NL8615015A - CANON SYSTEMS. - Google Patents

Description

V

> NO 34599

Short designation: Gun systems.

The present invention relates to gun systems, more particularly towed howitzer systems.

The artillery gun system, known as the British Light Gun L118 (hereinafter referred to as the "Light Gun"), is a well known artillery gun system manufactured and sold by applicant's company. The structure of this system includes a gun carried in a cradle on a supporting gun carriage fitted with a saddle mounted on a short spindle, the gun being balanced relative to the spindle by a tail-10 configuration that includes tubular legs protruding behind the gun to the ground. The spindle is secured to a platform to which the gunfoot legs are also attached, and the platform is supported by wheel-mounted axles that allow the system to be pulled if necessary.

15 The Light Gun has a very suitable light-weight construction that makes it possible to tow the system using a land vehicle or to transport it using a helicopter.

However, it is desirable for certain applications to provide a new construction for a gun system that provides further weight savings over the dimensions of the gun compared to the structures of known systems such as that of the Light Gun.

In accordance with the invention, the gun 25 system includes a gun mounted on a gun and provided with a tail configuration to provide a stable equilibrium of the gun to the gun, the gun being saddle-mounted by means of which the rear end of the gun is supported, a support structure on which the saddle is mounted, a base structure that may be located on or anchored in the ground, and a coupling between the support structure and the base structure that allows the support structure and the saddle can rotate relative to the basic structure.

The gun system of the present invention utilizes a new stabilizing principle to balance the gun during gun recoil.

In artillery gun systems it becomes stabilizing. 8 § E 0 1 5 * ί Η moment, which functions through the tail configuration that balances the gun in a stable state relative to the center of gravity of the galaxy, reduced if the gun moves backward under the effect of the recoil, causing it to center of gravity 5 moves in the direction of the tail. However, in known systems such as the Light Gun, the stabilizing moment is kept sufficiently large during and after the recoil due to the weight of the tail.

In contrast, the gun system 10 of the present invention utilizes a stabilizing principle that is new in its application to artillery gun systems. The tendency to reduce the stabilizing moment produced by the shift of the center of gravity at the recoil is counteracted by the tendency to increase the stabilizing moment by rotation of the saddle relative to said coupling. The overall effect of this is that the gun system can be balanced in a stable position by a tail configuration which, relative to the dimensions of the gun system, may be lighter than used in known systems.

The gun system of the present invention can provide further means that help maintain the system in a stable equilibrium state during recoil. For example, the stabilizing moment can be increased by allowing the gun taps to move backward during the recoil, as described by Applicant in a copending application of the same date.

The tail configuration in the system of the present invention may therefore include two gun legs made from or provided with a light weight, e.g.

Composite material, for example a fiber-reinforced plastic material.

The saddle is preferably mounted directly above the tail configuration, e.g. above the gun legs at the end nearest to the gun where they may be attached to the support structure, preferably clear of the bottom.

This configuration, in combination with the rotatability of the saddle by the rotational movement around said coupling, ensures that the tail configuration is subjected to a bending load during recoil and that the compressive load, .8615015 3, »δ acting on the tail configuration, is significantly is reduced.

Such a load is potentially harmful to light-weight materials, e.g. composites, and their reduction is therefore very advantageous. In contrast, the gun legs in known structures normally receive both a significant bending load and also a compression load produced by the recoil.

Said support structure in the system according to the present invention may comprise a supporting pillar which may be in the form of a spindle which is attached to the saddle via a bush.

The said coupling in the system according to the present invention can be provided with a flexible or a universal coupling, e.g. a ball joint or a sleeve joint.

For example, a protrusion that is received in and protrudes upward from the base structure can have a spherical top surface that fits into a complementary recess realized by a sleeve or a sleeve attached to the support structure, e.g. a pillar or pivot. Such a coupling not only prevents excessive reduction of the stabilizing moment by allowing rotation of the saddle in the manner described above, but also facilitates support of the saddle if the base structure is on an uneven bottom.

The tail configuration preferably includes two gunheads which may have spurs or shovels at their ends to anchor the legs in the ground. Preferably, the portion of the legs under the saddle is provided with metal, e.g. a steel or a titanium alloy, because that part is subject to the greatest loads during recoil.

If the gun legs have a portion 30 made of a composite material, this part of the legs can be formed from any known high strength composite material. For example, it can be provided with any known reinforcement fibers, e.g. selected from one or more of the following: carbon glass, aramid, metal or polyolefin fibers, embedded in a polymer matrix material which contains a curable, e.g. thermosetting plastic material or thermoplastic material may be as is known to those skilled in the art of composites. The reinforcing fibers may or may not be woven and their direction can be selected to obtain a directional strength adapted to the. i; C 1 5 ---- --— g <? 4 -n tax that is applied.

Fiber-reinforced plastic layers can be formed in a known laminate structure together with other layers, e.g. other fiber-reinforced plastics with different reinforcement fibers or with differently oriented fibers, unreinforced plastics or metal layers, e.g. made of aluminum or titanium.

If the gun legs have a portion formed from any of the above composite materials, they are preferably tubular with approximate square, rectangular, circular or any other suitable cross sections. The area enclosed by the tubular cross-section can be tapered in the longitudinal direction of the leg. The overall shape of the legs can be straight or curved.

The gun can be supported by the saddle by being carried in a cradle attached to the saddle via taps. The gun's elevation angle can be adjusted using a known elevation system. The recoil forces produced during the firing of the gun can be damped by a known buffer provided between the cradle and the gun and the gun can be reset by a known recuperator. The gun system can be provided with balancing means and known transverse displacement means.

The gun system of the present invention may comprise a light-weight, large-bore howitzer of e.g.

25 to be 155 mm. The towing is possible thanks to wheels that can be folded or secured during the operational use of the system. The system can also be provided with gripping means for air transport, for instance with the aid of a helicopter, which is possible because of the low weight obtained thanks to the new construction.

Embodiments of the present invention will now be described by way of example with reference to the accompanying drawings, in which:

Figure 1 is a side view of a gun assembly, Figure 2 is a partially sectioned side view of a more detailed form of the coupling used in the assembly shown in Figure 1.

In figure 1, a gun 1 with a known muzzle brake 2 is carried in a cradle 3 which is supported in a saddle 5. 86UC15

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5 by taps 7 and conventional lift arms 9 (only one of which is shown in Figure 1).

The gun 1 and the cradle 3 are balanced on a firing platform 11 by the gun legs 13 (5 of which are only shown in Figure 1), the gun legs 13 are anchored in the ground G by spores or shovels attached thereto, and the firing platform 11 is also anchored in the ground.

The gun legs 13, viewed longitudinally at the lower portion, are formed of a fiber-reinforced plastic composite material 10, the upper portion 17 of which is made directly below the saddle 5 from metal.

The saddle 5 is mounted above the firing platform 11 via a support 21 which is provided with a coupling 23 which allows the saddle 5 to rotate relative to the coupling 23. A retaining clip 24 is located at the bottom of the saddle 5, where the saddle 5 curves away from the gun legs 3. When the gun 1 is fired, the recoil forces are reduced by the muzzle brake 25 and damped by a conventional buffering recuperator system (not shown), which allows the gun 1 to move backward 20 during the recoil from the cradle 3 and then after the recoil is returned to its firing position. During recoil, the load on the trunnions 7 causes the saddle 5 to tend to rotate relative to the coupling 23 and this rotation flexes the gun legs 5 and absorbs the load in the ground mainly through the support 21 and the discharge platform 11.

As described in a related patent application, the load to be absorbed during the recoil can be reduced by allowing the gun 1 and cradle 3 to move upwards by allowing the trunnions 7 to move upwards in a guide (not shown) .

The gun system can be provided with other components (not shown in figure 1) such as balancing means which balance the system when the elevation angle of the gun 1 is increased, wheels for pulling the gun by means of a land vehicle, which wheels can pivot towards a storage position, and transverse displacement means for moving the gun in azimuth direction.

An embodiment of the support 21 and of the coupling 23 is shown in figure 2. On the top surface of the firing, δ ·, i C 1 5 λ 6% platform 11, which is sunk into the ground, a projection 33 is formed the surface of which forms the largest part of a sphere.

The protrusion 33 is inserted into a complementary cavity 35 formed in a sleeve 37 to provide the coupling 23.

The sleeve 37 rests on shoulders that project laterally at the lower end of a generally tubular pivot 39 which is attached with its upper end to the saddle 5 to support the saddle 5.

The upper parts 17 of the gun legs 13 are hinged to the structure 21 comprising the spindle 39 and the sleeve 37.

.8515015

Claims (11)

Gun system comprising a gun mounted on a gun and provided with a tail configuration to provide a stable equilibrium of the gun on the gun, the gun being provided with a saddle by which the rear end of the gun is supported, a support structure on which the saddle is mounted, a base structure that may be located on or anchored in the ground, and a coupling between the support structure and the base structure that allows the support structure and the saddle to rotate relative to the base structure. The gun system of claim 1, further comprising means for assisting in maintaining the system in a stably balanced state during the recoil by allowing the gun taps to move upward during the recoil. Gun system according to claim 1, wherein the tail configuration comprises two tail legs made of or provided with a light-weight material. The gun system of claim 3, wherein the tail configuration includes two tail legs made of or comprising a fiber reinforced plastic material. The gun system of claim 1, wherein the saddle is mounted directly above the gun legs on its nearest gun end where they are attached to the support structure free of the ground. The gun system of claim 1, wherein said support structure includes a support pillar which may be in the form of a pin attached to the saddle via a sleeve. Gun system according to claim 1, wherein said coupling is provided with a flexible or universal coupling. The gun system of claim 7, wherein a protruding portion is present in and protrudes upwardly from the base structure and has a spherical top surface that fits into a complementary cavity provided by a sleeve or sleeve attached to the support structure. The gun system of claim 7, wherein the tail configuration includes two gun legs with spades or spurs at their ends for anchoring the legs --- in. 8 β ί E 0 1 5 8 .... "A in the ground. The gun system of claim 3, wherein the portion of the legs under the saddle is metal. 11. Gun structure with support structure, substantially as described above with reference to the accompanying drawings. .8615015