RU59794U1 - NETWORK THROWING DEVICE - Google Patents

Abstract

The utility model relates to non-lethal weapons, in particular to devices for catching biological objects by throwing a net and can be used to protect public order, as well as when catching domestic and wild animals and birds. The technical task to be solved is to increase the efficiency of the device for throwing the net, to obtain the ability to equip the device for throwing the net both close and long distance, by adjusting the distance to the caught biological objects, taking into account the conditions of their location, including those located nearby living creatures and objects, increasing the safety of using the device for captured objects and their living creatures. A device for throwing a network is proposed, which comprises a sleeve with a blanked end and means for ejecting the network from the channel of the sleeve located on the side of the blanked end of the sleeve, a network in the folded state and loads for opening it attached to the network perimeter. What is new is that the sleeve further comprises a wad placed between the network ejection means and the folded network in which the loads are installed, and including means for pushing the goods in radial directions outside the open end of the sleeve. The device has the ability to equipment for throwing the network both close and long distance. 22 C.p.F., 6 ill.

Description

The utility model relates to non-lethal weapons, in particular to devices for catching biological objects by throwing a net and can be used to protect public order, as well as when catching domestic and wild animals and birds.

A device for throwing a network is known, comprising a housing inside which there is a gas expansion energy source, a network in the folded state and means for opening it in the form of weights secured around the network (patent JP 2002-355323, publ. 10.12.2002). With the expansion of gas, the network flies out of the outlet of the housing, opens under the action of flying cargo, covers a nearby biological object caught and gets entangled in it. The main disadvantages of the known device are its small radius of action, the inability to use it over a long distance, which limits its scope, low efficiency, since the configuration, size and location of the captured object are not taken into account, as well as the increased danger when using the device in cramped conditions in the presence of extraneous creatures and objects surrounding the object.

Also, a device for throwing a network is known, comprising a housing made in the form of a projectile with a removable head, inside of which there is a source of gas expansion energy in the form of a powder charge, a network in the folded state and means for opening it in the form of weights fixed around the perimeter of the network (patent FR 859282, publ. 12/14/1940). When approaching a captured biological object, under the influence of an ignited powder charge, the projectile head detaches, freeing the path of the network, which flies out of the shell and opens in flight with flying loads, covers the object and gets tangled up on it. The main disadvantages of the known device is the limited scope of its application, the inability to use it at close range, as well as low efficiency and increased danger to others, since the projectile is thrown at a fairly large distance without taking into account the terrain, the configuration of the biological object, its size and location relative to the horizontal surface and the surrounding creatures and objects.

As a prototype, a device for throwing a network was adopted, comprising a housing inside which there is a gas expansion energy source, a network in the folded state and a means for opening it in the form of weights secured around the network perimeter (patent CA 2162221, publ. 08.05.1996). When approaching a captured biological object

the gas expansion energy source is triggered, the gas expands, fills the internal space of the body, from the excess pressure of the gas, the front of the body is destroyed, the network flies out of the shell and opens with cargoes flying apart, covering the object and entangling on it. The main disadvantages of the known device is the limited scope, the inability to use at close range, low efficiency and increased danger to others, since the projectile is thrown at a fairly large distance without taking into account the terrain, the configuration of the biological object, its size and location relative to the horizontal surface and other creatures and objects surrounding it.

The technical task to be solved is to increase the efficiency of the device for throwing the net, to obtain the ability to equip the device for throwing the net both close and long distance, by adjusting the distance to the caught biological objects, taking into account the conditions of their location, including those located nearby living creatures and objects, increasing the safety of using the device for captured objects and their living creatures.

This problem is solved by the proposed device for throwing a network, containing a sleeve with a blanked end and means for ejecting the network from the channel of the sleeve located on the side of the blanked end of the sleeve located in the sleeve, the network in the folded state and loads for opening it attached to the perimeter of the network. What is new is that the sleeve further comprises a wad placed between the network ejection means and the folded network in which the loads are installed, and including means for pushing the goods in radial directions outside the open end of the sleeve. Means of ejecting the network can be of any design, for example, in the form of an energy source of expanding gas, including powder. The network opens faster if the means of pushing the goods includes radial slots for installing goods on a sliding landing, which have outlet openings on the side generatrix of the wad and inlet openings in communication with the space between the wad and the means of pushing the net. The wad may be made of a polymeric material, for example, fluoroplastic. The device works better if the loads are installed in the slots, made in the wad according to the number of loads, while the loads are more convenient to be placed in the wad if the slots have a round cross section, and the loads have, respectively, a cylindrical shape with a rounded front part or a spherical shape. To accelerate the operation, the means of ejection of goods may contain coil springs, which spring loads, installed in a wad in a radial

direction. It is better when the loads are spring-loaded in a wad so that they abut against the inner side walls of the liner, also, the loads can be spring-loaded in a wad in a different way, for example, so that the loads first abut in an intermediate ring, worn on a sliding wedge along its side forming and inserted into the channel of the sleeve, and the ring is made with the ability to jump off the wad outside the open end of the sleeve. The cargo ejection means may comprise a trigger element in the form of a central rod protruding from the front of the folded network, which allows the ring to jump off the wad when the protruding part of the central rod hits an obstacle. It is better if a fairing is made on the protruding part of the starting element, which allows for accurate throwing of the network. The central rod can be made telescopic in such a way that it can be moved apart after the network is ejected from the sleeve, in this case it is also possible to use the opening plumage mounted on a wad to stabilize the flight of the network. The ring can also be made in the form of a glass, including the bottom and side wall, when the ring can be worn on the wad on the inner surface of its side wall and can be inserted into the channel of the sleeve on the outer surface of its side wall, and the inner surface of its bottom can be in contact with the end part of the wad facing the means of ejecting the network, and the starting element can be made in the form of a central rod located along the longitudinal axis of the sleeve channel, which can pass along the sliding fit of the well communicating the central through hole in pyzhe and is connected with the bottom, wherein the network is in the folded state it can be placed between the wad and the free end of the central rod. It is better if the central rod passes through the central cell of the folded network. The loads can be spring-loaded in a wad so that they abut against the shell, which can be worn on the wad along its lateral generatrix and inserted into the channel of the sleeve, and the folded network can be placed inside the shell, and the shell is made with the possibility of breaking outside the open end of the sleeve so to free loads and a stacked network. It is better if the means of pushing the cargo contains a central rod located along the longitudinal axis of the sleeve channel, which passes along a sliding fit through the central through hole in the wad, while the free end of the central rod extends beyond the shell with the network inside it and is equipped with an element made with the ability to destroy the shell upon impact of the free end of the rod or element against an obstacle. Loads can be made of the same mass and shape, and installed in wad evenly on the same diameter. It is better if the sleeve is made cylindrical with a cylindrical inner channel. Cargoes may be

attached to the perimeter of the network using slings. It is better if the wad thickness is at least 1/3 of its diameter. The open end of the sleeve may be closed by an easily flush cover.

The proposed utility model is illustrated by graphic materials. Figure 1 shows a longitudinal section of a device equipped for throwing a network at close range, and figure 2 shows a cross section of a device at the location of the wad. Figure 3 shows a longitudinal section of the first variant of the device, equipped for throwing a network over a long distance, and figure 4 shows a cross section at the location of the wad. Figure 5 shows a longitudinal section of the second variant of the device, equipped for throwing a network over a long distance, and figure 6 shows a cross section at the location of the wad.

The proposed utility model is represented by three examples of a specific implementation of the device.

Example 1. A device equipped to throw a network at close range.

The device for throwing the network (see figure 1 and figure 2) contains an aluminum sleeve 1 of a cylindrical shape with an inner diameter of 135 mm At the rear end of the sleeve 1, a removable plug 2 is installed on the thread. In the sleeve 1 from the side of the plug 2 is inserted a can of compressed gas (not shown in the drawing), which is separated from the network 3, when folded, wad 4, made in monolithic execution of molding fluoroplastic. The diameter of wad 4 is equal to the inner diameter of the sleeve 1 and is 135 mm, respectively, the minimum thickness of wad 4 is 135 mm: 3 = 45 mm. Along the edges of wad 4 there are four round-section nests 5 radially located in the middle of its thickness, designed to install loads 7. The minimum diameter of nests 5 is 45 mm: 3 = 15 mm, and the depth of nest 5 is 90 mm: 3 = 30 mm The weights 7 are made of lead, have a cylindrical shape with a rounded front part and are attached to the perimeter of the folded network 3 using slings 8. The sockets 5 for installing goods 7 are connected through passage channels 6 of the same length for the passage of expanding gases from the can (not shown). When the device is equipped, loads 7 are installed in the slots 5 of the wad 4, after which the wad 4 with the loads 7 placed in it is inserted through the open end into the sleeve 1 until it stops on the protruding edges of the plug 2, then the wad 3 is laid down on the wad 4 in the folded state, after which the open end of the sleeve 1 from the side of the folded network 4 is closed by a flat cover 9. Then, the removable plug 2 is unscrewed and a can of compressed gas (not shown) is installed through the back of the sleeve 1, and the plug 2 is screwed into place. When actuating a gas spray, the gases expand

and press on the surface of wad 4, which under their influence begins to move to the open part of the sleeve 1, pushing the folded network 3. At the same time, expanding gases penetrate through channels 6 into the nests 5, in which the loads 7 are installed and exert pressure on the back of the cylindrical loads 7. When leaving the open end of the sleeve 1, under the action of expanding gas, the goods 7 fly out of the nests 5 and carry the network 3 along, spreading it in flight, while the network 3 continues to move in the direction of the caught biological object located closeup, cover it and twists it, depriving it of the ability to move.

Example 2. A device equipped to throw a network over a long distance.

The design of the device (see Fig. 3 and Fig. 4) is similar to Example 1, except that the loads 7 installed in the sockets 5 are spring-loaded with coil springs 10, and in the center of the wad 4 there is a through hole in which it is slidably mounted the central rod 11 passing through the central cell of the folded network 3, at an equal distance from its edges. In order to more efficiently open the network 3 when approaching the object to be caught and impact on its body, there is a cone-shaped extension 12 on the free end of the central rod 11. To avoid damage to the biological object being caught by flying loads 7, the extension angle 12 relative to the axis of the rod 11 should not be less than 45 °. The folded net 3 has a shell 13, one edge of which goes to the wad 4 with a margin of 45 mm: 3 · 2 = 30 mm to cover the spring-loaded loads 7. The central rod 11 projects from the open part of the sleeve 1 by 40 mm, which upon impact ensures that the shell 13 jumps off the edges of the wad 4 when the free end of the rod 11 hits the body of the target object, its destruction, and the unimpeded departure of goods 7 from the nests 5 under the influence of expanding springs 10. The open part of the sleeve 1 and the extension 12 of the guide rod 11 protruding from it closes lay down of discharged cover 14 shaped as a hemisphere. When the device is equipped, loads 7 are inserted into the slots 5 of the wad 4, attached with the help of slings 8 to the network 3, while they are pressed into the slots 5 with their fingers so that they fully enter them and compress the springs 10 located in the slots 5, after which the wad 4 sec installed weights 7 is inserted into the open part of the sleeve 1 until it stops on the inner protrusions of the plug 2, then the folded network 3 in the shell 13 with straightened slings 8 and inserted through its Central cell and the shell 13 guide rod 11 is laid on wad 4, while in the hole, located at the center of the wad 4, the thin end of the guide rod 11 is slidably inserted so that its free end with the extension 12 protrudes from the open part of the sleeve 1, which then

closed by a cover 13, made in the form of a hemisphere. When activating a gas spray (not shown in the drawing), expanding gases press on the surface of wad 4, which, together with the folded network 3 installed in it, in the shell, under their influence, begins to move to the open part of the sleeve 1, pushing the folded network 3 in the package with inserted rod 11 outward and directed towards the caught biological object. When approaching and hitting the free end of the rod 11 against the body of the object being caught, the package 13 jumps off the wad 4 and breaks when sliding along the rod 11 and bumps into the extension 12, at the same time under the influence of expanding springs 10, the loads 7 fly out of the nests 5 and carry the network 3, spreading it in flight, while the network 3 continues to move in the direction of the caught biological object located at a long distance, hits it with extension 12, wad 4 begins to slide along the guide rod 11 to extension 12, Cell 13 is torn, goods 7 fly out of the nests and carry the network 3 along, spreading it in flight towards the object to be caught, covering it and spinning on it, depriving it of the ability to move.

Example 3. A device equipped to throw a network over a long distance.

The design of the device (see Fig. 5 and Fig. 6) is similar to Example 2, except that on the wad 4 a metal ring 15 in the form of a cup is slidably slid so that it overlaps the sockets 5 with the spring loaded loads 7 installed in them. 7. Loads 7 are spring-loaded in wad 4 so that they abut against the ring 15, worn in sliding fit on wad 4 along its lateral generatrix and inserted into the channel of the sleeve 1, the ring 15 being able to jump off the wad 4 outside the open end of the sleeve 1. Means pushing cargo 7 contains start th element in the form of a central rod 11 projecting beyond the front of the folded network 3 allowing the ring 15 to jump wad 4 when hitting protruding part of the central rod 11 against an obstacle. In the center of the wad 4 there is a through hole in which the central rod 11, which passes through the central cell of the folded network 3, is installed with the possibility of slipping, at an equal distance from its edges. In order to more efficiently open the network 3 when approaching the object to be caught and impact on its body, there is a cone-shaped extension 12 on the free end of the central rod 11. To avoid damage to the biological object being caught by flying loads 7, the extension angle 12 relative to the axis of the rod 11 should not be less than 45 °. When the device is equipped, loads 7 are inserted into the slots 5 of the wad 4, attached with the help of slings 8 to the network 3, while they are pressed into the slots 5 with their fingers so that they fully enter the slots 6 and compress the slots 6

springs 7, after which a ring 15 is put on wad 4 with the installed loads 7, which blocks the loads 7 installed in the sockets 5 on the compressed springs 10. The wad 4 equipped in this way is inserted into the open part of the sleeve 1 until it stops against the inner protrusions of the plug 2, then a folded network 3 with straightened slings 8 and a central rod 11 inserted through its central cell is placed on the wad 4, while the thin end of the rod 11 is inserted with the possibility of sliding into the hole located in the center of the wad 4 so that it is free the end with the extension 12 protruded from the open part of the sleeve 1, which is then closed by a lid 13, made in the form of a hemisphere. When activating a gas spray (not shown), expanding gases press on the surface of the bottom of the ring 15, worn on wad 4, which transfers the force of expanding gases onto it, resulting in wad 4, together with the folded network 3 and rod 11 installed on it, begins to move to the open part of the sleeve 1, pushing the folded network 3 with the inserted rod 11 outward towards the trapped biological object. When approaching and hitting the free end of the rod against the body of the object to be caught, ring 15 jumps off wad 4, while under the influence of expanding springs 10, loads 7 fly out of nests 5 and carry network 3 along, spreading it in flight, while network 3 continues to move in the direction a captured biological object, covers it and spins on it, depriving it of the ability to move.

Claims (23)

1. A device for throwing a net, comprising a sleeve with a blanked end and means for ejecting the net from the channel of the sleeve located on the side of the blanked end of the sleeve, a net in the folded state and loads for opening it attached to the perimeter of the net, characterized in that the sleeve further comprises a wad placed between the network ejection means and the folded network in which the loads are installed, and including means for pushing the goods in radial directions outside the open end of the sleeve. 2. The device according to claim 1, characterized in that the means of ejecting the network is an energy source of expanding gas. 3. The device according to claim 2, characterized in that the means of ejecting goods includes radial jacks for installing goods on a sliding landing, having outlet openings on the side generatrix of the wad and inlet openings in communication with the space between the wad and the means of ejecting the network. 4. The device according to claim 1, characterized in that the wad is made of polymer material. 5. The device according to claim 4, characterized in that the wad is made of fluoroplastic. 6. The device according to claim 1, characterized in that the goods are installed in sockets made in wad according to the number of goods. 7. The device according to claim 6, characterized in that the nests have a circular cross section. 8. The device according to claim 7, characterized in that the goods have a cylindrical shape. 9. The device according to claim 7, characterized in that the goods have a spherical shape. 10. The device according to claim 6, characterized in that the means of ejecting loads includes coil springs that spring loads in the wad in a radial direction. 11. The device according to claim 10, characterized in that the loads are spring-loaded in wad so that they abut against the inner side walls of the sleeve. 12. The device according to claim 10, characterized in that the loads are spring-loaded in a wad so that they abut against a ring worn on a sliding fit on the wad along its lateral generatrix and inserted into the sleeve channel, the ring being made to jump off the wad outside open end of the sleeve. 13. The device according to p. 12, characterized in that the means of pushing the goods contains a trigger element that protrudes in front of the folded network, allowing the ring to jump off the wad when the protruding part of the trigger element hits an obstacle. 14. The device according to item 12, wherein the fairing is made on the protruding part of the starting element. 15. The device according to p. 12, characterized in that the ring is made in the form of a glass, including the bottom and side wall, and the ring is worn on the wad on the inner surface of its side wall and inserted into the channel of the sleeve on the outer surface of its side wall, and the inner surface its bottom is in contact with the end part of the wad facing the network ejection means, and the starting element is made in the form of a central rod located along the longitudinal axis of the sleeve channel, which passes along the sliding fit through the central squee a large hole in the wad and connected to the bottom, while the network in the folded state is placed between the wad and the free end of the Central rod. 16. The device according to p. 15, characterized in that the Central rod passes through the Central cell of the folded network. 17. The device according to claim 10, characterized in that the loads are spring-loaded in wad so that they abut against the shell, which is worn on the wad along its lateral generatrix and inserted into the channel of the sleeve, and the folded network is placed inside the shell, and the shell is made with the possibility collapse outside the open end of the liner so as to release loads and a folded network. 18. The device according to 17, characterized in that the means of pushing the cargo contains a Central rod located along the longitudinal axis of the channel of the sleeve, which runs along a sliding fit through the Central through hole in the wad, while the free end of the Central rod extends beyond the shell with it has a network and is equipped with an element configured to destroy the shell upon impact of the free end of the rod or element against an obstacle. 19. The device according to claim 1, characterized in that the goods are made of the same mass and shape and are installed in the wad evenly on the same diameter. 20. The device according to claim 1, characterized in that the sleeve is cylindrical with a cylindrical channel. 21. The device according to claim 1, characterized in that the goods are attached to the perimeter of the network using slings. 22. The device according to claim 1, characterized in that the wad thickness is at least 1/3 of its diameter. 23. The device according to claim 1, characterized in that the open end of the sleeve is closed with an easily resettable cover.