RU2071591C1 - Holder of projectile for firearms using liquid propelling agent - Google Patents

Abstract

FIELD: ammunition for firearms using liquid propelling agents. SUBSTANCE: holder of projectile has casing with hole in bottom and igniting device, jacket of tight burning material is positioned in casing and is attached to it with its lower part. It is used to take charge of liquid propelling agent with change of form and dimensions, for sealing and isolation of charge as whole and/or each component individually, to provide for removal of propelling charge and projectile when unloading. Elastic plug is put into hole in bottom of casing. Under above-mentioned jacket there is placed another jacket of smaller dimensions with elastic plug in throat which is attached coaxially and with clearance to plug in hole of bottom of casing to take, seal and isolate components of liquid propelling agent before shot. Igniter is mounted on bottom of casing. Valve is located between elastic plug and jacket. Jacket is attached to projectile. EFFECT: enhanced operational safety and efficiency. 8 cl, 7 dwg

Description

 The invention relates to ammunition for firearms using liquid propellants, and more particularly to devices for placing a liquid propellant charge in the chamber of a weapon.

 Known designs of devices for placing a charge of liquid propellant in the gun chamber, containing chamber walls, a projectile with sealing elements forming the front end part, and an element in the form of a sleeve with seals forming the rear end part [1,2] An element in the form of a sleeve is connected to projectile, which ensures their uniform supply and retouching. After the propellant is fed into the chamber, the element is disconnected from the projectile, which is sent to the barrel bore by the pressure of the liquid substance. During the period of the shot, the element in the form of a sleeve provides abstraction of the chamber.

 A disadvantage of the known devices is not the functioning of the weapon containing the nozzle between the chamber and the bore, because at insignificant and negative angles of elevation of the barrel, the propellant flows out of the chamber into the nozzle, the bore and gaps. The presence of holes in the case of the element in the form of a sleeve for the passage of liquid substances predetermines their docking with the feed channels located in the chamber wall, which does not provide reliable and safe operation. The spreading of the propellant in the chamber between the projectile and the bottom of the element leads to gas formation or self-ignition upon contact with the heated walls of the chamber. Discharge is a long and dangerous process, because carried out in a series of sequentially performed operations, and the projectile is removed through the chamber with the remnants of the propellant on the walls.

 Known holder of a projectile for a tool using liquid propellant [3] containing an element in the form of a sleeve with holes in the wall and seals, forming the back of the device for accommodating liquid propellant. The walls of the chamber form the central part, and the projectile with seals forms the front end part of the device for accommodating liquid propellant. The projectile holder is connected to the projectile before filling the chamber with a propellant and is disconnected from the projectile after filling the chamber with a propellant. The projectile holder contains an ignition device.

 A disadvantage of the known device is the failure to ensure the functioning of the weapon containing the nozzle between the chamber and the bore. Because liquid propellant with negative and negligible positive elevation angles of the barrel flows from the chamber into the nozzle, the bore and gaps. The presence of holes in the element in the form of a sleeve and seals around them complicates the design of the holder and tools, reduces the reliability and safety of operation. The contact of liquid propellant with the heated walls of the chamber leads to gas formation and self-ignition or to a deviation in the shot parameter. Discharge is a long and dangerous process, as is carried out by sequentially extracting a liquid propellant, an element in the form of a sleeve and a shell. Moreover, the extraction of the projectile is carried out through the chamber with the remaining liquid on the walls and gas products. To extract the projectile, a device and an additional operation to capture it are necessary.

 The problem to which the invention is directed is to create a device capable of receiving a liquid propellant charge in a chamber of a weapon with a change in size and shape, sealing and isolating the charge as a whole and / or each component separately and burn completely or partially during the shot period, and remove propellant charge and projectile during discharge.

 The problem is solved in that in the known holder of a projectile for a tool using a liquid propellant containing an element in the form of a sleeve with an opening in the bottom and an ignition device, a shell made of a sealed combustible material capable of changing dimensions and shape is placed and attached to the sleeve by the lower part an elastic plug is installed in the opening of the bottom of the sleeve; an igniter is placed at the bottom of the sleeve. To receive, seal and isolate the components of the charge of liquid propellant with mutual isolation prior to firing, a smaller casing is placed under the casing with an elastic stopper in the neck, which is attached coaxially and with a gap to the stopper located in the opening of the bottom of the sleeve. In order to prevent breakthrough of gases through the elastic plug in the sleeve between the elastic plug and the sheath, a valve is installed. In order to prevent the breakthrough of gases through an elastic plug, the latter is located in an annular igniter device, the inner wall of which is made in the form of a truncated cone with an apex inside the sleeve. In order to prevent the breakthrough of gases through the elastic plug, the portion of the sleeve in which the plug is located is made in the form of a truncated cone with an apex inside the sleeve. In order to be able to extract the projectile during discharge, the shell is attached to the projectile. In order to protect the shell during storage and when feeding weapons into the chamber, the shell is covered with a cylinder that is removably mounted on the sleeve and attached to the shell. In order to supply a charge of liquid propellant to the projectile holder located in the weapon chamber having a chamber abtraction device other than a sleeve, an elastic plug is attached to the shell, under which there is a cylinder with holes and an igniter, the cylinder is coaxially attached to the elastic plug, on the shell surface around the cork in the radial direction with a gap there are ropes made of grape-cloth, the shell is covered with a cylinder and attached together with the cylinder to the projectile.

 In FIG. 1 shows a projectile holder for loading liquid propellant of a firearm having a chamber abutment device other than a sleeve, completely eliminated during the shot period. The holder of the projectile contains an elastic shell 1 of sintering fabric and quick-burning rubber, forming a closed volume. In the neck of the shell 1, a combustible elastic plug 2 is fixed. Around the plug 2 in a radial direction are located from the cap shell 1 with a fastening to the elastic plug 2, a cylinder 4 having holes 5 is located. An ignition device 6 with electrical initiation is located on the cylinder 4. The shell 1 in a compressed state is placed in the cylinder 7 and is attached together with the cylinder 7 to the projectile 8.

 In FIG. 2 shows a projectile holder for charging a liquid propellant, which is mostly eliminated during the shot period and contains an element in the form of a sleeve. The holder of the projectile contains an elastic shell 1 of sintering fabric and quick-burning rubber forming a closed volume. In the shell 1 there are holes 2 for the passage of liquid propellant and holes 3 for the passage of the beam of fire. The shell 1 is attached to the bottom of the sleeve 4. An elastic plug 5 and a valve 6 are installed in the opening of the bottom of the sleeve 4, around which an igniter device 7 is placed on the bottom of the sleeve 7. A cylinder 9 is installed coaxially to the walls 8, in which the shell 1 is compressed. 1 and cylinder 9 are attached to the projectile 10.

 In FIG. 3 shows a projectile holder for charging a liquid propellant, comprising a shell 1 made of sinter fabric and quick-burning rubber. In the shell 2 there are holes 2 for the passage of liquid propellant and holes 3 for the passage of the beam of fire. The shell 1 in a compressed form is located in the sleeve 4. In the hole in the bottom of the sleeve 4 there is a sleeve 5 in which there is an elastic plug 6 and valve 7. At the bottom of the sleeve 4 there is an ignition device 8 with electrical initiation. The shell 1 is attached to the bottom of the sleeve 4 and the shell 9, which is inserted into the sleeve.

 In FIG. 4 depicts a projectile holder for charging a liquid propellant consisting of components that require mutual isolation prior to firing. The holder of the projectile contains a shell 1 of sintering fabric and quick-burning rubber, forming a closed volume. In the shell 1, in its neck, an elastic plug 2 is installed and there are openings 3. Under the shell 1 there is a shell 4 made of a cap-like fabric and smaller quick-burning rubber, containing an elastic plug 5 of a combustible material in the neck. The plug 5 is attached coaxially and with a gap to the elastic plug 2, which is located in an annular igniter 6, the inner wall of which is made in the form of a truncated cone with an apex inside the sleeve. The igniter device 6 is installed in the hole of the bottom of the sleeve 3, in which the shells 1 and 4 are located in a compressed state.

 In FIG. 5 shows a projectile holder for charging a liquid propellant containing a shell 1 made of sintering fabric and quick-burning rubber, in which there are holes 2. An elastic plug 3 is fixed in the neck of the shell 1, which is fixed in the hole in the bottom of the sleeve 4, made in the form of a truncated cone with a top inside the sleeve. In the sleeve 4 is located in a compressed state, the shell 1 and at the bottom is an igniter 5.

 The projectile holder for a liquid propellant charge depicted in FIG. 1, works as follows. The projectile holder with the projectile attached to it is fed and sent to the gun chamber. A needle is inserted through the elastic stopper 2 by deforming its elastic walls, through which a liquid propellant is supplied under pressure, which through holes 5 of the cylinder 4 enters under the shell 1, which extends from the cylinder 7, filling the chamber, while the needle moves simultaneously with the sheath 1. After completion of the propellant charge, the needle is removed from the elastic plug 2. The igniter 6 is initiated, and a shot is fired. Shell 8 and cylinder 7 are thrown out of the bore. The shell 1, cylinder 4, elastic plug 2 and ropes 3 burn. When discharging, a grip is made on the ropes 3. A needle is inserted through the elastic stopper 2 through which a liquid propellant is sucked out. The needle is pulled out of the cork 2. For the ropes 3, the sheath 1 is pulled out of the gun’s chamber. The shell 1 extends the cylinder 7 and the projectile 8. For reuse of the holder of the projectile shell 1 in a compressed state is placed in the cylinder 7.

 The holder of the projectile shown in figure 2, operates as follows. The projectile holder connected to the projectile is fed and sent to the gun chamber 11, FIG. 6. Closes the shutter 12, from which the needle 13 extends. The needle 13 passes through the elastic tube 5, pushing its elastic walls, and raises the valve 6, stretching the sheath 1 above the valve. The propellant through the channel 14 enters under the valve 6 and through the holes 2 under the shell 1. Under the pressure of the liquid propellant, the projectile 10 and the cylinder 9 attached to it are detached from the sleeve 4 and move forward to the stop. The shell 1 fills the chamber 11 and presses the walls 8 of the sleeve 4 to the walls of the chamber 11. The needle 13 is drawn into the shutter 12. The valve 6, under the action of the elastic forces of the shell 1, sits in place, the elastic walls of the tube 5 are compressed. The igniter 7 is initiated, the propellant and the shell 1 are burned. The projectile 10 and the cylinder 9 are ejected from the bore. To discharge from the shutter 12, the needle 13 is extended, which passes through the elastic plug 5 and raises the valve 6. Through the channel 14, the liquid propellant is sucked out from under the sheath 1. The needle 13 is drawn into the shutter 12. The shutter 12 opens. The sleeve 4 is pulled out of the chamber 11, followed by the shell 1, the cylinder 9 and the projectile 10 are pulled behind the shell. For reuse of the projectile holder, the shell 1 is compressed in the cylinder 9, which is inserted into the sleeve 4 with an interference fit.

 The holder of the projectile shown in figure 3, operates as follows.

 The projectile holder connected to the projectile is fed and sent to the gun chamber. Through the elastic plug 6, pushing its elastic walls apart, a needle is inserted, which lifts the valve 7, stretching the sheath 1 above the valve. A liquid propellant is fed through the needle, which through holes 2 enters under the sheath 1. Under the pressure of the propellant, the projectile 9 is pushed out of the sleeve 4 and sent to the bore, the shell 1 fills the chamber. The needle is removed from the elastic plug 6. The valve 7 under the action of the elastic forces of the sheath 1 sits in place. An igniter device 8 is initiated, a beam of fire through holes 3 ignites a propellant that burns together with the shell 1. The projectile 9 is ejected from the barrel. After opening the shutter, the sleeve 4 is extracted. When discharging through the elastic stopper 6, a needle is inserted that lifts the valve 7. Through the needle, the propellant is sucked out from under the sheath 1. The needle is pulled out of the elastic stopper 6, valve 7 sits in place. The sleeve 4 is pulled out and pulls the shell 1, which extends the shell 9. For reuse of the shell holder, the shell 1 is compressed in the sleeve 4, the shell 9 is inserted with an interference fit into the sleeve 4. To disassemble the holder of the shell from the sleeve 4, the sleeve 5 is turned out, the shell 1 is released and together with the projectile 9 is removed from the sleeve 4. Assembly is carried out in the reverse order.

 The holder of the projectile shown in figure 4, operates as follows. The holder of the projectile is fed into the chamber 9 (Fig.7). Shutters 10 and 11 close. From the shutter 11, the needle 12 extends, which passes through the elastic tube 2 and the elastic tube 5, pushing their elastic walls. From the channel 13 through the gap between the elastic stopper 2 and the elastic stopper 5, liquid fuel is supplied under the casing 1. From the channel 14, a liquid oxidizing agent is supplied under the sheath 4. Under the pressure of the fuel, the sheath 1 fills the chamber 9 with an emphasis on the shutter 10. Under the pressure of the oxidizing agent, the sheath 4 is pulled all the way into the sheath 1 and the shutter 10. An igniter 6 is initiated, which when triggered generates pressure in the chamber 9, under the action of which the walls 7 compress the elastic the plug 2, and the shells 1 and 4 are torn opposite the nozzle 15. The fuel and oxidizer are mixed and ignited. At the same time, the shells 1 and 4 are burned. The combustion front moves frontally along the entire length of the chamber 9. The resulting gases are ejected through the nozzle 15, providing a relatively constant pressure in the bore. Fuel, oxidizer, shells 1 and 4, and elastic plug 5 are burned. The elastic stopper 2 is compressed by the walls 7 of the igniter 6, does not burn and provides a seal for the chamber 9. The shutter 11 opens, the sleeve 8 is extracted. When discharging from the shutter 11, the needle 12 is extended, which passes through the elastic stopper 2 and the elastic stopper 5. Fuel is sucked out through channel 13, and oxidizer is sucked out through channel 14. The needle 12 is pulled into the shutter 11. The shutter 11 opens, the sleeve 8 is pulled out and pulls out the shells 1 and 4. For reuse of the projectile holder, the shells 1 and 4 are compressed and fit into the sleeve 8.

 The holder of the projectile depicted in figure 5, operates as follows.

 Through an elastic stopper 3, pushing its elastic walls, a needle is inserted under the sheath 1, through which the propellant is injected. Under the pressure of a liquid propellant, the shell 1 extends from the sleeve 1 and fills the chamber of the weapon. The needle is pulled out of the elastic plug 3. An igniter 6 is initiated, a beam of fire ignites the propellant through the holes 2. The gas pressure in the chamber wall 5, the holes of the sleeve 4 compress the fireproof elastic plug 3, which provides sealing. Shell 1 burns with the propellant. After the shot, the sleeve 4 is extracted from the chamber. When discharged through an elastic plug 3, a needle is inserted under the sheath 1, through which a liquid propellant is aspirated. The needle is pulled out of the elastic plug 3. The projectile holder is removed from the weapon chamber. For reuse of the projectile holder, the shell 1 is compressed and fits into the sleeve 4.

Claims (8)

 1. The holder of the projectile for a firearm using a liquid propellant containing an element in the form of a sleeve with an opening in the bottom and an ignition device, characterized in that a shell of a sealed combustible material capable of changing dimensions and shape is placed and attached to the lower part of the sleeve An elastic plug is installed in the opening of the bottom of the sleeve, and an igniter is placed at the bottom of the sleeve.  2. The holder according to claim 1, characterized in that it contains a shell of a smaller size with an elastic stopper in the neck, which is attached coaxially and with a gap to the elastic stopper located in the opening of the bottom of the sleeve.  3. The holder according to claim 1, characterized in that a valve is installed in the sleeve between the elastic stopper and the sheath.  4. The holder according to claim 1, characterized in that the elastic stopper is located in an annular igniter device, the inner wall of which is made in the form of a truncated cone with an apex inside the sleeve.  5. The holder according to claim 1, characterized in that the portion of the sleeve containing the elastic plug is made in the form of a truncated cone with an apex inside the sleeve.  6. Holder according to any one of paragraphs. 1 to 5, characterized in that the shell is attached to the shell.  7. The holder according to claim 1 or 6, characterized in that the shell is covered by a cylinder, which is removably mounted on the sleeve and attached to the shell.  8. The holder according to claim 7, characterized in that the elastic plug is fixed in the neck of the shell, under which there is a cylinder with holes and an ignition device, the cylinder is coaxially attached to the elastic plug, and on the surface of the shell around the elastic plug in the radial direction, ropes are fixed with a gap from kartuznoy fabric.

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