RU2487310C2 - Mobile air defense system - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: mobile air defense system is installed inside a cargo container (1), which is prepared for transportation on a car chassis. Inside the container (1) there is a support (2) fixed on stands (3). On the support (2) there is a power boom (4) hingedly fixed with a power cylinder (5). Missile containers (6) are grouped by three into cassettes (7), which are crossed one above another with the help of a bearing frame (8). On the rear wall of the container (1) there is a lever (9), which is connected to the power cylinder (10). On the free end of the lever (9) there is a bracket (11) for a radar (12). The cover of the container (1) is divided into segments (14) and (15). To launch a missile, at first the lever (9) is turned with the roof and the radar (12) into vertical position, and then the boom is turned so that the boom (4), so that the frame (8) is vertically resting with the end against the container (1) floor.

EFFECT: increased battle characteristics of an air defense system, by improvement of its agility, security, gun power and combat readiness.

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Description

The invention relates to weapons, specifically to mobile anti-aircraft missile systems of air defense.

Known anti-aircraft missile system, including a self-propelled launcher (PU) for launching missiles from containers (see RF patent No. 2262647).

Closest to the proposed invention is, in our opinion, the S-300V anti-aircraft missile system (system), which provides vertical launch from containers of long-range missiles (see in the book. N. Vasilin, A. Gurinovich, Anti-aircraft missile systems , Minsk, "Potpourri", 2002, p.273, 274 - prototype). The specified complex includes a self-propelled launcher on a caterpillar chassis, on which mechanisms are mounted for securing, transporting missile containers and turning them into a vertical position for launching missiles. Here on the chassis mounted lift with a radar.

The disadvantages of the prototype include the low speed of movement of the missile system, which is mounted on a tracked chassis. The problem is that tracked vehicles are subject to certain road restrictions that prohibit the passage of heavy tracked vehicles on highways. Secondly, missile containers can only be loaded in turn in the complex’s system, which reduces its combat readiness. In addition, the presence of four missiles for a modern air defense system is no longer enough to provide the required firepower. Finally, this complex has no masking agents and is easy to detect.

The technical task is to increase the tactical and technical properties of an anti-aircraft missile system with a vertical launch of long-range missiles by improving its speed, stealth, firepower and combat readiness.

The technical result is achieved in that in a mobile anti-aircraft missile system, which includes a self-propelled chassis, a launcher for the vertical launch of anti-aircraft missiles from missile containers mounted on a power boom equipped with a power cylinder for turning and fixing the missile containers in a vertical position, a radar lift, self-propelled the chassis is made in the form of increased carrying capacity of a car chassis equipped with a standard cargo container, inside which the specified power boom, missile containers are fixed in at least two rows on a power boom made with the possibility of stopping missile containers on the floor of the cargo container after they are turned into a vertical position, the radar elevator is made in the form of a lever, at which one end is pivotally attached to the wall of the cargo container and the other end is equipped with a bracket for fixing the radar, and the specified lever is equipped with an additional power cylinder with the possibility of fixing both in vertical and horizontal positions, with this roof of the cargo container is mounted on the specified lever with the possibility of closing the cargo container from above after fixing the lever in a horizontal position.

In the proposed complex, missile containers are grouped in three in one row and mounted on the boom using a supporting frame. The radar lever, attached to the rear wall of the cargo container, is made no longer than the length of the cargo container with the possibility of placement inside the container with the radar. A standard 40-foot container was used as a freight container.

The invention is illustrated by drawings. Figure 1 schematically shows a side view of an anti-aircraft missile system in the stowed (transport) position inside a standard cargo container with a disassembled side wall, figure 2 is a rear view of the system in a container with an disassembled rear wall, and Fig. 3 is a view of a missile system in deployed (combat) position.

In an example of a specific embodiment, a mobile anti-aircraft missile system is located inside a standard 40-foot cargo container 1, which is prepared for transportation on an automobile chassis of increased carrying capacity (not shown). Inside the container 1 there is a support 2 mounted on the uprights 3. On the support 2 the power boom 4 is pivotally fixed, which is connected to the power cylinder 5. The rocket containers 6 (with missiles inside) are grouped three in cassettes 7. Two cassettes 7 are mounted one above the other using the supporting frame 8, which is fixed on the boom 4. Thus, the missile system contains six missile containers, which are placed in two rows covertly inside a standard cargo container.

The lever 9, pivotally mounted on the rear wall of the container, is connected to the power cylinder 10. At the free end of the lever 9 there is a bracket 11 for the radar 12. The bracket 11 is pivotally attached to the lever 9 with the possibility of rotation by means of the power cylinder 13. The roof of the container 1 is divided into segments 14 and 15. The segment 14 is mounted on the lever 9. The segment 15 is mounted on the bracket 11. The hydraulic cylinders are connected to the pump station 16.

The invention is used in the following order. Previously, in the workshop, anti-aircraft missiles are placed in containers 6. Containers with missiles are grouped three in cassettes 7. Cassettes 7 are placed two in a frame 8 and fixed. Frames with missiles are loaded onto a transport vehicle and delivered to the position where the complex is equipped with missiles.

To equip the complex with missiles, the cargo container 1 is first opened. To do this, turn on the pump station 16, which supplies the working pressure to the cylinder 10. The cylinder 10 raises the lever 9 together with the roof 14, 15, radar 12 and fixes it in a vertical position, as shown in FIG. .3. Then the frame 8 with the missile containers 6 is removed from the transport vehicle and rearranged on the boom 4. The frame 8 has a special yoke, and the boom 4 is equipped with appropriate guides. When loading the carcass of its yoke (not shown), lead into the guides on the arrow 4 (not shown), the frame is moved along the guides forward to the stop and fixed on the arrow. Thus, in one loading operation on missile launcher launchers, six missile containers are loaded at once. To close the container 1, switch the cylinder 10 to retract the rod. The cylinder 10 rotates the lever 9 in a horizontal position, as shown in figure 1, and fixes it. In this case, the roof 14, 15 is lowered together with the lever 9 and closes the container 1 from above.

For the production of missile launches, the complex is moved under its own power to a firing position. At the same time, a car chassis with a standard 40-foot cargo container, which has a normal appearance, can move openly and quickly on any road without special permission. After arriving at the firing position, the missile system must be rigidly fixed in order to exclude the influence of missile launches on each other. To do this, put forward special jacks (as on truck cranes, not shown), until they stop in the ground. In this case, the chassis with the container 1 is rigidly hung above the ground.

To prepare for launch, first turn on the cylinder 10, which rotates the lever 9, together with the roof and the radar, in a vertical position, as shown in figure 3. In this case, the radar 12 rises to a height of about 14 m. Then, the cylinder 5 is turned on. The kinematics of the boom 4 and the rod of the cylinder 5 are designed so that, with the rod fully extended, the cylinder 5 turns the boom 4 to a vertical position, in which the frame 8 rigidly abuts its end against the floor of the container 1, as shown in FIG.

After determining the target, a command is issued to launch the rocket from a specific container 6. To do this, use the control panel in the command compartment, which can be arranged in the enclosed front of the cargo container. According to the launch command, the catapult built into the container 6 first fires. The catapult throws a rocket (with the engine turned off) from the container to a height of at least 20 m. At this height, the rocket's starting engine is turned on, its turn and the flight starts toward the target. Similarly, missiles are launched from the remaining containers. The design of the container 6 is protected by the RF patent for the invention No. 220050, owned by the applicant.

After the completion of rocket launches, the hydraulic cylinder 5 is turned on to retract the rod, which rotates the boom 4 with the frame 8 in the opposite horizontal position and fixes it on the support 2 inside the container. Then, the cylinder 10 is switched to the reverse stroke, which transfers the lever 9 to the horizontal position and fixes it. In this case, the container is closed by a roof 14, 15. Then the jacks are retracted. In this case, the car chassis is lowered by wheels to the ground. After that, the anti-aircraft missile system moves under its own power to a technical position, where the frame is replaced with a frame with missiles.

The missile system proposed for patenting has a number of advantages compared to well-known analogues. It has high mobility and armament, as it provides the launch of up to six anti-aircraft missiles against four, like the prototype. Due to the grouping of containers in the frame, loading missiles on launchers takes less time than loading containers individually. It is not obvious here that the missile system units are mounted in a standard 40-foot cargo container along with a radar lift of sufficient height. This solution provides a good camouflage missile defense system and its secretive movement to the firing position. Moreover, the implementation of the rack for the radar in the form of a lever significantly simplifies the design of the radar elevator and increases its reliability. It should be noted that in known analogues, the radar lift is made in the form of a system of telescopic hydraulic cylinders with a rather complex structure.

According to the proposed scheme, the applicant’s enterprise developed technical documentation, and preparations began for the production of a prototype.

The new technical solution described above, which meets the criteria of non-obviousness and industrial applicability, is proposed for legal protection by a patent for an invention.

Claims (4)

1. Mobile anti-aircraft missile system, including a self-propelled chassis, a launcher for the vertical launch of anti-aircraft missiles from missile containers mounted on a power boom equipped with a power cylinder for turning and fixing the missile containers in a vertical position, a radar elevator, characterized in that the self-propelled chassis made in the form of increased carrying capacity of a car chassis equipped with a standard cargo container, inside which the indicated power boom is mounted, missile contours the banners are fixed in at least two rows on the power boom, which is capable of supporting the missile containers in the floor of the cargo container after they are turned into a vertical position, the radar elevator is made in the form of a lever, at which one end is pivotally attached to the wall of the cargo container and the other the end is equipped with a bracket for securing the radar, and the specified lever is equipped with an additional power cylinder with the possibility of fixing the lever in both vertical and horizontal positions, while the roof load Vågå container is fixed on said lever with the possibility of closing the freight container after fixing the lever to a horizontal position. 2. The complex according to claim 1, characterized in that the rocket containers are grouped in three in one row and mounted on the boom using a supporting frame. 3. The complex according to claim 1, characterized in that the radar lever, attached to the rear wall of the cargo container, is made no longer than the length of the cargo container with the possibility of placement inside the container with the radar. 4. The complex according to claim 1, characterized in that a standard 40-foot container is used as a freight container.

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