The present invention relates to a non-lethal weapon. More particularly, the present invention relates to circuitry which generates voltages and currents sufficient for incapacitation or immobilization of a target. The circuitry may be implemented in a projectile launched from a standard weapon.
Non-lethal weapons intend to temporarily disable a living target, i.e. a person or animal without causing permanent damage. Among possible methods for incapacitation, electrical current is considered relatively safe and practical to implement. In this approach, a pulsating current is injected across a portion of the body tissue of the target. The shape and magnitude of the current are such that the current interferes with the neuromuscular system of the target, and causes a temporary disabling or stun effect. In order to prevent possible interaction between the persons, e.g. who control the non-lethal weapon, and the target, remote operation of the non-lethal weapon is desirable. The electrical incapacitation preferably takes place while the controlling agent is at a distance from the subject. Non-lethal immobilization weapons have been developed with tethers or wires attached between the power source and the projectile.
Electrical pulses used for incapacitation preferably include a high voltage component. High voltage is required to breakdown any gaps in the electrical circuit path that carries the incapacitation signal from the weapon to the target. The presence of the gaps stems from the fact that the electrodes connected to the circuitry may not reach the body tissue of the target due to clothing and/or other obstacles. An electrical breakdown in the gaps generates electrically conducting plasmas which close the electrical circuit between the weapon and the target. Once the electrical breakdown occurs, the electrical circuit conducts from the weapon to the target without galvanic contact between the electrodes and the body tissue. Circuits which first breakdown non-conducting gaps by a high voltage and ionize the gas allowing a current to flow through the gap, are well known dating for instance to early designs of fluorescent lamp ballasts. (See for instance W. Elenbass, Ed. Fluorescent Lamp. UK. London, Macmillan, 1971.) Similar circuits are also used for starting high intensity discharge (HID) lamps such as a sodium HID lamp (e.g. S. Ben-Yaakov, and M. Gulko., Design and performance of an electronic ballast for high pressure sodium (HPS) lamps. IEEE Trans. Industrial Electronics, 44, 4, 486-491, 1997).
U.S. Pat. No. 6,999,295 discloses an electronic disabling device for immobilizing a target including a power supply, first and second energy storage capacitors, and two switches to selectively connect the two energy storage capacitors to down stream circuit elements. Reference is now made to
According to an aspect of the present invention, there is provided an electronic circuit which provides an electrical incapacitation current to a living target. The circuit includes a high voltage power supply, a charge-storing capacitor connected by a high voltage lead to the high voltage power supply. The charge-storing capacitor stores a charge at high voltage as supplied by the high voltage power supply. The circuit further includes a switch, a step-up transformer including a primary coil, a secondary coil, a resonant capacitor connected in parallel with the charge-storing capacitor through the primary coil, and an output terminal operatively connected through the secondary coil (optionally through the switch) to the high voltage lead of the charge-storing capacitor. The primary coil is connected in parallel with the charge-storing capacitor through the switch. During the incapacitation, the output terminal is operatively attached to at least a part of the living target. When the switch is closed, any gap if present between the output terminal and the living target undergoes electrical breakdown from energy stored in the charge-storing capacitor. After the electrical breakdown, the incapacitation current is provided substantially from the charge stored in the charge-storing capacitor. When the switch is closed an electrical resonance starts in a resonance path preferably including the primary coil, the resonant capacitor and the charge-storing capacitor through the switch. Voltage peaks of the resonance as induced in the secondary coil contribute to the electrical breakdown. A spark gap is operatively connected serially with the output terminal, the spark gap undergoes electrical breakdown from the energy stored in the charge-storing capacitor so that the spark gap provides an electrical breakdown step even when a gap between the output terminal and the living target is not present. The switch is preferably closed when the charge-storing capacitor is charged to a predetermined level. The switch preferably includes a spark gap which breaks down at a predetermined voltage. Alternatively, the switch is controlled by a timer previously set to close the switch at a predetermined rate (in pulses per second). The charge storing capacitor is charged so that the desired level of predetermined voltage is reached on or before closure of the switch. The high voltage power supply preferably includes: a battery, a tapped inductor with a first lead connected to the battery and a second lead operatively connected to the high voltage lead of the charge-storing capacitor; and a boost converter connected to a tapped lead of the tapped inductor with a high voltage output operatively connected to the charge-storing capacitor. The electronic circuit optionally includes a secondary coil of the transformer and a second output terminal attached to at least a part of the living target. The second secondary coil electrical connects the second output terminal to the low voltage lead of the charge-storing capacitor.
According to another aspect of the present invention, there is provided an electronic circuit which provides one or more electrical incapacitation pulses to a living target. The circuit includes a high voltage power supply, charge-storing capacitor connected by a high voltage lead to the high voltage power supply. The charge-storing capacitor stores a charge at high voltage as supplied by the high voltage power supply. The circuit further includes a switch, a step-up transformer including a primary coil and a secondary coil and a resonant capacitor. The primary coil and the resonant capacitor are connected in parallel with the charge-storing capacitor through said switch. An output terminal is series connected through the secondary coil to the high voltage lead of the charge-storing capacitor. During the incapacitation, the output terminal is operatively attached to at least a part of the living target. The circuit includes a control mechanism for actively controlling the incapacitation pulses. The control mechanism preferably includes a sense resistor operatively connected in series with the living target and an operational amplifier with an input connected to the sense resistor and an output operatively connected to the living target. The sense resistor and the operational amplifier provide active control of the incapacitation current of the incapacitation pulses in a closed loop. Alternatively, a sense resistor is operatively connected in series with the living target; and a control circuit, e.g. microprocessor, with an input from the sense resistor, the input being proportional to the incapacitation current of the incapacitation pulses. A sense capacitor is preferably connected in series with the living target. A control circuit preferably includes an input from the sense capacitor proportional to the charge of the incapacitation pulses delivered to the living target.
According to yet another aspect of the present invention there is provided a method for electrical incapacitation to a living target. A circuit is provided including a high voltage power supply, a charge-storing capacitor connected by a high voltage lead to the high voltage power supply, the charge-storing capacitor storing a charge at high voltage as supplied by the high voltage power supply, a switch, a step-up transformer including a primary coil and a secondary coil. A resonant circuit including the primary coil is connected in parallel with the charge-storing capacitor through the switch. An output terminal is series connected through the secondary coil to the high voltage lead of the charge-storing capacitor. The output terminal is attached to at least a part of the living target. The charge-storing capacitor is charged to a predetermined level. The switch is closed when the charge-storing capacitor is charged to the predetermined level and a gap if present between the output terminal and the living target is electrically broken down from energy stored in the charge storing capacitor. The living target is incapacitated from the charge stored in the charge-storing capacitor. Upon the closing the switch, an electrical resonance starts in the resonant circuit. Resonance peaks induced in the secondary coil contribute to the electrical breakdown. Just prior to closing the switch the resonant circuit preferably stores substantially zero energy. Upon closing the switch, an electrical resonance preferably starts in the resonant circuit including the primary coil, a resonant capacitor and the charge-storing capacitor through the switch. Resonance peaks are induced in the secondary coil which contribute to the electrical breakdown. The resonant capacitor is preferably connected in parallel with the charge-storing capacitor through the primary coil. The incapacitation current is preferably provided in a series of pulses. A residual voltage is preferably measured on the charge-storing capacitor. Based on the residual voltage, the predetermined level is adjusted for at least one subsequent pulse.
According to an embodiment of the present invention there is provided an electronic circuit which provides an electrical incapacitation current to a living target. The circuit includes a high voltage power supply, a charge-storing capacitor connected by a high voltage lead to the high voltage power supply. The charge-storing capacitor stores a charge at high voltage as supplied by the high voltage power supply. The circuit further includes a resonant circuit, a switch connecting the resonant circuit to the charge storing capacitor, a step-up transformer including a primary coil and a secondary coil. The primary coil is included in said resonant circuit. An output terminal is serially connected through the secondary coil to the high voltage lead of the charge-storing capacitor. During the incapacitation, the output terminal is operatively attached to at least a part of the living target. When the switch is closed, the resonant circuit stores initially substantially zero energy, and any gap if present between the output terminal and the living target undergoes electrical breakdown from energy stored in said charge-storing capacitor. After the electrical breakdown, the incapacitation current is provided substantially from the charge stored in the charge-storing capacitor.
According to an embodiment of the present invention there is provided an electronic circuit which provides an electrical incapacitation current to a living target. The circuit includes a high voltage power supply, a charge-storing capacitor connected by a high voltage lead to said high voltage power supply. The charge-storing capacitor stores a charge at high voltage as supplied by the high voltage power supply. The electronic circuit further includes: a resonant circuit, a switch closing the current path on the resonant circuit, a step-up transformer including a primary coil and a secondary coil. The primary coil is included in the resonant circuit. An output terminal is serially connected through the secondary coil to the high voltage lead of the charge-storing capacitor. During the incapacitation, the output terminal is operatively attached to at least a part of the living target. When the switch is closed, any gap if present between the output terminal and the living target undergoes electrical breakdown from energy circulating in the resonant circuit. After the electrical breakdown, the incapacitation current is provided substantially from the charge stored in said charge-storing capacitor. The electronic circuit includes a mechanism for actively controlling the incapacitation pulse(s).
The foregoing and/or other aspects will become apparent from the following detailed description when considered in conjunction with the accompanying drawing figures.
The invention is herein described, by way of example only, with reference to the accompanying drawings, wherein:
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. The embodiments are described below to explain the present invention by referring to the figures.
Before explaining embodiments of the invention in detail, it is to be understood that the invention is not limited in its application to the details of design and the arrangement of the components set forth in the following description or illustrated in the drawings. The invention is capable of other embodiments or of being practiced or carried out in various ways. Also, it is to be understood that the phraseology and terminology employed herein is for the purpose of description and should not be regarded as limiting.
By way of introduction, principal intentions of different aspects of the present invention are to (1) reduce the number of parts, complexity and weight of the circuitry required to incapacitate or immobilize the living target (2) provide control of the incapacitation current and/or charge.
Circuits according to some aspects of the present invention are more compact and of lighter weight and are more compatible with the volume and weight and weight requirements of a smaller caliber tetherless projectile. While the discussion herein is directed toward application to tetherless non-lethal weapons, principles according to different features of the present invention may be readily adapted for use with tethered non-lethal weapons.
Referring now to the drawings,
where L1 is the inductance seen at the primary n1 of T.
The oscillation imposes a sinusoidal voltage Vn1 across primary n1 of transformer T, and consequently a high voltage Vn2 across n2 as per the turns ratio of windings, n1:n2 of transformer T. Typically, the value of the components are: L1=50 μH, C1=C2=0.1 μF and turns ratio n1:n2=1:35.
Reference is now also made to
During the operation of circuit 20, assuming an initial voltage across C1, VC1o, the high voltage generated across the secondary of T, Vn2(t) is:
The energy available for breaking down the gaps by the high voltage, Phv, is:
and Pdc the energy stored in the capacitors after the decay of the high voltage oscillation:
Hence, by selecting C1, C2, VC1o, and n2:n1, sufficient voltages and energies can be made available for gaps breakdown and for the incapacitation current.
Initial voltage VC1o on C1, in circuit 20, is determined by the breakdown voltage of SPK. The accuracy of the high voltage Vn2(t) will thus depend on the spread of the breakdown voltages of the spark gap.
Reference is now made to
Reference is now made to
Thus in circuit 50, a precise control is achievable for the total charge per pulse delivered to the target, and an upper limit to the maximum incapacitation current.
Reference is now made to
In circuit 60 the initial voltage across capacitor C1 is controlled by sensing the voltage at the junction between the series-connected sensing resistors R1, R2, connected in parallel to capacitor C1. One input to a comparator 93a is connected to the junction of resistors R1 and R2. The second input of comparator 93a is a voltage reference Vref1. The digital output of comparator 93a is input to logical block 61. Comparators 93b and 93c have respective first inputs connected across sense capacitor Cs and second inputs connected respectively to voltage references Vref2 and Vref3. Outputs COMP2, COMP3 of comparators 93b and 93c, sense respectively maximum current limit and maximum charge limit and are both input to logical block 61. A current limiting resistor Rc is connected in series with load ZL and acts to limit current through load ZL. The current limit is set by transistor Q2 connected (source to drain) in series with current limiting resistor Rc and transistor Q3 connected (source to drain) in parallel with series-connected current limiting resistor Rc and transistor Q2. Transistors Q2 and Q3 preferably act as switches and are controlled by gate voltages set by logical block 61. Logical block 61 controls the operation of circuit 60 by
(i) sending a start/stop signal to the power supply PS which charges C1,
(ii) starting the pulse sequence, by turning Q3 off with transistor Q2 on and thereby transferring the current through current limiting resistor Rc connected in series with the target (load ZL),
(iii) or by turning both Q2 and Q3 off to stop the current flow.
Freewheeling diode D5 connected between transistor Q3 and the high voltage end of capacitor C1 tends to limits any voltage spikes, when transistors Q2 and/or Q3 are turned off.
According to a feature of the present invention, multiple incapacitation pulses are provided at a rate, e.g. 20 pulses per second, to living target ZL. During operation, the voltage required for breakdown of gaps GAP1 and GAP2 is variable because the length and resistance of gaps GAP1 and GAP2 are variable. When a galvanic connection exists to electrodes TM1, TM2 or when gaps GAP1 and GAP2 are relatively small, then the amount of energy required for breakdown of gaps GAP1 and GAP2 is comparatively small. Hence, the energy stored in C1 could be smaller. During the first pulse, relevant parameters may be measured such as, but not limited to, the residual voltage across C1 by sensing at the voltage divider resistors R1, R2 as illustrated in
Reference is now made to
Reference is now made to
where m1 and m2 are the number of turns of the tapped inductor L2, and Vbat is the battery voltage. Consequently, the voltage delivered to capacitor C1 is the sum of the output of the boost converter plus the voltage across capacitor C5 which is even higher than the voltage across C6.
Reference is now made to
Referring now to
While the invention has been described with respect to a select number of embodiments, it is to be appreciated that many variations, modifications and other applications of the invention may be made. Indeed, it is be appreciated that changes may be made in these described embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.
Number | Name | Date | Kind |
---|---|---|---|
3803463 | Cover | Apr 1974 | A |
7110897 | Nadig et al. | Sep 2006 | B2 |
7218501 | Keely | May 2007 | B2 |
7237352 | Keely et al. | Jul 2007 | B2 |
7778005 | Saliga | Aug 2010 | B2 |
20080297970 | Rutz et al. | Dec 2008 | A1 |
20110063770 | Brundula et al. | Mar 2011 | A1 |
Number | Date | Country | |
---|---|---|---|
20100008012 A1 | Jan 2010 | US |