RU2226255C2 - Method of increasing firing range of harpoon of underwater rifle and accuracy of hitting the target and device for realization of this method (versions) - Google Patents

Abstract

FIELD: small arms. SUBSTANCE: method includes setting dependence between velocity of harpoon of underwater rifle, diameter of spout-cavitator and flow rate of air per second, viz.: q = kV₀d², where V₀ is maximum velocity of harpoon at firing, m/s; d is diameter of spout- cavitator depending on ratio of maximum velocity of harpoon V₀ and diameter of spout-cavitator d equal to 1-10. Harpoon of underwater rifle is provided with end-piece with spout-cavitator in its front part. Inner cavity of body is made in form of receiver where piston is mounted; this piston dividing receiver into two cavities is connected with rod. In rear cavity of receiver there is charging valve and outlet hole for communicating this cavity with water medium; this hole is closed with stop valve on the outside. Through hole in the front cavity of receiver is used for receiving rod by its lesser diameter and its larger diameter of this rod shut-off this hole, thus forming check valve engageable with air supply passages. Air is fed to front cavity of receiver due to availability of large clearance between piston and receiver housing. Optimal ratio of maximum diameter of spout-cavitator and maximum diameter of end-piece body ranges from 0.5 to 1.5 and optimal ratio of distance between base of spout-cavitator and maximum diameter of end-piece body to this diameter ranges from 0 to 10. EFFECT: increased firing range; enhanced accuracy of hitting the target due to reduction of hydrodynamic resistance of harpoon moving in water medium and due to creation of steady axisymmetrical cavity around it. 6 cl, 2 dwg

Description

The invention relates to the field of sports equipment and relates to the issue of increasing the range of a spear spear gun and its accuracy in hitting a target.

There is a method of increasing the range of a spear gun’s harpoon by creating an air cavity around its body, which is formed during the movement of a harpoon in the aquatic environment, in which a streamlined pointed tip is installed in the bow due to the flow of water around the cavitator tip. Due to this, a part of the harpoon’s body moves while in the air cavity, experiencing significantly less resistance than when moving in an aqueous medium, and due to this, the range of movement of the harpoon in water increases. (Application of France No. 2458998, IPC ⁶ , A 01 K 81/06) .0 However, a cavity around the harpoon’s body is created only at high speeds at the initial moment after firing. In addition, it does not extend over the entire length of the harpoon body, so most of the harpoon body experiences friction resistance from the water side.

There is also known a method of increasing the firing range and accuracy of hitting a spear gun spear at the target of the Russian Federation application No. 95118762 from 04.11.95. IPC ⁶ A 01 K 81/06 (RF patent No. 2093983), according to which an air cavity around the harpoon body is created artificially by supplying compressed air from the harpoon cavity through channels formed in the harpoon nose body along the perimeter of the circle into the space behind the pointed cavitator - a tip mounted in the bow of a harpoon tip is a prototype. Due to this, the process of cavity formation is less dependent on the speed of the harpoon, the cavity becomes longer and covers a larger surface of the harpoon body than the cavity in the case of its natural formation. As a result, the range of the harpoon and the accuracy of its hit on the target increases.

Known harpoon for a speargun containing a housing that consists of a liner with a liner and a bow connected to a removable tip containing a flag pivotally mounted therein to hold the prey and made with a through central hole and air channels connected thereto for supplying air from the cavity the harpoon body into the space behind the pointed tip-cavitator placed in the said through hole, the harpoon body being hollow along the entire length (RF Patent 2093983) - prototype.

However, the known method and device have several disadvantages. So, the cavity around the harpoon’s body does not have sufficient length and stability at all speeds of its movement in the aquatic environment. The cavern does not cover the entire length of the harpoon. As a result, its combat range and accuracy of hitting the target are not optimal. The gas flow rate to create an artificial cavity around the harpoon body depends on the speed of the harpoon.

In addition, a cavern around the harpoon is formed only until its speed in water decreases, which corresponds to the resistance of the tip-cavitator, sufficient to recess the tip-cavitator with the rod and thereby open gas channels for supplying gas into the space behind the tip-cavitator, after which the cavern disappears and as a result, the range of the harpoon and the accuracy of its hit on the target are reduced.

A well-known harpoon to create and maintain an artificial cavity around its body when it moves in water, it is necessary to supply a sufficient amount of gas, which must be accumulated in the cavity of the harpoon and which occupies a significant amount. The mass of such a harpoon becomes significantly less than the mass of a traditional type harpoon with similar dimensions, therefore, such a harpoon when shooting has less kinetic energy than a traditional harpoon, and therefore a short battle range. Such a harpoon is effective only when used for firing powerful pneumatic, hydropneumatic or powder underwater guns.

Along with this, the harpoon tip is very likely to refuse to work if it can hit a stone at the bottom of a reservoir or in another emergency situation.

The task of the invention is to increase the efficiency of using a harpoon by increasing the range of its battle and the accuracy of hitting the target.

To achieve the specified technical result in the known method of increasing the range of the spear of a spear gun and the accuracy of hitting it at the target, the gas is supplied into the space behind the cavitator nose to form an artificial gas cavity with a second flow rate q, defined by the ratio

q = kV ₀ d ² ,

where V ₀ - the maximum speed of the harpoon during the shot;

d is the diameter of the nose-cavitator;

k is a coefficient depending on the ratio of the highest speed of the harpoon V ₀ and the diameter of the nozzle-cavitator d, equal to 1-10.

In this case, the gas supply for the formation of an artificial air cavity around the harpoon body is carried out from the cavity in the harpoon body.

In addition, it is possible to supply gas for the formation of an artificial cavity additionally through a line-hose from an underwater gun.

A well-known spear gun harpoon is equipped with a compressed gas receiver located in the housing of its removable tip with a piston mounted movably inside the receiver, having a rod made in the form of a check valve to close the through central hole of the tip, the end of the rod located inside the through central hole, and the receiver case has a central hole with a non-return valve for charging the receiver with high-pressure gas and a recess is formed in the back of the receiver case knoe port for communication with the cavity of the receiver's environment. At the same time, a check valve is located behind the receiver to block the specified outlet, mounted movably on the tip body. The tip is equipped with a removable locking device for fixing the said stop valve, while the ratio of the maximum diameter of the nozzle-cavitator d _{max nk} and the maximum outer diameter of the receiver d _{max np} (d _{max nk} / d _{max np} ) is 0.5-1.5, and the ratio the distance ΔL from the maximum outer diameter of the receiver casing d _{max нр} to the nose-cavitator (ΔL / d _{max нр} ) is 0-10.

In addition, the cavity of the harpoon receiver through the hole with a non-return valve is connected by a line-hose with a source of high pressure gas in the underwater gun.

The well-known spear gun harpoon is equipped with a replaceable receiver with compressed gas having a non-return valve located in the body of the detachable tip, a pusher with an expanding spring located behind the replaceable receiver and in contact with it, a hold-down spring and a valve with through-holes and a rod installed in the front of the receiver from the side of his non-return valve. In this case, the harpoon has a stopper hook connected to the pusher.

The gas supply for the formation of an artificial gas cavity around the harpoon body with a flow rate defined by the ratio q = kV ₀ d ² provides the best conditions for creating a cavity covering the maximum surface area of the harpoon in a wide range of speeds of the harpoon and the diameter of the harpoon cavitator.

The implementation of the gas supply for the formation of an artificial gas cavity through a line-hose from an underwater gun provides an increase in the range of the harpoon and, accordingly, the accuracy of its hit on the target.

Providing a harpoon with a compressed gas receiver allows accumulating compressed gas in the harpoon body, which is necessary to create and maintain an artificial gas cavity around the harpoon body when it moves in water, and also by increasing the mass of the harpoon, it will increase its kinetic energy than a traditional harpoon.

The presence of a piston with a piston in the receiver cavity overlaps the central hole for gas supply behind the cavitating nozzle, and the location of the stem end in the said central hole is necessary for centering the valve blocking this hole.

The presence of a line hose connected to the receiver and the high-pressure gas source in the underwater gun allows increasing the gas volume flow to form an artificial cavity around the harpoon body.

Providing the harpoon with a replaceable receiver with compressed gas makes it possible to use finished gas cans with a non-return valve filled with compressed gas as a receiver.

The presence of an expanding spring in the plunger ensures that the removable receiver moves towards the valve with through-through openings, and due to the pressure of its stem on the non-return valve of the replaceable receiver, the receiver cavity is communicated through the through-hole and the gas channels with the external medium behind the cavitator nozzle.

The invention is illustrated in the drawing, where in Fig.1 and Fig.2 shows general views of the options of the proposed harpoons with a longitudinal section of a removable tip, explaining the possibility of implementing a method of increasing the firing range of the harpoon and the accuracy of its hit on target, and the devices of the harpoons.

The spear gun spear (figure 1) has a housing 1, which consists of a shank 2 with a line 3 attached to the stabilizer 4 located on the harpoon body 1. In the bow of the harpoon body 1 there is a removable tip 5 containing a flag 6 for holding the prey pivotally fixed therein and a pointed cavitator nose 7 made in the form of a body of revolution. In the removable tip 5, a central through hole 8 and the through gas channels 9 connected with it are provided for supplying gas into the space behind the nozzle-cavitator 7. The harpoon is equipped with a receiver 10 with compressed gas located in the housing of the removable tip 5, inside which there is movably mounted with the possibility of return - translational movement of the piston 11 having a rod 12, made in the form of a check valve 13 to block the central through hole 8 of the removable tip 5. The end 13 of the rod 12 is located inside the through the Central hole 8. In the wall of the receiver 10 there is a hole 15, equipped with a non-return valve 16, for charging the receiver with high pressure gas, and in the wall of the rear of the receiver 10 there is an outlet 17 for communicating the cavity of the receiver 10 with the external environment after the harpoon is fired.

On the body of the removable tip 5, behind the receiver 10, a stop valve 18 is placed to block the outlet 17 of the receiver 10 until the harpoon is fired, mounted movably. The stop valve 18 is fixed by a removable stop device 19.

The maximum diameter of the nozzle-cavitator 7 is 0.5-1.5 of the maximum diameter of the receiver 10, and the distance from the nozzle-cavitator to the maximum outer diameter of the receiver 10 is 0-10 of the maximum outer diameter of the receiver 10.

In addition, the cavity of the harpoon receiver 10 through the hole 14 with a non-return valve 15 is connected by a line-hose 3 with a source of high pressure gas in an underwater gun (not shown).

The spear gun spear 1 (Fig. 2) has a replaceable receiver 20 with compressed gas located in the body of the removable tip 5, having a non-return valve 21, a pusher 22 with an expanding spring 23, which is movably behind the contact receiver 20 and is in contact with it. In the housing of the removable tip 5, on the side of the non-return valve 21 of the interchangeable receiver 20, a release spring 24 is placed, pressing the interchangeable receiver 20 to the follower 22, and a valve 25 with through-through holes 26 and a stem 27 for pressing the non-return valve 21 of the interchangeable receiver 20. The harpoon has associated with the pusher 22 stopper hook 28.

The implementation of the proposed method and the operation of the device is as follows.

Before the shot (figure 1), the tip 5 with the receiver 10 is separated from the harpoon, and through the hole 15 with the non-return valve 16 the receiver is charged with high-pressure gas, as a result of which compressed gas is accumulated in it. The check valve 18, thanks to a removable locking device - the latch 19, blocks the outlet 17, thereby excluding the communication of the cavity of the receiver 10 with the external environment (see Fig.), And the piston 11, moving in the receiver 10 to the right, overlaps the through central valve 13 the hole 8 of the removable tip 5. The specified movement of the piston 11 is ensured by the gap between the piston 11 and the inner surface of the receiver 10 so that when charging the receiver 10, the flow rate passing through the non-return valve 16 is greater than One gas passing through the gap of the piston, and then the pressure difference to the left and right of the piston 11 (see figure 1) will ensure its forward movement until the check valve 13 abuts against the valve seat and blocks the central through hole 8 of tip 5 . The receiver 10 is then charged to the desired gas pressure.

At the end of charging the receiver 10 with compressed gas, the removable tip 5 is mounted on the harpoon, and the harpoon is charged into an underwater gun. In this case, the stop valve 18 abuts against the muzzle of the gun (not shown) and keeps the outlet hole 17 closed. When fired, the stop valve 18 stops abutting against the muzzle of the gun (not shown) and moves back to the stop. This opens the outlet 17 and the air from the volume to the left of the piston 11 enters the surrounding space (into the water). Due to the pressure difference between the left and right of the piston 11, the piston moves to the left. In this case, the rod 12 also moves with the piston 11 and opens the through central hole 8 of the removable tip 5. Air through the specified hole 8 and through gas channels 9 enters the space behind the nozzle-cavitator 7, which ensures the creation and maintenance of a cavity around the harpoon during it movements in the aquatic environment. During the movement of the harpoon in the water behind the nose-cavitator 7, a region of reduced pressure is formed, into which gas passes through the gas channels 9 from the receiver 10 and creates an artificial cavity around the harpoon’s body, which excludes the case’s contact with water.

In the device (Fig. 2), after fixing the harpoon body in an underwater gun, the stopper-hook 28 holds the pusher 22 in a position in which the expanding spring 23 is in a compressed state. After that, a replaceable receiver 20 filled with compressed gas is inserted into the tip body 5, which is pressed against the plunger 22 by an extraction spring 24.

When fired, the stopper-hook 28 stops holding the pusher 22 and, under the action of the expanding spring 23 of the pusher 22, the replaceable receiver 20 moves forward in the direction of the valve 25, compressing the squeeze spring 24, the rod 27 presses the non-return valve 21 of the replaceable receiver 20, from which gas flows through through passage openings 26 of valve 25, into the central through hole 8 of the removable tip 5, from where, through the through gas channels 9, gas then escapes into the space behind the nozzle-cavitator 7, behind which a reduced pressure region forms Eden. As a result of the release of gas into the environment, an artificial cavity is created around the harpoon body, isolating the surface of the harpoon body from water. As a result of this, the harpoon's resistance to water is significantly reduced, which ensures an increase in the range of its movement in water and the accuracy of hitting the target.

As a result of the experimental firing of the proposed harpoons with the proposed method of forming a gas cavity around its body, carried out in a pool and in a natural water area, the range of its battle is 1.5-1.8 times higher than the firing range of a traditional harpoon with the formation of a gas cavity according to the traditionally known way. The suitability of the device for the formation of a cavity when firing from rifles having an insignificant maximum speed of the harpoon during firing is confirmed. At the same time, the accuracy of the harpoon hitting the target becomes 15-20% higher.

Claims (6)

1. A method of increasing the range of a spear gun’s spear and accuracy of hitting it with a target, according to which they reduce the resistance to its movement in water, for which they form an artificial gas cavity around the spear’s body by supplying gas in the space behind the cavitator nose during its movement in water, installed in the nose of the harpoon tip, from a source of high pressure gas, characterized in that the gas supply for the spout-cavitator for the formation of an artificial gas cavity is carried out with a second flow q defined by the relation q = kV ₀ d ² , where V ₀ - the maximum speed of the harpoon during the shot, m / s; d is the diameter of the nose-cavitator, m; k is a coefficient depending on the ratio of the highest speed of the harpoon V ₀ and the diameter of the nozzle-cavitator d, equal to 1-10. 2. A method for increasing the range of a spear gun’s harpoon and its accuracy in hitting a target according to claim 1, characterized in that the gas is fed into the space behind the cavitator nose to form an artificial gas cavity around the harpoon body directly from the harpoon body. 3. A method of increasing the range of a spear gun’s harpoon and the accuracy of hitting it at the target according to claim 2, characterized in that the gas is supplied into the space behind the cavitator nose through a line-hose from an underwater gun. 4. Spear spear gun, having a housing that consists of a liner with a line and a nose connected to a removable tip containing a flag pivotally mounted therein to hold the prey and a pointed cavitator nose in the form of a body of revolution, and made with a through central hole and through gas channels connected with it for supplying gas into the space behind the cavitator nose, while a stabilizer is installed on the harpoon body, characterized in that it is equipped with a receiver located in the body of the removable tip ohm with compressed gas with a piston mounted movably inside the receiver, having a rod made in the form of a check valve to close the through central hole of the tip, the end of the rod being located inside the said through central hole, and in the receiver case there is a central hole with a non-return valve for charging the receiver high-pressure gas, and in the rear part of the receiver body an outlet is formed for the cavity of the receiver to communicate with the external environment, while the receiver is placed behind the receiver a support valve for blocking said outlet opening mounted movably on the tip body, the tip being equipped with a removable locking device for fixing said stop valve, the ratio of the maximum diameter of the nozzle-cavitator d _{max nk} and the maximum outer diameter of the receiver body d _{max np} (d _{max nk} / d _{max nr} ) is 0.5-1.5, and the ratio of the distance ΔL from the maximum outer diameter of the receiver casing d _{max nr} to the cavitation nose (ΔL / d _{max nr} ) is 0-10. 5. Spear spear gun under item 4, characterized in that the cavity of the harpoon receiver through the hole with a non-return valve is communicated by a line-hose with a source of high pressure gas in the spear gun. 6. Spear spear gun, having a housing that consists of a shank and a nose connected to a removable tip containing a flag pivotally mounted therein to hold the prey and a pointed cavitator nose in the form of a body of revolution, and made with a through central hole and communicated with through gas channels for supplying gas into the space behind the nozzle-cavitator, while on the harpoon body there is a stabilizer to which a line is attached, characterized in that it is equipped with a removable tip, a replaceable receiver with compressed gas having a non-return valve, a pusher with an expandable spring located movably behind the replaceable receiver and in contact with it, a hold-down spring and a valve with through holes and a rod installed in the front of the receiver, from the side of its non-return valve, while the harpoon has a stopper hook connected to the pusher.

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