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| United States Patent Application |
20060162605
|
| Kind Code
|
A1
|
|
Genis; Vladimir
; et al.
|
July 27, 2006
|
Piezoelectric stun projectile
Abstract
The present invention provides a non-lethal projectile for delivering an
electric pulse to a target. In one aspect of the invention, the
projectile utilizes a piezoelectric device and an electrical oscillating
circuit in order to generate a pulse. In another aspect of the invention,
the projectile utilizes a piezoelectric device and a mechanical
oscillating circuit in order to generate an electric pulse. Since the
projectile of the present invention contains the structure to generate
the required electric pulse, it can be employed effectively at distances
of up to 150 meters.
| Inventors: |
Genis; Vladimir; (Warminster, PA)
; Soukhomlinoff; Alexandre; (Passaic, NJ)
; Khomchenko; Irina; (Passaic, NJ)
|
| Correspondence Name and Address:
|
KNOBLE YOSHIDA & DUNLEAVY, LLC;SUITE 1350
EIGHT PENN CENTER
1628 JOHN F. KENNEDY BOULEVARD
PHILADELPHIA
PA
19103
US
|
| Serial No.:
|
292022 |
| Series Code:
|
11
|
| Filed:
|
December 1, 2005 |
| U.S. Current Class: |
102/512; 102/502; 361/232; 42/1.08; 89/1.11 |
| U.S. Class at Publication: |
102/512; 089/001.11; 361/232; 042/001.08; 102/502 |
| Intern'l Class: |
F42B 12/54 20060101 F42B012/54 |
Claims
1. A projectile for delivering an electric pulse to a target comprising: a
housing; a piezoelectric element located within said housing; an
electrical oscillating circuit connected to said piezoelectric element;
and structure for applying a force to said piezoelectric element.
2. The projectile of claim 1, wherein said structure for applying a force
to said piezoelectric material comprises a propellant.
3. The projectile of claim 2, wherein said structure for applying a force
to said piezoelectric element comprises at least one plate located
proximate to said piezoelectric element such that activation of said
propellant causes said plate to apply a force to said piezoelectric
element.
4. The projectile of claim 3, further comprising conductive needles
positioned in a distal portion of said housing to create a closed circuit
upon penetration of said projectile into a conductive body.
5. The projectile of claim 4, wherein said propellant is an explosive
material.
6. The projectile of claim 5, further comprising a detonator operatively
associated with said conductive needles to cause detonation of said
explosive material when said closed circuit is created.
7. The projectile of claim 6, further comprising an electronic device
operatively connected to said detonator to activate said detonator when
said closed circuit is created.
8. The projectile of claim 7, wherein said distal portion of said housing
is compressible.
9. The projectile of claim 1, wherein said projectile has a range of
greater than 100 meters.
10. The projectile of claim 1, wherein said projectile upon impact creates
an impulse of energy in the range of 1 to 300 joules.
11. A projectile for delivering an electric pulse to a target comprising:
a housing; a piezoelectric element located within said housing; a stress
spring, wherein compression of said stress spring completes a circuit
with said piezeoelectric element; and structure for applying a force to
said piezoelectric element.
12. The projectile of claim 11, wherein said structure for applying a
force to said piezoelectric material comprises a propellant.
13. The projectile of claim 12, wherein said structure for applying a
force to said piezoelectric element comprises at least one plate located
proximate to said piezoelectric element such that activation of said
propellant causes said plate to apply a force to said piezoelectric
element.
14. The projectile of claim 13, further comprising conductive needles
positioned in a distal portion of said housing to create a closed circuit
upon penetration of said projectile into a conductive body.
15. The projectile of claim 14, wherein said propellant is an explosive
material.
16. The projectile of claim 15, further comprising a detonator operatively
associated with said conductive needles to cause detonation of said
explosive material when said closed circuit is created.
17. The projectile of claim 16, wherein said explosive material is
positioned such tat detonation of said explosive material compresses said
stress spring, which, in turn, compresses said plate to cause said plate
to compress said piezoelectric element.
18. The projectile of claim 17, wherein said distal portion of said
housing is compressible.
19. The projectile of claim 11, wherein said projectile has a range of
greater than 100 meters.
20. The projectile of claim 11, wherein said projectile upon impact
creates an impulse of energy in the range of 1 to 300 joules.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the benefit of U.S. Provisional patent
application no. 60/632,162, filed on Dec. 1, 2004, under 35 U.S.C.
.sctn.119(e).
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates to a non-lethal stun projectile that
relies on an electrical impulse to stun the target. More specifically,
the present invention relates to a self-contained, non-lethal
piezoelectric stun projectile.
[0004] 2. Description of the Prior Art
[0005] Non-lethal neuromuscular disrupter weapons, sometimes referred to
as "stun guns", use a handpiece to deliver a high voltage charge to a
human or animal target. The high voltage causes the target's muscles to
contract uncontrollably, thereby disabling the target without causing
permanent physical damage.
[0006] The most well known type of stun gun is known as the TASER gun.
TASER guns look like pistols but use compressed air to fire two darts
from a handpiece. The darts trail conductive wires back to the handpiece.
When the darts strike their target, a high voltage charge is carried down
the wire. A typical discharge is a pulsed discharge at 0.3 joules per
pulse.
[0007] Taser guns and other guns of that type (herein referred to as
"neuromuscular disrupter guns" or "NDG's") are useful in situations when
a firearm is inappropriate. However, a shortcoming of conventional NDGs
is the need for physical connection between the projectile and the source
of electrical power, i.e., the handpiece. This requirement limits the
range of the NDG to about 20 feet.
[0008] One approach to eliminating the physical connection is to use an
ionized air path to the target to create a conductive air path. For
example, it might be possible to ionize the air between the handpiece and
the target by using high-powered bursts or other air-ionizing techniques.
However, this approach unduly complicates an otherwise simple weapon. An
example of a NDG that uses conductive air paths to deliver a charge to
the target is described in U.S. Pat. No. 5,675,103.
[0009] U.S. Pat. No. 5,698,815 describes a stun bullet that does not
require a wired connection to the handpiece and which is designed to
penetrate the skin of the target and deliver an electrical charge having
a lower voltage and lower energy per pulse than typical stun guns. This
stun bullet is provided with a battery or alternatively it may have a
capacitor to temporarily store a charge delivered to the bullet just
prior to firing. The range of this device is said to be well over 100
yards, but the dual dart electrodes must unwind from the bullet to be
deployed, and subsequently penetrate the skin. Thus, these projectiles
have some disadvantages resulting from the method of deploying the
electrodes.
[0010] Another approach to providing an NDG that does not require an
electrical connection between the handpiece and the projectile is
described in U.S. Pat. No. 5,962,806. In this device, an electrical
charge is generated within the projectile by means of a battery-powered
converter housed within the projectile.
[0011] U.S. Patent Nos. 6,679,180; 6,802,261 and 6,802,262 each describe a
tetherless neuromuscular disrupter gun employing a liquid-based capacitor
projectile. In these patents, the projectile has an outer housing for the
liquid and a capacitor is also located within the housing. The gun
charges the projectile prior to discharge of the projectile from the gun.
Upon impact, the liquid is discharged to deliver a single pulse with
sufficient electrical charge to disrupt neuromuscular activity. These
projectiles have a limited range of about 60 meters.
[0012] There remains a need in the art for a non-lethal approach to
stunning or inhibiting a target that does not require electrical contact
between the target and a hand-held apparatus, such as a stun gun. In
addition what is needed is a single projectile, non-lethal approach to
stunning or inhibiting a target that is not range-limited by wires
coupled to darts, such as with a TASER, and that can be easily reloaded
if an initial firing is unsuccessful.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] FIG. 1 is a diagram of the piezoelectric stun projectile with an
electrical oscillating circuit.
[0014] FIG. 2 is a diagram of the piezoelectric stun projectile with a
mechanical oscillating circuit.
[0015] FIG. 3 is a schematic diagram of the experimental setup used to
demonstrate the effectiveness of the piezoelectric element of the
invention.
[0016] FIG. 4 is a photograph of the experimental device of FIG. 3.
[0017] FIG. 5 is a graph of the voltage oscillogram for Experiment 1.
[0018] FIG. 6 is a graph of the voltage oscillogram for Experiment 2.
SUMMARY OF THE INVENTION
[0019] The present invention provides a non-lethal projectile for
delivering an electric pulse to a target that does not require electrical
contact between the projectile and the hand held apparatus.
[0020] According to a first aspect of the invention, a projectile for
delivering an electric pulse to a target is disclosed. The projectile has
a housing; a piezoelectric element located within the housing; and an
electrical oscillating circuit connected to the piezoelectric element.
[0021] According to a second aspect of the invention, a projectile for
delivering an electric pulse to a target is disclosed. The projectile has
a housing, a piezoelectric element located within said housing; and a
stress spring, wherein compression of the stress spring completes a
circuit that is connected to the piezeoelectric element.
[0022] These and various other advantages and features of novelty that
characterize the invention are pointed out with particularity in the
claims annexed hereto and forming a part hereof. However, for a better
understanding of the invention, its advantages, and the objects obtained
by its use, reference should be made to the drawings which form a further
part hereof, and to the accompanying descriptive matter, in which there
is illustrated and described a preferred embodiment of the invention.
DETAILED DESCRIPTION OF THE INVENTION
[0023] The term "piezoelectric" refers to a class of materials that
generate an electrical charge when subjected to an applied force that
produces stress or otherwise induces strain in the piezoelectric
material. One common type of piezoelectric device is a pressure
transducer.
[0024] Piezoelectric pressure transducers typically are exposed to a fluid
medium which exerts pressure directly or indirectly upon a diaphragm that
is mechanically coupled to the piezoelectric element in a manner that
applies a force thereto. The applied force generates a stress and related
strain in the piezoelectric material. The piezoelectric element responds
to the applied force and strain by generating an electrical charge. The
electrical charge is directed to poles of the piezoelectric element which
have electrical leads connected thereto. Electrical circuitry detects
this generated electric charge and derives an electric signal
representative of the pressure within the fluid medium. One attribute of
piezoelectric devices is that the amount of electrical charge is
typically very low.
[0025] A piezoelectric stun projectile (PESP) is designed to incapacitate
a target by generating a powerful electrical output pulse. The principle
of operating a PESP is based on the phenomenon of the direct
piezoelectric effect. The source of electrical energy is a piezoelectric
element, which generates a short electrical pulse upon application of
mechanical stress to the piezoelectric element. In the context of the
present invention, the short electrical pulse of the piezoelectric
element may be applied to an under-damped oscillating circuit, which
generates an attenuated periodic signal for about 0.5-1 second. During
this time interval, the amplitude of the generated voltage can reach tens
of kilovolts.
[0026] In the device of the present invention, the source of the
mechanical stress may be the energy of a direct internal controlled
explosion in the projectile. The PESP of the present invention is thus
able to generate a powerful impulse of electrical energy in the range of
1 to 300 joules, and has a distance-range of up to about 150 meters. To
deliver the PESP of the present invention, to the target, conventional
sources of mechanical energy could be used, such as pneumatic devices or
other devices for delivery of projectiles.
[0027] A diagram of one embodiment of a PESP in accordance with the
present invention is presented in FIG. 1. FIG. 1 depicts a PESP 30
provided with an electrical oscillating circuit. The housing 1 holds the
components of the PESP 30 together. The housing 1 may be a single molded
piece of high impact plastic or it may be any suitable casing material
including a standard shell casing for a shotgun or M203 grenade. The
housing 1 has a nose tip 2 made of a material that shields the electrodes
10, 13, in this case conductive needles 10, 13, prior to discharge of the
PESP 30. Nose tip 2 may be an energy-absorbing foam rubber, but any
material may be used to fabricate nose tip 2, so long as the material can
be compressed upon impact to allow the conductive needles 10, 13 to
pierce through nose tip 2, once nose tip 2 of projectile 30 strikes a
target.
[0028] A depression or hole 3 may be provided in the housing 1 for the
purpose of assisting in deployment of the projectile 30 by a suitable
deployment mechanism. Housing 1 also contains a piezoelectric element 4,
located between a pair of metallic plates 5, 6. Explosive material 7, 8
is positioned adjacent to metallic plates 5, 6, such that detonation of
explosive material 7, 8 will apply a force to metallic plates 5, 6
causing plates 5, 6 to compress piezoelectric element 4. Explosive
material 7, 8 may be detonated upon impact of the projectile 30 with a
target by electro-detonators 14.
[0029] When PESP 30 hits a target, the nose tip 2 is compressed and
conductive needles, 10, 13, penetrate into the target thereby creating an
electrical connection between conductive needles 10, 13. This electrical
connection between conductive needles 10, 13, activates electronic device
11 to close switch S, connecting electro-detonators 14 to energy source
E. This results in the substantially simultaneous explosion of explosive
materials 7, 8. Explosion of explosive materials 7, 8 breaks wires 9, 12
along the lines A-A and B-B, respectively, thereby breaking the
connection between conductive needles 10, 13 and electronic device 11. At
the same time, the metal plates 5, 6 apply a force to piezoelectric
element 4 to cause piezoelectric element 4 to generate an electric pulse.
Also, piezoelectric element 4 is connected in parallel to the electrical
oscillating circuit L, C and conductive needles 10, 13, via metal plates
5, 6, thereby transmitting the high voltage electric pulse from the
piezoelectric element 4 to the target via electrical oscillating circuit
L, C and conductive needles 10, 13.
[0030] Turning now to FIG. 2, an alternative embodiment of the PESP of the
present invention is shown. FIG. 2 shows a PESP 100 wherein a mechanical
spring-mass system is used to create a harmonic mechanical stress on
piezoelectric element 104, which will generate the high voltage
electrical signal. FIG. 2 shows projectile body or housing 101, nose tip
102, hole or recess 103 that may be provided in the housing 101 for the
purpose of assisting in deployment of the projectile 100 by a suitable
deployment mechanism, piezoelectric element 104, metal plates 105, 106,
propellant 107, flat springs 108, 115, electrical wires 109, 112,
conductive needles or electrodes 110, 113, electronic device 111,
electrodetonator 114, and metal plates 116, 117.
[0031] When PESP 100 hits a target, nose tip 102 is compressed and
conductive needles, 110, 113, penetrate into the target thereby creating
an electrical connection between conductive needles 110, 113. The impact
with the target activates electronic device 111 to close switch S.sub.1,
connecting electro-detonator 114 to energy source El. This results in the
explosion of propellant 107. As a result of the explosion, propellant
107, applies severe mechanical stress to springs 108, 115 causing springs
108, 115 to compress. The compression of stress springs 108, 115 results
in the contact of metal plates 116, 117 with metal plates 105 and 106
thereby completing a circuit to allow an electric pulse generated by the
force applied to piezoelectric element 104 to be transferred to the
target via conductive needles 110, 113.
[0032] FIG. 3 is a schematic diagram of an experiment conducted to
demonstrate the usefulness of the present invention. The diagram shows
piezoelectric element 60 with a height h and a diameter d, a holder 62,
metal plates 64, 66 and an attached oscilloscope 68. Resisters R1 and R2
are shown as well as H, which represents the altitude from which a 5.313
kg object 70 was dropped, generating force F onto plate 64. In this
experimental setup, a 5.313 kg object 70, was dropped on two circular
piezoelectric disks the position of which is represented by piezoelectric
element 60, mounted in a holder 62 between two metal plates 64 and 66.
Each time the object 70 was dropped, the voltage was recorded by the
oscilloscope using a voltage divider V and an attenuator V1 (10:1). The
first piezoelectric element had a diameter (d) of 9.56 mm and a height
(h) of 1 mm. The second one had a diameter (d) of 6.96 mm and a height
(h) of 8.86 mm. FIG. 4 is a photograph showing the experimental apparatus
of FIG. 3: holder 62 and the two metal plates 64, 66.
[0033] In the first experiment, the object was dropped from the altitude H
of 1.08 m and the voltage divider V was constructed of two resistors,
R.sub.1=100 k.OMEGA. and R.sub.2=3.3 k.OMEGA.. In the second experiment,
the object was dropped from the altitude H of 1.75 m and the voltage
divider V was constructed of two resistors, R.sub.1=100 k.OMEGA. and
R.sub.2=1.5 k.OMEGA.. Recorded voltages for both experiments are
presented in FIG. 5 (experiment 1) and FIG. 6 (experiment 2),
respectively, as oscillograms.
[0034] As can be seen from FIGS. 5 and 6, and accounting for the values of
the resistors R.sub.1 and R.sub.2, as well as the attenuation coefficient
of the attenuator, the voltage amplitudes in both experiments are 16.7 kV
and 44.7 kV, respectively. Thus, this demonstrates that piezoelectric
elements can effectively develop sufficient charge to disable a target by
electric shock without the need for batteries or trailing wire.
* * * * *
