RU2080551C1 - Technique of launching of guided missile from artillery gun and shot - Google Patents

Abstract

FIELD: designing of guided missiles and shot for artillery guns. SUBSTANCE: technique of launching of guided missile from artillery gun and shot includes guided missile 1 fastened in case 2 with propelling device 3, delayed-action pyrotechnic mechanism 4 and rocket engine 5; guided missile 1 is placed in artillery gun barrel 6 with breechblock 7. The missile tail bay accommodates magnetoelectric pulse generator 8, and safety device 9 is installed in alignment with it in the bottom of case 2, it is fastened to the case by means of pin 10. The windings of pulse generator 11 are connected via a wire coupling line to delayed-action pyrotechnic mechanism 12 of the functional units of the on-board systems and delayed- action pyrotechnic mechanism 4 of propelling device 3. Located in breechblock 7 is the firing mechanism, for instance firing pin 13. A pulse-shaping unit is provided in the shot, it includes pusher 14 rigidly coupled to generator 8, and safety device 9, a safety gap is formed between them. EFFECT: facilitated procedure. 2 cl, 2 dwg

Description

 The invention relates to the field of military equipment, in particular to a method for launching a guided missile from an artillery gun, and can be used in designs for firing without supplying an electrical impulse to the board of a guided projectile from the outside.

When firing an artillery gun with an unguided projectile, after filling the projectile into the barrel and locking the bolt, the capsule sleeve is struck with a striking shock mechanism, which ignites the powder charge, and the projectile is thrown out of the barrel under gas pressure [1]
When firing a cannon with an artillery shot, which includes a guided missile, a propellant device with pyroenergomechanisms and an inductor generator electrically connected to an electric igniter of a propelling device, an electric current is generated on board the guided missile using an autonomous generator and fed to an electric igniter of a propelling device. The generator is made in the form of a piezoelectric element with a leading belt, deformable at the entrance to the rifles of the gun barrel [2]
In this case, the method of launching a guided missile from an artillery gun consists in loading the artillery gun with a shot while releasing the shock mechanism, applying an electric impulse to the rocket’s pyroenergy mechanisms according to the battery launch cycle and throwing the rocket out of the barrel with the pressure of powder gases.

 However, the above design of the shot and the method of launching a guided missile from an artillery gun do not provide reliable operation of all the pyroenergy mechanisms of a guided missile fired from the barrel of an artillery gun.

 To eliminate the above drawbacks, a method for launching a guided missile from an artillery gun is proposed, which includes loading, releasing the strike mechanism of the gun’s shutter, applying an electrical impulse to the pyroenergy mechanisms of the missile according to the triggering cycle of the functional blocks of the onboard systems of the guided missile and propelling device, and ejecting the missile from the barrel by the pressure of powder gases, when the shock mechanism of the shutter of the gun is released, its kinetic energy is generated in the generator windings into electrical pulses, which simultaneously feed the pyroenergomechanisms of the functional blocks of the onboard systems of the guided missile and the propelling device, then trigger the pyroenergomechanisms with varying degrees of deceleration in accordance with the trigger sequence, the starting point of which are pulses for the onboard batteries and gyro coordinator, which are converted by pyroenergomechanisms without deceleration.

 In addition, to implement the method of launching a guided missile from an artillery gun, in a shot that includes a guided missile fixed in a sleeve, pyroenergy mechanisms of the functional units of the on-board systems and a throwing device, a generator, a pulse forming unit in the form of a pusher rigidly connected to the generator and a fuse, is provided, placed coaxially to the pusher and fixed in two sleeves with a shear pin, and between the pusher and the fuse there is a safety clearance equal to or greater elichiny maximum displacement counter fuse and pusher at deformations shot operation under all conditions, and delayed action piroenergomehanizmy electrically connected to the generator coils.

 In Fig.1 shows a General view of the shot, in Fig. 2 ridge 1 in figure 1 on an enlarged scale.

 The shot contains a guided missile 1, mounted in a sleeve 2 with a propelling device 3, a delayed-action pyroenergomechanism 4 and a rocket engine 5. The guided missile is located in the barrel 6 with a shutter 7. A pulsed magnetoelectric generator 8 is placed in the tail compartment of the rocket, and coaxially with it in the bottom of the sleeve 2, a fuse 9 is installed, made in the form of a cylindrical body fastened with a sleeve by a pin 10.

 The windings of the pulse generator 11 are connected via a wireline to the delayed-action pyroenergy mechanisms 12 of the on-board systems functional units and the delayed-action pyroenergy mechanisms 4 of the throwing device 3. The shutter has a shock mechanism, such as striker 13, and a pulse-forming unit including a pusher 14 is provided in the shot associated with the generator, and the fuse 9, and between the pusher and the fuse formed a safety gap.

 The operation of the described device is as follows. When firing the firing pin 13 of the bolt, it hits the pulse generating unit, which includes the fuse 9, and, due to the kinetic energy stored by the moving parts of the bolt, cuts the pin 10 and reports a certain speed to the fuse 9. In the initial period of the action of the firing pin on the fuse, they move together. Then the firing pin is fixed by the shutter parts, and the fuse 9 transfers the kinetic energy of the shutter to the pusher 14 and they, together with the armature of the pulse generator, already by inertia move at a given speed in the field of the permanent magnet by the magnitude of the stroke. Moreover, in the windings 11 of the generator 8, the kinetic energy from the gate 7 transmitted to the generator by the pulse forming unit is generated into electrical pulses. These pulses from different windings of the generator are issued and fed simultaneously to the inputs of the pyroenergomechanisms 12 functional blocks of the onboard systems of the guided missile and the pyroenergomechanisms 4 of the propelling device. The predetermined sequence diagram for switching on the functional blocks of the onboard systems of the rocket and the propelling device is provided by various times of slowing down of the pyroenergy mechanisms. So, for example, electrical impulses for on-board batteries and gyro-coordinator are converted by pyroenergomechanisms without slowing down, which is the starting point of the cyclogram. After reaching the on-board systems mode, approximately 1-2 seconds later, the delayed-action squib triggers to ignite the propellant charge of the propelling device, and another 1 2 seconds after the rear pallet of the projectile, which is one of the functional blocks, is reset, the rocket-propelled squib.

 Introduction to the design of the gap between the pusher of the generator and the fuse, an advantageous equal or greater value of the maximum counter movement of the fuse in all operating conditions, including temperature displacements, displacements during throws, transportation, sending to the bore, etc. provides complete security, as excludes the movement of the pusher rigidly connected to the generator armature. This gap, in addition, should not be more than 0.1-0.2 of the output of the striker for the shutter slice, because otherwise, most of the energy of the percussion mechanism will not be converted into an electrical impulse.

 The proposed method of launching a guided missile from an artillery gun and a device for its implementation can improve the reliability of launch and thereby increase the likelihood of hitting a target.

Claims (2)

 1. A method of launching a guided missile from an artillery gun, including loading, releasing the strike mechanism of the bolt of the gun, applying an electrical impulse to the pyroenergy mechanisms of the rocket according to the cyclogram of launching the functional blocks of the onboard systems of the guided missile and propelling device, and ejecting the rocket from the barrel by the pressure of powder gases, characterized in that when the shock mechanism of the shutter of the gun is released, its kinetic energy is generated in the windings of the generator into electrical pulses, which are simultaneously fed to the inputs of roenergomehanizmov functional blocks board guided missile systems and the throwing device, then provide piroenergomehanizmov operation with varying degrees of deceleration in accordance with the cyclogram run, which is the initial point of reference pulses for on-board batteries and girokoordinatora transforming piroenergomehanizmami without deceleration.  2. A shot including a guided missile fixed in a sleeve, pyroenergomechanisms of the functional units of the on-board systems and the propelling device, a generator, characterized in that the shot is injected with a pulse forming unit in the form of a pusher rigidly connected to the generator, and a fuse placed coaxially with the pusher and fixed in the bottom of the sleeve with a shear pin, and between the pusher and the fuse there is a safety clearance equal to or greater than the maximum counter movement of the fuse and t pusher under deformations in all operating conditions of the shot, and pyroenergomechanisms of delayed action are electrically connected with the windings of the generator.

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