RU2537355C1 - Method for packing parachute and fastened to it container with useful equipment into grenade body head and device for packing parachute and fastened to it container with useful equipment into grenade body head - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: proposed set of inventions relates to military equipment, namely to method and means for parachute and fastened to it container packing. Method for packing parachute and fastened to it container with useful equipment into grenade body head includes packing of parachute canopy, shroud lines and metal extension (if present) into grenade body head. When parachute canopy is packed it is used to form dome in the grenade body head by means of special appliance. The major portion of canopy material is placed at side wall of dome. Portion of shroud lines of parachute adjacent to its canopy is wound as spiral onto the rod placed in concavity of dome. Appliance for packing parachute and fastened to it container with useful equipment into grenade body head is formed by body which consists of two coaxial and installed one inside the other bushings and by rod freely accommodated in the channel of inner bushing. On the outer bushing, at its front butt end on the outside fascia is made which centres it in grenade body head. On the inner bushing, at the side of its front butt end, outer diametrical lowering is made on which radial-longitudinal grooves are made which are symmetric to end slots of outer bushing and spaced from front butt end of inner bushing by minimum distance.

EFFECT: higher reliability of parachute deployment.

3 cl, 4 dwg

Description

The proposed group of inventions relates to the field of military equipment, and in particular to a method and means of laying a parachute and a container attached with it with useful equipment of a small grenade into the head of its body, but can be used for the specified purpose in the production of ammunition of almost any caliber.

Known cartridges, useful grenade equipment of which descends by parachute from a certain height to the ground, are used mainly for aerial reconnaissance and lighting of the terrain.

The first include American air reconnaissance systems: Hunter, in which the M1070 Hunter cartridge is fired from a hand grenade launcher, and a mine created on the basis of an illuminating mine and fired from an 81-mm mortar, which are described in Foreign Military Review, 2011, No. 4, p. 45-53.

They consist of appropriate ammunition and a mini computer or laptop. The ammunition contains parachutes and containers fastened with its slings with an IR (photo) video camera, transmitter and power source. At the required height, the ammunition of these systems is opened, their containers with useful equipment are lowered by parachutes and they shoot and transfer the terrain beneath them to a microcomputer or laptop, respectively. Otherwise, the ammunition of airborne reconnaissance systems is structurally similar to the American lighting cartridges M583A1, M661 and M662, M676, M680 and M682 and MK583A1 described in the "Jane's Ammunition Handbook Edited by Terry J Cander and Charles Q Cutshaw Ninth Edition 2000-2001" on page 572 , 573 and 574, respectively.

Lighting cartridges are fired from hand grenade launchers and have almost the same device. They consist of a sleeve with a propelling charge and a grenade, the body of which is formed by a bottom metal part in the form of a glass, in the bottom of which there is a pyrotechnic moderator and an expelling charge, and a plastic head connected to it by a destructible bond. A parachute and useful equipment in the form of a pyrotechnic end-combustion composition enclosed in a container are placed in the body cavity. The container is connected to the parachute slings through a metal extension in the form of a chain, which protects the canopy from exposure to high-temperature combustion products of the pyrotechnic composition. A parachute with slings and a chain is placed in the head of the hull, and a container with a pyrotechnic composition is located in its bottom.

The disadvantages of the above ammunition of airborne reconnaissance systems and lighting cartridges (any of which can serve both as an analogue and as a prototype of the present invention, for example, the M661 lighting cartridge) are in frequent failure to open parachutes or in their slow disclosure, which leads to a complete failure of ammunition or to a significant reduction in the time of shooting the terrain or its lighting. These shortcomings are caused by the manual arbitrary laying of the parachute and the container with useful equipment separately in the limited volumes of the head and bottom parts of the grenade body, as a result of which the chain, slings and the edges of the parachute dome adjacent to the slings can overlap each other and, in this position, be crammed during a long storage. This is exacerbated by the humidity of the slings and the canopy of the parachute and the high probability of leaks in the small joint of the grenade body parts.

The objective of the present proposed group of inventions is to eliminate the disadvantages of known cartridges with parachute useful equipment, namely, ensuring reliable disclosure of the parachute and reducing the time of its disclosure due to the uniform and most optimal placement in the head of the grenade body.

The solution of the problem according to the group of proposed inventions is achieved by the fact that:

- in the method of laying the parachute and the container attached with it with useful equipment to the head of the grenade body, which includes laying the canopy of the parachute, then the sling, and if there is a metal extension cord in the head of the grenade, it is new that when putting the canopy of the canopy from it into the head part of the grenade body with the help of a device forms a cap, while the main part of the dome material is placed at the side wall of the cap, after which the part of the parachute line adjacent to its dome is wound in the form of a spiral on the rod b, placed in the cavity of the cap, and at the same time as the rod is removed from the cavity of the cap, the part of the parachute lines wound in a spiral form is placed in it, and then the rest of the parachute lines, the metal extension cord and a useful container equipment

- laying is carried out using a device for laying a parachute and a container connected to it with useful equipment in the head of the grenade body, formed by a body consisting of two coaxial and installed one in the other bushings, and a rod freely placed in the channel of the inner sleeve, and on the outer sleeve at its front end, a belt is made outside, centering it in the head of the grenade body, the height of which is greater than the thickness of the parachute slings, and the end grooves evenly spaced around its circumference sectional belt and having a width greater than the thickness of the parachute slings, and on the inner sleeve from the front end side, an outer diametrical reduction is made, on which radial-longitudinal grooves are made, symmetrical to the end grooves of the outer sleeve and spaced apart from the front end of the inner sleeve at a minimum distance, and placed flat springs located above the radial-longitudinal grooves, fastened at one end with a diametrical reduction of the inner sleeve behind the radial-longitudinal grooves and passing the second ends to the end wall of these grooves at the front end of the inner sleeve, where they are elastically pressed against the inner surface of the outer sleeve, while the inner sleeve is spring-loaded relative to the outer one and mounted with the possibility of longitudinal movement in the direction of its front end by an amount equal to or greater than the depth of the end grooves of the outer sleeve, and the length of the rod installed in the channel of the inner sleeve is made greater than the sum of the length of the device body and the radius of the canopy of the parachute.

In a particular case:

- when a parachute is used in a grenade with inertial loads placed on its slings near the dome at the base of the end grooves of the outer sleeve of the device, through radial holes are made, the diameter of which exceeds the diameter of the inertial loads and which are separated from the end walls of the radial-longitudinal grooves by the front end, at a distance, more than half the diameter of inertial loads.

The essence of the invention is illustrated by drawings, in which Fig. 1 shows a device with a conventional parachute attached to it, in Fig. 2 - callout A in Fig. 1 for a parachute equipped with inertial loads in the form of balls fixed on its slings at the canopy of the parachute, in Fig. .3 - a parachute mounted in the head of the grenade, and in Fig.4 - the head of the grenade with a parachute in it.

The device (Fig. 1) consists of an external sleeve 1, coaxial with it and installed in its channel of the internal sleeve 2, which form the body of the device, and a rod 3, freely installed in the channel of the internal sleeve 2.

On the outer sleeve 1 outside the front end there is a belt 4, the height of which is greater than the thickness of the lines of the parachute 5, and the end grooves 6 in an amount equal to the number of lines of the 5 parachute, evenly distributed around the circumference of the outer sleeve 1, intersecting the belt 4 and having a width greater than the thickness of the lines 5 parachutes. On the inner sleeve 2, from the front end side, an outer diametrical decrease is made 7, on which radial-longitudinal grooves 8 are made, spaced from the front end at the minimum possible distance, which is determined by the technological capabilities of the equipment for their manufacture. The radial-longitudinal grooves 8 are made symmetrical with respect to the end grooves 6 and above them are flat springs 10, which are fixed at one end to the diametrical lowering 7 of the inner sleeve 2, for example with screws 11, and the other end extend to the end wall 9 of the radial-longitudinal grooves 8, where they are elastically pressed to the inner surface of the outer sleeve 1 on both sides of the end grooves 6 in it. An annular protrusion 12 is made at the rear end of the inner sleeve 2, a compression spring 13 is installed between the rear end of the outer sleeve 1 and the bushings 1 and 2 are kept from turning relative to each other by any known method, for example, a screw 14 screwed into the wall of the outer sleeve 1. End the screw 14 is placed in a longitudinal groove 15, made on the inner sleeve 2 and having a length that allows you to move the inner sleeve 2 relative to the outer sleeve 1 towards the front end by an amount equal to or greater than the length of the end grooves 6.

Attaching a parachute to the device is as follows. The parachute slings 5 are alternately inserted into the end slots 6 with one hand and held in this position, at the same time the edges of the canopy 16 against the slings 5 with the other hand are pulled into the interference axis with the other hand and for the slings 5 the edges of the parachute canopy are pulled into the gap between the inner surface of the outer sleeve 1 and pressed while the flat springs 10.

If the parachute slings 5 have inertial loads 17 made in the form of metal balls with a diameter of 18 (see FIG. 2), then radial holes 19 are made in the base of the end grooves 6 in the outer sleeve 1, the diameter of which is slightly larger than the diameter of the 18 inertial loads 17 and which spaced from the front end walls 9 of the radial-longitudinal grooves 8 at a distance of 20, slightly larger than half the diameter of 18 inertial loads 17. The parachute is attached to the device in this case in the following order. The inertial loads 17 together with the slings 5 are alternately installed with one hand in the holes 19, recessed in them in the radial direction to the axis of the device, and with the other hand for the canopy 16 parachute pull the loads 17 into the radial-longitudinal grooves 8 until they stop in their front end walls 9.

Laying the parachute in the head part 21 of the grenade body (see figure 3) is done by installing the device with the parachute forward until it stops with the external sleeve 1 of the device in the annular protrusion 22 of the head part. Then, along the arrow 23, the inner sleeve 2 is moved towards the head part 21 by the length of the longitudinal groove 6. The front end of the inner sleeve 2, crushing the canopy 16 of the parachute, is advanced forward along with the edges 24 of the canopy parachute or with inertial weights 17 and the flat springs 10 are pushed out the edges 24 of the canopy of the parachute or the loads 17 in the radial direction from the device. After that, the body of the device, formed by the outer 1 and inner 3 bushings, is removed from the head part 21 of the grenade and along the rod 3 is removed from it.

After that (see Fig. 4), the slings 5 are wound in a spiral manner onto the rod 3. After winding the part of the slings 5, the rod 3 is removed with one hand from the head part 21 of the grenade, releasing the parachute cavity 27 in the dome 16, and at the same time the wound slings 5 are moved by the second hand along the rod 3 in the direction of the head part 21 of the grenade, occupying the vacant cavity 27. Next, in the cavity of the head part 21 of the grenade body, the rest of the slings, extension cord 25 and container 26 with useful equipment are placed. The head part 21 of the grenade with a parachute laid in it, an extension cord 25 and a container 26 is ready for attaching the bottom of the grenade to it.

From the description of the device of the device and the method of laying with its use a parachute and a container connected to it, including through a metal extension cord, into the head of the grenade body of the present invention, it is seen that:

- the dome of the parachute takes the shape of a cap in the head of the grenade, where its material is concentrated mainly near the side wall of the cap, and the slings of the parachute are partially located in the cavity of the cap formed by the dome of the parachute;

- it is obvious that such a mutual arrangement of the canopy and the sling of the parachute, as well as the metal extension cord, will be preserved under all conditions of mechanical and climatic effects on the grenade;

- when the parachute and the container with useful equipment are ejected from the grenade body, they acquire different speeds, so the slings and the metal extension cord are removed from the cavity of the canopy of the parachute and this cavity becomes an air intake cavity, which contributes to the reliable and quick opening of the parachute;

- if the grenade is stabilized by rotation, then the concentration of the main part of the dome at the side wall of the cap formed by it due to centrifugal force accelerates the process of opening the canopy of the parachute in the radial direction. It is obvious that the presence of inertial loads on the slings of the parachute at its dome will further increase the reliability of the opening of the parachute and significantly reduce the time of this process.

Claims (3)

1. The method of laying the parachute and the container attached with it with useful equipment to the head of the grenade body, including laying the canopy of the parachute, then the sling, and if there is a metal extension cord in the head of the grenade, characterized in that when putting the canopy of the canopy from it into the head parts of the grenade body with the help of a device form a cap, while the main part of the dome material is placed at the side wall of the cap, after which the part of the parachute line adjacent to its dome is wound in a spiral shape on the rod, placed in the cavity of the cap, and simultaneously with removing the rod from the cavity of the cap, place the part of the parachute line wound in a spiral form into it, and then the rest of the line of the parachute, a metal extension cord and a container with useful equipment, are placed in the cavity of the head of the grenade body. 2. A device for storing a parachute and a container connected with it with useful equipment in the head of the grenade body, formed by a body consisting of two coaxial and installed one in the other bushings, and a rod freely placed in the channel of the inner sleeve, and on the outer sleeve at its front the end has a belt made outside, centering it in the head of the grenade body, the height of which is greater than the thickness of the parachute slings, and end grooves evenly spaced around its circumference, intersecting the belt and having a width of more than the thickness of the parachute sling, and on the inner sleeve from the front end side, an external diametrical reduction is performed, on which radial-longitudinal grooves are made, symmetrical to the end grooves of the outer sleeve and spaced at a minimum distance from the front end of the inner sleeve, and flat springs located above the radially - longitudinal grooves, fastened at one end with a diametrical lowering of the inner sleeve behind the radial-longitudinal grooves and passing the second ends to the end wall of these grooves at the front its end face of the inner sleeve, where they are elastically pressed to the inner surface of the outer sleeve, while the inner sleeve is spring-loaded relative to the outer one and installed with the possibility of longitudinal movement in the direction of its front end by an amount equal to or greater than the depth of the end grooves of the outer sleeve, and the length of the shaft installed in the channel of the inner sleeve, made more than the sum of the length of the body of the device and the radius of the canopy of the parachute. 3. The device according to claim 2, characterized in that when using a parachute in a grenade with inertial loads placed on its slings near the dome at the base of the end grooves of the outer sleeve, through radial holes are made whose diameter exceeds the diameter of the inertial weights and which are radially spaced from the end walls - longitudinal grooves from the front end at a distance greater than half the diameter of the inertial loads.

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