The present invention relates to a system and a method for the reversible transfer of ammunition between an external transfer magazine, referred to as a secondary magazine, and a primary magazine, for example in an automatic cannon.
Systems for loading ammunition from a secondary magazine to a primary magazine in an automatic cannon are known from the prior art. Known loading systems are, however, characterized by their low transfer speed and by their limited opportunities for handling mixed types of ammunition.
SE466872B describes a loading system for loading ammunition from a secondary magazine to a primary magazine in connection with an automatic cannon. The system comprises two ammunition drums, being a first upper rotatable ammunition drum corresponding to a primary magazine, and a second rotatable ammunition drum corresponding to a secondary magazine, arranged beneath the first ammunition drum.
The primary magazine comprises an ammunition outlet for the manual transfer of ammunition to the cannon's charging mechanism, and an ammunition inlet for the manual loading of ammunition from the secondary magazine to the primary magazine. The secondary magazine comprises an ammunition outlet for the manual transfer of ammunition from the secondary magazine to the primary magazine and an ammunition inlet for the manual loading of ammunition from an ammunition stock to the secondary magazine. The transfer of ammunition between the two magazines is performed with the help of an electric lifting device arranged in the form of a height-adjustable articulated arm mechanism of the parallelogram type, via two openable hatches between the two magazines.
The above-mentioned system with an articulated arm mechanism for the manual handling and transfer of ammunition between the magazines is a complicated and time-consuming method. During repeated automatic fire with an automatic cannon, there is a requirement for the flow of ammunition to the automatic cannon to take place without interruption. This is especially important during the shooting of automatic fire where rounds that are fired in periods one after the other are expected to hit one and the same target substantially at the same time as previously fired rounds. There is also a requirement for the system to be capable of handling mixed types of ammunition. Furthermore, the manual handling of ammunition presents a risk for both personnel and the environment.
It is desirable to make available a rapid and secure system and method for the reversible transfer of ammunition between a secondary magazine and a primary magazine, for example in an automatic cannon.
The aforementioned invention permits, according to an aspect thereof, the shooting of repeated automatic fire with interruptions only for loading ammunition to a primary magazine. Likewise, a system according to an aspect of the invention can be used in the opposite direction, that is to say during the emptying of a magazine.
It is also desirable to make available a system and a method which can handle mixed types of ammunition during the transfer of ammunition between a primary magazine and a secondary magazine.
A system for the reversible transfer of ammunition to or from a primary magazine, for example in an automatic cannon, is therefore made available according to the present invention. The aforementioned system comprises, in addition to a primary magazine, at least one transfer magazine, hereinafter referred to as a secondary magazine.
The secondary magazine can be arranged in an ammunition storage place situated beneath the primary magazine. The ammunition storage place can accommodate more than one secondary magazine, which are then in a ready position (RP) before being guided into the hoisting device beneath the primary magazine. In one embodiment, a secondary magazine is arranged directly in the hoisting device beneath the primary magazine in a bottom position (BP) or stand-by position (SP) in anticipation of being hoisted up to the docking position (DP). The secondary magazine or secondary magazines can also be positioned in an ammunition storage place which is arranged adjacent to the hoist. The hoisting device comprises a chain drive arrangement for transport of the aforementioned at least one secondary magazine from the bottom position up to the primary magazine.
A docking and transfer arrangement for docking the secondary magazine with the primary magazine permits the transfer of ammunition between the magazines. The docking and transfer mechanism is described more fully in the detailed description. The arrangement also comprises at least one drive arrangement for driving the secondary magazine and the primary magazine during the transfer of ammunition between the magazines.
According to a second embodiment of the system, the hoisting device is arranged in the form of two vertical self-supporting pairs of rails between the ammunition storage place and the primary magazine, being a front pair of rails and a rear pair of rails configured for the hoist transport of the secondary magazine, wherein the chain drive arrangement of the hoisting device, which is a freestanding construction separated from the pairs of rails, is attached and fixed to the outside of the two front pairs of rails.
According to a third embodiment of the system, the hoisting device is arranged in the form of a self-supporting framework comprising two parallel, side-mounted vertical pairs of members between the ammunition storage place and the primary magazine of the automatic cannon, wherein each of the two pairs of members is linked together via a lower transverse member, two intermediate transverse members and an upper transverse member, wherein, arranged on the insides of the two pairs of members, are four vertical parallel support rails, being two front support rails and two rear support rails, between which rails the secondary magazine is transported upwards and downwards to the primary magazine via the chain drive arrangement of the hoisting device, and wherein the chain drive arrangement is arranged in the framework in the form of a loop on the inside of the pair of members of the framework via chain wheels and drive wheels mounted on the transverse members of the framework.
According to a fourth embodiment of the system, the ammunition transfer system comprises a common drive arrangement for synchronous driving of the secondary magazine and the primary magazine during the transfer of one type of ammunition from the secondary magazine to the primary magazine.
According to a fifth embodiment of the system, the secondary magazine is driven by the drive arrangement of the primary magazine via a slave driver.
According to a sixth embodiment of the system, the ammunition transfer system comprises two separate drive arrangements for independent driving of the secondary magazine and the primary magazine during the transfer of mixed types of ammunition from the secondary magazine to different positions in the primary magazine.
According to a seventh embodiment of the system, the ammunition transfer system comprises a switching unit for switching between the common drive arrangement and the two separate drive arrangements.
According to an eighth embodiment of the system, the ammunition transfer system comprises a programmable control and monitoring unit for controlling and monitoring the hoisting device and the docking and transfer mechanism.
According to the present invention, a method for the reversible transfer of ammunition in an ammunition transfer system, comprising at least one secondary magazine arranged in a hoisting device beneath the primary magazine of an automatic cannon, has also been made available. The aforementioned hoisting device comprises a chain drive arrangement, a docking and transfer arrangement for the execution of the docking and transfer mechanism and at least one drive arrangement for driving the magazine. The method comprises the following steps: hoist transport of one secondary magazine at a time between the ammunition storage place and the primary magazine via the hoisting device, and docking and transfer of ammunition between the secondary magazine and the primary magazine via the docking and transfer arrangement and via the aforementioned at least one drive arrangement.
A rapid and secure system and method for the reversible transfer of ammunition between a secondary magazine and a primary magazine in an automatic cannon are achieved on the basis of what is proposed above.
Synchronous driving of the chain conveyors of the magazines via a common drive arrangement means the rapid and secure transfer of ammunition between the magazines with no risk or with a low risk of interruption in the transfer.
Automatic switching between a common drive arrangement and two separate drive arrangements for independent driving of the chain conveyors of the magazines means that a single type of ammunition as well as mixed types of ammunition can be handled during the ammunition transfer.
Activation of the docking and transfer mechanism via the operating force from the connecting secondary magazine during docking means the rapid and secure transfer of ammunition between the magazines.
The invention is now described by way of example with reference to the accompanying drawings, in which:
a and b depict a schematic perspective view of a secondary magazine and a transport carriage respectively unmounted (a) and mounted (b) on the secondary magazine.
a-f depict a schematic detailed view of the hoisting of the secondary magazine, the ammunition outlet and the ammunition inlet of the primary magazine before docking (a, b), the docking e of the magazines and the transfer of ammunition from the secondary magazine to the primary magazine (c, d, e) and after transfer (f).
Before the invention is described in detail, it must be appreciated that this invention is not restricted to specific materials or configurations that are disclosed herein. Suchlike configurations and materials may vary. It must also be appreciated that the terminology applied herein is used only to describe specific embodiments, and is not intended to be restrictive so that the scope of the present invention is restricted only by the attached claims.
The present invention will now be described in more detail with reference to the accompanying figures, in which different illustrative examples of the invention are depicted.
The secondary magazine can also be kept outside the hoisting device 7 in a so-called ammunition storage place 6.
The secondary magazine may contain 60 rounds, for example, as in
In a corresponding manner, the primary magazine 4 comprises a chain conveyor, not illustrated here, for feeding the ammunition 2 to an ammunition outlet on the upper side of the primary magazine 4, where the transfer of the ammunition 2 takes place to the breech casing of the automatic cannon 5.
Also included in the secondary magazine 3 are two drive shafts 20, each having two chain wheels 21 for the synchronization of two separate drive chains 22 arranged in front and rear end walls 12, 13 of the secondary magazine 3. The two drive chains 22 drive the chain conveyor 17 of the secondary magazine 3 and distribute the driving force from an electric drive arrangement 23 to the two drive chains 22.
The transport carriage 11 is configured so that the secondary magazine 3 can be easily attached/mounted (b) to the transport carriage 11 during the hoist transport.
The transport carriage 11 comprises external wheels 50, which run on the slide rails 44, 45 of the framework during the hoist transport (see
In a further embodiment, the locking and coupling arrangement can comprise a lock hook arranged on the chain drive arrangement 8, not illustrated here, which is then hooked securely in a recess or on a frame on the front end wall 12 of the secondary magazine 3, or alternatively on the transport carriage 11. The position of the lock hook can then be secured via a transverse locking bolt. In another embodiment of the locking and coupling device, this consists of or comprises a remotely controlled magnetic lock, not illustrated here.
In the primary magazine 4, seven drive shafts and seven chain wheels are used to ensure that the drive chains are always synchronized with one another even if any of the drive chains are slack, not depicted here. The drive chains of the primary magazine 4 can also be adjusted manually via a chain adjustment mechanism.
In a special embodiment, the transport carriage 11 is securely mounted on the drive chain of the chain drive arrangement 8 via screwed, bolted or clamped joints between the drive chain and the outsides of the transport carriage 11.
Secondary magazines 3 that are parked in the ammunition storage place 6 outside the hoisting device according to the second embodiment are rolled forwards to the ammunition storage place 6, whereupon it is positioned and locked securely in a transport carriage 11 (see
In one embodiment, when more than one magazine is waiting in turn in the ammunition storage place 6 for feeding, the locking and coupling arrangement 10 can be arranged on a transport carriage 11, wherein the secondary magazine 3 is docked to the chain drive arrangement 8 via the transport carriage.
In another embodiment, the hoisting device 7 of the transfer system 1 is arranged in the form of a self-supporting framework comprising two parallel, side-mounted vertical pairs of members 40 between the magazine store 6 and the primary magazine 4 of the automatic cannon 5.
Each of the pairs of members 40 is linked together via a lower pair of transverse members 41, two intermediate pairs of transverse members 42 and an upper pair of transverse members 43. Arranged on the insides of the two vertical pairs of members 40 are four vertical parallel support rails 44, 45. Two front support rails 44 and two rear support rails 45, between which the transport carriage 11 with a secondary magazine 4 mounted is transported up and down to the primary magazine 3 via the chain drive arrangement 8 of the hoisting device 7.
The ammunition storage place 6 can have two horizontal guide rails 51 arranged for controlling the secondary magazines 3 in the horizontal plane during the rolling transport to and from the docking position of the hoisting device 7. The guide rails 51, being one lower and one upper guide rail, are securely mounted on the outsides of the pair of members 40 of the framework.
The different embodiments of the ammunition transfer system ammunition store 1 comprise at least one, two or preferably three secondary magazines 3, or more.
In an alternative embodiment, the hoisting device 7 is driven by a pinion instead of a drive chain, not illustrated here. In a further, alternative embodiment, the hoisting device 7 is driven via a winch and counter-weights, not illustrated here.
The link arm systems of the magazines 3, 4 are driven via separate drive chains arranged in the front and rear end wall parts of the respective magazine 3, 4. The drive chains are synchronized with one another via the drive shafts of the chain conveyors, wherein the drive shafts distribute the driving force from a programmable drive arrangement that is capable of engagement and disengagement, not illustrated here.
The ammunition 2 is transported round in the respective magazine 3, 4 on guide rods, which are connected to the link arm systems via mounting pins, not illustrated here.
The transfer of ammunition 2 between the magazines 3, 4 can take place forwards or backwards depending on whether the primary magazine 4 is to be filled or emptied. For example, the primary magazine must be emptied in the event of a change of the type of ammunition.
In one embodiment, the link arm system of the secondary magazine 3 is driven synchronously with the link arm system of the primary magazine 4 via a slave driver connected to the drive arrangement 23 of the primary magazine 3.
The drive arrangement of the primary magazine 4 is capable of engagement and disengagement and is controlled manually via a control and monitoring unit. Alternatively, the drive arrangement can be remotely controlled.
The slave driver is mounted on the front end wall 12 of the secondary magazine 3 and is attached/connected to one of the drive wheels 21 of the secondary magazine 3. Synchronous driving of the link arm systems of the two magazines permits the rapid and secure transfer of ammunition between the magazines 3, 4.
a-f depict the docking and transfer process, where hoisting and started docking (a, b), docking in €, when the ammunition transfer between the magazines 3, 4 has started (d), has come half-way € and the position of the docking arrangement after the completed transfer of ammunition 2 between the magazines 3, 4 (f). The area within a circle in the respective image illustrates the docking mechanism. The secondary magazine is hoisted up towards the primary magazine (a), and the docking is activated by the force which the movement in the connecting secondary magazine 3 exerts on the primary magazine 4 in the course of docking of the magazines 3, 4 (b). Via four contact surfaces 63 arranged on the ammunition outlet 18 of the secondary magazine 3 (inlet during emptying), the force is transferred to the docking arrangement via four, preloaded, V-shaped projecting articulation mechanisms, referred to as articulations 64, arranged in the corners of the ammunition inlet 19 of the primary magazine 4 and are movably connected to the four movable locking bolts 61, so that the locking bolts 61 are displaced radially, during activation of the articulations 64, from the closed blocking position to the open position in the ammunition inlet of the primary magazine 4. The locking arrangement of the secondary magazine is described in more detail in FIGS. Sa and b. The chain conveyors of the secondary magazine 3 and the primary magazine 4 comprises a link arm system comprising star-shaped drive wheels 21, which, after docking of the magazines 3, 4, are positioned and synchronized with one another so that the ammunition 2 is transferred between the link arm systems of the magazines 3, 4 via the transfer channel 62 that is released after docking.
A transfer channel 62 between the magazines 3, 4 opens (a), whereupon the transfer of ammunition 2 between the magazines 3, 4 can begin (d). During the return transport of the secondary magazine 3 to the ammunition storage place, the articulations 64, under the influence of the preloading on the articulation mechanisms, return to their starting positions projecting from the primary magazine 4. At the same time, the four locking bolts 61 return to their closed starting positions in the ammunition inlet 19 of the primary magazine 4 (outlet during emptying). The movement of the secondary magazine 3 during docking (b, c) thus regulates the position of the locking bolts 61 between the closed and open position in the ammunition inlet 19 of the primary magazine 4. The outlet 18 of the secondary magazine 3 is likewise closed when the contact surfaces 63 return to the non-preloaded starting position (see also
In a second embodiment of the driving of the magazines 3, 4, not illustrated here, in respect of the transfer of mixed types of ammunition, two independent drive arrangements can be used instead of a common drive arrangement. The chain conveyors of the magazines 3, 4 are driven here by separate independent drive arrangements, being one drive arrangement for each chain conveyor. The two independent drive arrangements each comprise control and monitoring functions for independent driving of the respective link arm system, forwards or backwards, at the same or at different speeds.
Independent driving of the link arm systems permits, for example, the transfer of different types of ammunition 2 from the secondary magazine 3 to different positions in the primary magazine 4. Having regard for the question of whether one or a plurality of types of ammunition 2 must be used, the possibility also exists for alternating automatically, via a switching unit, between common synchronous or separate independent driving of the magazines 3, 4 by engaging or disengaging the slave driver and respectively engaging or disengaging the other independent drive arrangement.
FIGS. Sa and b depict the gate device 87 in the secondary magazine 3 in the open (a) and respectively in the closed (b) position. The arrangement consists of or comprises a contact surface 63 in the form of a sprung toothed rack, a toothed wheel 88, a chain wheel 89 and a chain link 90, which are enclosed by a casing 91. The gate device is opened in that the contact surface 63 is pressed down by the contact between the magazines 3, 4, whereupon the toothed wheel 88 rotates and drives the chain wheel 89, and with it the chain link 90, into the open position (a). When separation of the magazines begins, the arrangement returns to the closed position when the movement of the magazines away from one another releases the pressure on the contact surface 63.
The articulations 64 are depicted in more detail in
The ammunition transfer system 1 also comprises a central control and monitoring unit 80 for controlling both the hoisting device 7 and the docking and transfer device 60.
The central control and monitoring unit 80 is preferably remotely controlled, but can also be controlled manually via a keypad on the control and monitoring unit 80.
Number | Date | Country | Kind |
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1630158-2 | Jun 2016 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SE2017/050666 | 6/20/2017 | WO | 00 |