RU2107251C1 - Rocket projectile launched from launching tube - Google Patents

Abstract

FIELD: rocketry, rocket projectiles intended for launching from launching tube. SUBSTANCE: rocket projectile has a fuse, warhead, solid-propellant rocket engine, nozzle block with opening stabilizer fins and contact cover with a contact sector, guide pin and stabilizer fin ring. The nozzle block exhaust part has a cylindrical section and a thrust shoulder. In addition, a ring resting on the shoulder is installed and fixed on the cylindrical section. Contact cover with an additional detachable current-conducting element and second contact in the form of an L-shaped plate contacting with the ring through thee detachable current-conducting element is secured on the ring. EFFECT: rocket projectile can be launched from launchers with different arrangement of firing contact and launching circuits. 2 cl, 3 dwg

Description

 The invention relates to the field of rocket technology, and more particularly to uncontrolled rockets (LRS), launched from a tubular guide, and can be widely used in the development of new samples of unguided shells.

 As you know, when starting an LDC from launchers (PU), an electric current pulse is supplied to the electric igniter of the LDC engine through the contact devices of the launcher and the projectile itself.

 Typically, the contact device of both the LDCs and the launcher is one or more contacts located respectively on the projectile and launcher. Conductors from an electric igniter are connected to the LDC contacts, and conductors from ground-based starting equipment are connected to the PU contacts.

 It should be noted that the LDC contact is usually a rigid plate made of high alloy stainless steel (to prevent corrosion) and isolated from the shell of the projectile.

 The contact on the launcher is a rather complicated design and contains a power housing that protects the contact itself from operational and climatic factors, a spring-loaded contact (to compensate for technological variations in the manufacture of LDCs and PUs), an electrical conductor connecting the contact with the launch equipment, and the housing mount to the guide. Thus, to place a contact on the PU, a lot of space is required.

Basically, electric pulse transmission schemes are used on an electric igniter:
- single-wire, in which one contact is isolated from the shell of the projectile and the “mass” of the launcher and the launcher, the second contact is the metal shell of the projectile connected to the ground of the launcher, and the second conductor from the electric igniter is connected to the shell of the projectile;
- two-wire, in which two contacts are used on the LDC and PU, isolated from the shell of the shell and the "mass" of the PU.

 A single-wire circuit is sensitive to guidance currents generated by electromagnetic radiation sources (radars, lightning discharges, etc.) and static electricity charges accumulated by maintenance personnel and the launcher. This can lead to unauthorized launches of shells, the prevention of which requires special measures.

 The two-wire circuit, despite some design complexity, is less sensitive to the above factors and has recently become more widespread.

 To ensure the smooth launch of the LDCs, the location of the contacts on the projectile and launcher should be tied to each other.

 This is ensured by tight binding of the angular and linear arrangement of the projectile contacts relative to any of its surface; relative to the same surface, the location of the contacts on the launcher is also set.

 Known LDCs, in which a leading pin is used as the base surface, with the help of which the initial spin of the projectile 6 of the guide and its locking in the launcher is carried out [1].

 It contains a fuse, a head, a jet engine with a charge of solid fuel, a nozzle block, a contact sector mounted on the front bottom of the engine, a pin and a rigid stabilizer. The projectile is launched from the truss guide, using a single-wire launch scheme.

 The location of the contact sector in the well-known LDC is rigidly tied to the location of the leading pin, and the location of the reciprocal contact of the PU is tied to the locking device of the installation (which includes and fixed the leading pin), which prevents the projectile from falling out when lifting the guides of the installation for firing.

 The placement of the contact sector on the front bottom of the engine (approximately half the length of the projectile), and therefore the same location of the electric igniter, is optimal from the point of view of organizing the process of ignition of the charge of solid fuel, but it makes it necessary to place the reciprocal contact of the PU in the middle of the truss guide, while the PU contact exposed to the gases of a running engine when the projectile moves along the guide. This causes increased wear of the contact and the need for its frequent replacement, which requires almost complete disassembly of the guide package.

 In addition, the location of the contact sector on approximately half the length of the projectile does not allow the use of this technical solution in other shells launched from tubular guides. This is due to the lack of space for placing contacts in the middle of the package of tubular guides having a high density of placement on the PU.

 Thus, the above limitations are significant disadvantages of the considered design of the projectile.

 The objective of this technical solution was the development of an uncontrolled rocket projectile, which ensures automatic docking of contacts during charging and the failure-free launch of the projectile only from truss guides, but does not ensure the durability of the PU contact, the convenience of its replacement and its use for shells launched from tubular guides.

 Common features with the missile proposed by the authors are a fuse, a warhead, a jet engine with a charge of solid fuel, a nozzle block, a pin, a contact sector and a stabilizer.

 The optimal design of the LDC, satisfying the requirements on the durability of the RU contact, the convenience of replacing it and allowing it to be launched from the tubular guide would be the design of the projectile in which its contact would be brought to the rear end and located above the diameter of the nozzle exit section, which would allow the reciprocal the launcher contact is also on the cut of the tubular guide (or even beyond its cut if the projectile extends beyond its cut) and remove it from the direct gas zone of the working engine gases.

 The closest in technical essence and the achieved technical effect is unguided missile 9M22U [2], adopted by the authors as a prototype. It starts from a tubular guide and contains a fuse, a head part, an engine with a charge of solid fuel, a nozzle block with a drop-down stabilizer, a drive pin, a stabilizer ring and a contact cover with a contact sector.

 The contact cover overlaps the outlet section of the nozzle and is fixed with a thread on the outlet of the nozzle block. The contact sector is located on the side (cylindrical) part of the contact cover, and its diameter is larger than the diameter of the outlet section of the nozzle.

 Thus, the reciprocal contact of the PU is located behind the guide cut and removed from the gas range of the working engine, which ensures its durability, reliability and ease of replacement if necessary.

 To launch the projectile, a single-wire circuit was used: one conductor from the electric igniter is connected to the contact sector, the metal shell of the shell and the launcher ground are used as the second conductor, and the second conductor from the electric igniter is connected to the shell of the projectile.

 The angular and linear arrangement of the contact sector is associated with the location of the drive pin, and the location of the PU contact is associated with the locking device of the installation.

The disadvantages of the known projectile are:
- the use of threads to fix the contact cover on the nozzle block greatly complicates the installation of the necessary angular location of the contact sector relative to the leading pin, which is associated with technological variations in thread cutting (the number of turns of thread varies within the tolerance for its length) and the uncertainty in the position of the lead-in turn (lead-in the coil can be located anywhere in the circle) and makes it impossible to reset the cover to a different position if necessary, for example, for firing from the launch output installations with a different contact arrangement;
- the presence on the contact cover of only one contact sector necessitates the use of only a single-wire launch scheme and does not allow the use of shells to launch them from launchers with a different launch scheme, for example, two-wire.

 All this leads to the fact that the projectile can only be launched from a specific launcher and cannot be used when changing the location of the contacts on the launcher or introducing a more progressive two-wire launcher when upgrading or creating new installations.

 Thus, the objective of this technical solution (prototype) was the development of a projectile, the contact device of which is simple in design, but ensures that the projectile is launched only from one specific tubular launcher and only with a single-wire launch circuit, i.e. does not have the versatility of its use.

 When the LDCs are charged into the guide, the lead pin enters the PU locking device, and the contact sector of the projectile and the contact of the installation are automatically connected, as well as the connection of the shell of the projectile with the "mass" of the launcher.

 When an electrical impulse is supplied from a ground-based launcher to a PU contact, and then through a conductor connected to the sector, to an electric igniter of the projectile engine (the shell of the shell and the launcher’s ground are used as the second conductor), the electric igniter fires and ignites the igniter. When the latter is triggered, a solid fuel charge ignites. When a certain pressure is reached, the contact cover is reset and the projectile begins to move along the guide. The stabilizer ring, which holds the stabilizer from opening, is discarded from the projectile by the rear end of the guide. When the projectile leaves the guide, the stabilizer opens and the LDC starts moving along the trajectory.

 Common signs with the missile proposed by the authors are the presence of a fuse, a head part, an engine including a solid fuel charge, and a nozzle block with a drop-down stabilizer located on the output part of the nozzle block of the contact cover with a contact sector, a driving pin and a stabilizer ring.

 Unlike the prototype, the missile proposed by the authors is additionally equipped with a ring, and the output part of its nozzle block has a cylindrical section, while the ring is placed on the cylindrical section and fixed on it, the contact cover is fixed on the ring, and the cylindrical section is equipped with a shoulder interacting with the ring end moreover, the contact cover is further provided with a removable conductive element and a second contact, which is fixed in the contact cover, for example, diametrically opposite contact sector and made in the form of a L-shaped plate in contact through a removable conductive element with a ring.

 It is this that allows us to conclude that there is a causal relationship between the totality of the essential features of the claimed technical solution and the achieved technical results.

 The indicated features, distinctive from the prototype and to which the requested scope of legal protection applies, are sufficient in all cases.

 The objective of the proposed technical solution is to create the design of an uncontrolled missile launched from a tubular guide and allowing it to be launched from launchers with different contact locations and launch circuits, i.e. possessing the versatility of its use.

The introduction of the projectile ring and the implementation of the output part of its nozzle block with a cylindrical section on which the ring is placed and fixing the contact cover on the ring allows the latter to be reset to any angular position (within 360 ^o ), which makes it possible to launch the projectile from various launchers .

 Fixing the ring on the cylindrical section of the output part of the nozzle block eliminates the possibility of its rotation and the associated contact cover during operation (transportation, loading, etc.).

 The collar on the cylindrical section of the output part of the nozzle block prevents the dropping of the ring when the contact cover is broken at the moment the engine enters the mode.

 The presence of a removable conductive element and a second contact, mounted in a contact cover and made in the form of a L-shaped plate in contact with a removable conductive element with a ring, allows it to be used as a second contact sector when firing from launchers with a two-wire launch circuit (the conductive element is removed ) or as a conductive element connecting the shell of the projectile with an electric igniter (conductive element supplied) when firing from launchers with a single starting circuit.

 The essence of the invention lies in the fact that an uncontrolled missile launched from a tubular guide containing a fuse, a head part, an engine including a solid fuel charge, a nozzle block with a drop-down stabilizer, a contact cover with a contact sector, a leading pin and a pin on the output part of the nozzle block the stabilizer ring, in contrast to the prototype according to the invention is additionally provided with a ring, and the output part of its nozzle block is a cylindrical section, while the ring is placed on and the cylindrical section is fixed on it, the contact cover is fixed to the ring, and the cylindrical section of the output part of the nozzle block is provided with a stop interacting with the end of the ring, and the contact cover is additionally equipped with a removable conductive element and a second contact, which is fixed in the contact cover, for example, diametrically opposite to the contact sector and made in the form of a L-shaped plate in contact with a removable conductive element with a ring.

 In FIG. 1 shows a general view of the projectile; in FIG. 2 is a longitudinal section of the output part of the nozzle block on an enlarged scale; in FIG. 3 is a view along arrow A of the contact cover.

 A missile (Fig. 1) contains a fuse 1, a head 2, an engine 3 with a solid fuel charge 4, a nozzle block 5, a drop-down stabilizer 6, a pin 7, a contact cover 8 with a contact sector 9 (Fig. 3) and a stabilizer ring ten.

 The output part of the nozzle block 5 (Fig. 2) is made with a cylindrical section 11 (Fig. 2), on which the ring 12 is freely placed, and the contact cover 8 is fixed, for example, by means of a thread on the ring 12. The end face of the ring 12 abuts against the bead 13 made on a cylindrical section 11. From rotation, the ring is fixed by a locking screw 14. The contact cover 8 (Fig. 1) is provided with a second contact 15 (Fig. 2, 3), made in the form of a L-shaped plate, which is, for example, diametrically opposed contact sector 9 (Fig. 3). Using a screw 16 (Fig. 2), the second contact is connected to the ring 12. To the contact sector 9 and contact 15 by means of screws 17, 18, conductors 19, 20 connected to the electric igniter are connected.

The angular and linear location of the contact sector is associated with the location of the drive pin:
- size "a" (Fig. 1), for example, 256 mm;
- angle α (Fig. 3), for example, 41 ... 43 ^o .

When assembling the projectile, the contact cover 8 (Fig. 1, 2) is mounted on the ring 12, then it is turned to the required angle, for example, 41 ^o (Fig. 3), after which the ring is pulled (with the cap fixed) to the end of its end in the shoulder 13 fixed by turning screw 14.

 If the projectile is intended for firing from a launcher with a single-wire trigger circuit, then screw 16 is screwed into the second terminal 15 until it stops in ring 12 (Fig. 2). Thus, the conductor 20 is connected to the shell of the projectile.

 For firing from a launcher with a two-wire starting circuit, the screw 16 is not screwed, while the pin 15 (Fig. 2) is isolated from the shell of the projectile and is used for its intended purpose.

Unguided missile operates as follows. When the projectile is charged (in the launcher with a two-wire trigger circuit), the leading pin 7 (Fig. 1) enters the launcher of the launcher and is fixed in it, while the contact sector 9 (Fig. 2, 3), the second contact 15 is automatically connected to the response contacts launcher due to the binding of the angular (angle α, for example, 41 ^o ) and linear (size "a", for example, 256 mm), the location of the contact sector 9 and the second contact 15 relative to the leading pin 7, and the response contacts PU - relative to the locking device installation.

 When the projectile is charged (in a launcher with a single-wire trigger circuit), due to the connection of the contact 15 with the threaded ring 12 through the screw 16, the conductor 20 (Fig. 2) is automatically connected to the "mass" of the launcher.

 When applying an electric pulse to the contacts of the PU (a two-wire starting circuit is considered), it is transmitted to the contact sector 9 and contact 15 (Fig. 2), and then through the conductors 19, 20, fixed with screws 17, 18 on the contact sector and the second contact 15 , to the electric igniter of engine 3 (Fig. 1), which fires and ignites the igniter, and the latter ignites the charge of solid fuel 4. With a single-wire starting circuit, an electric pulse is applied only to contact sector 9, and then to conductor 19, and the second conductor 20 through pin 15, screw 16 and threaded ring 12 is connected to the shell of the projectile and the "mass" of the launcher. Further operation of the start-up circuits and electric igniter is similar to that described above.

 When a certain pressure is reached in the engine, the contact cover 8 is reset (Fig. 1), and the bead 13 protects the ring 12 from resetting together with the contact cover 8 (Fig. 1, 2). The projectile begins to move along the guide, the stabilizer ring 10 (Fig. 1), which holds the stabilizer 6 from opening, is reset by the rear end of the guide. When exiting the guide, the stabilizer opens and the LDC starts moving along the path.

 According to the invention, design documentation was developed (Fig. Inv. N I-2428, I-2430, I-2431), according to which prototype shells are currently manufactured.

 The control assembly showed that the contact cover of the projectile is freely installed in any position to orient the contact sector relative to the leading pin; fixing the ring completely eliminates the possibility of unauthorized rotation of the cover; the presence of a removable conductive element (screw) provides a reliable connection of the second contact with the shell of the shell, and in the absence of this screw provides reliable isolation of the second contact from the housing of the LDCs.

 According to the results of the control assembly, the design of the LDCs was recognized as promising and an experimental batch of LDCs with contact devices for acceptance tests is being manufactured. In the future, serial production of shells is planned with the prospect of their use in launchers with both a single-wire and a two-wire scheme for launching and deliveries for export.

Claims (2)

 1. An uncontrolled missile launched from a tubular guide, comprising a fuse, a head, an engine with a charge of solid fuel, a nozzle block with expandable stabilizers, a contact cover with a contact sector located on the output of the nozzle block, a drive pin and a stabilizer ring, characterized in that the output part of the nozzle block is made with a cylindrical section and a thrust collar, in addition to the cylindrical section, a ring abutted in the collar is installed and fixed, on which a contact cover is fixed, equipped with an additional removable conductive element and a second contact fixed thereon, made in the form of a L-shaped plate in contact with a ring through a removable conductive element.  2. The projectile according to claim 1, characterized in that the second contact is fixed on the lid diametrically opposite to the contact sector.

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