JP6806712B2 - Reactive armor - Google Patents

Description

The present invention relates to the field of protecting an armored vehicle or armored structure from the oncoming Kinetic Energy Penetrators (KEP) or rocket propelled HEAT warheads. More specifically, the present invention relates to protecting an armored vehicle or armored structure from the oncoming Tandem warheads.

In essence, it is extremely important that HEAT (High Energy Anti-Tank , hereafter referred to as HEAT ) ammunition penetrate the external armor of the armored vehicle and kill the crew inside. Incapacitate mechanical systems, or work by all of them.

To allow the armored vehicle to withstand the impact of the shaped charge HEAT, an external explosive element named Explosive Reactive Armor ( hereafter referred to as ERA ) is attached to the vehicle's armor.

The ERA consists of two plates, typically multiple high explosive sheets or one high explosive slab, sandwiched between two plates, called reactive or dynamic elements.

In one example, in order to neutralize a flying rocket-propelled HEAT such as the RPG-7 at the time of impact, a high-performance explosive of reactive armor explodes and reacts to the shaped charge jet. Forcibly push the metal plate away. The fired plate crushes metal jet bullets.

In one example of the prior art, the remarkable effectiveness of ERA is largely due to two basic mechanisms. First, the moving plate changes the effective velocity and impact angle of the shaped charge jet, changing the angle of incidence of the jet and reducing the effective velocity. In the second aspect, since the two plates are angled relative to the normal impact direction of the molded explosive warhead, the impact points on the plates change over time as the plates move outwards. The jet needs to get through the fresh board. This second effect significantly increases the effective thickness of the board during impact.

The ERA has shown high efficiency in defeating rocket-propelled HEAT-formed explosive warheads such as the RPG7, TOW, and LOW.

Soldiers rely heavily on the use of rocket-propelled HEATs to defeat armored vehicles, so a new warhead technology called Tandem-Change has been developed to defeat ERA. In essence, a Tandem-Charge weapon is an explosive device or projectile with two or more detonation stages. Tandem-Charge weapons are effective against reactive armor designed to protect armored vehicles (mainly tanks) from anti-tank ammunition.

As mentioned above, the Tandem-Charge has two or more detonation stages. The first detonation stage of a tandem explosive weapon is typically a detonation, which penetrates the target's reactive armor without detonation and allows the second warhead to pass unimpeded. Either leave the channel through the reactive armor to get it, or simply detonate the reactive armor to untimen the counter explosion. The second detonation stage of the tandem detonation weapon attacks the same spot at the first detonation impact point, where the reactive armor is at risk. Reactive armor is the only element that allows the integrated armor of an armored vehicle to withstand the impact of a HEAT jet, so if reactive armor is endangered by the first detonation stage, the main explosive (second). Detonation) is likely to penetrate the vehicle's main armor.

Therefore, one object of the embodiments of the present invention is to provide a reactive armor module capable of defeating a tandem warhead.

Another object of the embodiments of the present invention is to improve and enhance the sensitivity of existing reactive armor modules to withstand the impact of tandem warheads.

Another object of the embodiments of the present invention is to provide the improved reactive armor in a simple, relatively lightweight and reliable form.

The present invention relates to a reactive armor module comprising (a) a front and back plates, (b) a particle layer between the plates, and (c) an explosive layer in front of the back plate.

Preferably, the reactive armor module further comprises an additional explosive layer between the particle layer and the anterior layer.

Preferably, the particles in the particle layer are separated.

Preferably, the reaction armor module is determined a shape so as to form a directional grain child cloud Ri by the directing blast effect.

According to one aspect of the invention
The front layer of armor and
A particle layer containing multiple particles and
The first explosive layer adjacent to the particle layer and
A reaction armor module and a rear surface layer of the armor, the first explosive layer is triggered by a first explosion from flying to the munition, the plurality of particles emanating combustion toward the particle layer A reactive armor module is provided that ejects, thereby blocking a second explosion from the warhead.

The reactive armor module may include a second explosive layer between the particle layer and the anterior layer.

In one embodiment, the plurality of particles of the particle layer is spaced apart by a spacer.

The plurality of particles can include rigid particles.

A second explosive layer may be disposed between the front layer and the particle layer.

In one embodiment, the plurality of particles of the particle layer is spaced apart by a spacer.

The plurality of particles can be shaped into spherical particles, cylindrical particles, or particles in which a plurality of shapes are combined.

Second explosive layer may be seen between the front layer and the particle layer.

Explosive layer directs the explosion, it is possible to define the shape to form a directional grain child cloud by it. The armor layer can include steel, ballistic aluminum, titanium, aluminum, polymers, or a combination of polymers and rigid materials.

The reactive armor module may be located on the armored vehicle near, in front of, or behind another reactive module, separated from other modules, or with spacers containing energy absorbing material. Good. The reactive armor module may include a rigid body layer between the explosive layer and the particle layer.

The high performance explosive charge may be mixed with the particles of the particle layer.

The reaction armor module may comprise a casing, the cross-sectional structure of the casing is designed to achieve the first Tokoro to induce energy explosion of the explosive layer Nozomu of particle clouds vector and shapes.

The explosive layer may be shaped into a curved shape and the casing may be molded or curved.

Rigid material is disposed on a portion of the explosive, it is possible to produce a time difference explosion intergranular child cross emitted by it. Rigid material can comprise a geometric shape elements. The geometry element can it to contain pyramidal elements to be inserted between the particles of the particle layer, the pyramid has a pointed end, 該尖end facing explosive layer.

The reaction armor module may further comprise an additional front layer before the front layer of the armor.

The additional front layer may comprise a trigger, the trigger is the impact HEAT jet you flying on the trigger, one for thus the first of electrical signaling and persists blast It activates the explosive layer, before Symbol continue to occur explosion wind, including the explosives attached to the front layer of the additional.

Trigger can be urchin constituting by causing triggering of the first explosive layer prior to impact by the jet.

Explosive layer can be defined by sea urchin shape to explode in a plurality of ground zero.

The triggering mechanism can use a proximity fuze or a proximity sensor.

The first explosive layer can be shaped to direct the explosion of the first explosive layer using the Monroe effect and / or a blast lens can be used.

One embodiment of the reactive armor module can include four explosive layers that separate the three particle layers.

The reactive armor module may include a triggering element and a delay element, the delay element for delaying the explosion and waiting for the second explosion of the warhead.

The triggering element is
(A) Battery,
(B) Capacitor,
(C) Inductive circuit,
(D) An electromechanical element that moves a pendulum type element in an electromagnetic field to generate electricity, and the electricity is supplied to a capacitor, a battery, or the like.
(E) Piezoelectric element,
(F) Chemical substance or metal
The voltage may be supplied by one of the members.

In use, the blast of the first explosive layer is directed in the rigid particle Cotai of the particle layer, before Symbol rigid particles bodies are arranged in a predetermined structure, the blast of the first explosive layer is this structure by breaking internal collapse, adding a plurality of multi-directional movement impact jet flying, thereby deforming the jets the flying.

Given structure of the first explosive layer, at least one extension along the side plates of the prior SL reaction armor module, in particular, comprises two extensions along two side plates opposing the previous SL reaction armor module it can, the explosion is triggered at a location other than the center between the two extensions.

The above reactive armor module may be combined with a second reactive armor module, the second reactive armor module
The second front layer of armor and
The second back layer of armor and
A third explosive layer between the front layer and the back layer,
With a triggering mechanism, the third explosive layer is triggered by the triggering mechanism after a certain delay in the first explosion of the incoming warhead facing into the second front layer. A second front layer can be ejected, thereby blocking a second explosion from the warhead .

Explosive layer directs the explosion, it is possible to define the shape to form a directional grain child cloud by it.

According to the second aspect of the present invention
The front layer of armor and
The back layer of the armor and
An explosive layer between the front layer and the back layer,
A reaction armor module and a triggering mechanism, explosive layer is flying to the first explosion is triggered by the triggering mechanism after a certain delay of previous SL front warhead in the front layer A reactive armor module is provided that ejects a layer, thereby blocking a second explosion from the warhead.

According to a third aspect of the present invention, there is provided a way to defend et al or a tandem warhead, tandem warhead, following the primary explosive, which primarily explode after a small delay which is set in advance,
The step of detecting the primary explosion and
Using the results of the step of detecting the primary explosive, and a step of detonating a directional explosion wind to interfere with the secondary explosive, a method is provided.

One embodiment, the can comprises adding the initiator delay between the step of the step initiation of detecting the primary explosive, the detonator delay is consistent with a small delay the preset.

One embodiment, the utilizing pre Symbol directional explosion wind toward the tandem warhead implanted rigid particles cloud may include a step which interferes with pre-Symbol secondary explosions thereby.

One embodiment may include a step of detonating asymmetrically to direct the step of causing the implosion of the rigid particles layer, in particular the directional blast.

It is a figure which shows the schematic structure of the HEAT molded explosive tandem warhead. It is sectional drawing of a typical reactive armor module. FIG. 6 is a cross-sectional view of a typical reactive armor module with a triggering screen. It is sectional drawing of the structure of the reactive armor module by one Embodiment of this invention. It is a figure which showed the schematic operation mode of the reaction module 30 of various embodiments of this invention. It is a figure which shows the schematic structure of the reaction module by another embodiment. It is a figure which shows the other embodiment of the reaction module 130 by one embodiment of this invention. It is a figure which shows another reaction module by one Embodiment of this invention. FIG. 6 is a cross-sectional view of a reactive armor module according to an embodiment of the present invention provided with a triggering screen. It is a figure which shows another reaction module by one Embodiment of this invention. FIG. 6 is a cross-sectional view of a reactive armor module according to an embodiment of the present invention provided with a triggering screen. It is a figure which shows the triggering screen used for ERA of various embodiments of this invention. It is a figure which shows another embodiment of this invention. It is a figure which shows another embodiment of this invention. It is a figure which shows another embodiment of this invention. It is a figure which shows another embodiment of this invention. It is a figure which shows another embodiment of this invention.

FIG. 1 shows the schematic structure of the HEAT molded explosive tandem warhead 10. The warhead 10 includes a tip 11, an initial (first) explosive charge 12, a first stage fuze 13, a spacing rod 14, a main explosive charge 15, and a second stage (main explosive charge) fuze 16.

As mentioned above, upon impact with typical reactive armor, the first explosive charge of the tandem warhead detonates and triggers a first jet, which penetrates or activates the reactive armor. Then, at high precision timing, the second explosive of the tandem warhead detonates and triggers a second jet, which passes through the space of the reaction module previously pierced by the first explosive of the vehicle. Penetrate the body armor.

A cross section of a typical reactive armor module 20 is shown in FIG. The reactive armor module 20 comprises a front plate 21, a back plate 22, and a high performance explosive charge 23 between the two plates. As mentioned above, the remarkable effectiveness of reactive armor is largely due to two basic mechanisms. First, the moving plate changes the effective velocity and impact angle of the shaped charge jet, changing the angle of incidence of the jet and reducing the effective velocity. In the second aspect, since the two plates are angled relative to the normal impact direction of the molded explosive warhead, the impact points on the plates change over time as the plates move outwards. The jet needs to cut through the fresh board, which in fact increases the effective thickness of the board upon impact.

Typical reactive armor has shown to be very effective in defeating the very famous rocket-propelled HEAT-formed explosive warheads such as the RPG7, TOW, and LOW, but still in tandems such as the RPG-29. I have failed many times to defeat the warhead.

FIG. 3 shows a cross section of the structure of the reactive armor module 30 according to an embodiment of the present invention. The reactive armor 30 can be a stand-alone module or an additional module to an existing reactive armor module. In the latter case, the armor 30 can come before the typical reactive armor module (20 in FIG. 2) or after the module 20. In certain embodiments, a space can be provided between the module 30 and the module 20.

The module 30 of the embodiments of the present invention includes a front plate 31 and a back plate 32. In one embodiment, the plate is made of any rigid material such as steel, ballistic aluminum, titanium, alumina, or any composition of the material. In another embodiment, the plates 31 and 32 are made of a polymer or material with similar properties, such as Dynama, Spectra, Aramid. In another embodiment, the plates 31 and 32 can be made of a combination of polymer and rigid material. In another embodiment, the front plate 31 and the back plate 32 can be made of different materials or a combination of different materials, respectively.

The module 30 further includes two inner layers between the front plate 31 and the back plate 32. The first of the two layers is the particle layer 33, and the second of the two layers is the high explosive layer 34.

The particle layer 33 includes a plurality of rigid particles. For example, rigid particles have spherical shape, cylindrical shape, or, reliable collision with tandem warhead flying, a specifically designed shape to maximize reliable transmural input possibility for a tandem warhead be able to. In some embodiments, a combination of various shapes may be used.

FIG. 4 is a diagram illustrating a schematic operation mode of the reaction module 30 according to the embodiments of the present invention. When the tandem warhead 50 collides with the front plate 31, the first fuze of the tandem warhead causes a blast, resulting in a jet that penetrates the front plate. As the jet passes through the particle layer 33, the jet eventually collides with the high explosive layer 34, resulting in a blast in that layer that ejects particles towards the main (second) explosive of the tandem warhead 50. These particles are ejected toward the flying second portion of the tandem warhead, collide with the second portion at ultra-high speed, and then cause a blast in the second portion of the second warhead. The collision of metal particles traveling at ultrafast speeds damages the integrity of the second portion of the tandem warhead and significantly impairs the tandem warhead's ability to form cohesive focused jets. In some cases, a large number of particles hitting the second part can make the second part completely useless, even if the main explosive in the second part could not be detonated.

In one embodiment, the particles are separated to reduce the kinetic energy transfer between the particles caused by the mechanical impact caused by the jet. Separation between particles can be achieved by covering each particle with a swollen energy absorbing material. Alternatively, energy absorbing elements may be provided between the particles. In another alternative, the high performance explosive charge may be mixed between the particles. In another embodiment, in addition to mixing the charge between the particles, a back layer of a high performance explosive charge is provided. In another embodiment, an additional explosive layer may be provided between the particle layer and the faceplate. In another embodiment, the rigid or composite layer is high performance with the particles to prevent damage to the high explosive layer due to the kinetic impact of the jet on the metal particles that can damage the explosive charge. It may be placed between the explosive layer.

In another embodiment, the cross-sectional structure of the casing is designed to guide the energy of the blast to achieve the desired particle cloud vector and shape. For example, the high explosive is shaped into a curved shape or placed in an inclined or curved casing. In another alternative, the rigid material can be placed over a portion of the shaped charge to create a staggered explosion between the emitted particles. In another aspect, a geometric element, such as a pyramidal element, is inserted between the particles with the tip of the element directed towards the explosive layer so that the detonation has a blast effect on the particle vector.

The reaction module 30 of the embodiments of the present invention may also include an additional front layer in front of the front plate 31. Additional front layer of this type, the impact of the tandem warhead, used as an electronic signaling or triggering mechanism for actuating the reaction armor module either is that subsequent blast caused by explosives mounted on the additional plate can do.

In another embodiment, a proximity fuze or proximity sensor may be associated with one or more reactive armor modules 30 to facilitate detonation before the tandem warhead collides with the faceplate.

FIG. 5 shows a schematic structure of a reaction module according to another embodiment. Unlike the previous embodiments, the reaction module of Figure 5, is designed to utilize the effect known as implosion in the art, the blast of the reaction module directed along the direction of the HEAT jet flying is the blast wave, the structure was destroyed inside collapsed directed in the name Ru mass from arranged rigid particles within a predetermined structure, the relative position rigid particles forming the structure relative to one another rigid particles The flying jet is deformed by applying a plurality of multidirectional motion impacts to the flying jet and exposing the flying jet to a large number of interactions with moving particles. The collision angle, velocity, surface, etc. of each particle affect the HEAT jet not only when the particle forms, but also at the initial penetration stage of the particle, and even after the initial impact, the residual blast energy of the internal rupture is transferred to the particle. It also affects the continuous impact on the HEAT jet tail as it continues the detrimental movement of the particles. The reaction module 130 includes a front plate 131, a back plate 132, a front explosive layer 134 mounted on the rear surface of the front plate 131, and a particle layer 133. The explosive layer 134 of this embodiment covers substantially the entire area of the rear surface of the front plate 131. Due to the impact of the HEA T jet , the explosive layer 134 is detonated so as to cause an explosion that self-destructs the structure of the rigid particle, internally ruptures as described above, and has high kinetic energy from multiple directions to the jet. The jet is effectively destroyed by adding the above jet, and the jet is effectively destroyed.

FIG. 6 shows another embodiment of the reaction module 130 according to one embodiment of the present invention. The reaction module 130 includes a front plate 131, a back plate 132, a front explosive layer 134 mounted on the rear surface of the front plate 131, and a particle layer 133. The explosive layer 134 of this embodiment covers substantially the entire area of the rear surface of the front plate 131 and also has an extension 141 along the side plates of the reaction module. Upon impact of the HEAT explosive, the explosive layer is detonated to cause an explosion that ejects rigid particles according to the blast wave. (As a geometry in this embodiment), the blast waves from each surface move the particles in multiple directions, exposing the incoming HEAT jet to a large number of kinetic forces and effectively damaging the jet. Optionally, the explosive geometry is different to create a large number of shock wave centers, which eject the particles and cause the particles to apply high kinetic energy to the jet from multiple directions, effectively destroying the jet. To do. In addition, the focus of the shock wave generated by the explosion is by shaping the explosive by creating a geometric structure of the explosive so as to achieve a directional blast wave in a manner known in the art as the Monroe effect. Can be oriented and / or amplified. The shock wave is directed in a given direction such that the blast lens 140 fires the particles along with the jet or other particles in a collision course so as to generate a secondary impact on the particles that will affect the jet. Shaped to direct and amplify. This effect can be enhanced by inserting a liner into the blast lens 140. In an alternative embodiment, the function of the blast lens can be modified to disperse the shock wave so as to provide an orbit to the desired course of the rigid particles.

FIG. 7 shows another embodiment of the present invention. The structure of the reaction module 130 is similar to that of the embodiment shown in FIG. 6, but the differences from the embodiment are as follows. The extension portion 141 of the explosive layer of FIG. 6 completely covers the side plate , whereas the extension portion 141a covers only a part of the side plate . Further, in the embodiment of FIG. 6, there is only one extension portion 141, whereas in the embodiment of FIG. 7, a second extension portion 141b is provided, and the second extension portion 141b is described in this example. It is located in the opposite corner of the reactive armor module 130. Preferably, the two extensions 141a and 141b are arranged on different axes as shown. Upon impact of the HEAT explosive, the explosive layer is detonated to cause an explosion that ejects rigid particles according to the blast wave. Since the detonation wave has multiple centers (as a result of the asymmetric explosive layer geometry in this embodiment), when an impact-flying HEAT jet detonates the explosive charge 134, the detonation wave from each surface Move the particles sequentially in multiple directions. Since the detonation point can be close to either the extension 141a or the extension 141b, the explosion will reach one of the extensions earlier than the other. Different types of explosives may be used for the extensions 141a and 141b to ensure such non-simultaneous explosions. Moreover, the two extensions are not strictly opposed to each other in order to prevent a decrease in the blast yield effect. In another embodiment, the rigid particles adjacent to the sides 141a and 141b, respectively, have one or more of different masses, different shapes, different structural alignments, eg, the particles are materials of different densities. It is embedded in materials with different particle arrangements, materials with different tensile strengths, etc. The large number of kinetic forces generated by the asymmetric array effectively damages the jet. Also in this embodiment, as in FIG. 6, the explosive geometry can be different to create a large number of shock wave centers, thereby ejecting the particles and raising the particles from multiple directions into the jet. Adds kinetic energy and effectively destroys the jet. In addition, the focus of the shock wave generated by the explosion is by shaping the explosive by creating a geometric structure of the explosive so as to achieve a directional blast wave in a manner known in the art as the Monroe effect. Can be oriented and / or amplified. The blast lens 140 (shown in FIG. 6) fires the particles along with the jet or other particles in the collision course so as to generate a secondary impact on the particles that will affect the jet. It may also be incorporated into one or more locations in the blast layer to shape, direct and amplify the shock wave in a given direction. This effect can be enhanced by inserting a liner into the blast lens 140. In an alternative embodiment, the function of the blast lens can be modified to disperse the shock wave so as to provide an orbit to the desired course of the rigid particles.

FIG. 8 shows a reaction module consisting of three particle structures according to another embodiment of the present invention. The reaction module 230 includes a striking surface 231 and a back surface 232, a first explosive layer 234, a second explosive layer 235, a third explosive layer 236, and a fourth explosive layer 237. A first steel wall with openings 246a, 246b, and 246c separates the first explosive layer 234 and the second explosive layer 235. The separator 239 separates the second particle structure 233b from the third particle structure 233c. Upon impact with the HEAT jet, the explosive layer 234 explodes and ejects rigid particles toward the flying jet, or in the case of a tandem warhead, towards the main explosive charge of the warhead. When the explosion begins in the first particle structure 233a, the blast propagates through the opening 246 and activates the second explosive layer 235, causing an immediate explosion of the second explosive layer 235. When the second explosive layer 235 detonates, the implosion process detailed above begins in the self-destructing particle structure 233b. Following this explosion, the blast propagates within the explosive layer 236 and initiates the blast sequence for explosive layer 237. When the explosive layer 237 detonates, the entire particle mass collides with the collapsed particle structure 233b, so that the particle structure 233c is self-destructed. This implosion tandem process within the multiple explosion structure effectively damages the incoming HEAT jet. More specifically, the large number of kinetic forces generated by the asymmetric array effectively damages the jet. Also in this embodiment, as in FIG. 6, the explosive geometry can be different to create a large number of shock wave centers, thereby ejecting the particles and raising the particles from multiple directions into the jet. Adds kinetic energy and effectively destroys the jet. In addition, the focus of the shock wave generated by the explosion is by shaping the explosive by creating a geometric structure of the explosive so as to achieve a directional blast wave in a manner known in the art as the Monroe effect. Can be oriented and / or amplified. The blast lens 140 (shown in FIG. 6) fires the particles along with the jet or other particles in the collision course so as to generate a secondary impact on the particles that will affect the jet. It may also be incorporated into one or more locations in the blast layer to shape, direct and amplify the shock wave in a given direction. This effect can be enhanced by inserting a liner into the blast lens 140. In an alternative embodiment, the function of the blast lens can be modified to disperse the shock wave so as to provide an orbit to the desired course of the rigid particles. It should also be noted that including openings within the sheet steel or separator is optional. This example is non-limiting as additional separators, lenses, or steel sheets can be used to shield one or more explosive layers, thereby prematurely preventing damage to the explosive layers. .. Further, to reinforce the steel sheet, materials such as alumina 98 and silicon carbide may be used as part of this reaction module, as described above, as well as a plurality of different materials such as polymers and a large number. Hollow structures with geometric shapes can be used to direct, strengthen, reduce, etc. blast-inducing forces and physical and mechanical effects that can affect the end result of the module, as described above. It must also be kept in mind. The use of reaction modules according to embodiments of the present invention may be carried out either as stand-alone modules or in combination with other modules, i.e. modules described herein or known in the art. It should be noted that.

It should be noted that typical reactive armor is generally mounted at an angle to the vertical (note that this overall situation is not shown in FIGS. 2 and 4).

In another embodiment of the invention, a triggering screen is provided to allow timed detonation of the blast sequence within the ERA of the embodiments of the invention. Triggering screens are known in the art. For example, the triggering screen, model number PT-0303500600MK, is manufactured by Whisner Corporation (US company) and is shown in FIG. The triggering screen is typically used to close the electrical circuit through the triggering screen. When piercing the triggering screen, the electrical circuit is closed and the detonation circuit is activated, causing the explosive in the charge to detonate. The latency of the blast sequence can be managed by means known in the art such as allowing the blast sequence to start, for example, 5 microseconds to 20 microseconds from the drilling time of the triggering screen. .. The distance from the explosive layer 134 or other parts considered important in the charge to the triggering screen is a major factor that allows the blast to be managed prior to the impact of the jet. As shown in FIGS. 7a and 9, the triggering screen 241 is used to set the blast time for the high explosive layer 134. According to embodiments of the present invention, this type of triggering screen 241 is mounted behind the striking surface. The distance from the explosive layer 134 to the triggering screen 241 should be adjusted to determine the maximum time during which the blast sequence can be initiated within the charge before the jet collides with an element in the ERA of FIG. 7a. Can be done. In FIG. 8a, the screen is arranged, for example, within the elements that make up the charge. As the jet moves through the components of the charge, it triggers a blast sequence before the jet arrives at a designated location within the charge.

This type of technique can also be used to trigger the prior art ERA module 20 (FIG. 2) to explode the ERA module 20 before the shaped charge jet collides with the front steel plate sandwiching the high explosive. Should be noted. It is also noted that the use of the triggering mechanism with the triggering screen 241 (shown in FIG. 2a) can dramatically increase the likelihood that the ERA module of FIG. 2 will break the jet. Should. FIG. 2a shows a screen 241 arranged at some distance in front of the front plate 21 of the ERA 20. The detonator is shown as number 243 in FIGS. 2a, 7a, and 8a. The blast circuit is not shown in the figure above for brevity.

It should also be noted that the triggering screen 241 described above can be augmented by other means known in the art to create a blast sequence before the incoming jet collides with a predetermined element in the ERA. is there.

FIG. 10 discloses another embodiment of the present invention. In this embodiment, the explosive layer 234 is formed or formed at a slight angle to either a horizontal or vertical plane. In the above-mentioned arrangement of the reactive armor, when exploded, the particle structure 233 is ejected toward the flying HEAT jet and collides with the flying HEAT jet while applying an angular shear force to the jet 277. In another embodiment shown in FIG. 11, reactive armor, in addition to said diagonal explosive layer 234, activates a detonation sequence via wiring 278, resulting in a trigger for detonating the detonator 243. A ring screen 241 is provided. The triggering screen may be used as a means of closing an electrical circuit to generate an electromagnetic or radio frequency signal received by a suitable receiver, which will cause the detonator 243 to detonate. Activate the blast sequence.

The triggering screen can operate in any of the embodiments described above, for example, as shown in FIG. The means for generating a voltage to the screen, switching mechanism, or roaring element is to (a) a battery, (b) a capacitor, (c) an inductive circuit, (d) a locking motion to bring the pendulum element into an electromagnetic field. An electromechanical element that operates in a manner known in the art and thereby generates electricity, wherein the electricity is supplied to a capacitor, battery, or the like, under pressure or impact from an electromechanical element, (e) a HEAT jet. Electricity that can be directed into the triggering screen can be due to the use of a piezoelectric element, which is generated as a means necessary for the operation of the triggering screen. Alternatively, the voltage generated by the piezoelectric element activates a switching mechanism that can release the stored energy in the capacitor or battery as a means of activating the explosion sequence, (f) upon contact (beginning with a HEAT explosion), as described above. Use of chemicals or metals known in the art to generate the electricity needed to operate.

The means (b), (e), and (f) can be used in connection with the triggering screen or as a triggering mechanism for the reaction exterior according to any of the embodiments described above. These means can replace the triggering screen because they can release the required voltage required to trigger the blast sequence in a collision. Preferably, the elements (b), (e), and (f) are placed at some distance in front of the explosive charge.

FIG. 12 shows reactive armor with two steel plates sandwiching a high explosive. The high performance explosive charge is fitted with a detonator that operates by drilling the triggering screen as depicted in the above length. When the triggering screen is drilled, the blast is initiated by the triggering screen mechanism before it begins to contact the high explosives sandwiched between the steel plates, and the incoming jets perform high performance before colliding with the reactive armor sandwich. Explosives are detonated and one or more of the metal plates are fired at the incoming jet. The triggering screen is behind the striking surface to prevent accidental activation by elements other than the HEAT jet.

It should be noted that the striking surface of all or any of the above reactive armor modules may be composed of rigid metal elements such as steel, titanium, ballistic aluminum and all kinds of metal alloys. Further, the striking surface may be made of a rigid material such as alumina or boron carbide. Further, the striking surface may be composed of various polymers such as aramid and dinema. Further, the striking surface may be made of compressed fibers such as glass and carbon fibers. Each of the above materials may be combined or replaced by a striking surface, as described in the drawings shown as steel in the drawings.

FIG. 13 shows another embodiment of the present invention. The blast lens is actuated by a triggering screen and is therefore used to defeat incoming HEAT jets with or without a liner (known in the art). To better direct the blast wave, the cross-sectional shape of the lens can be triangular (shown in the figure), spherical, or other shape.

FIG. 14 shows a combination of particle-based reactive armor and the reactive armor 721 described in FIG. Triggering screens are provided on each of the reactive armor modules 720 and 721. Both of the two triggering screens allow the reaction module to operate in a timed blast sequence.

Although some embodiments of the present invention have been described as examples, the present invention has many modifications, modifications, and conformances without departing from the spirit of the invention or beyond the scope of the claims. It can be put to practical use using many equivalents or alternative solutions in the form and within the scope of those skilled in the art.

Claims (33)

The front layer of armor and
A particle layer containing multiple particles and
A first explosive layer adjacent to the rear of the particle layer,
A reactive armor module comprising the rear layer of armor.
The particle layer extends between the anterior layer and the first explosive layer.
The first explosive layer is triggered by a first explosion in the front layer from an incoming warhead, explodes towards the adjacent particle layer and ejects the plurality of particles forward .
The first explosive layer is disposed all particles of the particle layer so as to be able to exit reliably outwardly of the front layer, thereby interfering with the second explosion from the warhead, the reaction Armor module. The reactive armor module of claim 1, further comprising a second explosive layer between the particle layer and the anterior surface layer. The reactive armor module according to claim 1, wherein the plurality of particles in the particle layer are separated by a spacer. The reactive armor module according to claim 3, wherein the plurality of particles include rigid particles. The reactive armor module according to claim 3, wherein the plurality of particles are shaped into one of a spherical particle, a cylindrical particle, and a particle in which a plurality of shapes are combined. The reactive armor module of claim 1, wherein the first explosive layer is shaped to direct the explosion of the first explosive layer, thereby forming a directional particle cloud. The reactive armor module of claim 1, wherein the armor layer comprises one member of steel, ballistic aluminum, titanium, aluminum, a polymer, and a combination of a polymer and a rigid material. .. The reactive armor module of claim 1, which is provided on the armored vehicle in the vicinity, in front of, or behind another reactive module. The reactive armor module of claim 3, wherein the spacer comprises an energy absorbing material. The reactive armor module of claim 8, which is separated from the other reactive module. The reactive armor module according to claim 1, further comprising a rigid body layer between the first explosive layer and the particle layer. The reactive armor module of claim 1, wherein the high performance explosive charge is mixed with the plurality of particles in the particle layer. The reaction of claim 1, further comprising a casing, wherein the cross-sectional structure of the casing is designed to induce the energy of the explosion of the first explosive layer to achieve the desired particle cloud vector and shape. Armor module. The reactive armor module of claim 11, wherein the first explosive layer is shaped into a curved shape. 13. The reactive armor module of claim 13, wherein the casing is molded or curved. The reactive armor module of claim 1, wherein a rigid material is placed on a portion of the first explosive layer, thereby creating a staggered explosion between the plurality of particles ejected. The reactive armor module of claim 16, wherein the rigid material comprises a geometric element. The geometric element comprises a pyramid-shaped element inserted between the particles of the particle layer, the pyramid-shaped element having a tip portion, and the tip portion facing toward the first explosive layer. The reactive armor module according to claim 17. The reactive armor module of claim 1, further comprising an additional front layer in front of the front layer of the armor. The additional front layer comprises a trigger, which activates the first explosive layer by the impact of a HEAT jet coming into the trigger by electronic signaling and one of subsequent blasts, the continuation. 19. The reactive armor module of claim 19, wherein the resulting blast comprises an explosive mounted on the additional front layer. 20. The reactive armor module of claim 20, wherein the trigger is configured to trigger the triggering of the first explosive layer prior to impact by the HEAT jet. The reactive armor module of claim 1, wherein the first explosive layer is shaped to explode with a plurality of explosive centers. The reactive armor module of claim 1, further comprising a proximity fuze or proximity sensor. The reactive armor module of claim 1, wherein the first explosive layer is shaped to direct the explosion of the first explosive layer using the Monroe effect. 24. The reactive armor module of claim 24, further using a blast lens. The reactive armor module of claim 1, comprising four explosive layers that separate the three particle layers. The reaction according to any one of claims 1 to 26, comprising a triggering element and a delay element, wherein the delay element delays the explosion and waits for the second explosion of the warhead. Armor module. The triggering element
(A) Battery,
(B) Capacitor,
(C) Inductive circuit,
(D) An electromechanical element that moves a pendulum type element in an electromagnetic field to generate electricity, and the electricity is supplied to a capacitor or a battery.
(E) Piezoelectric element,
(F) The reactive armor module of claim 27, wherein the voltage is supplied by one member of a chemical or metal. The blast of the first explosive layer is directed into the rigid particle body of the particle layer, the rigid particle body is arranged in a predetermined structure, and the blast of the first explosive layer causes the structure to collapse internally. The reactive armor module according to claim 1, wherein a plurality of multi-directional motion impacts are applied to the flying jet, thereby deforming the flying jet. 29. The reactive armor module of claim 29, wherein the predetermined structure comprises at least one extension along the side plate of the reactive armor module. 30. The predetermined structure comprises two extensions along two opposing side plates of the reactive armor module, the explosion being triggered at a location other than the center between the two extensions. Reactive armor module described in. The reactive armor module according to claim 1, wherein the second reactive armor module is combined with the second reactive armor module.
The second front layer of armor and
The second back layer of armor and
A third explosive layer between the second front layer and the second back layer,
Equipped with a triggering mechanism
The third explosive layer is triggered by the triggering mechanism after a certain delay in the first explosion of the incoming warhead facing into the second front layer to bring the second front layer. The reactive armor module of claim 1, which ejects and interferes with a second explosion from the warhead. The front layer of armor and
A particle layer containing multiple particles and
A first explosive layer adjacent to the rear of the particle layer,
With the rear layer of the armor
Reactive armor module with
The particle layer extends between the anterior layer and the first explosive layer.
The first explosive layer is triggered by a first explosion in the front layer from an incoming warhead, exploding towards the adjacent particle layer and ejecting the plurality of particles forward.
The blast of the first explosive layer is directed at the rigid particles of the particle layer.
The rigid particle body is arranged to have a predetermined structure, the predetermined structure includes at least one extension along the side plate of the reactive armor module, and the blast causes internal rupture of the predetermined structure. A reactive armor module that applies a multi-directional mechanical impact to an incoming jet, thereby deforming the incoming jet.