RU2441193C1 - Separating high-explosive fragmentation warhead of volley fire rocket system - Google Patents

Abstract

FIELD: weapons and ammunition. ^ SUBSTANCE: separating warhead comprises a contact firing mechanism, an explosive, a body and a parachute system. The body is made as a combination of cylindrical and conical parts. In the bottom compartment of the warhead there is an additional detonator and a timer, preferably of a powder type. The area of the parachute system dome makes 0.45-0.55 of the area of the external surface of the body. The area of the surface of the conical nose part makes 10-20% of the total area of the external surface of the body. The distance between the warhead centre of gravity from the nose part of the body makes 0.55-0.6 of its length. ^ EFFECT: reduced consumption of charges for hitting standard targets. ^ 1 dwg

Description

The invention relates to the field of rocketry, and in particular to rockets of multiple launch rocket systems.

The object of the invention is a detachable high-explosive fragmentation warhead (OOFCH) to the rocket projectile (PC) of the multiple launch rocket system.

Multiple launch rocket systems (MLRS) are successfully used to combat many area targets. The high efficiency of the use of MLRS shells is achieved due to the possibility of delivering a massive missile strike to the dispersal area of the target at its relatively low cost. The use of high-explosive fragmentation warheads equipped with a contact fuse allows the warhead to be detonated on the ground surface, thereby defeating manpower, unarmored and lightly armored vehicles that are open on the ground both due to the formation of a fragmentation field and due to a high-explosive shock wave actions.

So known patent No. 2166172, adopted by the authors for an analogue that describes a high-explosive fragmentation warhead of a missile containing a fuse, a body, an explosive charge and a block of finished fragments. The objective of this technical solution was to increase the efficiency of the use of high-explosive fragmentation warheads in manpower and unarmored vehicles by increasing the speed and optimizing the direction of expansion of the finished fragments. However, the use of non-separable high-explosive high-explosive projectiles even in this case does not provide an optimal distribution of the fragmentation field, since the direction of fragmentation of the fragments is not parallel to the earth's surface, as a result of which the effectiveness of the destruction by the warhead of each shell is not maximum.

Common features with the design of the high-explosive fragmentation warhead of the multiple launch rocket proposed by the authors are the presence of an analogue shell with an explosive and a fuse.

To achieve maximum effectiveness of destruction by the warhead of each projectile, it is necessary to ensure an approach angle to the ground close to or equal to 90 °, and an angle of attack close to or equal to 0 °. In this case, the most effective fragmentation field is formed, uniformly distributed relative to the point of contact with the soil of the warhead and the direction of the expansion of the fragments parallel to the surface of the earth (see, for example, Gogin V., Fedoseyev A. Prospects for the development of multiple launch rocket systems // Foreign Military Review, No. 1, 1995). It is possible to achieve approach angles to the ground that are close to or equal to 90 ° by using brake systems with vertical trajectory. The most efficient way shells function with a warhead detaching along the trajectory, equipped with a braking parachute system (PS).

So known patent No. 2176375, which describes a detachable warhead, adopted by the authors as a prototype, containing a cylindrical body with a pointed nose, contact fuse, explosive and parachute system. The objective of this technical solution was to create a detachable warhead for a rocket of increased combat efficiency by obtaining the minimum dimensions and weight of the parachute system while ensuring the necessary stability and reliable retardation of the initial angular disturbances when separated from the missile part (RF).

Common features with the proposed by the authors detachable high-explosive fragmentation warhead are the presence in the prototype of a cylindrical body with a pointed nose, contact fuse, explosive and parachute system.

Detachable warhead, taken as a prototype, operates as follows. At a given point in the flight path of the rocket, the warhead is separated from the missile. After separation, the warhead, due to disturbances obtained during separation and the presence of a destabilizing moment of the bow, performs an unstabilized flight. Then, a parachute system is introduced into the oncoming air stream and its dome opens. The open dome increases the value of the stabilizing moment relative to the center of gravity of the warhead, which begins to make damped oscillations and stabilizes, providing flight with a close to zero angle of attack, braking and a vertical approach to the ground.

The design adopted by the authors for the prototype allows for the delivery of the payload to the target area with optimal parameters of the approach of the warhead to the ground, provided it is reliable and trouble-free. However, due to the complexity of the design of the input mechanism of the parachute system and the impossibility of accurately determining the operating conditions and parameters of the movement of the warhead after separation (since they depend on many random factors), it is impossible to ensure 100% reliable operation during movement after separation and commissioning of the aircraft. As failures, the possibility of not introducing a parachute system due to a malfunction or incorrect operation of the PS input mechanism and the possibility of destruction of the parachute system due to its entry in off-design modes or due to contact of the PS with the separated missile part is considered. This leads to the fact that there is a probability of failure of the functioning of the PC during movement after separation of the warhead from the RF. An unregulated ratio of the surface area of the canopy of the parachute system and the surface area of the warhead housing will lead to the fact that the trajectory of the warhead after separation during abnormal operation (in case of failure) can change significantly, without ensuring the delivery of the payload to the target area. In addition, the approach of the warhead to the ground surface will be carried out with an angle of attack close to 90 °, which will lead to contact with the ground mainly on the side surface of the warhead without providing a contact fuse. Thus, a missile operating abnormally after separation will not fulfill its combat mission.

Unlike the prototype, the detachable high-explosive fragmentation warhead of a multiple launch rocket has a parachute system dome area equal to 0.45-0.55 of the outer surface of the hull, the surface area of the conical nose is 10-20% of the total outer surface of the hull while the removal of the center of mass of the warhead from the bow of the hull is 0.55-0.6 of its length, and an additional detonator and timer, mainly of a powder type, are installed in the bottom compartment of the warhead. The selected ratio of the area of the outer surfaces of the hull with the conical bow to the area of the canopy of the parachute system in combination with the specified distance of the center of mass from the bow of the hull allows for delivery of high-explosive fragmentation warheads to the target area, even with abnormal functioning of the parachute system, and an additional detonator and timer installed in the bottom compartment of the warhead, provide its detonation after a specified time after the moment of separation in case of failure of the main contact explosion Atelier.

This allows us to conclude that there is a causal relationship between the totality of existing features of the claimed technical solution and the achieved technical result.

The objective of the invention is to reduce the consumption of rockets of multiple launch rocket systems with detachable high-explosive fragmentation warheads to defeat typical targets by ensuring the fulfillment of the assigned combat mission even in the event of a failure or abnormal functioning of the OOFCH after its separation from the missile unit.

The specified technical result is achieved in that the detonating high-explosive fragmentation warhead of a multiple launch rocket has a parachute system dome area equal to 0.45-0.55 of the outer surface of the hull, the surface area of the conical bow is 10-20% of the total outer the surface of the hull, while the removal of the center of mass of the warhead from the bow of the hull is 0.55-0.6 of its length, and an additional detonator and timer, mainly of a powder type, are installed in the bottom compartment of the warhead.

A new set of structural elements, as well as the presence of connections between parts of a detonating high-explosive fragmentation warhead, allow, in particular, due to

- the surface area of the conical nose, equal to 10-20% of the total area of the outer surface of the hull with the removal of the center of mass of the warhead from the bow of the hull equal to 0.55-0.6 of its length, to ensure the movement of the OOFCH after separation with an angle of attack close to to 90 °. The value of the surface area of the conical nose with respect to the total surface area of the warhead determines the position of the center of pressure, that is, the position of the point of application of the total aerodynamic force acting on the warhead during its movement after separation. An increase in the surface area of the conical nose relative to the total surface area of the warhead more than 20% shifts the position of the center of pressure back, which, with the center of mass equal to 0.55-0.6 of the length of the warhead, leads to an increase in the balancing angle of attack to 130- 140 °. A decrease in the surface area of the conical nose relative to the total surface area of the warhead less than 10% shifts the position of the center of pressure forward, which, when the center of mass is equal to 0.55-0.6 length of the warhead, leads to a decrease in the balancing angle of attack to 40- 50 °. In both cases, the drag force of the OOFBC hull decreases compared to the value obtained with a balancing angle of attack close to 90 °, which will not allow the OOFCH to move when the PS fails, identical to the movement by parachute. In addition, a change in the position of the center of mass more or less 0.55-0.6 of the length of the warhead requires the artificial weighting of the bow or stern of the OOFCH, which leads to a decrease in the payload mass and negatively affects the combat effectiveness of the ammunition.

- the area of the canopy of the parachute system, equal to 0.45-0.55 of the outer surface of the shell of the warhead, to ensure movement after separation along the same paths in the case of normal functioning of the parachute system, and in case of failure or destruction. This circumstance makes it possible in any case to deliver a high-explosive fragmentation warhead to the target area, thereby reducing dispersion, increasing accuracy characteristics and reducing the consumption of shells in a salvo. Achieving the same range during abnormal functioning of the OOFCH, as during its normal operation, is achieved by providing characteristics of the resistance of the detached warhead with an unincorporated or destroyed parachute, close to the resistance characteristics of the warhead moving on a parachute. The necessary resistance characteristics are achieved by creating a resistance force close to the drag force of the parachute system on the surface of the body of the warhead, which is located transverse to the incoming air flow. In this case, the aerodynamic force arising on the body is proportional to the area of the streamlined surface. With the area of the canopy of the parachute system equal to 0.45-0.55 of the outer surface of the hull, the resistance forces on the hull standing across the stream will be close to the forces created when the OOFCH moves by parachute. This circumstance will ensure the same flight ranges both with the introduction of the parachute system, and with its failure. With a decrease in the ratio of the areas of the outer surface of the hull and the parachute system to less than 0.45, the drag force on the hull will be greater than on a parachute, and with an increase in the ratio of the areas over 0.55, the drag force on the hull will be less than on a parachute. Both this and other circumstances will lead to the fact that the movement of the warhead with the parachute inserted and not entered will take place along different trajectories and provide different ranges. As a result, the warhead will not be delivered to the target area.

- an additional detonator and timer, mainly of a powder type, installed in the bottom compartment of the warhead, to provide for the detonation of the warhead on command from the timer in case of failure of the contact fuse in contact with the ground. In the event of an abnormal operation of the warhead after separation (non-introduction or destruction of the PS), it moves in an unstabilized flight mode, making damped oscillations relative to its center of mass and trying to stabilize with a balanced angle of attack close to 90 °. With this mode of movement, the contact of the warhead with the soil surface will be carried out mainly by the side surface of the hull. In this case, the likelihood of a contact fuse tripping is reduced. In addition, even with the normal functioning of the warhead after separation, a manifestation of a failure in the contact fuse itself is possible. Thus, in both cases described, the warhead in contact with the ground, in the absence of an additional detonator and timer, will not work, and therefore will not fulfill the assigned combat mission. The installation of an additional detonator and timer can provide reliable detonation of the warhead in the event of failure of any of its components. An additional detonator in this case is triggered after a predetermined time interval upon command from the timer, which starts when the OOFCH is separated. Any type of timer can be used in the OOBCH, however, the powder type timer is the most preferable, which is a powder bomber, ignited at the moment of separation of the warhead from the propulsion system and burning for a predetermined time interval. A powder bomber is most preferable, since during operation on the trajectory and when in contact with the ground, the projectile and its elements perceive significant axial and lateral overloads, and the powder type timer, as experiments show, is the most resistant to these overloads.

The invention is illustrated in the drawing, which shows a General view of a detonating high-explosive fragmentation warhead.

A detachable high-explosive fragmentation warhead consists of a shell (1) equipped with an explosive (2), a contact fuse (3), a parachute system (4) and an additional detonator (5) with a powder timer (6) located in the tail cylindrical part ( 7).

The warhead housing is a combination of a cylindrical part (7) and a conical nose (8), consisting of a conical fairing (9) and a contact fuse (3).

, где D_M - диаметр Миделевого сечения корпуса, γ - угол полураствора конуса. Площадь поверхности цилиндрической части корпуса (7) определяется выражением

, где L - длина боевой части. Площадь купола парашютной системы (4) определяется выражением

, где D_куп - диаметр купола парашютной системы.The surface area of the body of the warhead, consisting of a contact fuse 3, a conical fairing 9 and a cylindrical part 7, is determined from the considerations of the layout and ensure the specified performance characteristics of high-explosive fragmentation. The area of the canopy of the parachute system 4 is selected from the condition of providing the necessary braking and stabilization characteristics for movement along a trajectory close to the trajectory of the warhead with an uncharted or destroyed parachute, and should be 0.45-0.55 of the surface area of the warhead. The surface area of the body is determined by the expression S _p = S _nose + S _cyl , where S _nose is the surface area of the conical nose, and S _cyl is the surface area of the cylindrical part. The surface area of the conical nose (8) is determined by the expression

where D _M is the diameter of the mid-section of the hull, γ is the angle of the half-solution of the cone. The surface area of the cylindrical part of the housing (7) is determined by the expression

where L is the length of the warhead. The area of the canopy of the parachute system (4) is determined by the expression

Where _kup D - diameter of the dome of the parachute system.

The value of the surface area of the conical nose (8) is 10-20% of the total surface area of the warhead, and the distance of the center of mass of the warhead from the bow of the hull is 0.55-0.6 of its length.

The proposed detachable high-explosive fragmentation warhead works as follows. During normal operation, after separation of the warhead from the propulsion system, the warhead makes the unstable movement necessary to damp the speed to a value acceptable for the introduction of the parachute system. After that, the input mechanism of the parachute system is triggered, the canopy of the parachute opens (4) and the warhead is verticalized and reduced to the target area. Upon contact with the soil surface, the contact fuse (3) is triggered and OOFCH is undermined. During abnormal functioning, in case of failure of the input mechanism of the parachute system (4) or in case of its destruction after entry, the warhead continues unstabilized movement, making damped oscillations relative to the center of mass and trying to stabilize with a balanced angle of attack close to 90 °. At the same time, the resistance force arising on the warhead located across the stream is close to the resistance force arising on the warhead moving by parachute. As a result of this, the warhead moves along the same trajectory as when moving by parachute and reaches the same range. Upon contact with the ground, the OOFCH is undermined either by the operation of the contact fuse (3), or after a predetermined time interval corresponding to the burning time of the powder bombs of the powder timer (6), from an additional detonator (5). Thus, even an abnormally functioning detachable high-explosive fragmentation warhead performs the assigned combat mission.

The indicated positive effect is confirmed by the large volume of experimental studies of prototypes and full-scale combat units, made in accordance with the invention, on stands, in wind tunnels and during flight tests.

Currently, development of working design documentation is underway, mass production of detached high-explosive fragmentation warheads of the proposed design is planned.

Claims (1)

Separating high-explosive fragmentation warhead of a multiple launch rocket, including a contact fuse, explosive, a housing made in the form of a combination of cylindrical and conical parts, and a parachute system, characterized in that the area of the canopy of the parachute system is 0.45-0, 55 the area of the outer surface of the hull, the surface area of the conical nose part leaves 10-20% of the total area of the outer surface of the hull, while the removal of the center of mass of the warhead from the bow of the hull is 0.55-0.6 e length, and in the bottom compartment of the head portion is an additional detonator and a timer, preferably a powder type.