RU2115085C1 - Charge pad and device for adiabatic ignition of powder charge - Google Patents

Abstract

FIELD: ignition of powder charges. SUBSTANCE: charge pad has a case-like body with a bottom having a hole with an adjacent section used to receive the igniter plate initiated by hot gas fed through the hole, and a section used to receive powder charge ignited by the igniter plate; the pad has a burning chamber for swirling of fragments of the igniter plate with hot gas and for burning of ignitor plate located between the section receiving the igniter plate and section receiving the powder charge. The device for adiabatic ignition of powder charge has a body with a compression chamber, piston for movement in the compression chamber and intended for compression of gas in the compression chamber, the charge pad is located in the body inlet chamber and has a case-like body with a bottom with a hole, section receiving the powder charge and section for receiving the igniter plate; the inlet chamber through a connecting hole, used to feed compressed hot gas, communicates with the compression chamber; in addition, the pad has a burning chamber for swirling of fragments of the igniter plate with hot gas and for burning of igniter plate located between the section for receiving the igniter plate and section receiving the powder charge. EFFECT: reduced energy required for ignition of igniter plate. 9 cl, 1 dwg

Description

 The invention relates to ignition devices, in particular to a charging cap and a device for adiabatic ignition of a powder charge.

 Known charging cap containing a sleeve-like housing with a bottom, in which a hole is made, a section adjacent to the hole for receiving an incendiary plate initiated by a hot gas entering through an opening, and a section for receiving a powder charge ignited by an incendiary plate (application DE N 4140020, MKI B 25 C 1/10, 1992). A device for adiabatic ignition of a powder charge is also known from the indicated source, comprising a housing in which a compression chamber is made, a piston movably directed in the compression chamber and used to compress the gas located in the compression chamber, and a charging cap located in the receiving chamber of the housing and comprising a sleeve-like housing with a bottom in which a hole is made, a section for receiving a powder charge and a section for receiving an incendiary plate, the receiving chamber through the connecting hole A hole for supplying compressed hot gas is in communication with the compression chamber.

 A disadvantage of the known charging cap and device is that a relatively high ignition energy is required for adiabatic ignition of the powder charge.

 The basis of the invention is the creation of a charging cap and a device for adiabatic ignition of a powder charge, in which the energy required for ignition of the incendiary plate is reduced.

 The problem is solved in the proposed charging cap containing a sleeve-like body with a bottom, in which a hole is made, a section adjacent to the hole for receiving an incendiary plate initiated by hot gas coming through the hole, and a section for receiving a powder charge ignited by an incendiary plate, due to that it contains a combustion space located between the area for receiving the incendiary plate and the section for receiving the powder charge to swirl the debris of the incendiary plate with hot gas and for burning an incendiary plate.

 In addition, the problem is solved in the proposed device for adiabatic ignition of a powder charge, comprising a housing in which a compression chamber is made, a piston movably directed in the compression chamber and used to compress the gas located in the compression chamber, and a charging cap located in the receiving a housing chamber and comprising a sleeve-like housing with a bottom in which an opening is made, a portion for receiving a powder charge and a portion for receiving an incendiary plate, the receiving chamber through soy An expansion hole for supplying compressed hot gas is communicated with the compression chamber due to the fact that the charging cap further comprises a combustion space located between the section for receiving the ignition plate and the section for receiving the powder charge to swirl fragments of the ignition plate with hot gas and to burn the ignition plate.

 According to the invention, a cavity is provided between the ignition plate and the powder charge (hereinafter referred to as the combustion space), which is blocked by the ignition plate towards the connecting hole. Coming through the connecting hole compressed hot gas enters the incendiary plate and destroys it. The debris enters the combustion space located behind the incendiary plate in the direction of gas supply, where they swirl with hot compressed gas. Comprehensive washing of individual fragments of a destroyed incendiary plate with hot compressed gas leads to a significant increase in their surface. This greatly improves the introduction of energy into the material of the incendiary plate, so that in the proposed charging cap and in the proposed device requires less energy for ignition. This further means that the proposed device can be made with a shorter stroke and a smaller piston diameter. In addition, the spring force for preloading the piston may be less. Reducing the energy required to ignite the incendiary plate, as a result, leads to the fact that it is possible to carry out the entire device for adiabatic ignition of the powder charge (for example, to a construction gun or to a weapon) small-sized.

 In experiments on the ignition principle of the proposed cap and device, it was found that an extremely short piston stroke of the order of 10–25 mm with an extremely small piston diameter of the order of 5–10 mm and a relatively small spring force of the order of 100–200 N is sufficient to ignite the ignition plate with compressed almost adiabatically air . It turned out that for ignition of an incendiary plate, a pressure of about 60 - 80 bar on average is sufficient. This is due to the fact that due to the presence of the combustion space there is enough space for swirling and mixing individual fragments of the incendiary plate with hot compressed gas. It is only due to this that optimal introduction and transfer of energy is achieved.

 The proposed charging cap contains a closed sleeve-like housing in which there is an incendiary plate and a powder charge, while in the bottom of the housing there is a hole located coaxially with the connecting hole covered by a thin membrane. The latter serves to protect the cap from moisture.

 To fix the incendiary plate, the proposed cap contains a holder made with a cavity open on one side. A recess has been made on the open side of the cavity for receiving the incendiary plate. When the incendiary plate is placed in the recess, it covers the cavity, which then forms the combustion space, in which fragments of the incendiary plate swirl and burn. The cavity is separated from the site for receiving the powder charge by means of a thin wall of the holder. This wall, which, like the entire holder, is preferably made of plastic, is destroyed when the incendiary plate is burned in the cavity (combustion space). In this case, hot gaseous products of combustion enter the site for receiving a powder charge.

 The material of the incendiary plate is preferably free of lubricants, thereby preventing erosion of the cap. Preferably, it is a sensitized material, in particular sensitized nitrocellulose. As a sensitizer used, for example, tetrazene. Due to this, harmful substances are not released during combustion of the ignition plate. It does not contain heavy metals.

 It is advisable to make an incendiary plate with a zone of smaller thickness, and this zone is located coaxially with the connecting hole and with the hole made in the bottom of the sleeve-like case of the cap. Due to the presence of the said zone of smaller thickness, in which the mechanical stability of the incendiary plate is reduced, when exposed to pressure from a hot compressed gas, the incendiary plate collapses faster. Therefore, in the zone surrounding the zone of smaller thickness, the incendiary plate is made with a thickness providing sufficient material for reliable ignition of the powder charge.

 Preferably, the zone of smaller thickness of the ignition plate at least partially covers the combustion space. The zone of reduced thickness is formed due to the fact that the incendiary plate on both sides is provided with a recess on the edge made with a thickened wall. The thickness of the incendiary plate in the zone of smaller thickness is from about half to one sixth of the maximum thickness of the incendiary plate.

 According to a preferred embodiment of the device according to the invention, the compression chamber and the receiving chamber are connected to each other through a check valve, which serves to prevent the backflow formed during the combustion of the ignition plate and the powder charge of the combustion gas products into the compression chamber. Depending on the type of device for adiabatic ignition of the powder charge, it may be advisable to prevent the piston from moving backwards with the reverse gaseous products of combustion and to fully use the energy generated during the combustion of the powder charge for ignition. Such a check valve is available in the device, which serves to ignite the hot gas charge for the projectile.

 According to another preferred embodiment of the device according to the invention, the check valve comprises a valve chamber in which the ball is placed. The valve chamber is made in the connecting hole between the compression chamber and the camera for receiving the cap. Through the central hole with the seat, the valve chamber is in communication with the compression chamber, while it is in communication with the camera for receiving the cap through the hole entering the valve chamber is not central. Due to the entrance of this hole into the valve chamber outside its center, the connecting hole between the compression chamber and the camera for receiving the cap is not closed by the ball when hot gas enters, while when the hot gas returns from the camera for receiving the cap into the valve chamber, the ball is pressed tightly to the seat . Preferably, the ball is freely mounted in the valve chamber, so that high pressure is not required to control the check valve.

 Below with reference to the attached drawing describes one example of the invention. The drawing shows a partial longitudinal section through equipped with the proposed charging cap device for adiabatic ignition of the powder charge.

 A device 1 for igniting a powder charge by adiabatic compression of air, presented in partial section, contains a housing 2, which can be made either as a whole, or can consist of several parts. According to the embodiment shown in the drawing, a cylindrical compression chamber 3 and a chamber 4 for receiving a charging cap 5 are made in the housing 2. The chambers 3 and 4 are separated from each other by an insert 6 inserted into the housing 2. In the compression chamber 3, the piston is axially moved 7, equipped with an annular seal 8, located between the piston 7 and the piston plate 9. The piston 7 is installed with the possibility of installation with preload in the direction of arrow A, for example, using springs not shown in the drawing s. With a pre-loaded piston 7, the latter, when subjected to this load, moves in the direction of arrow A towards the insert 6. In this case, the air in the compression chamber 3 is compressed, and it heats up. Hot compressed gas enters the check valve 10, made in the insert 6, and from there into the chamber 4, where it enters the cap 5. The implementation of the check valve 10 is described in more detail below.

 The charging cap 5, made of plastic and placed in the chamber 4, contains a mainly cylindrical sleeve 11, open from the upper side and made of plastic. The sleeve 11 is provided with a bottom 12. A plastic cap 13 is inserted into the open end of the sleeve 11, which, by means of a snap-fit connection, is connected to the sleeve 11 and provided, for example, with a star-shaped recess. The snap connection is provided due to the annular protrusion 14 of the cap 13, interacting with the annular recess 15, made in the inner surface of the cylindrical part of the housing 11. In the bottom 12 of the housing 11 there is a Central hole 16, overlapped by a plastic membrane 17. The hole 16 is opposite to the entrance of the connecting hole 18 into the chamber 4. The connecting hole 18 is made in the insert 6 and when the check valve 10 is open, it serves to communicate the compression chamber 3 with the chamber 4 for receiving the cap 5.

 An incendiary plate 19 is placed in the cap 5, made of a sensitized material (nitrocellulose with tetrazene as a sensitizer). The incendiary plate 19 is a pressed product in the form of a plate adjacent to the inner side of the bottom 12 of the housing 11 and overlapping the hole 16. In the central zone 20, the incendiary plate is made with a much smaller thickness than in the edge zone 21. The incendiary plate 19 is opposite to the hole 16 zone 20 of lesser thickness, with a thick annular zone 21 adjacent to the bottom 12.

 Incendiary plate 19 is fixed in position by a holder 22, preferably made of plastic. The holder 22 is adjacent to the bottom 23, and its cross-section corresponds to the cross section of the sleeve 11. From the side turned away from the bottom 12, the holder 22 is provided with an annular protrusion 23, with which the end of the cap 13 that enters the sleeve 11 interacts. That is, the holder 22 is fixed in the axial direction a cap 5 between the bottom 12 and the cap 13. The space bounded by the holder 22 and the cap 13 is filled with a powder charge 24.

 The ignition plate 19, provided with a central recess 25 on both sides, is located in a recess 26 made in the holder 22. This recess 26 is made on the lower side of the holder 22 facing the bottom 12, and its depth corresponds to the thickness of the annular zone 21 of the ignition plate 19. Adjacent with a recess 26 in the holder 22 is made coaxial cavity 27 (hereinafter referred to as the combustion space). The combustion space 27 extends over almost the entire length of the holder 22 so that on the side of the powder charge 24 there is only a relatively thin wall 28 separating the combustion space 27 from the powder charge 24. From the bottom 12, the combustion space 27 is separated by an ignition plate 19, and its zone 20 smaller thickness covers the combustion space 27.

 As already indicated, a check valve 10 is placed in insert 6. The valve chamber 29 of the check valve 10 is formed in the connecting hole 18 made in the insert 6. A ball 30 is placed in the valve chamber 29. The camera 29 is in communication with the compression chamber 3 through the hole 31. In the zone the entrance of the hole 31 into the valve chamber 29 is formed by a seat 32, and when the ball 30 is pressed against the seat 32, the hole 31 closes mainly tightly. With the camera 4 for receiving the cap 5, the valve chamber 29 is connected through an opening 33 ending opposite to the hole 16 made in the bottom 12 of the housing 11 and overlapped by the membrane 17. The holes 31 and 33 and the valve chamber 29 form a connecting hole 18, through which, in that case if the ball 30 does not interact with the seat 32, the compression chamber 3 is in communication with the camera 4 for receiving the cap 5.

 The operation of the proposed device 1 for igniting a powder charge 24 by mainly adiabatic air compression is explained below.

 The piston 7 subjected to the load, which is in the rear starting position, after controlling it moves in the compression chamber 3 in the direction of arrow A. Moreover, the air in the compression chamber 3 is compressed and simultaneously heated. Hot compressed air through the connecting hole 18 enters the chamber 4 for receiving the cap 5, where it enters the membrane 17, overlapping the hole 16 made in the bottom 12. In this case, the check valve 10 is open, since the flow of compressed air coming from the compression chamber 3, the ball 30 is separated from the seat 32 and abuts against the opposite seat 32 by the end of the valve chamber 29. In this case, the hole 33 is not closed by the ball 30, because it enters the valve chamber 29 outside its center. Compressed air under high pressure destroys the membrane 17 and enters the incendiary plate 19 in its zone 20 of smaller thickness, which it also destroys. When this incendiary plate 19 breaks up into small fragments, in the combustion space 27 of the holder 22 in the direction of gas supply, located behind the incendiary plate 19, the fragments swirl with the incoming hot compressed air. Thus, a significantly larger contact surface of the ignition material with the hot compressed air is obtained, which ensures such an effective energy input that the material is ignited by the hot air. Combustion is also facilitated by the fact that due to the implementation of the annular zone 21 of the igniter plate 19 with a larger thickness, there is enough ignition material. Upon combustion of the ignition plate 19 and as a result of high pressure in the combustion space 27, the wall 28 is destroyed, separating the combustion space 27 from the powder charge 24, as a result of which hot gaseous products of combustion come into contact with the powder charge 24 and initiate it. When the pressure in the cap 5 exceeds the pressure in the compression chamber 3, the check valve is controlled so that the ball 30 is pressed back by the incoming gas to the seat 32.

Partially presented device 1 with a piston stroke of 16 mm, it is possible to achieve a pressure of 69 bar on average (50 - 80 bar), and with a piston stroke of 22 mm, a pressure of 74 bar (60 - 90 bar) can be achieved. The piston diameter is approximately 8 mm. According to this example of a specific implementation of the proposed device 1, the piston in its initial position is under a spring load with a force of 100 to 130 N. The diameter of the hole 31 is about 1.5 mm and the diameter of the hole 33 is about 0.7 mm. The hole 16, made in the bottom 12 of the sleeve-like body 11, has a diameter of 1.8 mm The diameter of the incendiary plate is 4 mm with a thickness of approximately 0.8 mm. Moreover, in zone 21, the thickness of the incendiary plate 19 is approximately 1.5 mm. The volume of the combustion space is 27 - 0.015 cm ³ .

Claims (10)

 1. Charging cap containing a sleeve-like housing with a bottom, in which a hole is made, a portion adjacent to the hole for receiving the incendiary plate initiated by the hot gas coming through the hole, and a section for receiving the powder charge ignited by the incendiary plate, characterized in that it contains between the section for receiving the ignition plate and the section for receiving the powder charge, the combustion space for swirling the debris of the ignition plate with hot gas and for burning the igniter linen plate.  2. A cartouche according to claim 1, characterized in that it comprises a membrane located in a hole made in the bottom and destroyed when hot gas enters.  3. A cartouche according to claim 1 or 2, characterized in that it comprises an incendiary plate holder adjacent to a site for receiving a powder charge and made with a stepped recess from the site for receiving a powder charge with a separate wall that is destroyed when the incendiary plate is burned, the inner a recess stage facing the site for receiving the powder charge forms a combustion space, and an outer stage, turned away from the site for receiving the powder charge, forms a site for receiving the incendiary plate.  4. A cartouche according to claim 3, characterized in that the stage of the recess of the holder forming the portion for receiving the incendiary plate has a larger cross section than the stage forming the combustion space.  5. A device for adiabatic ignition of a powder charge, comprising a housing in which a compression chamber is made, a piston movably located in the compression chamber and used to compress the gas located in the compression chamber, and a charging cap located in the receiving chamber of the housing and comprising a sleeve-like housing with a bottom in which a hole is made, a section for receiving a powder charge and a section for receiving an incendiary plate, the receiving chamber through a connecting hole for supplying compressed hot ha and communicates with the compression chamber, characterized in that the battery comprises a cap arranged between the portion for receiving incendiary plastics portion and for receiving the propellant charge combustion space incendiary fragments swirl plate with the hot gas to the combustion plate incendiary.  6. The device according to claim 5, characterized in that it contains a membrane installed in the hole of the bottom of the cap.  7. The device according to claim 5 or 6, characterized in that it contains an incendiary plate holder located in the cap adjacent to the site for receiving the powder charge and made with a stepped recess, separated from the site for receiving the powder charge by the wall that is destroyed when the ignition plate is burned moreover, the inner stage of the notch facing the site for receiving the powder charge forms a combustion space, and the external stage, turned away from the site for receiving the powder charge, forms a site for receiving incendiary oh records.  8. The device according to claim 5, 6, or 7, characterized in that it contains a check valve located between the receiving chamber and the compression chamber.  9. The device according to claim 8, characterized in that the check valve contains a ball located in the valve chamber, the check valve through the central hole communicating with the compression chamber, and through the eccentric hole with the receiving chamber.  10. The device according to claim 8 or 9, characterized in that the ball is placed in the valve chamber with the possibility of free movement.