Nonlethal wireless knocking-out bullet for short-time paralysing by neuromuscular distress

FIELD: weapons and ammunition.

SUBSTANCE: proposed bullet comprises first and second electrodes. Second electrode may unfold at second distance from first electrode after collision with target and connect to target at 10 cm from said first electrode. Proposed bullet comprises shock cushioning subsystem to protect target against traumatising, mechanism to retain bullet on target and power supply subsystem that may feed electric current after bullet is attached thereto by said mechanism. Bullet comprises galvanic element made using thin-film technology. Said galvanic element comprises separating substrate, two electrodes and electrolyte. Said electrolyte is absorbed by separating substrate to facilitate ion motion between two electrodes and to produce potential difference there between. Bullet comprises transformer. Said transformer comprises multiple coils and two blocks. Each said block incorporates package made form spiral coil of multiple spiral coils. Method of target knocking out by said nonlethal bullet consists in unfolding second electrode at second distance from first electrode after collision with target and connecting first electrode to target at 10 cm from said first electrode and passing electric current from second electrode to first electrode.

EFFECT: increased bullet range, possibility to be used with small arms, ease of use and storage, higher safety.

47 cl, 16 dwg

This invention is a partial continuation of provisional patent application U.S. No. 60698009 filed July 12, 2005, and provisional patent application U.S. No. 60698010 filed July 12, 2005

The technical field of invention and background of its creation

The present invention relates to non-lethal wireless deafening pool, and more specifically to the bullet being shot off from conventional weapons; when confronted with a man-the purpose of this bullet stun and incapacitate the purpose of using pulsed electric charge. Electric bullet is defined as non-lethal munition designed to bring a person down, to deprive him of the ability to move within a short period of time, to prevent him to commit the crime and to enable authorized persons to detain him.

Electric bullet works by sending electric pulses at the target, paralyzing her for a short time without any need for medical assistance after exposure. During the collision the bullet itself is attached to the target and provides the same effect as a standard manual Taser. The electric pulses generated by a bullet, much weaker than the critical level of cardiac contractions, and therefore these electrical pulses are non-lethal. These electrical impulses cause the neuromuscular disorder which incapacitate a living object.

The present invention also includes a new transformer, manufactured using the technology of thin films, and the battery is made using the technology of thin films. The transformer and the battery is smaller and lighter than conventional transformers and batteries with the same output power. Small batteries and transformers with high power necessary to create an electric shock, which can stun the person using the device that has the size of a regular bullet.

The increase in attacks on unarmed civilian targets around the world has put the government and law enforcement agencies in a difficult position. You need to quickly and effectively stop the terrorists, to avoid injury to civilians, but terrorists are difficult to distinguish from civilians and terrorists strike in places not suitable for the location of large forces special forces. Therefore, to quickly stop the terrorists before they carry out destructive actions, some police forces use units of snipers. Obviously, the use of such units is causing controversy in the community, as this can lead to losses among the civilian population. On the other hand, indecision in such cases, it may lead to means is determined as being the losses among the civilian population, as for death delaying a police officer. Often police must detain the fleeing suspicious person. It is obvious that a deadly weapon in this case cannot be applied, it allows you to escape a dangerous offender, which is also undesirable.

Therefore, law enforcement agencies need non-lethal weapons that can stop the terrorist, without the risk of lethal injury of civilians. One type of such weapons, currently popular, is industrially produced a pistol under the trademark of TASER weapon was described in U.S. patent No. 3,803,463, published on 9 April 1974 and is now null and void, and in U.S. patent No. 4,253,132, published on 24 February 1981 and is now null and void, the improvement of these weapons have been described in U.S. patent No. 5,654,867, published August 9, 1977, and U.S. patent No. 6,636,412, published on 21 October 2003). Gun TASER fires two Darts with sharp electrodes, wires connected to the housing of the gun. Through these wires is fed pulse voltage between the two wires. When both Darts hit the target, pointed electrodes penetrate the skin or clothing. The electrical circuit is closed, and through the goal between the two electrodes current flows, bringing the goal of the system. The obvious disadvantages of the TASER gun are: 1) for the with action is limited by the length of the wires; 2) both dart must hit the target, otherwise the weapon will not work; 3) the target or weapon can cause tension wires, pulling out the electrodes from the target, while the stun wears off; 4) the weapon is hard to recharge, and it may not be quickly re-used if one of the dart misses the goal or if there is a need in the stunning second goal; 5) the TASER gun is a specialist weapon, unwieldy for regular police officers, who are also required to have normal weapons.

Therefore, the bullet that without hesitation can be used in situations where it is difficult to identify the target or isolate it, this is just what you need. Excellent if the bullet would bring the target down at different range, easily charged, vystrelivaet and charged in conventional firearms, such as automatic pistol 45 caliber M16 assault rifle, revolver, standard police pistol or rifle) and did not cause serious injury. In addition, it is desirable that objective was derived from the action within a few minutes (long enough to secure the space and delay target).

This bullet should have the following properties:

a) no need for medical assistance after impacts the via;

b) the absence of wires (this means that you do not need to attach wires to a stationary power source);

c) a self-contained power source;

d) shooting from the standard weapons without any changes in the weapon;

e) ballistic characteristics similar to the characteristics of conventional ammunition;

f) store as conventional ammunition, and safety in operation;

g) storing for a long time (months or years);

h) the ability to adapt to different calibers.

Summary of the present invention

The present invention is a wireless non-lethal stunning bullet. More precisely, the present invention is a bullet being shot off from conventional weapons; when confronted with a person bullet stun and incapacitate the target, applying a pulsed electric charge. Electric bullet is defined as non-lethal ammunition aimed at the elimination of human failure, depriving him of the ability to move within a short period of time, which prevents the Commission of the crime and allows authorized persons to arrest him.

Electric bullet works by sending electric pulses at the target, paralyzing her for a short time is without necessary medical care after exposure. During the collision the bullet itself is attached to the target and provides the same effect as a standard manual Taser. The electric pulses generated by a bullet, much weaker than the critical level of cardiac contractions, and therefore these electrical pulses are non-lethal. These electrical impulses cause neuromuscular disorder that destroys a living object.

The present invention also includes a new transformer, manufactured using the technology of thin films, and the battery is made using the technology of thin films. The transformer and the battery is smaller and lighter than conventional transformers and batteries with the same output power. Small batteries and transformers with high power necessary to create an electric shock, which can stun the person using the device that has the size of a regular bullet.

According to the present invention offers wireless bullet to stun targets, including subsystem soften the blow to protect the goal from injury during impact caused by the collision of the bullet with the target, the attachment mechanism for attaching a wireless bullet to the target when you hit it into the goal, and the subsystem power supply, which delivers energy to the target and through this to stun the target after the wireless bullet CIDP is aleesa to the goal through the mechanism of attachment.

According to the present invention offers a galvanic element manufactured using the technology of thin films to create an electrical potential. Galvanic element includes separating a substrate, two electrodes are deposited on separating the substrate and the electrolyte. When the electrolyte is absorbed separating the substrate, the ions pass through the electrolyte between the two electrodes. This creates an electric potential between the two electrodes.

According to the present invention is provided with a transformer, produced using a technology of thin films, including many of spiral coils, housed in two blocks. Each coil unit is placed in service at least one coil.

In accordance with other features of the described preferred embodiments, described below, wireless bullet also includes a one-piece rim, contributing to the shot wireless bullet when firing a wireless bullet from a conventional firearm.

In accordance with other features of the described preferred embodiments the wireless bullet of the present invention made with the possibility of shooting from conventional firearms. In particular, the size, shape and weight of the bullet is similar to the size of the ru, the form and weight of a normal bullet, and that bullet is placed in the sleeve for shooting from a pistol.

In accordance with other features of the described preferred embodiments the wireless bullet includes a stabilizer that creates aerodynamic drag, slowing the bullet and preventing injury when hitting the target. Stabilizer, in addition, supports the aerodynamic resistance, so that the ballistic trajectory of the bullet remains, as far as possible, a flat even at low speed.

In accordance with other features of the described preferred embodiments the mechanism for attaching wireless bullet remains protected from accidental deployment while the mechanism is activated. Activating bullet happens when shot.

In accordance with other features of the described preferred embodiments the mechanism for attaching the bullet is driven and rotated near the destination.

In accordance with other features of the described preferred embodiments the mechanism for attaching wireless bullet is actuated when the wireless collision of the bullet with the target.

In accordance with other features of the described preferred embodiments during storage bullet p is Sistema supply the bullets energy is non-activated state with the purpose of conservation of charge. Subsystem power supply is actuated when the wireless collision of the bullet with the target.

In accordance with other features of the described preferred embodiments the subsystem supply of bullet energy comprises a battery, and this battery is stored in a non-activated state with the purpose of conservation of charge. The battery is activated when the wireless collision of the bullet with the target.

In accordance with other features of the described preferred embodiments the subsystem mitigate the impact of the bullet includes a deformable cushion. A deformable cushion is located in the impact zone wireless bullet. In the collision with the purpose of the cushion is deformed and "stretches" the impact energy in time and space, preventing injuries when hitting the target.

In accordance with other features of the described preferred embodiments the subsystem supply of bullet energy includes galvanic element manufactured using the technology of thin films.

In accordance with other features of the described preferred embodiments the subsystem supply of bullet energy includes the transformer, manufactured using the technology of thin films.

In accordance with other features of anywaymuch preferred embodiments subsystem mitigate the impact of the bullet includes a movable block. The movable block is not attached firmly to the impact zone of the bullet and can move relative to it.

In accordance with other features of the described preferred embodiments the movable block includes at least one element selected from the group consisting of subsystems of energy supply, mechanism of attachment, grip, battery, transformer and capacitor.

In accordance with other features of the described preferred embodiments the movement of the movable unit relative to the strike zone actuates one of the components of bullets.

In accordance with other features of the described preferred embodiments the bullet includes a movable block and, in addition, the node energy absorption. Site energy absorption reduces the slow rolling of the collecting site and reduces the force of impact of the bullet when you hit the target.

In accordance with other features of the described preferred embodiments the bullet includes a movable block and the node energy absorption. Site energy absorption includes a friction connector, spring, hydraulic shock absorber, gear guide, and a flexible retainer.

In accordance with other features of the described preferred embodiments Podesta is and mitigation of impact includes additional part of the bullet. The additional part of the bullet collides with the purpose separately from the impact zone of the main part of the bullet. Thus, the weight associated with the impact area of the main part of the bullet is reduced (since the bullet does not include components that are installed on the extra bullets; therefore, their mass does not contribute to the force of impact of the main part of the bullet). In this regard, the kinetic energy associated with the shock zone is reduced, which reduces the injury when hitting the target.

In accordance with other features of the described preferred embodiments the bullet includes an additional part of the bullet. The additional part of the bullet connected with the main part of the bullet and the impact area of the main part of the bullet through the wire. When the collision of the main part of the bullet with the target wire wraps itself around its target, fixing the drop zone on goal in one location, and the additional part of the bullet, in the second location.

In accordance with other features of the described preferred embodiments the subsystem supply of bullet energy generates an electrical voltage. Voltage is used as the potential difference between the impact area of the main part of the bullet and the extra bullets so that when the shock zone is located near the destination in the same positioning and, as an additional part of the bullet is near the destination in a different location, electrical energy passes through the objective in the form of electric current from the first location to the second location.

In accordance with other features of the described preferred embodiments the mechanism for incorporation of bullets, in addition, serves as a channel of energy transfer from the engine supply energy to the target.

In accordance with other features of the described preferred embodiments the mechanism for attaching an electrode and, in addition, serves as a channel of energy transfer from the engine supply energy to the target.

In accordance with other features of the described preferred embodiments the mechanism of attaching the bullet includes a hook with a beard.

In accordance with other features of the described preferred embodiments the mechanism of attaching the bullet includes a first hook with a beard and a second hook with a beard. The first hook with the barb engages for the purpose of one angle, and the second mentioned hook with the barb engages behind the goal at the opposite angle. Thus, the two hook with a beard capture and ensnare the target.

In accordance with other features of the described preferred Varian is s implementation mechanism for attaching includes a grip.

In accordance with other features of the described preferred embodiments the mechanism of attaching includes the capture, and the capture is emitted from a side of the wireless bullet.

In accordance with other features of the described preferred embodiments the mechanism of attaching includes the capture and the movable block. The movable unit can move relative to the shock zone bullets. The movement of the movable unit relative to the strike zone is to implement capture the target.

In accordance with other features of the described preferred embodiments the separating substrate galvanic element has a thickness less than 50 microns.

In accordance with other features of the described preferred embodiments the electrodes of a galvanic cell have a thickness less than 100 μm each.

In accordance with other features of the described preferred embodiments the separating substrate galvanic cells in the dry state is an insulator.

In accordance with other features of the described preferred embodiments the galvanic element is activated during use, when applying the electrolyte separating the substrate.

In accordance with other what osobennosti the described preferred embodiments the transformer, manufactured using the technology of thin films includes a first spiral coil, which is a right-hand coil and the second spiral coil, which is a left-hand coil. Right-hand and left-hand coils are connected in alternating sequence, so that the current flows around the Central axis of the transformer in the corresponding direction, thereby creating a coherent magnetic field.

In accordance with other features of the described preferred embodiments each of the spiral coil of the transformer, manufactured using the technology of thin films, includes an insulating substrate and a conductor. The conductor is placed on the insulating substrate in the form of a spiral.

In accordance with other features of the described preferred embodiments, the insulating substrate of the transformer, manufactured using the technology of thin films has a thickness less than 30 microns.

In accordance with other features of the described preferred embodiments the wire of the transformer, manufactured using the technology of thin films has a thickness less than 50 microns.

In accordance with other features of the described preferred embodiments the transformer, manufactured blenny using the technology of thin films, made with the possibility of optimal transformation voltage during a given time interval.

Brief description of figures

The present invention is described only as an example with reference to the accompanying figures, where:

Figure 1 is an external view of the first variant implementation blinding bullets having electrodes in the form of mechanical capture, in an inactive state (for example, before the shot);

Figure 2 represents a first variant implementation blinding bullets in an inactive state in the incision;

Figure 3 presents the mechanical subsystem of the first variant implementation blinding bullets in an inactive state (e.g., during storage and loading of the weapon) closeup;

Figure 4 presents the mechanical subsystem of the first variant implementation blinding bullets in the active state (for example, during flight) closeup;

Figure 5 presents the mechanical subsystem of the first variant implementation blinding bullets, interacting with a goal in the docked state (after the collision) closeup;

6 represents a second variant implementation blinding bullets in an inactive state in the context; the second implementation includes electrodes in the form of mechanical grippers and movable block;

7 represents a second variant of the westline deafening bullet fixed in place in the incision;

Fig is an external view of the third variant implementation blinding bullets having electrodes in the form of a flexible gripper;

Figure 9 is an external view of a fourth variant of the implementation blinding bullets, consisting of two complementary parts of the bullet, before the shot;

Figure 10 is an external view of a fourth variant of the implementation of deafening bullet during flight;

11 is an external view of a fourth variant of the implementation blinding bullets, geared for the purpose;

Fig is the spiral pattern of the miniature transformer, manufactured using thin films technologies;

Fig represents an image of the package spirals forming unit miniature transformer, manufactured using thin films technologies;

Figa represents the image of the miniature transformer, manufactured using the technology of thin films in accordance with the present invention;

Fig.14b is a schematic diagram of a transformer manufactured using the technology of thin films, Figa;

Fig represents an image of a miniature galvanic cell made using the technology of thin films, in accordance with the present invention;

Fig is a miniature image Akku is ulator, manufactured using the technology of thin films, in accordance with the present invention.

Description of the preferred embodiments

The principle of non-lethal wireless blinding bullets in accordance with the present invention may be better understood with reference to the figures and accompanying description.

Figure 1 is an external view of the first variant implementation of the 10 deafening bullet in accordance with the present invention. Figure 1, figure 2 and Figure 3 present an implementation option 10 in an inactive state. Inactive bullet can be safely handled, it will not explode even when moderate pressure, for example at the drop of a bullet from a height of 1.5 m For shooting oglasa bullet charged in an inactive state in conventional firearms. Bullet and, in particular, the mechanism of attachment remain in an inactive state prior to release (for example, when fired from a gun), during which the acceleration when the shot calls activating bullet and mechanism of attachment (see Fig. 3, 4 and 5 with an accompanying description). An implementation option 10 consists of two main blocks: the mechanical block (see Figure 1, figure 2, figure 3, Figure 4 and Figure 5) and electric unit (see Fig.2, Fig.6, Fig.7 and Fig). Mechanical block is used as a mechanism for attaching fixed what I bullet on the target. Electric block is used as a subsystem of the supply of energy to expose the purpose of pulsed electric shock.

Figure 1 shows the body 12 bullets. The body 12 of the bullet is hollow and accommodates the active elements of a bullet, as it is shown in subsequent figures. Four slots 14 on the side of the housing 12 bullets serve as passages through which the collision ejected and deployed grips 20 (see Figure 3, Figure 4 and Figure 5). The gripper mechanism to attach, to fasten the bullet on the target 40 (see Figure 5).

Bullet 10 may be released at a distance of 10-30 m without defeat death. Electric bullet is quite heavy. Therefore, in order to avoid serious injury at such short distances, the impact is minimized by using subsystem soften the blow. Subsystem soften the blow operates so that: 1) increasing the area of impact, disperse the impact energy over a larger area and 2) to soften the blow to distribute the impact energy over a relatively long period of time. The increase in the area of impact and the distribution of the impact energy in time is achieved by means of a deformable cushion 16, located in the impact area of the bullet. In the embodiment 10 of the preferred ballistic characteristic is flat, to the extent possible, the trajectory to achieve easy aiming and more Technosteel strike perpendicular to the target, and impact area is the front part of the bullet (labeled deformable cushion 16).

A deformable cushion 16 deforms and collapses upon impact, thus residuosity the impact energy over a larger area and distribute the impact energy over a longer time required to compress a deformable cushion 16)than the area of impact and the time for a solid bullet. The distribution of the impact energy reduces the possibility of injury. To further reduce the probability of severe injury, shock zone in the embodiment 10 is free from solid elements to reduce the penetrating ability or "hard" stroke, which can cause injury fatal. This design takes into account that the maximum allowable ratio of energy/area, to avoid requiring long-term treatment of injuries due to impact is about 30 j/cm².

Figure 1 also shows a one-piece rim 18, which seals and maintains the pressure in the cartridge case. One-piece rim 18 includes an annular groove 19, which allows the rim to expand under the action of pressure during the shot and improves the seal between the bullet and the cartridge case. This effect occurs throughout the movement of the bullet in the cartridge case. The usual dimensions of the seal are: lug 0.2 mm, thickness 1 mm and the depth Kanak is or unclamping of material around the circumference of 4 mm.

Figure 2 is an implementation option 10 deafening bullet in accordance with the present invention in the context. It shows the body 12 bullets, the slits 14, the deformable cushion 16, the hooks 20, a battery 52, a high voltage transformer 54, the low-voltage transformer 56 and the capacitor 58.

Figure 3 represents a section of the upper half of the front of the case for 10 deafening bullet in accordance with the present invention in an inactive (safe) state. An implementation option 10 symmetric, so the bottom half is a mirror image of the lower half. Consequently, the lower part is not shown. Mechanical block bullets may include the grip 20, the stud 22, the guide pin 24, the spring 26 release safety pin and a trigger element 28. The starting element 28 has a groove 38. Also shows the latch 30 of the grip, the weight 32 of the pendulum and the axis of the hinge 34. The grip 20 is constantly kept retainer 30 capture and cannot be deployed. In this way the latch 30 capture constantly kept the axis of the hinge 34 and sinker 32 of the pendulum. In the inactive state, the sinker 32 of the pendulum cannot swing forward, as in the direction of its movement is blocked safety pin 24. Figure 3 you can also see the battery 52, which will be described in more detail in the description, is knitted with Fig and Fig.

Figure 4 is an implementation option 10 bullets in the activated state during flight. The grip 20 is still held by the latch 30 engages. However, figure 4 an implementation option 10 bullets is in the activated state. In particular, when the shot (shooting bullet) inertial forces cause the slide pad element 28 in the opposite direction, with the groove 38 of the starting element 28 is in line with the safety pin 24. Then the spring 26 release safety pin pushes the guide pin 24 in the slot 38. Thus, the guide pin 24 is no longer blocks movement of the sinker 32 of the pendulum. Accordingly, the latch 30 of the grip and the weight 32 of the pendulum can be freely rotated around the axis of the hinge 34.

Figure 5 is an implementation option 10 blinding bullets, when the mechanism of insertion into the docking state. When an implementation option 10 is activated bullets (as shown in Figure 4) collides with the purpose of 40 (as shown in Figure 5), inertial forces are pushing the weights 32 of the pendulum forward, which causes rotation of the weights 32 of the pendulum and retainers 30 grips around the axis of the hinge 34, revealing and putting into action grips 20a-d. Grips 20a-d after the liberation thrown on the sides of the bullet through the slot 14, so that hooking objective 40, attached to not the bullet.

The mechanism of attachment of a bullet in the embodiment 10 includes four capture 20A, 20b, 20C, 20d with the corresponding studs 22A, 22b, 22s and 22d each. Thanks semicircular trajectory grips 20a-d each gripper touches the goal of 40 different angles. The studs 22a-d thin and sharp. Therefore, the studs 22a-d and, therefore, the grippers 20a-d penetrate clothing, skin and other materials and attached to the body 40 goals to tie the objective 40, preventing target 40 to be released from a bullet in the embodiment 10. In particular, the grip 22A engages behind the goal at the first corner and capture 22p engaged for the purpose of 40 at the opposite angle. In this way the hooks 22b and 22d is attached to a target 40 in opposite directions. The prior art non-lethal weapons, it is clear that as the studs 22A 22s and engage the target 40 from opposite sides and in opposite directions, they shrink, entangle and capture the objective 40, attaching the bullet to the target 40 and extremely making it difficult target 40 to be released from a bullet in the embodiment 10. The same effect is achieved by the opposite studs 22b and 22d. Since the grippers 20a-d closer to the goal in a semicircular arc on the side of the bullet, the grippers 20a-d does not intersect with the front impact area of the deformable cushion 16, which is deformed during impact.

The kick triggers the action system is tion subsystem blinding bullets. The electrical subsystem is not shown in the embodiment 10, as illustrated in embodiment 100 figure 6. The electrical subsystem is a subsystem of the power supplies that allows you to expose the purpose of electric shock. The subsystem of energy supply options implementation 100 includes a battery 52 to supply electricity, a circuit breaker (not shown) for converting direct current from the battery 52 into alternating current. Subsystem power supply also includes a spring-loaded electrodes 108 for supplying alternating electric current at a low voltage transformer 56. Subsystem power supply also includes a high voltage transformer 54 for converting pulses of low voltage from the low voltage transformer 56 in pulses of high voltage current. In the process of converting alternating current of low voltage is rectified and stored in the capacitor 58. The capacitor 58 is discharged through the high voltage transformer 54, in which the low pulse voltage is converted into a pulse of high voltage. Finally, subsystem power supplies are connected to the hooks 20, which serve as electrodes, transferring the charge from the high voltage transformer 54 to the target 40.

In particular, the bullet in the embodiment, 100 (6) includes the impact rigidly fixed block 102, rigidly coupled to the housing 12 bullets. Fixed block 102 includes mechanical elements (not shown) and a battery 52. Movable block 104 slides along the guide rail 106. Thus, the movable block 104 can move relative to the housing 12 bullets and relatively shock zone bullet (deformable cushion 16). The movable block 104 includes a high voltage transformer 54, the low-voltage transformer 56, a capacitor 58 and a spring-loaded electrical contacts 108. The movable block 104 also includes a flexible latch 110. As the movable block 104 slides along the guide 106, a flexible latch 110 slides along the toothed rail 112, moving the teeth and settle, thus, energy.

When the bullet in the embodiment 100 collides with the target (not shown), a deformable cushion 16 is quickly crushed, and the body 12 of the bullet and the fixed block 102 sharply decelerated. On the other hand, the movable block 104 continues to move forward, sliding along the guide 106 toward the fixed block 102. The movable block 104 is inhibited due to the energy absorbed by contact of the flexible retainer 110 with the toothed rail 112. Therefore, the rate of deceleration of the rolling unit 104 is less than the rate of deceleration of the housing 12 bullets and rigidly fixed block 102. As follows from the prior art in which troist absorption of kinetic energy, the impact force is proportional to the speed, braking and weight, which is retarded. Therefore, due to the placement of the rolling block 104 on the guide, absorbing the energy, the force of impact of a bullet in the embodiment 100 on goal is significantly reduced. This reduces the likelihood that the target will suffer from shock. Thus, the subsystem mitigate the impact of option implementation 100 includes a movable block 104, spring-loaded electrical contacts 108, the flexible latch 110 and gear guide 112 together with a deformable cushion 16.

When the collision of a bullet in the embodiment 100 with the purpose of the inertial force causes the sliding of the rolling unit 104 forward along the guide 106. Shortly after the collision of the bullet in the embodiment 100, with the aim movable block 104 slides to the end of the guide 106. Then the movable block 104 collides with fixed unit 102. When the collision of the movable block 104 pushes the launch button 602 (see Fig), operate the batteries 52. Accordingly, in the absence of extreme inertial forces (inertial forces when shot and the bullet hit) movable block 104 is held in conjunction with fixed unit 102 via the coupling strength between the flexible latch 110 and gear guide 112, as shown in Fig.7. While the movable block 104 and the fixed BA are held together, spring electrical contacts 108 connect the low-voltage transformer 56 through a circuit breaker with terminals a and 604b of the battery 52 (see Fig) (each spring electrical contact 108 is connected to each terminal 604 of the battery), summing a constant current to the circuit breaker and AC electric current to low voltage transformer 56. Low voltage transformer 56 is electrically connected to the capacitor 58 and, in turn, is connected to the high voltage transformer 54.

Low voltage transformer 56 is fully charges the capacitor 58. The capacitor 58 is discharged through the high voltage transformer 54 to grips 20, passing a pulse of electric current of high voltage through a 40 goal, bringing it down. Thus, the electrical system remains inactivated before the collision with the target, at which point the movement of the rolling unit 104 relative to the impact zone of the bullet causes activation of the battery 52 and connects them with a low voltage transformer 56, the high voltage transformer 54 and a capacitor 58. The prior art electrical devices it is clear that before the collision with the target (for example, during storage of the bullet during its flight) batteries 52 active and are not connected with a low voltage transformer 56, a high voltage transformer capacitor 54 or 58. Therefore, in EMEA storage battery 52 is stored maximum charge for maximum stun actions on the target during the shot.

Braking rolling block 104 is calculated at a time so that the collision between the movable block 104 and the fixed unit 102 occurs after the launch, deployment, and straightening of the grippers 20 (see Fig.7). At the moment of collision between the movable block 104 and the fixed unit 102 kinetic energy from the moving unit 104 is transmitted through the fixed block 102 deployed grips 20. This transferred kinetic energy promotes the hooks 20 on the target, making it difficult to release target from a bullet in the embodiment 100.

Oglasa bullet in the embodiment 100 has the following electrical parameters:

- output voltage 50 to 100 kilovolts (kV);

- output current from 1-10 microamps (μa);

a pulse width of 10 microseconds (μs) to 10 milliseconds (MS);

- the repetition frequency of 10-40 Hz;

- working time from 1 minute to 5 minutes

Figure 7 also shows the stabilizer 114. The stabilizer 114 is installed on the hinge 116. The hinge 116 gives the possibility to fold the stabilizer 114 in the housing 12 bullets during storage and loading of the weapon. The stabilizer 114 is held in the folded (closed) position sleeve bullets. When the bullet is fired, it is released from the liner, and the stabilizer 114 is opened. In flight stabilizer 114 serves two purposes. First, the stabilizer 114 creates AE is DINAMIChESKOE resistance and slows down the bullet, reducing the likelihood of injury goals. In addition, thanks to its aerodynamic characteristics of the stabilizer 114 increases the stability of the bullet. Thus, even at low speeds ballistic characteristics remain high, and the trajectory remains flat as possible.

Fig illustrates an alternate implementation 200 blinding bullets in accordance with the present invention. Instead grabs, charged via a spring mechanism (as in the variants of implementation of 10 and 100), the attachment mechanism 200 deafening bullet includes a flexible grippers 220, made of flexible wire. When the shock zone 210 blinding bullets in the embodiment 200 encounters a target (not shown), flexible grips 220 due to inertia forces bent towards the target, in addition, these forces are driving studs 22 on the ends of flexible grippers 220 in goal. With the exception of the mechanics of the grippers 220 oglasa bullet in the embodiment 200 operates in the same manner as stun bullets in the variants of implementation of 10 and 100. When flexible grippers 220 are in contact with the target, they act as electrodes, incapacitating goal by passing through it a current of high voltage. Because flexible grippers 220 does not include moving parts, it is cheaper to produce with what avanyu with grippers 20 of embodiments 10 and 100. Oglasa bullet in the embodiment 200 also includes spikes 222 in the impact zone 210 bullets. Spikes 222 short, they do not penetrate into man through the clothing, but are designed for fixing on clothes, holding the bullet on the target. In the pool according to the variant of implementation 200 electric voltage is applied to the opposite flexible grippers 220 (thus, some flexible grippers 220 have a positive electric potential, and other flexible grippers 220 - negative electrical potential). Due to the potential difference across goal between positively and negatively charged flexible grippers passes electrical energy (current), as in the embodiment 10, shown in figure 5. Alternatively, a positive potential may be applied to the studs 222 and the negative potential on the hooks 220. Thus, the current passes through the objective between the grips 220 and pins 222.

Figure 9 shows another variant implementation 300 blinding bullets. Figure 9 shows an implementation option 300 blinding bullets before shot. It shows the extra bullets a and 302b. High voltage wire 304 connects the bullet a and 302b. Before shot bullets high voltage wire 304 leaves and placed in a one-piece capsule along additional parts bullet a and 302b, as shown in Fig.9.

Figure 11 shows the consolidation of blinding bullets in the embodiment 300 in goal 40. The mechanism of attachment of a bullet in the embodiment 300 includes a high-voltage wire 304, which is wrapped around the target 40, and spikes 222, which stuck in goal 40. When the shock zone extra bullets 302 is faced with the objective 40, spikes 222 on the extra bullets a stout in goal 40. Due to the elasticity of the high-voltage wires 304 it is wrapped around the target 40. In addition, since the high-voltage wire 304 is wrapped around the target 40, the additional part of the bullet 302b hits 40 goals separately from the impact zone (the extra bullets a). Then spikes 222 on the extra bullets 302b stout in goal 40. When both the extra bullets a and 302b are near the target 40, the potential difference between the complementary parts of the bullet a and 302b provides a pulse current through the target 40, stunning and bringing it down. Note that as an additional part of the bullet a contains the impact area of the bullet, the additional part of the bullet a also called the body of the bullet.

The advantages of option implementation 300 bullets include:

a) bullet weight is divided into two parts, and therefore, the impact force is reduced as compared with a solid bullet;

b) electrodes variant implementation 300 bullets must not touch or penetrate the skin 40 goals. Thus, the probability of significant damage to the target skin 40 is reduced. Because the positive and negative electrodes (for extra parts of a bullet a and 302b, respectively) are separated from each other by a distance 10-50 cm, the high voltage current will pass through the objective 40 and act on it, even when electrode separated from the target skin 40 clothing or air gap;

c) an implementation option 300 bullets requires fewer spikes to hold the Shocker in the zone of interaction, compared to 10, 100, and 200 bullets;

(d) the need to hold the bullet only on clothes and not on the body leads to a decrease in the size of the spikes, which, ultimately, reduces the possibility of injury caused by spikes on human tissue, if a bullet hits a target 40 near sensitive point;

e) separation of the bullet into two parts (or more) can increase the effective range of fire of the weapon.

For the formation of the shock, which will incapacitate an adult for 5 min, using a mechanism having dimensions of a standard weapon, it is required that the electrical elements (battery 52, the high voltage transformer 54, the low-voltage transformer 56 and the capacitor 58) were smaller and more efficient than those currently available. The present invention is a miniature electric elements using the new technology of thin films.

High-voltage transformer 54 is made using the technology of thin films. Fig illustrates a helical coil 400A, which is the element of the transformer, manufactured using the technology of thin films. Explorer a is a thin layer of metal is outstretched and twisted in a spiral on the surface of the insulating film substrate a. Explorer a made in the form of a right-hand spiral. On the outer end of this spiral is the external connector electrode 406a. On the inner end of this spiral is internal connector a electrode. External connector electrode 406a available and opens on the upper side (facing away from the plane of the page) spiral coils 400A. Internal connector a electrode is isolated from above, but is available and opens on the reverse side of the spiral electrode 400A. Thus, the spiral electrode 400A is connected with the external electrode from the top through the external connector 406a and the spiral electrode 400A is connected to the second external electrode from the bottom through the inner connector a electrode (see Fig).

Shown in Fig many spiral coils 400A, 400b, 400C and 400d with the corresponding conductive spiral layers 400A, 400b, 400C and 400d are going to block 420, which serves as a winding of the transformer (see Figa-b). When an electric voltage is applied to the input terminals a and 412b, the current flows from the input terminal a to the external connector electrode 406a. The current continues to flow through the conductor a that twists inside in a right-handed helix to the inner connector a electrode. Internal connector a electrode connected to the internal connector electrode 408b on the spiral coil 400b through mechanical is the third coupling element a. Spiral coil 400b is similar to the spiral coil 400A except that the conductor 402b spiral coil 400b is a left-hand spiral. In addition, the internal connector electrode 408b on the spiral coil 400b is open for connections from the top of the spiral coil 400b, while the external connector electrode 406b is open for connections from the bottom of the spiral coil 400b. Thus, the current flows from the internal connector electrode 408b, twisted to the right, out to the external connector electrode 406b. From the prior art electromagnetic devices, it is clear that since the current is twisted to the right and in the spiral coil 400A, and a helical coil 400b, both coils create a magnetic field directed downward. Therefore, magnetic fields generated by coils 400A and 400b are added.

In this way the spiral coil 400C is a right-hand spiral, exactly the same as the spiral coil 400A. Accordingly, current flows from the spiral coil 400b to the helical coil 400C through a mechanical coupling element 414b to the external connector s electrode is twisted to the right and inside to the inner connector s electrode, contributing to the strengthening of the magnetic field directed downward. The current continues to flow through helical coil 400d, which is the left-hand coil is exactly the same as SPIRA the other coil 400b. Thus, current twists to the right and out to the external connector electrode 406d, increasing the magnetic field is directed downward. The current passes from the external connector 406d electrode to an external terminal 412b.

Figa and Fig.14b illustrate block 420 that serves as the primary winding of the step-up transformer. Block 420 is connected to the AC power source 416. The current passing through the winding unit 420, induces an alternating magnetic field. This magnetic field induces a current in the unit 420b. Unit 420b is a package of alternating right-and left-handed helices (400 not shown)connected in groups in the same way as in block 400A. Unit 420b contains 16 spiral coils (400 not shown). Coil (400) block 420b collected in two packages a and 422b 8 coils each. Packages a and 422b are connected near the mechanical connecting elements e. Block 420 is installed between packages a and 422b so that the spiral coils 400a-400d coaxial with the helical coils (400) block 420b. Thus, when the input voltage and current are fed to the block 420, a magnetic field. The magnetic field induces an electric potential, more than four times the input voltage on the block 420b (from input terminals s to the output terminals 412d).

Conventional transformers for transmission of the magnetic field from the primary winding to the secondary winding of the need to ferry the new or steel cores. Ferrite core increases the weight of the transformer and also reduces its effectiveness. Since the high-voltage winding of the transformer 52, made using the technology of thin films, very tightly Packed, the distance between the primary and secondary windings is small, and high-voltage transformer 52 has a conductive core. In the high-voltage transformer 52 is lighter and more efficient than conventional transformers.

Because of the high voltage transformer 52 is intended for single use only and time is not more than 10 min, the cross section of the conducting layer of the high voltage transformer 52 may be less than that allowed in an ordinary transformer. A thin conductive layer will cause a temporary heating of the transformer, but, nevertheless, the short lifetime of the transformer ensures that thermal breakdown will not occur. Reducing the size of the conducting layer allows, in addition, to reduce the size and weight of the high voltage transformer 52 compared to conventional transformers.

For example, one variant of implementation of the transformer, manufactured using the technology of thin films, has an input voltage of 1 kV and a current of 1 mA, the output voltage and current of 100 kV and 10 μa and working time of 5 minutes, manufactured from the following materials.

The outer diameter of each spiral coil is 12 mm and the inner diameter of each coil is 5 mm; each coil has 10 turns. The transformer has 10 spiral coils Packed in the primary winding, and 1000 spiral coils Packed in the secondary winding. Thus, the transformer is a cylinder with General dimensions: height 16 mm and a diameter of 12 mm Weight of transformer is 10,

It is smaller, lighter and more efficient than conventional transformers with wire windings and ferrite cores. To obtain the output voltage of 100 kV and a current of 10 μa, the conventional transformer must have an input voltage of 1 kV and a current of 1 mA, and its size should the s to be: diameter 23 mm, height 50 mm, weight 40 g

The prior art electrical devices it is clear that the electric potential (voltage drop) between adjacent helical coils 400A and 400b is approximately one quarter of the electrical potential between the input terminal a and output terminal 412b. In the General case, since the spiral coil (400) arranged in blocks (420), the electric potential between adjacent helical coils is V/N, where V is the electric potential on the entire block, and N is the number of spiral coils in the unit. Since the potential difference between adjacent helical coils is much smaller than the voltage drop across the entire block, then the ability to short-circuit the winding is reduced. This gives the possibility to manufacture the transformer is very high voltage without the need of bulk/heavy insulating material between the windings. This reduces the size and weight of the transformer relative to conventional transformers with wire winding.

The transformer is manufactured using the technology of thin films, in accordance with the present invention is smaller and lighter than a conventional transformer, because:

- the transformer is manufactured using the technology of thin films, more densely Packed coils compared to conventional transformer;

since the transformer is manufactured with the use of the group of thin films technology, has a layered structure, the potential difference between adjacent windings is less than the voltage between the first and last winding (through the power transformer). Therefore, in the case of high voltage (>10 kV) transformer, manufactured using thin films technologies, requires less insulation between the windings, than for a conventional transformer, and there is no need to fill high-voltage transformer-based thin films of liquid insulating material to reduce the possibility of short circuit between windings;

in conventional transformers, to facilitate distribution of the magnetic field from the primary winding to the secondary winding, it is necessary to have iron (ferrite/steel) magnetic core. Owing to the small size of the windings in the transformer, manufactured using thin films, the magnetic field of the primary coil is distributed to the secondary coil without the need for a ferrite core;

the authors of reduced cross-section of the conductive layer compared to conventional transformers. Although nicking conductive layer leads to high current densities and even to the heating coils of the transformer, there is no need to worry about the possibility of thermal breakdown, because the transformer disposable, use the in a short time.

Other advantages of the transformer, manufactured using thin films, in accordance with the present invention compared to conventional transformers are not necessary in the iron core, which reduces the efficiency of the voltage transformation; the transformation parameters of the transformer, manufactured using thin film can be easily varied by changing the number of spiral coils.

The prior art electronic devices, it is clear that many possible variants of the transformer, the corresponding entities of the present invention, are included in this patent. For spiral coils can be used an alternative conductive materials such as copper, aluminum, and carbon. The connection between the ends of the spirals may be alternative methods, such as mechanical connecting elements or conductive glue. Transformer, manufactured using thin film may include a magnetic ferrite core or to work without ferrite. Spiral conductors can be created by separating the substrate in many ways, including spreading, chemical precipitation/sedimentation in the usual way or by other known methods. Layers of insulating substrates can be joined with glue or to resist external what instrukzia bullets. Materials such insulating substrates may include various insulators such as paper and plastic.

Typical intervals of the parameters in the production of transformers with application of technology of thin films, are: thickness of the insulating substrate 3-50 microns; one transformer contains from 10 spiral coils to 10000 spiral coils; height unit stacked spiral coils 10-30 mm On the transformer output voltage is 100-2000 V At a current of 1-10 mA for low-voltage transformer and 50-100 kV at a current of 1-100 mA for high-voltage transformer.

On Fig presents galvanic element 500 in accordance with the present invention. Galvanic element 500 is a small disposable chemical energy source, manufactured using thin films. The electrodes (cathode 502 as oxidant and the anode 504 as reductant) is made in the form of a set of solid layers as electrodes with redox films deposited on separating the substrate 506. And the cathode 502 and the anode 504 are connected with the poles of a and 604b of the battery (see Fig) through power wires a and 508b.

First dry separating the substrate 506 acts as a dielectric insulating membrane separating the electrodes (plus [the cathode 502] and minus [the anode 504]). And the cathode 502, the anode 504 created using spray installation creating a thin surface layer separating the substrate 506. Galvanic element 500 is activated when initially dry separating the substrate 506 absorbs the electrolyte 606 (see Fig). Dry separating the substrate 506 is very hydrophilic and quickly tighten the electrolyte 606 in the pores separating the substrate 506. Capillary forces quickly distribute the electrolyte 606 over the entire surface and the cathode 502 and the anode 504. Then the electrolyte 606 facilitates the movement of ions between the cathode 502 and the anode 504, creating an electric potential on the power wires a and 508b and the poles a and 604b of the battery.

Separating the substrate 506 is made in the form of a tape wound in a spiral shape as shown in Fig. In this way we get a large surface area and a cathode 502 and the anode 504 in a small (small volume) galvanic element. A large area of the electrode surface gives the possibility of obtaining a significant current in the short time existence of a galvanic cell 500.

Galvanic element 500 is activated when separating the substrate 506 absorbs the electrolyte 606. First, the electrolyte 606 is inside the ampoule 608. During use, the ampoule 608 destroyed with the help of tiny sharp boron 610, as shown in Fig. In particular, in the embodiment 100 of deafening bullets (see Fig.6 Is 7), ampoule 608 is broken after the collision with the purpose of 40 (not shown), when the movable block 104 presses the launch button 602. The kinetic energy from the moving block 104, therefore, is transferred to the ampoule 608, pushing the ampoule 608 with acute boron 610, breaking it and freeing the electrolyte 606. Then the electrolyte 606 comes into contact with the separating substrate 506 and absorbed it. After that, the movement of ions through the electrolyte 606 between the cathode 502 and the anode 504 generates (and activates) galvanic element 500 and, accordingly, the battery 52.

In the prior art galvanic elements it is clear that because of the galvanic element 500 and the battery 52 is inactive, when the element is assembled (at the factory before use), galvanic element 500 and the battery 52 is stored in an inactive state. Therefore, galvanic element 500 and the battery 52 retain their charge better and have a longer shelf life than conventional batteries.

For example, one variant of implementation of the galvanic element manufactured using the technology of thin films, for use in deafening pool is made as follows.

These tapes are rolled up in the form of a cylinder with a height of 6 mm and a diameter of 12 mm, the Battery is activated by electrolyte displacement of 3 cm³consisting of 50%H₂SO₄+50%H₂O. Galvanic cell generates a current of 5 amps with an electric voltage of 2 V (producing, thus, the power of 10 W) for 2 minutes

Obviously the advantage of short-term action battery manufactured using the technology of thin films, compared to the standard small-size batteries (for example, with standard batteries hearing AIDS with weight and volume, similar to the above option exercise the battery-based thin films)that generate the Mac is imally current 1.5 a at 1.5V Century

In the prior art galvanic elements it is clear that the materials and dimensions of the battery are made using the technology of thin films, can be modified depending on the desired output and the physical characteristics of the battery. Such modifications consistent with the essence of the present patent. Exemplary parameters for a battery with an output voltage of 0.5 to 3 V and an output current of 1-10 And are as follows: thickness separating the substrate 10 to 50 μm, the thickness of the electrode layers of 1-50 μm, and the volume of electrolyte 1-6 cm³.

Advantages of chemical battery 52, made using the technology of thin films, compared to conventional batteries are as follows:

- large surface electrodes generate a large current at a relatively small size of the source;

- single use and short time (2-10 min) to reduce the amount of electrolyte and electrodes, and hence the size and weight of the new chemical source;

the electrodes and membrane are distributed in such a way that the acceleration of the bullet shooting and interaction with the human body (in order) will be called by the electrolyte rapid activation of the chemical source. Thus, the chemical source remains inactive during storage and flight.

You should take into consideration that the above descriptions serve only as examples, in the framework of the present invention may be many other ways to implement the corresponding entity of the present invention.

All publications, patents and patent applications mentioned in this description of the invention, are incorporated in full by reference in the description of the invention just as if each individual publication, patent or patent application were specifically and individually incorporated into this document by reference. Moreover, citation or identification of any source of information in this description of the invention is not to be construed as an assumption that such link is to the already known prior art to the present invention.

1. Bullet to stun the target, containing
a) the first electrode, and
b) a second electrode configured to deploy at some distance from the first electrode after the collision of the bullet with the target and re-attaching to the target at a distance of at least 10 cm from the first mentioned electrode, so that the electrical current flowing between the first-mentioned electrode and said second electrode after attaching the second electrode to the target, the target is stunned.

2. The bullet according to claim 1, characterized in that the said second electrode is configured to pull-out of the bullet casing in the deployment process.

4. The bullet according to claim 1, characterized in that the said first electrode includes a hook with a beard.

5. The bullet according to claim 1, characterized in that the said first electrode is located on the body of the bullet.

6. The bullet according to claim 1, characterized in that the said first electrode also configured to deploy upon collision of the bullet with the target.

7. The bullet according to claim 1, characterized in that it further comprises:
c) subsystem soften the blow to protect the target from injury caused by impact of the bullet on the target;
d) an attachment mechanism to hold the bullet on the target at impact with the target; and (e) the subsystem of energy supply, configured to supply electric current after the application of the bullet to the target using the above-mentioned mechanism, thus stunning the target.

8. The bullet according to claim 7, further comprising:
f) one-piece bezel, contributing to shot bullets of conventional firearms.

9. The bullet according to claim 7, characterized in that it is designed in such a way that it is shot from conventional firearms.

10. The bullet according to claim 7, further contains (f) a stabilizer.

11. The bullet according to claim 7, characterized in that the said attachment mechanism and riverwest when you shot the bullet.

12. The bullet according to claim 7, characterized in that the said attachment mechanism is actuated near the destination.

13. The bullet according to claim 7, characterized in that the said attachment mechanism is actuated when the collision with the target.

14. The bullet according to claim 7, characterized in that the said subsystem power supply is activated when the collision of the bullet with the target.

15. The bullet according to claim 7, characterized in that the said subsystem power supply includes a battery, and the battery is activated when the collision of the bullet with the target.

16. The bullet according to claim 7, characterized in that the subsystem mitigate the impact includes a deformable cushion in the impact zone of the bullet.

17. The bullet according to claim 7, characterized in that the said subsystem power supply includes a galvanic element manufactured using the technology of thin films.

18. The bullet according to claim 7, characterized in that the said subsystem power supply includes a transformer, manufactured using the technology of thin films.

19. The bullet according to claim 7, characterized in that it further includes a movable block made with the possibility of weakening the force of impact at the collision of the bullet with the target.

20. The bullet according to claim 19, characterized in that the said movable block includes at least one node selected from the group SOS is oasa of the above-mentioned mechanism of attachment, grip, battery, transformer and capacitor.

21. The bullet according to claim 19, characterized in that the movement mentioned movable block relative to that of the shock zone actuates one of the components of bullets.

22. The bullet according to claim 19, characterized in that the said movable block includes at least one node energy absorption.

23. The bullet in item 22, characterized in that the mentioned site energy absorption includes at least one component selected from the group consisting of a friction connector, springs, gear guide, and a flexible retainer.

24. The bullet according to claim 7, characterized in that the subsystem mitigate the impact includes at least one part of the bullet, which collides with the purpose separately from the impact zone, reducing, thus, the weight associated with the said impact area, therefore reducing the kinetic energy associated with the said impact area and therefore reducing injury upon impact.

25. Bullet at point 24, characterized in that the said at least one part of the bullet connected by a wire with the said impact zone, and the said wire is wrapped around the target, fixing, thus, referred to the impact zone on goal in one place, and the aforementioned at least one portion of the bullets in a different location on the target.

26. Bullet at point 24, the best is the rpm die, that said subsystem power supply generates voltage as the potential difference between the said impact zone and said at least one part of the bullet, so that when the said impact zone is located near the destination in one place, and the aforementioned at least one portion of the bullet is near the destination in the second place, through the target electric current is mentioned from one place to the aforementioned second place.

27. The bullet according to claim 7, characterized in that the said attachment mechanism additionally serves as a conduit for passing an electric current from the engine supply energy to the target.

28. The bullet in item 27, characterized in that the said attachment mechanism serves also as an electrode.

29. The bullet in item 27, characterized in that the said attachment mechanism includes a hook with a beard.

30. The bullet according to claim 7, characterized in that the said attachment mechanism includes:
(i) a first hook with a beard and
(ii) a second hook with a barb,
with the first mentioned hook with a beard touches the purpose of one angle, and said second hook with a beard touches the goal at the opposite corner.

31. The bullet according to claim 7, characterized in that the said attachment mechanism includes a capture.

32. Bullet for p, characterized in that mention the initial capture is emitted from the side surface of the bullet.

33. Bullet for p, further comprising movable block made with the possibility of movement relative to the impact zone of the bullet, and the motion mentioned rolling block on the said impact zone is to implement the above-mentioned capture the target.

34. The bullet according to claim 1, characterized in that it further includes:
(C) galvanic element manufactured using the technology of thin films, to create an electrical potential, comprising:
i) separating the substrate;
ii) at least two electrodes are deposited on the aforementioned separating the substrate; and
iii) an electrolyte, and the above-mentioned electrolyte is absorbed mentioned separating the substrate, thereby facilitating the movement of ions between the said at least two electrodes and the formation of a potential difference between the said at least two electrodes.

35. A bullet to 34, characterized in that the said separating the substrate has a thickness less than 50 microns.

36. A bullet to 34, characterized in that each of the said at least two electrodes has a thickness less than 100 microns.

37. A bullet to 34, characterized in that the said separating the substrate in a dry state is an insulator.

38. Bullet in clause 37, wherein the galvanic element is activated during use is of when getting mentioned electrolyte on said separating substrate.

39. The bullet according to claim 1, characterized in that it further includes:
(C) the transformer is manufactured using the technology of thin films, containing:
i) a set of spiral coils, and
ii) at least two blocks, and each of the said at least two blocks includes a package of at least one spiral coil mentioned multiple spiral coils.

40. Bullet in § 39, wherein the first spiral coil of the above-mentioned set of spiral coils is a right-hand coil and the second spiral coil of the above-mentioned set of spiral coils is left-handed coil.

41. Bullet in § 39, wherein each spiral coil of the above-mentioned set of spiral coils includes
a) an insulating substrate, and
b) a conductor deposited on said insulating substrate in the form of a spiral.

42. Bullet in paragraph 41, characterized in that the said insulating substrate has a thickness less than 50 microns.

43. Bullet in paragraph 41, characterized in that the conductor has a thickness less than 50 microns.

44. Bullet in § 39, wherein the transformer is configured to the optimal transformation of the voltage in a given time interval.

45. Way to stun targets with non-lethal bullets, including:
a) deployment of the W of the first electrode after the collision non-lethal bullets with purpose,
b) attaching a first electrode to the target after it is deployed, and
c) after the accession of passing electrical current from the first electrode through the objective to the second electrode located at a distance of at least 10 cm from the first mentioned electrode, and the above-mentioned deployment involves the separation of the first and second electrodes by an appropriate distance.

46. The method according to item 45, characterized in that the said stage of deployment involves running the capture of the corps non-lethal bullets.

47. The method according to item 45, characterized in that the said stage of deployment involves bending of the capture.

48. The method according to item 45, characterized in that the said stage of deployment includes the turning of the hinge.

49. The method according to item 45, characterized in that the said stage of deployment occurs along an arched path.

50. The method according to item 45, characterized in that the said attaching includes attaching mentioned first electrode on purpose.