecture for an inline fuze or initiation system. The Three-Switch architecture consists of an Upper Static Switch controlled by Upper Static Safety Logic, a Lower Static Switch controlled by Lower Static Safety Logic, a Dynamic Switch controlled by Dynamic Signal Generation Circuitry, and a High Voltage Transformer.
FISTRP: Fuze and Initiation System Technical Review Panel is a panel of technical experts tasked with reviewing fuze and initiation systems for system safety as directed by the WSESRB.
WSESRB: Weapons Systems Explosive Safety Review Board, the governing body for Insensitive Munitions, Energetics Safety, and Fuzing Safety for the US Navy.
Inline (Explosive Train): An initiation system where the initiator is connected to the booster, often through explosive leads, and the main energetic charge without interruption.
Out of Line (Explosive Train): An initiation system where the initiator is separated from the booster and the main energetic charge with a mechanical interruption that may be removed to arm the initiation system.
Exploding Foil Initiator: A high-voltage initiator that has been approved for inline initiation systems. The Exploding Foil Initiator is typically abbreviated as EFI.
Initiator: A device, such as an EFI, that initiates an explosive train based on an input signal of some type. This is also referred to as an electro-explosive device, or an EED.
Booster: An energetic material that initiates when exposed to the output of the initiator and is capable of initiating the Main Charge.
Main Charge: An energetic material that makes up the fill of the munition.
LSC: The TIVS Linear Shaped Charge.
Linear Shaped Charge: A device that consists of a linear hollow charge designed to cut through most of the rocket motor case, without cutting through the entire rocket motor case, in order to reduce the containment of the rocket motor propellant. The Linear Shaped Charge contains a Booster and is filled with a small amount of Main Charge material.
TIVS: A Thermally Initiated Venting System is a device connected to a Rocket Motor to improve the behavior of the rocket motor when it is exposed to high temperatures. The TIVS has a Trigger Mechanism, such as the proposed E-TIVS, an Initiator that is triggered by the Trigger Mechanism, and a Linear-Shaped Charge to score the case of the rocket motor. A Thermally Initiated Venting System (TIVS) will vent the case of the munition if exposed to cookoff environmental conditions. The TIVS utilizes a specially designed linear shaped charge to cut through most, but not all, of the case of the munition it is mounted on. This decreases the amount of pressure needed to split the case of the munition.
Under cookoff conditions: Under cookoff means that the case splits before enough pressure is built up inside the case to cause a violent reaction in the bulk of energetic materials. Without the buildup of pressure caused by the decomposing energetics, it is likely that the bulk of the energetic materials loaded into the munition will burn, or deflagrate rather than explode, after the case of the munition is split by TIVS.
Over cookoff conditions: Over cookoff means that a failure occurs in the function of the ETIVS device where there is enough pressure built up inside the case to cause a violent reaction of the energetic materials.
In the accompanying drawings, like reference numbers indicate like elements.
Embodiments of the invention generally relate to an inline venting system for rocket motors.
At least one exploding foil initiator (EFI) 106 is attached to the linear shaped charge 102. At least one electronic thermally-initiated venting system (ETIVS) circuit 200 is electrically-connected to the exploding foil initiator 106. The ETIVS circuit 200 is sometimes referred to as an ETIVS trigger. The exploding foil initiator 106 is configured to auto-fire when the electronic thermally-initiated venting system circuit 200 relays a current pulse through the exploding foil initiator 106, which causes the linear-shaped charge 102 to initiate. The linear-shaped charge 102 houses a booster (not shown) and an energetic material (not shown). The exploding foil initiator 106 is connected to the booster through explosive electrical leads (not shown). A person having ordinary skill in the art will recognize that embodiments will function with various types of exploding foil initiators. For instance, an older exploding foil initiator is sometimes simply referred to as an “EFI.” Newer exploding foil initiators are referred to as low energy exploding foil initiators (LEEFI″ for short). Thus, when exploding foil initiators or any variation thereof are mentioned, embodiments of the invention include current and future EFI versions.
Turning now to
As mentioned earlier, the electronic thermally-initiated venting system circuit 200 is in electrical communication with at least one exploding foil initiator (EFI) 106. The electronic thermally-initiated venting system circuit 200 includes at least one power source 202. The power source 202 is a thermal battery having an output terminal. For ease of viewing the thermal battery and output terminal are both referenced as reference character 202. The battery 202 is configured to generate power using heat of fire from a munition. The generated power is output through the battery output terminal 202.
A first integrated circuit (includes reference characters 206 and 212) is electronically-connected to the battery output terminal 202, and is described in greater detail below. A second integrated circuit (includes reference characters 240, 246, 256, & 260) and is electronically-connected to the battery output terminal 202. The first (206 & 212) and second (240, 246, 256, & 260) integrated circuits are electronically-connected to each other. The thermally-insulated housing described above, thus, is configured to house both the first and second integrated circuits. Electrical/signal communication is shown with lines and arrows in
The battery is a low melting point electrolyte thermal battery configured to auto-initiate under both slow cook-off (SCO) and fast cook-off (FCO) conditions. The battery 202 has a salt electrolyte. SCO corresponds to the melting point of the salt electrolyte. FCO corresponds to the auto-initiation of an uninsulated thermal pellet. SCO conditions are in the range of about 135 to 145 degrees Celsius. FCO conditions are in the range of about 145 to 175 degrees Celsius. The temperature ranges are based upon weapon properties as tested during cookoff tests. The battery 202 is tailored to activate before cookoff so that the ETIVS circuit 200 is powered.
The munition (such as a rocket motor) has an ignition temperature (INITIATION_TEMP). The battery 202 has a battery temperature (BATTERY_TEMP). The battery 202 is configured to generate power (using heat of fire) when BATTERY_TEMP≥INITIATION_TEMP for about 50 milliseconds. This function is shown as reference character 204. The ignition temperature is a range of cookoff temperatures from the testing of the weapon so that the ETIVS circuit 200 activates at no less than 50 degrees Celsius below the respective cookoff temperatures for both SCO and FCO.
The first integrated circuit (206 & 212), includes a thermal environment system check (TESC) circuit 206 having a system check input 208 and a system check output 210. The system check input 208 is electrically-connected to said battery output terminal 202 and is configured to receive the generated power from said battery output terminal. An upper static switch 212 having an upper static switch power input 214, an upper static switch signal input 216, and an upper static switch signal output 218. The upper static switch signal input 216 and upper static switch signal output 218 are shown in the same location on
The TESC circuit 206 includes a thermally-initiated power check (reference character 220), (TIVS_Power), to determine output voltage, (TIVS_Power), from the battery 202, and whether 12 V≤TIVS_Power<16V for at least 10 mSec. The thermally-initiated power check 220 has a thermally-initiated power check output 222. A TIVS_INHIBIT assertion block (reference character 224) is configured to receive a signal from an ignition safety device (shown as reference character 226) on the munition, said TIVS_INHIBIT having an TIVS_INHIBIT output 227.
A TESC two input AND gate 228 having a first AND gate input 230, a second AND gate input 232, and an AND gate output 236 is included. Inverters (reference character 234) are used to allow regular AND gates to be used throughout embodiments of the invention. The first AND gate input 230 is electrically-connected to the thermally-initiated power check output 222 and the second AND gate input 232 is electrically-connected to the TIVS_INHIBIT output 227.
A thermal environment validation circuit 238 is included. When 12 V≤TIVS_Power<16V for at least 10 mSec and the signal from the TIVS_INHIBIT is not asserted, then the thermal environment validation circuit validates whether the munition temperature, TEMP_REMOTE, is greater than or or equal to an actuation temperature threshold, TEMP_ACTUATION (TEMP_REMOTE≥TEMP_ACTUATION) for at least 10 mSec. When TEMP_REMOTE≥TEMP_ACTUATION for at least 10 mSec, the upper static switch 212 is asserted through the upper static switch signal input 216.
The second integrated circuit (240, 246, 256, & 260) includes a cookoff environment validation (CEV) circuit 240 having a CEV power input 242 and a cookoff environment validation (CEV) signal output 244. The CEV power input 242 is electrically-connected to the battery output terminal 202. A dynamic signal generator (DSG) circuit 246 has a DSG power input 248, a first DSG signal input 250, a second DSG signal input 252, and DSG output 254. The DSG power input 248 is electrically-connected to the battery output terminal 202. The said first DSG signal input 250 is electrically-connected to the TESC system check output 210. The second DSG signal input 252 is electrically-connected to the CEV signal output 244. The dynamic signal generator circuit 246 is configured to generate a dynamic signal.
A dynamic switch 256 has a dynamic switch input 258 in electrical communication with the DSG output 254. The dynamic switch input 258 is configured to receive the dynamic signal from the DSG output 254. A lower static switch 260 has a first lower static switch input 262 electrically connected to the CEV signal output 244 and a second lower static switch input 264 electrically connected to the dynamic switch 256. The CEV circuit 240 also includes a temperature gradient positioned between a local sensor mounted within the ETIVS housing (or alternatively mounted on the EFI 106) and at least one remote sensor (shown as “distributed sensors in
The CEV circuit 240 has a first CEV two input AND gate 266 having a first AND gate input 268, a second AND gate input 270, and a first CEV AND gate output 272. The first CEV two input AND gate 266 is a fast cook off AND gate. The fast cook off AND gate 266 is asserted when fast cook off conditions are detected and validated. Fast cook off conditions are detected, as shown in block 274, when TEMP_REMOTE−TEMP_LOCAL>DETECT_FCO, where TEMP_REMOTE is the temperature of the remote sensors 108, and TEMP_LOCAL is the temperature of the local sensors, and DETECT_FCO is the fast cook off temperature.
The fast cook off conditions are validated, as shown in block 276, when TEMP_REMOTE≥T_FCO_UT<TEMP_REMOTE<T_FCO_OT for 10 milliseconds, where T_FCO_UT and T_FCO_OT are the under temperature and over temperature, respectively, of the remote sensors 108. For both fast and slow cook off, “UT” and “Or” are used to determine that the sensors are functioning properly.
A second CEV two input AND gate 278 having a first AND gate input 280, a second AND gate input 282, and a second CEV AND gate output 284. The second CEV two input AND gate 278 is a slow cook off AND gate. The slow cook off AND gate 278 is asserted when fast cook off conditions are not detected (from block 274) and slow cook off conditions are validated. Slow cook off conditions are validated, as depicted in block 286, when TEMP_REMOTE≥T_SCO_UT<TEMP_REMOTE<T_SCO_OT for 10 milliseconds, where T_SCO_UT and T_SCO_OT are the under temperature and over temperature, respectively, of the remote sensors 108.
A two input OR gate 288 has a first OR gate input 289A, a second OR gate input 289B, and an OR gate output 290. The first OR gate input 289A is electrically-connected to the first CEV AND gate output 272. The second OR gate input 289B is electrically-connected to the second CEV AND gate output 284. The OR gate output 290 is the CEV signal output 244 mentioned above, but is depicted with a different number for ease of reading and viewing. The OR gate output 290 is in electrical signal communication with the DSG circuit 246 and the lower static switch 260.
A flyback transformer (sometimes referred to as a high-voltage transformer or flyback converter/controller) 291 and a high voltage diode 292 are connected in series. The flyback transformer 291 is electrically-connected to the upper static switch 212 and the DSG circuit 246. A firing capacitor 293 is electrically-connected to the flyback transformer 291 and high-voltage diode 292. The firing capacitor 293 has a capacitance range of about 0.1 μF to about 0.2 μF and a voltage range of about 1000 V to about 4000 V.
The firing capacitor 293 is connected in parallel to a gas discharge tube 294 and the exploding foil initiator 106. The exploding foil initiator 106, the firing capacitor 293 is connected in parallel with the upper static switch 212 and the lower static switch 260. The firing capacitor is charged when the dynamic signal from the DSG circuit 246 is fed to the dynamic switch 256. The gas discharge tube 294 is configured to discharge when the firing capacitor 291 reaches firing voltage. The gas discharge tube 294 is configured to break over. The firing capacitor 291 is configured to discharge a current pulse through the exploding foil initiator 106. The current pulse then initiates the linear-shaped charge 102.
A pulse discharge circuit may be electrically connected to the exploding foil initiator 106. The pulse discharge circuit detects the current pulse through the exploding foil initiator 106. The current pulse may be detected using a high-speed transimpedance amplifier latched through a D flip-flop. When a latched signal is asserted, the lower static switch 260 is disabled.
In embodiments, battery voltage is checked using a window comparator for proper operation. The TIVS_INHIBIT signal 226 is controlled by a device external to the ETIVS circuit 200. An Ignition Safety Device (ISD) will assert TIVS_INHIBIT when the ISD initiates the Rocket Motor. Other systems may implement this functionality in a different manner. If TIVS_INHIBIT is asserted, the TIVS will not operate.
Sensors implement a thermal cutoff switch, a bimetallic switch, or a fusible link. The bimetallic switch is resettable nature and has reasonably accurate switching points. Multiple sensors (multiple bimetallic switches, wired in parallel) can be distributed along the weapon (along the rocket motor case), if so desired, without detracting from the merits or generalities of embodiments of the invention.
In embodiments, the sensors actuate at a specified temperature, and when the sensor reaches this temperature it will actuate. Within the E-TIVS, the sensor actuation is qualified for 10 mSec to filter out spurious actions. When the sensor input asserted, an upper static switch 212 will be enabled/asserted. The actuation temperature of the thermal environment sensor can be selected for a given energetic material and qualification time of the thermal environment can be programmed through use of passive components, allowing for flexibility in configuring the E-TIVS trigger.
In embodiments, the E-TIVS housing is thermally insulated and provided with a sufficiently large thermal mass, to allow the E-TIVS hardware to survive the fast cookoff environment. This insulation and thermal mass is used to detect thermal gradients, as the local sensor will take much longer to heat up than the remote sensor.
When the remote temperature has exceeded the slow cookoff temperature threshold, but does not exceed the programmed error threshold used to detect a faulty sensor, for a programmed period of time, the lower static switch 260 is enabled/asserted. If the E-TIVS has detected fast cookoff conditions, where the local temperature and the remote temperature differ by more than a programmed margin, the programmed fast cookoff thresholds are used to determine when the lower static switch 260 is enabled. When the remote temperature has exceeded the fast cookoff temperature threshold, but does not exceed the programmed error threshold used to detect a faulty sensor, for a programmed period of time, the lower static switch is enabled. The slow cookoff time and temperature settings, fast cookoff time and temperature settings, and the cookoff temperature margin can be individually programmed through use of passive components, allowing for flexibility in configuring the E-TIVS trigger.
In embodiments, when both static switches (212 & 260) have been enabled, the dynamic signal generator circuit 246 (sometimes referred to as dynamic drive circuitry or simply dynamic driver) is engaged. The dynamic signal generator circuit 246 is prevented from operating before this point using two separate drive controls. The upper static switch 212 is used to control power supplied to the dynamic signal generator circuit 246. When upper static switch 212 is asserted, power is supplied to the device. The lower static switch 262 is used to enable the dynamic signal generator circuit 246 through an accessible run control input on the dynamic signal generator circuit 246. Embodiments of the invention also include the option of increasing the number of controls on the dynamic driver circuitry, such as controlling an oscillator input to the dynamic driver, should additional controls be warranted.
Embodiments of the invention are configured using components based on application-specific conditions such as, for example, temperature. Some of the many possible types of components that can be used for configuring embodiments of the invention are discussed below.
Commercial-Off-the-Shelf (COTS) Components
Commercially available electronics have traditionally had a maximum temperature rating of +125 C. Components are selected based on expected operating temperature. For components that are not rated to operate at the high temperature, temperature performance testing, and long-term burn-in testing methods can be used to screen low temperature parts for performance at high temperatures.
Semi-Custom Hybrid Module
A hybrid module, also known as a hybrid circuit, contains much of what is in a modern integrated circuit, including diodes, resistors, capacitors, and transistors. Unlike a modern integrated circuit, where all of these components are integrated onto a single semiconductor die, a hybrid circuit contains multiple parts within a single sealed package, including discrete components and integrated circuits.
A similar method can be used to build the E-TIVS trigger device. Most commercially available high-temperature components are sold as bare silicon dies, without large and heavy packaging. Custom integrated circuits can also be delivered in this manner. A number of these bare dies can be packaged in a single, hermetically sealed ceramic module that will implement all the necessary interconnects between the components.
Custom Integrated Circuit, Standard Process
Custom integrated circuits may be used for component circuitry. High temperature electronics rely on specific fabrication processes to work. As electronics get hot, the leakage current increases greatly. For integrated circuits fabricated using a bulk silicon process, this leakage will overwhelm the desired signal in the device at a relatively low temperature, in the range of +125 C to +150 C. Integrated circuits fabricated using a silicon-on-insulator (SOI) process have greatly reduced leakage, as the active devices have no connection to one another apart from the etched metal traces on the IC. These SOI processes have been tested and qualified to operate at temperatures up to +220 C. A full-custom integrated circuit can be developed to implement the E-TIVS trigger device. Using one of the available high temperature processes, an integrated circuit can be fabricated that will work across the operating temperature range of the E-TIVS device.
Custom Integrated Circuit, Exotic Process
Wide bandgap semiconductors, such as Silicon Carbide (SiC) or Gallium Nitride (GaN), are also included within embodiments of the invention. Circuits built using these wide bandgap semiconductor technologies have been demonstrated in the laboratory and even have been fabricated at small scales. The performance of these processes is undeniable, with mixed analog and digital circuit operation at temperatures up to and above +400 C being reported. The operational voltages of devices fabricated using these processes is also impressive, with operating voltages reported to be in the range of 15V to 20V compared to the +3.3V to +5V of standard silicon processes.
A full-custom integrated circuit can be developed on one of these emerging exotic processes to implement the E-TIVS trigger device. Using one of the emerging exotic processes, an integrated circuit can be fabricated that will work outside the expected operating temperature range of the E-TIVS device. The custom IC can then be packaged in a hermetically sealed ceramic module that will also exceed the expected operating temperature range of the E-TIVS device.
Summary of Potential ETIVS Components
Several viable component options may be used to configure an electronic TIVS trigger device using an in-line explosive train configuration for the output to the TIVS linear shaped charge. Embodiments of the invention may incorporate any single, combination, or other components not listed, depending on application-specific conditions such as, for example, on how the system is intended to be fielded.
Most digital circuits, such as logic gates and flip-flops, and some analog circuits, such as operational amplifiers and comparators, are easily implementable in custom integrated circuits. In some cases, the integrated circuit fabrication house can provide these circuit elements as a library of standard cells when providing documentation on the fabrication process.
Table I is a listing of commercially available extreme temperature components. The operating temperatures are shown in degrees Celsius. Extreme temperature is generally considered in the art to be temperatures in excess of 210 degrees Celsius. The last column indicates whether or not testing (screening) is needed to determine whether the component is operational at 210 degrees Celsius.
While the invention has been described, disclosed, illustrated and shown in various terms of certain embodiments or modifications which it has presumed in practice, the scope of the invention is not intended to be, nor should it be deemed to be, limited thereby and such other modifications or embodiments as may be suggested by the teachings herein are particularly reserved especially as they fall within the breadth and scope of the claims here appended.
This is a non-provisional application, claiming the benefit of parent provisional application No. 61/854,266 filed on Sep. 17, 2013, whereby the entire disclosure of which is incorporated herein by reference.
The invention described herein may be manufactured and used by or for the government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.
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