RU2092768C1 - Hydropneumatic harpoon gun for sporting underwater shooting - Google Patents

Abstract

FIELD: hydropneumatic guns for underwater shooting. SUBSTANCE: the gun is loaded in water, after which water is injected in the hydraulic chamber by a plunger-type hydraulic pump. The number of injected portions of water controls the pressure in the pneumonic cell and hydraulic chamber of the pneumatic accumulator. When the trigger is pulled, the sear gets disengaged from the tail piece, which is pushed out by water of the hydraulic chamber actuated by the piston of the pneumonic cell. The harpoon tail piece, at least 60 mm long, is conjugate to the walls of the breech and barrel ducts, and the stroke of the tail piece in the breech and barrel ducts is at least 600 mm. The difference between the diameter of the harpoon rod and the diameters of the barrel and breech ducts is at least 1 mm. Ware in the barrel between the harpoon rod and walls of the barrel duct is ejected through the barrel orifice, whose area exceeds the cross-section area of the barrel duct at least by two times, and through the annular gap between the rod and bore. EFFECT: improved design. 12 dwg, 2 tbl

Description

 The invention relates to sports weapons, in particular to hydropneumatic guns for sports underwater shooting.

Known hydraulic gun for sports underwater shooting, containing a barrel with a harpoon, a working cylinder-pneumatic accumulator with a piston and a hydraulic lock, a rear tube-clutch with a filling valve, a handle with a hydraulic pump with a connecting rod, a piston and a lever, a trigger [1]
Such a device of a hydropneumatic gun allows not to use force when loading a harpoon when it is introduced into the barrel of a gun. The disadvantages of this device are the complexity of the design and manufacture, the large length of the pneumatic accumulator with a short barrel and harpoon, the operational unreliability of complex valves of the pneumatic accumulator and hydraulic pump, insufficient strength, range and accuracy of the shot.

 A hydropneumatic spearfishing gun is also known, containing a pneumatic chamber with a shock absorber piston separating its air and water parts, a centrally located breech box with a hydraulic chamber in its upper part, a hydraulic pump attached to the front of the box and a barrel with a harpoon having on the tail part a piston with a seal for locking water in the hydraulic chamber of the box; a trigger with a compacted trigger lever located in the hydraulic chamber of the breech box.

In such a device, the gun also does not apply force to introduce a harpoon into the barrel when loading. But the disadvantages of this device include the considerable length of the pneumatic chamber with its small volume, the structural complexity of the breech box, which is also part of the hydraulic chamber with locking it with a sealed harpoon piston, the operational unreliability of the harpoon with a piston at its rear end, the seal of which will very often be damaged in case of unavoidable blows from an obstacle when firing, increased resistance to the harpoon in the barrel, due to the tight fit of the piston seal to the walls of its channel, and that due to the resistance of the intra-barrel water located in the barrel channel due to the noticeable difference in the diameters of the harpoon rod and the barrel channel and the absence of a hole at the barrel end for ejection of intra-barrel water, the design complexity, operational unreliability and inconvenience of placing the trigger mechanism, with the trigger located inside the box’s hydraulic chamber [2]
As the closest analogue / prototype / proposed device, a hydropneumatic shotgun for sports underwater shooting was selected, which contains a tubular pneumatic accumulator with a rear charging nipple, a piston, a hydraulic chamber with a locking valve, a breech ring with a valve ring, a plunger hydraulic pump attached to the breech block with a lever handle, a barrel with a harpoon, a muzzle and a gunner, a trigger mechanism for laying and dumping tench.

 The pneumatic accumulator consists of a pipe and a threaded connecting fitting, the internal channel of which is a cavity of the hydraulic chamber, and a piston made of impact-resistant plastic is placed inside the pneumatic accumulator.

 A fitting with a non-return valve is connected to the rear end of the pneumatic accumulator for filling the pneumatic accumulator cavity with compressed air. The front end of the connecting fitting of the pneumatic accumulator has a circular groove, in the circular groove of which a rubber washer-seal is inserted for the harpoon and the gap between the valve ring and the breech ring groove.

 The breech is cylindrical in shape, of equal diameter with a pneumatic accumulator, with a central through channel for the passage of a harpoon, which at the front passes into the connecting channel for the barrel, and at the rear opens into a wide channel for connecting the pneumatic accumulator fitting. In the front wall of the connecting channel for the pneumatic accumulator, around the channel for the passage of the harpoon, a circular groove is made to accommodate the valve ring. In the front of the breech there is a transverse blind hole for a cylindrical rotary sear, partially intersecting the axial channel for harpoon passage, with the center of the channel wall opening. A through hole is made in the breech below, connecting the cavity of the circular groove of the breech with the channel of the hydraulic pump welded to the breech.

 When the nozzle is screwed into the breech connecting channel, the pneumatic accumulator, the rubber washer-seal inserted into the guide washer at the end of the nozzle, is pressed against the breech wall around the channel for harpoon passage and covers the circumferential groove with the valve ring, as well as the gap between the harpoon and the channel breech. The water pushed by the plunger of the hydraulic pump passes through the hole in the breech into the cavity of the circular groove of the groove with the valve ring and, through the circular gap between the outer diameter of the ring and the external strut of the groove of the groove, squeezing the rubber seal washer with its pressure passes through the end grooves of the fitting into cavity chambers of the fitting. The back pressure of the water in the pressure chamber presses the metal and rubber washers against the breech wall with overlapping gaps, locking the water in the pressure chamber. Water pumped into the hydraulic chamber, squeezing the piston of the pneumatic accumulator back, increases the pressure in the pneumatic chamber and hydraulic chamber. When the harpoon is released from engagement with the sear, the piston, pushing the water of the hydraulic chamber forward, throws it and the pushed harpoon out of the breech and trunk channels. A hydraulic pump with a tubular body is welded with its upper part to the lower part of the breech housing, around the breech hole for pumping water into the cavity of the circular groove groove. In the housing channel there is a plunger sealed in its lower part with a rubber washer and a guide sleeve screwed into the expanded lower part of the channel with holes in its body for water passage, which overlap and are released during the plunger passage in the channels of the housing and the sleeve. When mixing the lever-handle of the hydraulic pump, the reciprocating movements of the plunger of the hydraulic pump occur, transmitted by the earring.

 The barrel is made of a tube with a wall thickness of 1.5 mm, on the outside, threaded sections are made at both ends for connecting to the front channel of the breech and for the compression nut of the muzzle. Behind the thread section, at the front end of the barrel, a groove is made for attaching and supporting the muzzle. The rear end of the barrel is screwed into the channel in front of the breech. The tubular barrel muzzle is coaxially mounted with the trunk on the rear end of the muzzle and on the front of the breech and is fixed between the muzzle and breech with a compression nut.

 The harpoon is mated with the walls of the bore along the entire length, with an annular groove in the form of an inverse cone in its rear part.

The trigger mechanism consists of a cylindrical rotary sear with a central semicircular groove and a shoulder for fixing the sear in a side slot on the breech housing. At the outer end of the sear, the trigger is fixed with its upper part, which is spring-loaded in the middle part of the pushing spring and has a protrusion that interacts with the back tooth of the mechanism for laying and dumping the line [3]
In this device, a hydropneumatic gun eliminated some of the shortcomings of analog devices, increased operational reliability of some components and parts, increased shot power. However, the disadvantages of this prototype device include the small volume and relatively large length of the pneumatic accumulator, the small ballistic length of the barrel with a short working stroke of the harpoon in its channel, the coupling of the harpoon with the walls of the barrel channel along its entire length with a large area of contact and friction, the complicated design of the breech and the trigger with a blind hole for the rotary sear and unequal force on its right and left ends when locking the harpoon.

 The reasons for the insufficient length of the barrel and harpoon are interrelated with the volume and the length of the pneumatic accumulator, since with a long pneumatic accumulator the possibility of lengthening the barrel and the harpoon is limited due to an excessive increase in the total length of the gun.

 In a low-volume pneumatic accumulator, the pressure increases rapidly, with a sharp rise, when water is pumped into its hydraulic chamber, worsening the adjustment of the shot force, and the pressure in it decreases rapidly when the volume is restored during the shot. The small length of the trunk and the harpoon adversely affects the strength, range and accuracy of the harpoon’s flight, due to the short time of the action of the water ejected from the hydro-chamber on the harpoon, and the short path for acceleration; a harpoon of insufficient length and weight is unstable when flying in a given direction. The conjugation of the harpoon rod with the walls of the barrel channel along its entire length leads to increased friction over a large area, reducing the speed and strength of the shot, the insufficient conjugation of the harpoon with the barrel channel leads to water flow through the gap, which also reduces the strength of the shot, and ensuring high accuracy of the gap all over the trunk and harpoon it is technically extremely difficult. In addition, if the harpoon strikes from an obstacle that is inevitable during spearfishing, the probability of deformation of its shaft is very high, after which putting the harpoon into the barrel and shooting become difficult and often impossible.

 The short-barreled and light guns have a stronger throw up when firing, the accuracy of the battle is reduced.

 The practical experience of sports underwater shooting has shown that, in addition to the volume of water pumped into the hydraulic chamber and the pressure in it and the pneumatic chamber, the value of the volume of the pneumatic accumulator, the ballistic length of the barrel, with the elongated working stroke of the harpoon, is of primary importance for improving the strength, range, accuracy of the shot. mute, the length of the harpoon and its weight. However, the most characteristic common shortcomings of both the prototype device and the analog devices are the small length from the barrel and the harpoon, a small and elongated pneumatic accumulator.

 The problem to which the claimed constructive device of the hydropneumatic gun is aimed is to eliminate the disadvantages of the analog devices and the prototype, namely: increasing the volume of the pneumatic accumulator, increasing the length of the barrel, and therefore lengthening the working stroke, accelerating the harpoon in the barrel, reducing the area the contact and friction of the harpoon with the walls of the channels of the barrel and breech, reducing the resistance of the intra-barrel water to the harpoon in the barrel.

 The technical result that can be obtained by implementing the proposed constructive device for a hydropneumatic gun is expressed as an improvement in the ballistic quality of the gun, that is, an increase in the strength, speed, accuracy and range of the harpoon when firing, simplifying the design, and increasing operational reliability.

 The specified technical result is achieved by the fact that in a hydropneumatic rifle for sports underwater shooting, containing a tubular pneumatic accumulator with a fuel nozzle, a piston and a hydraulic chamber with a locking valve, a breech with a valve ring, a plunger hydraulic pump attached to the breech with a lever-handle, a barrel with a muzzle and a muzzle, on the harpoon, the trigger mechanism, the mechanism for laying and dumping the line, the following significant structural differences are provided: the volume of the pneumatic accumulator is not less than twice The total volume of the bore and breech channels, the difference between the diameter of the harpoon shaft and the diameters of the bore and breech channels is not less than one millimeter, while the harpoon shaft is not in contact with the walls of the bore and breech channels, and the harpoon shank, at least sixty millimeters in length, with walls of the channels of the breech and barrel, the stroke length of the harpoon shank in the channels of the breech and barrel is not less than six hundred millimeters, the barrel has a hole for ejecting intra-barrel water, the area of which is not less than twice It is the area of its cross section.

 The conformity of the proposed technical solution to the criterion of "significant differences" is evidenced by the following information in table. one.

 The achievement of a given technical result in the implementation of the proposed technical solution is confirmed by the new properties listed in table 1, as well as the technical advantages given below.

 In FIG. 1 shows the proposed hydropneumatic rifle assembly, in a state before starting pumping water into the hydraulic chamber, general view, lateral section (warhead); in FIG. 2 the same (middle part); in FIG. 3 the same (tail); in FIG. 4 breech, lateral longitudinal section; in FIG. 5 is a cross-section through the arrangement of lateral, oblique grooves and a transverse through hole for the sear; in FIG. 6 pneumatic accumulator connecting nipple with a hydraulic chamber, lateral longitudinal section; in FIG. 7 - end part of the connecting fitting of the pneumatic accumulator, a cross section through the location of a circular groove for the guide washer and end grooves for the flow of water into the hydraulic chamber; in FIG. 8 cylindrical turning sear, longitudinal lateral section; in FIG. 9 valve ring, lateral vertical section; in FIG. 10 rubber sealing washer, lateral vertical section; in FIG. 11 metal guide washer, lateral vertical section; in FIG. 12 guide sleeve of the hydraulic pump, lateral longitudinal section.

 The proposed hydropneumatic harpoon gun for sports underwater shooting consists of a tubular pneumatic accumulator with a rear stopper with a fuel nozzle, a piston and a locking valve, a breech with a valve ring, a hydraulic pump with a lever arm, a barrel with a muzzle, a barrel guide and a harpoon, a handle with a protective bracket , a mechanism for laying and dumping the tench.

 The listed structural elements are made as follows: The pneumatic accumulator 1 consists of a housing 2, a rear plug 3, a piston 4, a shut-off check valve 5. The housing 2 of the pneumatic accumulator 1 is made of a tubular monolithic metal billet. The internal channel-pneumatic chamber 6 for compressed air, with its polished walls, passes in front of the channel-hydraulic chamber 7, of reduced diameter, the walls of the channel-hydraulic chamber 7 with external thread are the connecting fitting 8 of the pneumatic accumulator 1. The section of the channel-pneumatic chamber 6, before transition it in the hydraulic chamber 7 is reduced in diameter in the form of a conical narrowing at an angle of 45 to stop the piston head 4. At the transition point of the tubular part of the housing 2 into the connecting fitting 8, a circular groove 9 for sealing ltsa. At the end part 10 of the connecting fitting 8, a circular groove 11 is made for placing and supporting the metal guide washer of the locking valve 5 and four radial mechanical grooves 12, for the flow of water pumped into the hydraulic chamber 7, starting outside the circular groove 11, passing along its bottom and connected to the cavity of the hydro-chamber 7. The edges of the rear sample of the channel-pneumatic chamber 6 are beveled inwards at an angle of 45 to clamp the sealing ring. At the rear end of the channel 6, a portion of the internal thread is made for attaching the rear plug 3. The rear plug 3 is of a cylindrical shape equal to the outer diameter with a pneumatic accumulator 1, its front connecting part 13 is made in the form of a wide short tube with an external thread on which it is screwed into the threaded rear section of the channel-pneumatic chamber 6 of the pneumatic accumulator 1. The outer part 14 of the rear plug 3 is made as a unit with the filling nozzle 15 with an external thread. In the place of transition of the outer part 14 to the connecting part 13, a circular groove 16 for the sealing ring is made on the surface of the rear plug 3. At the bottom of the connecting part 13 of the rear plug 3, a threaded hole 17 is made, into which the valve body 18 is screwed, made in the form of a glass with a hole for air passage in its bottom and an external thread, a spring-loaded conical locking valve 19 is placed in the cavity of the valve body 18. socket 20 at the bottom of the hole 17, for the valve head 19 passes into the through hole 21 passing along the central axis of the outer part 14 and the filling nozzle 15 and used to pump air into the pneumatic chamber 6. The piston 4 consists of a housing 2 2 and rubber o-rings. The housing 22 is made of impact-resistant plastic, cylindrical, mated to the walls of the channel-pneumatic chamber 6 with a gap of not more than 0.1 mm, its front part is tapered narrower at an angle of 45, respectively, of the thrust area at the junction of the channel-pneumatic chamber 6 into the channel of the hydraulic chamber 7. On the surface of the housing 22 there are two circular grooves-grooves 23 for the sealing rings. The locking valve 5, the reverse action, consists of a rubber washer-seal 24, embedded in a circular groove of the guide of the metal washer 25, which in turn is inserted into the circular groove 11 in the end portion 10 of the connecting fitting 8 with its rear surface. When the fitting 8 of the pneumatic accumulator 1 is screwed into the breech, the rubber washer-seal 24 is pressed by its front surface to the breech wall and seals the gap for the water flow and the gap between the harpoon and the breech channel.

 The breech box 26 consists of a body 27 and a valve ring 28. A barrel 27 is of cylindrical shape, of equal diameter with a pneumatic accumulator 1, a pneumatic accumulator 1 is connected to its rear part by its union 8, a barrel and a table are attached to its front part, and a hydraulic pump housing is welded to its middle from the bottom its bracket. On the Central axis of the breech 26 passes the channel 29 for the shank, in the rear part of the channel 29 is connected to a wide channel 30 with an internal thread, for connecting the fitting 8 of the pneumatic accumulator 1.

 In the front end wall of the channel 30 of the breech 26, around the opening of the channel 29 for the harpoon shank, a circular groove 31 is made for the valve ring 28, which is inserted into it with its front surface, beveled anteriorly and downward at an angle of 45. The front part of the valve ring 28 has in a lateral projection the shape of a truncated semiconus, its rear, flat part faces the cavity of the channel 30 and is adjacent to the front surface of the sealing washer 24 of the locking valve 5. The gap between the outer diameter of the ring 28 and the outer diameter of the circular groove the grooves 31 are kept within 0.1 mm, are used for the water flow when it is pumped into the hydraulic chamber 7 and sealed with a washer 24 of the locking valve 5. From below, in the breech 26, a through hole 32 is made, connecting to the cavity of the circular groove groove 31 and opening into the channel hydraulic pump through which there is a flow of injected water from the hydraulic pump.

 In the front part of the breech 26, at the end of the channel 29, vertical grooves 33 are beveled at both sides of the channel 29 and are beveled at an angle downwards for the arcuate lever of the sear. In the center of the grooves 33, a through transverse hole 34 is made for a rotary cylindrical sear that crosses perpendicular to the channel 29, with the center of its axis along the upper wall of the channel 29. The channel 29 in the front of the breech 26, behind the grooves 33, passes into the channel 35 with an increased diameter, with a thread for attaching the rear end of the barrel. The middle part of the breech 26 is outside machined to the size of the inner diameter of the trunk, which with its rear end is worn on the flow part of the breech 26. The front, end part of the breech 27 is turned outside to a reduced diameter, the rear end of the barrel is screwed into its channel 35. On the lower surface of the breech 26, in the front and middle parts, a segmental section was removed with the formation of a groove 36, to a height of 8-9 mm, to accommodate and move the trigger head with a rod and spring, at the end of the groove 36 in the breech 26 an arcuate groove 37 is made to accommodate and abut the rear end of the trigger spring.

The hydraulic pump 38 consists of a housing 39, a plunger 40, a thrust washer 41, a sealing washer 42, a guide sleeve 43, an upper support bracket 44, a lower support bracket 45, a support fork 46, an earring 47, a lever arm 48. The housing 39 is cylindrical in shape the upper part has a thickened section of its walls to increase the area of the weld. The housing 39 of the hydraulic pump 38 is welded to the lower part of the breech 26 at an angle of 125 ^o around the hole 32 connecting the channel of the housing 39 with the cavity of the groove groove 31 of the breech 26. A channel 49 passes through the central axis of the housing 39, in which the plunger 40 is located and moves. of the housing part 39, the channel 49 passes into the channel 50, of an increased diameter, with a threaded section in the middle-lower part, in which a thrust metal washer 41, a rubber washer 42, a sealing plunger 40 are placed, and a guide pinch sleeve 43 is screwed in, with a diameter of its channel match the diameter of the plunger 40. On the body of the sleeve 43, a thread section is made on the outside, a circular groove 51 is made in its upper part, in the wall of which there are four through holes 52 for the flow of water into its channel and into the channel 49 of the hydraulic pump 38, which are closed and opened by the plunger 40 when it is reciprocating in the channel of the sleeve 43.

 The lower part 53 of the housing 39, corresponding to the channel 50, increased diameter, in its wall a hole 54 is made, combined with the cavity of the circular groove 51 of the sleeve 43, for the flow of water into the holes 52 in the sleeve 43.

 To the rear surface of the housing 39, from the lower part 53 to the upper thickening of the housing, the upper support bracket 44 is welded by the upper bracket, which is also welded with its upper end to the rear-lower part of the breech housing 26.

 To the lower part 53 of the housing 39 of the hydraulic pump 38, a lower stop bracket 45 is welded to the front surface with a through hole for bolting the upper head of the curved removable support fork 46, the lower head of which is pivotally connected to the front end of the lever arm 48, which is also pivotally connected to the front its part with the lower head of the fork-earring 47, the upper head of which is movably connected on the axis with the lower end of the plunger 40 protruding from the sleeve channel 43. The reciprocating movements from the growl are transmitted through the earring 47 ha-handles 48 to the plunger 40 of the hydraulic pump 38.

 The barrel 55 with a muzzle 56, a muzzle 57 and a harpoon 58 is made of a metal tube with a wall thickness of at least 1.5 mm with the possibility of greater accuracy of the channel gauge along its entire length and grinding of the channel walls. At the front and rear ends of the barrel 55, male threads are provided for connection to the breech 26 and the muzzle 56. The rear of the barrel 55 is located and fixed in the threaded portion of the channel 35 at the front of the breech 26. The front of the barrel 55 is located in the muzzle channel 56 with a threaded section . In front of the barrel 55, behind its edge, a hole 59 is made for ejecting intra-barrel water during a shot, the area of which is twice as large as the cross-sectional area of the barrel.

 The muzzle 56 is of a cylindrical shape, a channel 60 is made along its central axis to accommodate the front end of the barrel 55, a threaded section is made in the front of the channel 60, on which the muzzle 56 is screwed onto the threaded end of the barrel 55 and pressed against the muzzle 57. The front of the muzzle is 60 56 passes into a short channel 61, of a smaller diameter than channel 60. The transition point of channel 60 to channel 61 serves as a support for the front edge of the trunk 55 and the muzzle 56 when it is pressed against the barrel 57. The channel 61 of the muzzle 56 ends with a funnel 62. Anteroposterior h the part of the muzzle 56 is tapered narrowed, a transverse hole 63 for ejection of intra-barrel water is made from above in the front part, combined with a similar hole 59 of the barrel 55. The rear part of the muzzle 56 is outside machined to the size of the inner diameter of the barrel 57, the end of the rear part is machined to a reduced diameter, channel 60 in this part is the front end of the barrel 55.

 Behind the hole 63 in the muzzle 56 a blind threaded hole 64 is made, to which the front sight 65 is attached. Below, in the front conical part of the muzzle 56, a blind threaded hole 66 is made, to which the front tooth 67 of the line laying and dumping mechanism is attached. The gunner 57 is made of a pipe with an inner diameter at both ends corresponding to the outer diameter of the machined portions of the back of the muzzle 56 and the middle part of the breech 26, on which it is worn at its ends, is tightened and fixed with the barrel, between the muzzle 56 and the breech 26, with emphasis in the protrusions of their bodies, while the muzzle 56 operates as a compression nut. At the rear end of the gunner 57, from the bottom, in the projection of the anterior-middle part of the breech 26 and its segmental groove 36, there is a longitudinal window-hole 68 with sections of different widths for installing, removing and moving the trigger head of the hook with the rod and spring, which is made , as a whole with two side vertical rectangular windows-openings, combined with the vertical grooves 33 of the breech 26, which serve to install and remove the rotary sear with its arcuate lever, without disassembling the gun.

 In front of the hole 68, from below, in the trunk 57, an opening 69 is made to accommodate and fix the end of the handle bracket.

 Harpoon 58 consists of a rod 70 and a shank 71 made as separate parts and interconnected on a thread. The shaft 70 of the harpoon 58 is not in contact with the walls of the bore 55 and has an elongated thread section at the rear for connection with the shank 71. Before starting the threaded section on the surface of the shaft 70, an annular groove is made in the form of an inverse cone to a depth of not more than 0.5 mm. Shank 71, with a length of at least 60 mm and a diameter increased by 1 mm relative to the diameter of the shaft, is mated to the walls of the bore 55 with a gap of up to 0.1 mm, with a polished surface. In the front end of the shank 71, a blind threaded hole is made for connecting the shaft 70 with a depth corresponding to the length of the threaded portion at the rear end of the shaft 70. The junction of the shaft 70 and the shaft 71 with the difference of their diameters is the engagement and fixing section of the harpoon 58 for the protrusion end of the shank 71, whispered the rear edge of the groove. A thread section is made at the front end of the harpoon rod 70 for attaching the tip 72. A sliding sleeve 73 is attached to the rod 70 with a hole for attaching a line that remains on the rod 70 after firing, stopped by the protrusion of the shank 71, or the line is fixed in the transverse hole 74, in the front of the shaft 70, behind the tip 72.

 The handle 75 is made of plastic and consists of right and left parts — cheeks of unequal thickness, on the inner surfaces of which grooves are made corresponding to the geometric shape and dimensions of the housing 39 of the hydraulic pump 38 and its brackets 44 and 45. Both parts of the handle 75 are bolted through holes 76 in the brackets 44 and 45. The protective bracket 77 of the handle 78 is made integrally with one of the parts-cheeks of the handle 75, its vertical part is fixed with its end in the hole 69 of the barrel 57, in the horizontal part there is a longitudinal through a groove 78 for accommodating the rear tooth of the line release mechanism, which is connected to a longitudinal blind groove 79, for locating and running the lower end of the trigger. In the housing of the handle 75, a hole 80 is made for the flow of water, combined with the hole 54 of the hydraulic pump 38.

 The trigger mechanism consists of a cylindrical rotary sear 81, a lever 82, a trigger 83, a fixing bolt 84, a rod 85, a spring 86. The cylindrical rotary sear 81 is made of hardened stainless steel and is placed in the through cross-hole 34 of the breech 26. In the center of the sear 81 a semicircular groove 87 is made, to a height of the whisper radius, which coincides geometrically with the walls of the channel 29 of the breech 26. At the ends of the whisper 81 there are made vertical through holes 88 for the ends of the lever 82, and end holes 89 for fixing their lever bolts 82. The ends of the arcuate lever 82 are inserted into the openings 88 of the whispered 81, its right and left branches extend along the grooves 33 of the breech 26 with the possibility of anteroposterior movement within the boundaries of the grooves 33. The lower, horizontal part of the arc of the lever 82 is installed in an oblique vertical groove of the trigger head 83 and is additionally fixed by a bolt 84 screwed into the hole in the front of the trigger head 83. The rod 85 is screwed into the threaded hole in the rear of the trigger head 83, a spring 85 is put on the rod, pressed against the rear her wall groove 37 breech 26 and pushing the trigger / mechanism / hook 83 forward, with a whisper 81 whispered clockwise. The trigger head 83, the stem 85 and the spring 86 are located and move in the space between the segmental groove 36 of the breech 26 and the inner wall of the barrel 57 with its opening-window 68. The lower part of the trigger 83, curved arcuate rear, is located with the possibility of movement in the blind a longitudinal groove 79, the brackets 77 of the handle 75. The front end of the lower part of the trigger 83 is made in the form of a wedge-shaped protrusion 90 with a bevel angle of 30-35 and is engaged with the upper shoulder of the rear rotary tooth of the line relief mechanism.

 The mechanism for laying and dumping the line consists of a front fixed tooth 67 installed in the hole 66 of the muzzle 56, with a protrusion beveled at an angle of 45, and with an opening for fastening the line and the rear rotary tooth 91, which is a two-arm lever, bent at an angle of 100-110 mounted on an axis in the walls of the through groove 78 of the bracket 77 of the handle 75. The upper shoulder of the tooth 91 is engaged with the wedge-shaped protrusion 90 of the trigger 83, with the possibility of its release from the mesh when the trigger 83 is moved back. On the lower shoulder of the rear rotary tooth 91 and the protrusion of the front tooth 67, the hinges of the line fit.

 The choice of the proposed sizes, diameters and volumes of the pneumatic accumulator, barrel, harpoon, their ratio, the limits of the values are justified by the following explanations.

 With an increased volume of the pneumatic accumulator, more smoothly, without sharp rises, the pressure increases with an increase in the amount of water pumped into his hydro chamber, reducing the volume of his pneumatic chamber by a smaller part than in a small tank, resulting in improved adjustment of the shot force, without drastic changes with increasing volume of injected water. When firing, when the harpoon is released from the engagement, the piston pushing force is more uniform, without a sharp drop in pressure at the end of its stroke, and the hydro chamber water pushed by the piston also pushes the harpoon with more uniform force, without an accelerated force drop at the end of the barrel. Practical experience of underwater shooting shows that a fairly uniform force of pressure on the water of the chambers and the harpoon, ejected when fired from the breech and bore channels, with its almost imperceptible drop at the end of the harpoon, is achieved if the volume of the pneumatic accumulator exceeds the total volume of the bore and breech channels at least than twice.

 The increased ballistic length of the barrel and the elongated harpoon increase the speed, range and accuracy of the shot due to the longer exposure time of the hydro chamber pushed by the piston to the harpoon, longer acceleration path, harpoon working stroke, in addition, a longer and heavier harpoon has greater inertia, better holds a predetermined direction of movement in the water, and practical experience of underwater shooting shows that the above ballistic qualities are achieved if the length of the working stroke, i.e. the stroke of the harpoon shank in ol of at least six hundred millimeters.

 The reason for choosing a harpoon that does not come in contact with the walls of the bore, with an oversized shank paired with the walls of the bore, is the insufficient operational reliability of the harpoon mated with the walls of the bore along its entire length. Since during spearfishing deformation of the harpoon rod is unavoidable as a result of hitting obstacles, which leads to difficulty, and more often to the impossibility of introducing the harpoon into the bore, severe friction against the walls of the bore, this requires stopping the hunt. In addition, with the conjugation of the harpoon rod with the walls of the barrel channel along the entire length, the area of contact and friction is very large, which reduces the speed and strength of the shot.

 The proposed diameter of the harpoon shaft is less than the diameter of the channels of the barrel and breech by 1 mm, that is, the difference between the diameter of the shaft of the harpoon and the diameters of the channels of the barrel and breech is not less than 1 mm, and the shank, the diameter of which is larger than the diameter of the shaft by 1 mm, is conjugated along the entire length with the walls of the bore with a gap of up to 0.1 mm. Deformation of the harpoon rod after hitting an obstacle with the proposed diameter of the rod will not be an obstacle for entering the harpoon into the barrel, due to the sufficient difference in their diameters, which significantly increases the operational reliability of the gun, in addition, the contact area and the friction of the harpoon against the barrel wall are reduced, which reduces the resistance of the harpoon to the bore. The length of the shank should be greater than the distance from the point of its engagement with the sear to the rear edge of the shut-off valve of the hydraulic chamber, that is, at least 60 mm, in addition, with such a length, there will be practically no flow of water from the hydraulic chamber when firing at the gap between it and the bore what is possible with a short shank.

 Since at the proposed diameter of the harpoon between it and the walls of the bore to the liner there will be an annular cylinder of water with a wall thickness of 0.5 mm, a hole is provided at the front end of the barrel for ejecting this water, with a larger exit area exceeding twice the cross-sectional area trunk, which significantly reduces the resistance of the harpoon to the trunk.

 The reason for the design changes of the trigger mechanism and the breech is the difficulty in manufacturing the breech and whisper of the trigger in the prototype device, with a blind hole for the sear.

 The proposed hydropneumatic harpoon gun is used as follows.

The pneumatic accumulator 1 assembly with a piston 4 installed in its channel-pneumatic chamber 8 and an attached rear plug 3 is charged with compressed air through the filling nozzle 15 to a value within 110-130 kg / cm ² . At the same time, the piston 4 occupies an extreme forward position in the pneumatic chamber 6, resting its head against the circular conical section of the pneumatic chamber 6 before it passes into the hydraulic chamber 7. The pneumatic accumulator 1 charged with compressed air has a shut-off check valve 5 installed in the circular groove 11 of the end face 10 of the nozzle 8 , screwed by its fitting 8 into the connecting threaded channel 30 of the breech 26. The loading of the gun is made in water; without filling the chamber 7 with water, loading the gun is impossible, which increases the safety of the gun. After filling the barrel 55, the hydraulic pump 38 and the hydraulic chamber 7 with external water, the harpoon 58 is inserted with its shank 71 into the barrel 55, by pressing the trigger 83, to reduce the obstacle to the passage of the shank 71 through the channel 29, since the whisper 81 is turned counterclockwise and the edges of its groove 87 coincide with the walls of the channel 29. The shank 71 passes through the bore 55, the channel 29 of the breech 26, the holes of the rubber washer 24 and the metal washer 25 into the cavity of the hydraulic chamber 7, until it contacts the piston 4. Then, slightly feeding the harpoon 58 forward let go the trigger 83, the sear 81, pushed by the spring 86 through the lever 82, enters the junction of the shaft 70 and the shank 71 with the rear edge of its groove 87 and fixes the harpoon 58 in the channel 29 with an emphasis on the protrusion of the shank 71. After installing and fixing the harpoon 58 in the barrel 55, external water is pumped into the hydraulic chamber 7 by the plunger hydraulic pump 38, for which the lever-arm 48 performs reciprocating movements up and down in a swing that ensures that the plunger 40 comes out of contact with the holes 52 of the sleeve 43, through which the hydraulic pump 39 to the channel 49 of the housing the wasp 38 receives water, due to the appearance of a vacuum in the channel 49 during the reverse stroke of the plunger 40. With the forward stroke, the plunger 40, blocking the holes 52, creating high pressure in the channel 49, squeezes water from the channel 49 through the opening 32 of the breech 25 into the cavity of the circular groove grooves 31, where, through the annular gap between the outer diameter of the ring 28 and the outer wall of the groove 31, squeezing the rubber washer 24, the water passes through the end grooves 12 of the pneumatic accumulator 1 into the hydraulic chamber 7. The rubber washer 24 locks back the pressure in the hydraulic chamber 7 its valve 5, is pressed tightly against the end front wall of the channel 30 of the breech 26, around the groove of the groove 31 and the channel 29, reliably sealing the gaps between the outer diameter of the ring of the valve 26 and the outer wall of the circular groove of the groove 31, as well as between the shaft 71 of the harpoon 58 and the walls of the channel 29 of the breech 26, locking the water in the hydraulic chamber 7. Repeated movements of the lever-handle 48 with the plunger 40 occurs as described, each portion of the water pumped into the hydraulic chamber 7, increasing its volume, squeezes the piston 4 back, reduces the volume of the pneumatic chamber 6 pneumatic umulyatora 1, increases the pressure therein and 7. The number of uploaded gidrokamere portions of water, the pressure force is regulated in pneumatic chamber 6 and 7 gidrokamere pressure reservoir 1, for each individual gun, depending on the chosen diameters and pneumatic accumulator volume and its gidrokamery.

 After that, the line is laid on the front tooth 67 and the back tooth 91 of the mechanism for laying and dumping the line. When you press the trigger 83 for firing, the rear edge of the groove 87 of the whisper 81, pivoted by the lever 82, disengages from the end protrusion of the shank 71, freeing it. The pressure of compressed air in the pneumatic chamber 6 pushes the piston 4 forward, which forces water out of the increased volume of the hydraulic chamber 7, which, in turn, pushes the shaft 71 of the harpoon 58 and the harpoon 58 from the channel 29 of the breech 26 and the channel of the barrel 55. Water in the barrel 55 between the shaft 70 of the harpoon 58 and the walls of the channel of the barrel 55 to the shaft 71, is ejected by the shaft 71 through the hole 59 of the barrel 55 and through the annular gap between the shaft 70 of the harpoon and the edge of the channel of the barrel 55, which reduces the resistance to travel of the shaft 71, as the water flow accelerates Power shaft 71 through an enlarged area of its output.

 The harpoon line 58 is reset until the shank 71 is released by the sear 81, while the upper shoulder of the rear rotary tooth 91 of the line release mechanism, sliding along the wedge-shaped protrusion 90 of the trigger 83, disengages from it, the lower shoulder of the tooth 91, turning on the axis sheds the loop of the line, at the same time the loop of the line goes also from the protrusion of the front tooth 67 of the reset mechanism.

 The proposed hydropneumatic spear gun for sports underwater shooting has the following technical advantages over the prototype, are given in table. 2.

 According to the proposed technical solution, working drawings have been developed, a prototype is in the manufacturing stage.

Claims (1)

 Hydropneumatic harpoon gun for sports underwater shooting, containing a tubular pneumatic accumulator with a filling nozzle, a piston and a hydraulic chamber with a locking valve, a breech with a valve ring attached to the breech, a plunger hydraulic pump with a lever handle, a barrel with a muzzle, a trigger mechanism and a harpoon laying and dumping the tench, characterized in that the volume of the pneumatic accumulator exceeds the total volume of the channels of the barrel and breech by at least twice the difference between the diameter of the harpoon shaft and the diameters of the bore and breech channels not less than one millimeter, the harpoon shaft not in contact with the walls of the bore and breech channels, and the harpoon shank of at least 60 mm in length mated with the walls of the breech and barrel channels, the stroke length of the harpoon in the breech and barrel channels less than 600 mm, the area of the hole of the barrel for ejection of intra-barrel water is not less than twice the area of its cross section.

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