SE507777C2 - Artillery shell firing method - Google Patents

Abstract

A method for controlling the combustion of an end-burning explosive charge (4) comprises supplying an electric current through the charge combustion zone (9) using conductors (e.g. wires) which run the length of the charge. These conductors are connected to a power source (27) and are also used to remove current from the charge. A projectile firing device utilising this method is also claimed, comprising a firing tube (1), a projectile (3) and an explosive charge (4) located behind the projectile, designed to be burnt in order to fire the projectile out of the tube. At least one pair of conductors are provided, along with tools (7, 8) for connecting the conductors to the power source.

Description

507 777 with the rails or of ionized gas, a plasma. Other rail cannon configurations that instead of two parallel rails use several pairs of rails, coaxial current conductors or more complicated wiring of the current conductors to amplify the magnetic field behind the luminaire, so-called reinforced rail cannons, are also known.

An object of the present invention is to provide a method of increasing and controlling the combustion rate of an end-burning propellant charge charge and to provide an improved projectile launch device using the method.

This is achieved by a method and a launching device as defined in the claims.

The invention is based on the realization that when burning gunpowder, the reaction / combustion zone outside the gunpowder surface is highly ionized and therefore well electrically conductive, while the unburned charge, as well as the combusted gunpowder gases, are essentially to be regarded as insulators in comparison. According to the invention, electric current is conducted through the combustion zone so that the temperature is raised, whereby a significant increase in the combustion rate is achieved.

The invention is applicable to an end-burning propellant charge which is combusted in a chamber of some kind. The method according to the invention is characterized in that electric current is supplied through the combustion zone of the charge and that the current is led to the zone and is diverted from the zone via current conductors, which are arranged along the charge and connected to a current source.

According to an embodiment of the invention, the current conductors are arranged along the charge in a rail cannon configuration, and the current connection to said conductor is selected so that the combustion zone, like a plasma fitting, is pressed against the burning end surface of the charge by the generated Lorentz force.

The supplied current increases the combustion rate of the powder by electrical power generation in the combustion zone, whereby the temperature increases in the combustion zone and on the unburned powder surface. In addition, the electrical energy supplement in a known manner means that the temperature and thus also the pressure increases in the already burned gunpowder.

When the current conductors are arranged in a rail cannon configuration, it is also achieved that the resulting Lorentz force gives a pressure gradient towards the powder surface and increases the pressure in the combustion zone and forces the current, which is the source of the energy supplement, in paths even closer to the powder surface.

The method is primarily intended for propellant charges in projectile launchers, whereby the propellant charge is combusted from its end facing the projectile.

By varying the strength and time course of the current, the combustion can be controlled to provide maximum performance. A more favorable pressure-time curve can be achieved in the barrel.

The pressure due to the Lorentz force gives an increased pressure only locally in the combustion zone and on the powder surface.

The end-burning propellant charge can be made compact with a charge density close to TMD while achieving a high combustion rate through the new way of increasing and controlling the combustion rate. A compact charge is mechanically strong and less sensitive than a loose-packed charge and allows greater freedom in the choice of fuel. Possibly, energy-rich explosives such as CL-20, HMX and TNAZ are used.

Because the charge is stationary during combustion, a higher reproducibility is also achieved. In a conventional charge, the gunpowder pieces can move around freely during combustion and break against each other and the barrel wall, whereby the burning area can be changed.

The invention also relates to a projectile launching device, preferably a cannon, in which the method is applied. Launching device comprising a barrel, a projectile and a propellant charge arranged behind the projectile, which is arranged to be combusted from its end facing the projectile and thereby generate a combustion zone at the end surface of the charge. The device is characterized by at least a pair of current conductors, which extend along the charge and are arranged to be placed in conductive communication with each other via the combustion zone during the combustion of the charge and means for connecting the current conductors to a current source. According to one embodiment, the current conductors extend along the charge in a rail cannon configuration and the connection of the current conductors to the current source is so oriented that the combustion zone, like a plasma fitting, is pressed against the burning end surface when current is supplied through the circuit.

According to a further embodiment of the launching device, the propellant charge and parts of the current conductors are arranged in an ammunition sleeve. The invention will be described in more detail below in connection with the accompanying figures.

Fig. 1 schematically shows a section through an embodiment of a cannon according to the invention.

Fig. 2 shows a corresponding section through a gun where the current conductors are arranged in a rail gun configuration.

Fig. 3 schematically shows a section through an embodiment of a cannon according to the invention for sleeve-bound ammunition.

Fig. 4 shows a section A-A through the device according to Fig. 3.

Figures 5-11 show examples of different rail cannon configurations.

Fig. 5 shows a simple rail gun configuration with a pair of parallel rails.

Fig. 6 shows a section through a barrel with a square barrel and a pair of rails.

Fig. 7 shows a section through a barrel with a cylindrical bore and a pair of rails.

Fig. 8 shows a section through a barrel with a cylindrical barrel and two pairs of rails.

Fig. 9 shows a configuration for a reinforced rail gun.

Fig. 10 shows a coaxial rail gun configuration.

Fig. 11 shows a section through a barrel with coaxial rail cannon configuration.

Figure 1 schematically shows a longitudinal section through the rear part of a cannon comprising a barrel 1 with a combustion chamber 2, a projectile 3 and a compact propellant charge arranged in the combustion chamber 4. Current conductors in the form of two electrically conductive rails 5 and 6 extend along the charge and further out through the rear of the cannon or combustion chamber wall. The rails are provided with connectors 7 and 8 for connection to a current source 27 arranged outside the gun, e.g. a pulsed power plant. Rails 5 and 6 are arranged diametrically opposite each other in the combustion chamber 2 and run axially along the outside of the charge and in contact therewith.

The rails are insulated from the combustion chamber wall or the combustion chamber may in its entirety be made of an electrically non-conductive material, e.g. a fiber composite or ceramic.

An alternative embodiment is to arrange the current conductors coaxially, whereby the fire tube can be used as one of the current conductors. 10 15 20 25 30 35 507 777 The figure shows the ongoing combustion of the propellant charge and 9 denotes the combustion zone of the charge which contains a high degree of ionized gas. The burned gunpowder gases 10 and the propellant charge 4 lack or have low electrical conductivity in relation to the combustion zone 9.

Figure 2 shows an embodiment which differs from Figure 1 in that the two electrically conductive rails 5 and 6 form a rail cannon configuration and extend along the charge, out through the fire tube 1 and a distance forward along the fire tube. At their forward, facing ends of the barrel mouth, the rails are provided with the connectors 7 and 8 for connection to the current source 27.

Details that correspond to each other in the different figures have been given the same reference designation.

The launching device works as follows: The compact propellant charge 4 ignites in its front end facing the projectile and an end combustion starts. The combustion generates a combustion zone 9, which has electrical conductivity, near the end surface 11 of the charge. The rails 5 and 6 are supplied with current through the current source 27 connected to the connectors 7 and 8. The circuit is closed through the combustion zone 9. When the rails are arranged in rail cannon configuration (figure 2) the combustion zone 9 will correspond to the plasma luminaire in a rearwardly directed rail cannon and a luminaire stream I through the combustion zone (plasma luminaire) and the rails 5 and 6 as shown by pillar figure 2. giving rise to a Lorentz force FL, which presses the combustion zone 9 against the burning end surface 11, increases the pressure in the combustion zone and forces the current in paths closer to the powder surface.

The current through the combustion zone provides an electrical power development that raises the temperature in the combustion zone and heats the not yet gasified fuel surface. Because the combustion rate of the gunpowder is pressure and temperature dependent, the arrangement according to the invention provides a combustion rate increasing effect.

In addition, the electrothermal energy supplement provides a higher temperature and thus higher pressure of the combusted gases.

The combustion of the propellant charge can be controlled to obtain the best performance by varying the current to the rails. For example, the current source 27 may be a pulsed force plant, where the amplitude, shape and duration of the pulse may be varied. 507 777 10 15 20 25 30 35 Figures 3 and 4 show an alternative embodiment for sleeve-bound ammunition. Figure 4 shows a section A-A through the device according to figure 3. 12 denotes a sleeve of an electrically non-conductive material. 19 denotes details of an electric ignition system for igniting the propellant charge at its front projectile-facing end. The current conductors, which in the embodiment shown form a rail cannon configuration, are partly arranged in the sleeve and consist of two rails 13 and 14 in the sleeve and as a continuation of these two further conductors 15 and 16 outside the sleeve. The latter pass through the fire tube 1 and continue a short distance along the outside of the fire tube and end with connectors 7 and 8 for connection to a power source. The current connection to the conductors is thus oriented in front of the sleeve 12. The rails 13 and 14 are arranged diametrically opposite each other on the inner wall of the sleeve and extend axially along the charge. In the front part of the sleeve, the rails 13 and 14 pass through the sleeve wall and form contact means 17 and 18 on the outside of the sleeve. The members 15 and 16 are attached to the cannon's barrel and are brought into contact with said contact means when the sleeve is moved into position in the cargo space. The cannon works in the same way as described in connection with Figures 1 and 2.

Various known rail cannon configurations that can be used in the invention are shown in Figures 5-11. Figure 5 shows a simple rail gun configuration with two parallel current conductors in the form of rails 20 and 21, which are connected by a luminaire 22, e.g. a plasma.

When a current I is fed through the rails, the magnetic fields interact around the current-conducting conductors and give rise to a Lorentzkraft FL on the luminaire.

Figure 6 shows a section through a fire tube 1 with built-in current conductors which form a simple rail cannon configuration in a square barrel. Figures 7 and 8 show the corresponding section through a barrel with a cylindrical bore. In Figure 7 with simple rail cannon configuration and in Figure 8 with double pairs of current conductors.

Figure 9 shows an example of a configuration for a so-called reinforced rail cannon. The current conductors in this case are drawn so that you get several conductors with the same current direction on each side of the luminaire and thereby a reinforced magnetic field. In such a configuration, it is also possible to connect the current source at the end of the rail gun to which the Lorentz force is directed, e.g. in points 23 and 24 of the figure, Figure 10 shows a coaxial rail cannon configuration and Figure 11 shows a section through a barrel 1 with such a rail cannon configuration. In this case, a pair of current conductors is formed by a tubular conductor 25, which forms the barrel of the barrel, and a second conductor 26, which is arranged centrally in the barrel, coaxial with the tubular conductor.

Claims (10)

507 777 10 15 20 25 30 35 Patent claim. Method of controlling the combustion of an end-burning propellant charge (4), characterized in that electric current is supplied through the combustion zone (9) of the charge and that the current is conducted to the zone and is diverted from the zone via current conductors extending along the charge and connected to a power source (27). Method according to claim 1, characterized in that the current conductors are arranged along the charge in a rail cannon configuration, and that the current connection to said conductor is oriented so that the combustion zone (9) is pressed like a plasma fitting against the burning end surface (11) of the charge of the resulting Lorentz . Method according to Claim 1, characterized in that the propellant charge (4) is arranged in a projectile launching device and is combusted from its end towards the projectile (3). Method according to claim 1, characterized in that the propellant charge (4) is compact and has a density close to the theoretical maximum for the propellant. Method according to Claim 1, characterized in that a pulsed power plant is used as the current source (27). Method according to Claim 1, characterized in that the current to the current conductors (5, 6) is varied during combustion. A projectile launching device comprising a barrel (1), a projectile (3) and a propellant charge (4) arranged behind the projectile which is arranged to be combusted from its end facing the projectile and thereby generate a combustion zone (9) at the end surface (11) of the charge. characterized by at least one pair of current conductors, which extend along the charge and are arranged to be put in conductive communication with each other via the combustion zone (9) during the combustion of the charge, and means (7,8) for connecting the current conductors to a current source (27). Projectile launch device according to claim 7, characterized in that the current conductors are arranged along the charge in a rail cannon configuration and that the connection of the current conductors to the power source (27) is oriented so that the combustion zone (9) is pressed against the burning end surface (11). kret- Sen. 507 777 Projectile launching device according to one of Claims 7 to 8, characterized in that the propellant charge (4) and parts of the current conductors are arranged in a sleeve (12). Projectile launching device according to claim 9, characterized in that the current conductors consist of at least a pair of electrically conductive rails (13, 14), which extend along the charge in the sleeve (12), and via contact means (17, 18) in the front part of the sleeve continue in shape. of the corresponding at least one pair of electrical conductors (15,16) extending through the barrel (1) and some distance along the barrel.