EP4053493A1 - Appareil et procédé adaptés pour une utilisation avec une munition - Google Patents

Appareil et procédé adaptés pour une utilisation avec une munition Download PDF

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Publication number
EP4053493A1
EP4053493A1 EP21275023.6A EP21275023A EP4053493A1 EP 4053493 A1 EP4053493 A1 EP 4053493A1 EP 21275023 A EP21275023 A EP 21275023A EP 4053493 A1 EP4053493 A1 EP 4053493A1
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EP
European Patent Office
Prior art keywords
arming
fuze
munition
event
setback
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Pending
Application number
EP21275023.6A
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German (de)
English (en)
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designation of the inventor has not yet been filed The
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BAE Systems PLC
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BAE Systems PLC
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Publication date
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Priority to EP21275023.6A priority Critical patent/EP4053493A1/fr
Publication of EP4053493A1 publication Critical patent/EP4053493A1/fr
Pending legal-status Critical Current

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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42CAMMUNITION FUZES; ARMING OR SAFETY MEANS THEREFOR
    • F42C15/00Arming-means in fuzes; Safety means for preventing premature detonation of fuzes or charges
    • F42C15/24Arming-means in fuzes; Safety means for preventing premature detonation of fuzes or charges wherein the safety or arming action is effected by inertia means

Definitions

  • the present invention relates generally to a fuze arming system for a munition, such as a munition or munition assembly that is adapted to be launched, into the air, from a gun barrel.
  • a munition such as a munition or munition assembly that is adapted to be launched, into the air, from a gun barrel.
  • a related munition and method are also provided.
  • Munitions are provided in a number of different forms, for a number of different applications. Typically, a particular munition will be used for a particular application or intention.
  • munitions are taken to include but are not limited to artillery shells and charges, missiles, rockets, and mortar rounds, as well as small arms munitions such as bullets.
  • Safety and arming units are utilised in munitions to prevent inadvertent or accidental detonation of explosive material within the munitions during routine handling or in the launcher, as well as during the initial flight.
  • the safety and arming units are typically part of a munition's fuze and prevent arming of the fuze until certain conditions are met.
  • An example of such condition may be setback acceleration associated with the launching of the munition.
  • not all safety and arming units are able to measure setback, or measure it in a safe way, and hence cannot exploit this as an arming environment. This limitation is due to the fact that peak acceleration of artillery, mortar and tank rounds typically occurs before a power source of the munition has fully activated. Electronic sensors that depend on electrical power to operate are therefore unable to detect this event.
  • a fuze arming system for a munition comprising: an arming circuit arranged to detect a setback event and, in response to the setback event, generate a signal indicating that an arming event has occurred, wherein the arming circuit comprises a solid-state sensor configured to generate a charge when the setback event occurs.
  • a setback event can be detected before a separate power supply (e.g. external to and separate from the solid-state sensor) becomes available, increasing design flexibility and providing a robust additional safety feature for arming the fuze of a munition.
  • the solid-state sensor may comprise a piezoelectric sensor.
  • piezoelectric sensor converts mechanical strain directly to electrical charge and hence does not require a separate power source to operate, thus addressing the issue of being able to use the sensor before the separate power source has fully activated.
  • the solid-state sensor may comprise a magnetostrictive sensor.
  • a magnetostrictive sensor also converts mechanical strain directly to electrical charge and hence does not require a separate power source to operate, thus addressing the issue of being able to use the sensor before the separate power source has fully activated.
  • the sensing axis of the solid-state sensor may be aligned with a main acceleration axis of the munition.
  • a solid-state sensor arranged with its sensing axis aligned with the main acceleration axis of the munition generates a charge proportional to the applied strain and the strain in turn is proportional to the magnitude of acceleration.
  • the arming circuit may further comprise a capacitor arranged to store a voltage corresponding to the charge generated by the solid-state sensor.
  • the capacitor facilitates the conversion of the charge generated by the solid-state sensor to a voltage.
  • the arming circuit may further comprise a comparator circuit arranged to compare the voltage stored by the capacitor with a threshold value to verify whether an arming event has occurred.
  • the arming circuit may further comprise a rectifier.
  • the arming circuit may further comprise a bleeder resistor.
  • the storage time of the capacitor can be limited, therefore preventing potential interference or errors due to acceleration events experienced prior to firing.
  • the arming circuit may output a signal to arm the fuze.
  • the fuze can be armed in a safe and effective manner.
  • the fuze may comprise an electronic fuze.
  • Electronic fuzes can, in general, be safer than mechanical alternatives.
  • the solid-state sensor may be configured to produce a graduated output.
  • the graduated output can be used to provide information on the prevailing launch conditions (e.g. charge increment, approximate muzzle velocity).
  • the solid-state sensor may be configured to generate the charge before a power source (e.g. external to and separate from the solid-state sensor) of the munition is activated.
  • a power source e.g. external to and separate from the solid-state sensor
  • a setback event can be detected before power from the power source is available.
  • a munition comprising the fuze arming system described herein.
  • a setback event can be detected before a separate power supply becomes available, increasing design flexibility and providing a robust additional safety feature for arming the fuze of a munition.
  • the munition may comprise a small arms munition.
  • the fuze arming system can be applied to a wide range of munitions, from artillery charges to small arm munitions.
  • a fuze arming method for a munition comprising: detecting a setback event, generating a signal that an arming event has occurred, and, in response to the setback event occurring, generating a charge by a solid-state sensor.
  • a fuze arming system for a munition, comprising: an arming circuit arranged to detect a setback event and, in response to the setback event, generate a signal indicating that an arming event has occurred, wherein the arming circuit comprises a sensor configured to produce a graduated output when the setback event occurs, and fuze arming system is arranged to use that graduated output.
  • the setback event can be utilised to provide a graduated output for use by the fuze arming system.
  • the graduated output may be used for arming a fuze, and/or programming a fuze, the fuze being in connection with or forming part of the fuze arming system.
  • the graduated output can be utilised by the fuze arming system in order to arm the fuze, and/or program the fuze in response to the detected setback event.
  • a graduation of the graduated output may be proportional to a degree of setback detected during the setback event.
  • the graduation can be used to indicate conditions characteristic to a specific setback event, further enhancing the utility of the fuze arming system.
  • the graduation of the graduated output may be used for providing information on launch conditions of the munition.
  • the graduated output can be used to provide information on the prevailing launch conditions (e.g. charge increment, approximate muzzle velocity).
  • the sensor may comprise a solid-state sensor, optionally a piezoelectric sensor, or a magnetostrictive sensor.
  • a solid-state sensor optionally a piezoelectric sensor, or a magnetostrictive sensor.
  • the advantage of using a solid-state sensor is that the solid-state sensor exhibits suitable shock/g-force resistance.
  • both the piezoelectric and magnetostrictive sensor convert mechanical strain directly to electrical charge and hence do not require a power source (external to and separate from the solid-state sensor) to operate, thus addressing the issue of being able to use the sensor before the power source has fully activated.
  • the sensing axis of the sensor may be aligned with a main acceleration axis of the munition.
  • a sensor arranged with its sensing axis aligned with the main acceleration axis of the munition generates a charge proportional to the applied strain and the strain in turn is proportional to the magnitude of acceleration.
  • the arming circuit may further comprise a capacitor arranged to store a voltage corresponding to the output generated by the sensor.
  • the capacitor facilitates the conversion of the output generated by the sensor to a voltage.
  • the arming circuit may further comprise a comparator circuit arranged to compare the voltage stored by the capacitor with a threshold value to verify whether an arming event has occurred.
  • the arming circuit may further comprise a rectifier.
  • the arming circuit may further comprise a bleeder resistor.
  • the storage time of the capacitor can be limited, therefore preventing potential interference or errors due to acceleration events experienced prior to firing.
  • the arming circuit may output a signal to arm the fuze.
  • the fuze can be armed in a safe and effective manner.
  • the fuze may comprise an electronic fuze.
  • Electronic fuzes can, in general, be safer than mechanical alternatives.
  • the sensor may be configured to generate a charge when the setback event occurs.
  • the fuze arming system can react in response to the setback event.
  • the sensor may be configured to produce the graduated output before a power source (e.g. external to and separate from the sensor) of the munition is activated.
  • a power source e.g. external to and separate from the sensor
  • a graduated output can be produced before power from the power source is available.
  • a munition comprising the fuze arming system described herein.
  • a setback event can be detected before a separate (e.g. external to and separate from the sensor) power supply becomes available, increasing design flexibility and providing a robust additional safety feature for arming the fuze of a munition.
  • the munition may comprise a small arms munition.
  • the fuze arming system can be applied to a wide range of munitions, from artillery charges to small arm munitions.
  • a fuze arming method for a munition comprising: detecting a setback event, generating a signal that an arming event has occurred, and, in response to the setback event occurring, producing a graduated output, and using that graduated output.
  • a graduated output can be produced in response to the detected setback event can be detected before a separate power supply becomes available, increasing design flexibility and providing a robust additional safety feature for arming the fuze of a munition.
  • any one or more features described in relation to any one aspect may be used in combination with, or in place of, any one or more feature of any one or more other aspects of the invention, unless such replacement or combination would be understood by the skilled person to be mutually exclusive, after a reading of the present disclosure.
  • the present disclosure provides a fuze arming for a munition.
  • the munition comprises an explosive charge and a fuze.
  • the munition is adapted to be launched, into the air.
  • the munition may be adapted to be launched from a gun barrel.
  • the munition typically (and practically likely) includes, or is at least used in conjunction with, a propelling explosive, and is capable of being explosively propelled and withstanding such explosive propulsion.
  • the munition will typically be a projectile, therefore being unpropelled and/or including no form of self-propulsion. This means that the munition is relatively simple and inexpensive.
  • FIG. 1 schematically depicts a fuze arming system in accordance with an example embodiment.
  • the fuze arming system 100 for a munition comprises an arming circuit 102 arranged to detect a setback event.
  • the setback force is the rearward force of inertia resulting from the forward acceleration of a projectile (in this case, a munition) during its launching phase, applied in the direction along of the path of travel of the projectile. That is, the setback force is the force generated as the munition is initially accelerated.
  • a projectile in this case, a munition
  • the setback force is the force generated as the munition is initially accelerated.
  • At least two separate environments must be detected in order to permit arming.
  • Mechanical artillery fuzes typically use separate, independent mechanisms to detect setback and spin.
  • Rotational arming requires that a munition reaches a certain rpm before an arming event occurs. Thus, by detecting a setback event, and using that to indicate that an arming event has occurred, earlier arming or safer might be achieved. Arming based on setback is beneficial in situations where early arming is required - for example, when the munition has a relatively short distance to travel to the target.
  • the arming circuit 102 In response to detecting the setback event, the arming circuit 102 is configured to generate a signal indicating that an arming event has occurred.
  • an arming event will be understood as an event representing a point in time at which the fuze may be armed; for example, the munition reaching its peak acceleration. It is noted that a plurality of different arming events might be required before the fuze is armed, in order to improve safety of the munition. This does not necessarily mean that the fuze can trigger an explosive charge, based on the detection of the setback event, and/or generation of the signal indicating that the arming event has occurred. Other conditions may need to be met.
  • the generation of the signal indicating that the arming event has occurred may occur before a power source 104 of the system is fully activated.
  • setback occurs, and is detected, before the power source 104 is usable or able to provide power to sensing or processing electronics.
  • a power source 104 of a munition is often itself triggered to be in an active or suitably power-supplying state based on launch of the munition.
  • component parts of the power source 104 may move or change state as the munition is launched, and this movement or state change moves the power source 104 to a power-supplying state.
  • this takes time and means that anything within or before that time simply cannot be detected by any sensor powered by that power supply.
  • the signal generated by the arming circuit 102 might be outputted via the output 106, and fed to another element of the fuze arming system, or another element of the munition, for example a control module within the munition.
  • the arming circuit 102 comprises a solid-state sensor 108 configured to generate a charge when the setback event occurs. Said charge is used by the arming circuit 102 for generating the signal indicating that an arming event has occurred.
  • the solid-state sensor 108 comprises anything that is able to generate a charge from a change in pressure (e.g. stress or strain) on the sensor - typically, this is a piezoelectric sensor, or a magnetostrictive sensor, or a combination thereof.
  • a piezoelectric sensor converts mechanical strain directly to electrical charge and thus does not require a power source to operate.
  • a magnetostrictive sensor also change in mechanical energy to changes in electromagnetic energy.
  • the solid-state sensor 108 is able to detect an event, such as a setback event, before the external power source 104 becomes available.
  • the fact that the solid-state sensor 108 does not require power from the external power source 104 is particularly useful also for detecting peak acceleration of certain types of munitions, for example artillery munitions, as typically the peak acceleration of an artillery munition occurs before the separate power source 104 of the munition is fully activated.
  • a sensing axis of the solid-state sensor 108 is aligned with a main (e.g. longitudinal) acceleration axis of the munition such as to generate a charge proportional to the applied strain.
  • the strain is proportional to the magnitude of acceleration of the munition.
  • Figure 2 schematically depicts an arming circuit, in accordance with an example embodiment. It will be appreciated that the arming circuit 200 of Figure 2 is the same as the arming circuit 102 of Figure 1 .
  • the arming circuit 200 comprises a solid-state sensor 208. Detailed description of the solid-state sensor 208 will be omitted as it will be appreciated that the solid-state sensor 208 of Figure 2 is the same as the solid-state sensor 108 of Figure 1 .
  • a charge generated by the solid-state sensor 208 is converted to a voltage via the use of a capacitor 212.
  • the capacitor behaves in a manner analogous to mathematical integration and thus the charge output from the setback event results in a distinct voltage magnitude being recorded on the capacitor 212.
  • an external power source 204 (equivalent to the external power source 104 of Figure 1 ) becomes available later, the voltage on the capacitor 212 can be interrogated via a high impedance comparator circuit 214 and, if the voltage is of the correct magnitude, this can be used to indicate that a valid arming event has occurred. That is, the comparator circuit 214 is arranged to compare the voltage stored by the capacitor 212 with a threshold value.
  • the output of the comparator circuit 218 is depicted schematically as output 206.
  • the output 206 is equivalent to the output 106 of Figure 1 .
  • the arming circuit 200 further comprises a rectifier 216, located between the solid-state sensor 208 and the capacitor 212, intended to prevent charging under accelerations of the wrong polarity, thus further enhancing the safety of the fuze arming system, as accelerations of the wrong polarity will not be falsely interpreted as a setback event.
  • the rectifier 216 comprises a rectifying diode.
  • the arming circuit 200 also comprises a bleed resistor 218, connected in parallel with the capacitor 212, arranged to limit the storage time to a few tens of milliseconds and hence prevents potential interference and/or errors due to acceleration events experienced prior to firing, once again enhancing the safety of the fuze arming system.
  • the charge generated by the solid-state sensor 208 is converted by the capacitor 212 in order to produce a graduated output.
  • the magnitude of the integrated setback voltage may be used to provide information on the prevailing launch conditions, such as charge increment and/or approximate muzzle velocity.
  • This graduated voltage output can be used to actively manage factors such as post-launch arming delay to allow safe separation distance to be relatively independent of charge increment, shell type, and other such factors.
  • the graduated output is used for arming a fuze, and/or programming a fuze. The provision of such graduated voltage output further improves the safety of the fuze arming system.
  • FIG 3 schematically depicts a munition comprising the fuze arming system, in accordance with an example embodiment.
  • the munition 300 comprises an explosive charge 301, a fuze 302, and a fuze arming system 303.
  • the fuze arming system 303 is equivalent to the fuze arming system 100 of Figure 1 .
  • the explosive charge 301 is activated by the fuze 302, causing the ammunition effect - for example, in case of the munition 300 being an artillery round, the exploding thereof.
  • the fuze 302 is the detonator of the explosive charge 301.
  • the fuze arming system 303 is arranged to produce an output indicating that an arming event has occurred in order to enable the fuze 302 to be armed, or to arm the fuze 302 directly.
  • the munition 300 comprises (but is not limited to) artillery shells and charges, missiles, rockets, and mortar rounds, as well as small arms munitions such as bullets.
  • FIG. 4 schematically depicts a fuze arming method for a munition, in accordance with an example embodiment.
  • the method comprises detecting a setback event.
  • the setback force is the rearward force of inertia resulting from the forward acceleration of a projectile (in this case, a munition) during its launching phase, applied in the direction along of the path of travel of the projectile. That is, the setback force is the force generated as the munition is initially accelerated.
  • a projectile in this case, a munition
  • the setback force is the force generated as the munition is initially accelerated.
  • At least two separate environments must be detected in order to permit arming.
  • Mechanical artillery fuzes typically use separate, independent mechanisms to detect setback and spin.
  • the method comprises the step of, in response the setback event being detected, generating a signal that an arming event has occurred.
  • An arming event is understood as an event representing a point in time at which the fuze may be armed; for example, the munition reaching its peak acceleration.
  • the method comprises the step of, in response to the setback event occurring, generating a charge by a solid-state sensor.
  • Such charge generated by the solid-state sensor is generated before an external power source (that is, a power source used to power components of the munition) becomes available, allowing for earlier detection of an arming event.
  • an external power source that is, a power source used to power components of the munition
  • the fuze can trigger an explosive charge, based on the detection of the setback event, and/or generation of the signal indicating that the arming event has occurred. Other conditions may need to be met.
  • the generation of the signal indicating that the arming event has occurred may occur before the power source of the fuze is fully activated.

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EP21275023.6A 2021-03-04 2021-03-04 Appareil et procédé adaptés pour une utilisation avec une munition Pending EP4053493A1 (fr)

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EP21275023.6A EP4053493A1 (fr) 2021-03-04 2021-03-04 Appareil et procédé adaptés pour une utilisation avec une munition

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Application Number Priority Date Filing Date Title
EP21275023.6A EP4053493A1 (fr) 2021-03-04 2021-03-04 Appareil et procédé adaptés pour une utilisation avec une munition

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EP4053493A1 true EP4053493A1 (fr) 2022-09-07

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Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3742857A (en) * 1971-04-05 1973-07-03 H Schmidt Fuzing system for stabilized anti-tank ammunition
US20120180681A1 (en) * 2007-07-10 2012-07-19 Omnitek Partners Llc Inertially Operated Electrical Initiation Methods
US20130180423A1 (en) * 2007-07-10 2013-07-18 Omnitek Partners Llc Shock Detection Circuit and Method of Shock Detection
US20180031357A1 (en) * 2016-07-26 2018-02-01 Omnitek Partners Llc Laser activated initiation devices with self-powered event detection and arming logic and false trigger protection for munitions

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3742857A (en) * 1971-04-05 1973-07-03 H Schmidt Fuzing system for stabilized anti-tank ammunition
US20120180681A1 (en) * 2007-07-10 2012-07-19 Omnitek Partners Llc Inertially Operated Electrical Initiation Methods
US20130180423A1 (en) * 2007-07-10 2013-07-18 Omnitek Partners Llc Shock Detection Circuit and Method of Shock Detection
US20180031357A1 (en) * 2016-07-26 2018-02-01 Omnitek Partners Llc Laser activated initiation devices with self-powered event detection and arming logic and false trigger protection for munitions

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