NL8701908A - Projectile head. - Google Patents

Description

Proj ectile head

A highly efficient head consists of a flying frame that contains two explosive charges with Munroe effect that are located behind each other on opposite sides of a barrier.

The charges are successively detonated as a projectile carrying the head, approaching a target and the combined effect of the two charges can penetrate and destroy the target.

The effective operation of the rear or secondary charge requires it to be protected from the disruptive effects of the detonation on the front, or primary charge during its formation sequence. In the past, this has been achieved by providing a barrier in the form of a mass adjacent to the primary charge and spaced from the secondary charge. The mass is accelerated to the secondary charge under the influence of the air pressure in the detonation of the primary charge, and the free space present between the mass and the secondary charge is of such a dimension that complete formation of the penetration capacity of the second charge has time to develop before the mass reaches the second charge. For example, the longitudinal dimension of the free space present between the mass and the secondary charge is about 1 to 1.5 times the body diameters of the projectile's flight frame. In modern weapon systems there is a strong tendency towards higher packing density, and thus the inclusion of such a relatively large empty space within the body of a weapon is undesirable.

An earlier proposal described in GB-A-2141809 describes an armor-piercing projectile, which after firing separates into two separate parts, each containing an explosive charge with Munroe effect. The two parts fly independently and arrive at the target one after the other. However, the different flight characteristics of the two parts mean that they often do not hit the same part of the target and so their joint effect is lost.

According to the present invention, a projectile head consists of a flying frame having separate primary and secondary explosive charges arranged one behind the other on a barrier side, which are sequentially detonated during use and which are movable away from each other while spaced apart. they are still enclosed by the flight gear prior to detonation to prevent detonation of the primary charge from improperly interfering with that of the secondary charge, which head also includes means for detonation after the projectile is launched and prior to head detonation cause the relative movement between the charges.

The means to cause the relative movement between the charges can be accomplished by deploying an anchor parachute coupled to the secondary charge and thus arranged to pull the primary charge during flight from the projectile. Alternatively, the means for causing the relative movement between the charges may be in the form of some energy storage device, such as a spring or a gas charge adapted to drive the two charges apart to their position in which they are distance from each other. It is preferred that the anchor parachute or energy storage device should only fire when the projectile approaches the end of any ballistic flight or when it approaches its target.

The secondary charge can easily move backward relative to the rest of the projectile and head or alternatively the primary charge and barrier may be arranged to move forward relative to the secondary charge and elements of the head or projectile. In this way, the separation of the barrier and the primary charge is constant and the separation between the barrier and the secondary charge increases as the charges move apart.

The projectile can be a grenade or a missile and the projectile preferably has a directional control system. If the projectile has a forward-facing directional control system that uses, for example, canards or thrusters located near the front of the projectile, the secondary charge is preferably arranged to move rearwardly relative to the rest of the projectile. In this way, with the secondary charge in its forward position, the projectile firing position, the projectile has the greatest aerodynamic stability. However, when the secondary charge moves rearward, it moves the projectile's center of gravity backward and moves closer to the projectile's center of pressure, allowing better maneuvering and increasing the steering torque of the front-mounted steering system. If the projectile has a tail steer system, it is preferable that the primary charge and barrier move forward relative to the missile's secondary charge and tail steer system, leading to forward motion of both center of gravity and center of pressure and again leading to lower stability when the charges are moved apart as the projectile approaches its target, allowing better maneuvering of the projectile.

Moving the two charges apart can be initiated by, or used to initiate a head reinforcement system, and in this case is initiated just prior to impact. It can be initiated by applying a signal pulse to some form of latch system to overcome a limitation in moving the two charges apart. Alternatively, moving the two charges apart can be used to initiate an armament system, and in this case initiating the moving of the charges occurs at a predetermined time after launch, and completing the movement of the charges apart causes the armament system to assume its active state.

The invention will be explained in more detail below with reference to the drawing, which shows by way of example an embodiment of a projectile head according to the invention. In the drawing shows:

Figure 1 shows a schematic of the head;

Figure 2 shows a sketch of a conventional projectile Figures 3A and 3B diagrams of a two-stage warhead according to the invention, Figure 3A shows the projectile before deployment, and Figure 3B shows the projectile after deployment when it is about to hit a target ;

Figures 4A and 4B are diagrams similar to that of Figure 3 to illustrate the improvement in control that occurs with the present invention; and

Figures 5A and 5B are diagrams of a second example of the invention which also illustrates the improvement of the control.

Figure 1 illustrates the principle of a head according to the invention and shows that the head contains a primary charge 1 located at the front of a secondary charge 2 viewed in the direction of escape of the head and, consequently, in its attack direction. Figure 2 shows a known two-stage head arrangement in which the primary charge 1 is located at the front of the flight frame of a projectile 3, and a secondary charge 2 located rearward of the frame of the projectile 3.

A barrier formed by a mass 4 is located adjacent to the primary charge 1 and a free space 5 is provided between the mass 4 and the secondary charge 2 "

In the first example of the invention, shown in Figure 3, Figure 3A shows the projectile in its deployed state, and in this state the secondary charge 2 is adjacent to the mass 4. This first example also includes an anchor parachute 6 which is wrapped in the tail of the projectile 3 and is connected to the secondary charge 2. During the flight of the projectile and as it approaches its target, the anchor parachute 6 is deployed and, since it is connected to the secondary charge 2, it decelerates these so that it moves backwards with respect to the closure 4 and the flying frame, to provide the free space 5 between the closure 4 and the secondary load 2.

Figure 4 shows the projectile shown in Figure 3, but also illustrates its center of gravity 7 and center of pressure point 8. The figures show how the center of gravity and center of pressure move closer together after the secondary charge 2 has moved backwards relative to the remainder of the projectile 3, thereby reducing the static clearance SM and increasing the steering arm CA, which is the distance between the point at which the steering force from thrusters or canards located towards the nose of the projectile 3, and the center of gravity 7.

Figure 5 shows the different configuration of the projectile with tail control surfaces 9. The body 3 of the projectile has a nose portion 10 containing the primary charge 1 and closure 4, and a tail section 11 carrying the control surfaces 9 and containing the secondary charge 2. The nose portion 10 and the tail section 11 of the flying frame telescope together. Before deployment, the two parts of the flight frame are written together as much as possible, with the secondary charge 2 abutting the barrier 4 and this is the state of the projectile in which it is launched. As the projectile approaches its target, the nose portion 10 and tail section 11 are moved apart, either by deploying an anchor attached to the tail section, or by means 12, such as relieving a spring or inflating a gas bag that between the two acts to drive the nose portion 10 away from the tail section 11 to the position shown in Figure 5B. This provides the free space 5 between the mass 4 and the secondary charge 2. Movement of the nose portion 10 advances the center of gravity 7 a greater distance than the center of pressure 8 and accordingly reduces the static clearance SM again and increases the control arm CA.

Claims (7)

Projectile head, consisting of a flight frame with separate primary and secondary explosive charges, which are arranged one behind the other on a barrier side and which are sequentially detonated during use, characterized in that the primary (1) and secondary (2) charges can be moved away from each other to a spaced position, while still being enclosed by the flight gear prior to detonation to prevent detonation of the primary charge (1) from interfering with that of the secondary charge inappropriately ( 2), and that the head also has means (6,12) to cause the relative movement between the charges (1 and 2) after launching the projectile and before detonating the head. Projectile according to Claim 1, characterized in that the means for causing relative movement between the charges consist of an anchor parachute (6) coupled to the secondary charge (2) and are arranged to pull it away from it during use. the primary charge (1) during flight of the projectile. Projectile according to claim 1, characterized in that the means for causing relative movement between the charges (1 and 2) are in the form of a device (12) for storing energy arranged every two charge (1 and 2) charges to each other in their spaced position. Projectile according to one of the preceding claims, characterized in that the secondary charge (2) moves backwards relative to the flight frame of the projectile. Projectile according to claim 4, characterized in that a forward direction steering system is also arranged. Projectile according to any one of claims 1 to 3, characterized in that the primary charge (1) and the closure (4) are arranged to move forward relative to the secondary charge (2). Projectile according to claim 6, characterized in that a rearward direction steering system (9) is also arranged.