This application claims the priority, under 35 U.S.C. §119, of German application DE 10 2007 060 567.8, filed Dec. 15, 2007; the prior application is herewith incorporated by reference in its entirety.
The invention relates to a safety and arming unit for a fuze of a projectile, comprising a firing means for transferring the firing energy to another firing means and a barrier for interrupting the transfer. The barrier is locked in a locking state by a safety means provided for an unlocking action due to a physical arming parameter.
A safety and arming unit for a fuze is used to prevent inadvertent activation of a main charge of a projectile; however, activating the main charge should be possible after arming. For this purpose, the safety and arming unit is a component of a fuze for firing the main charge and is provided with a firing chain of two or more firing means. In order to fire the main charge, the first firing means is firstly activated, for example by means of a puncture-sensitive mini-detonator which is punctured by a puncturing needle. Explosion energy of the first firing means is transferred to the second firing means by an appropriate arrangement of the first two firing means, where the second firing means may be designed as a firing booster. The latter can transfer its explosion energy to an initial charge or main charge.
Conventional fuzes, especially of simple projectiles such as mortar shells, have a safety pin as a first safety means and a device which detects the launch shock as a second safety means. The disadvantage of these safety means is that the safety pin needs to be pulled out manually before loading the mortar shell. It is fairly common to forget to pull out the safety pin. The result is that the mortar shell becomes a dud.
It is accordingly an object of the invention to provide a safety and arming device for the fuze of a projectile which overcomes the above-mentioned disadvantages of the heretofore-known devices and methods of this general type and which uses a physical arming parameter independent of a launch parameter to unlock the safety means without needing to pull out a safety pin.
With the foregoing and other objects in view there is provided, in accordance with the invention, a safety and arming unit for a fuze of a projectile, comprising:
a firing means disposed to transfer a firing energy thereof to another firing means;
a barrier for selectively interrupting the transfer of the firing energy; and
a safety disposed to lock said barrier in a locking state and to unlock said barrier in dependence on a physical arming parameter in the form of an apogee parameter effected when the projectile flies through an apogee of a projectile trajectory.
In other words, the objects are achieved by a safety and arming unit of the type mentioned initially, in which the arming parameter is an apogee parameter, effected by the projectile flying through the apogee of a projectile trajectory. A parameter (i.e., a criterion) is utilized by the invention which is independent of a launch parameter and which, in conjunction with using the launch parameter, can attain a high level of safety against inadvertent firing.
The invention is particularly suitable for projectiles in the form of mortar shells. Mortars are generally fired at an angle of >45° to the horizontal, as a result of which the profile of the trajectory is approximately characterized by a parabolic flight which has a prominent reversal point at the apogee. An effect of the reversal point on a projectile passing through the reversal point can be used as an apogee parameter.
The apogee parameter is a parameter which allows identification of the passage of the projectile through the apogee. Its use as an arming parameter expediently assumes sampling or otherwise evaluating the apogee parameter by the safety means so that flying through the apogee is identified at least implicitly. The apogee parameter can be a profile of a velocity or deceleration and/or rotation of the projectile or fuze about an axis which is transverse with respect to the flight direction. The rotation can be detected by inertia or other parameters, such as a direction of the magnetic field. The height profile of the fuze above a reference level such as the ground can also be an apogee parameter. Due to the fact that satisfying the apogee parameter indicates that the projectile is a long way from the launch tube, a high safe separation distance can be attained. Further arming parameters can be acceleration, angular momentum, a ram-air pressure, a time after launch or an impact pressure.
The barrier is used to absorb and/or deflect firing energy of the first firing means in such a manner that firing the second firing means due to the firing energy of the first firing means is reliably prevented. In addition to the safety means, provision is advantageously made for a second safety means which is independent of the first safety means and locks the barrier. The two safety means are expediently provided for an unlocking action on the basis of two physical arming parameters which are independent of one another. The safety means—expediently both safety means—serves or serve to in particular mechanically lock the barrier in such a way that, for example, movement of the barrier from its safe position to the armed position is reliably prevented. The barrier can be unblocked by an unlocking action of the corresponding safety means in such a way that it can be moved to the armed position, either independently due to inertia, for example, or driven by a moving means.
In one advantageous embodiment of the invention, the apogee parameter is a force. A force can easily be sampled and it is easy to identify whether the apogee parameter is satisfied.
The safety means can be designed to be robust and not susceptible to faults if provision is made for mechanical sampling of the apogee parameter.
The safety means expediently comprises a locking means which causes an unlocking action by changing its position in the fuze on passing through the apogee. The safety means can easily be produced in this manner. Equally advantageously, the locking means, in its safe position, advantageously mechanically blocks an unlocking action.
It is possible to sample the apogee parameter in a simple manner if provision is made for the locking means to change its position by means of its inertia. The locking means is advantageously a metal piece, in particular a heavy metal piece, which reacts particularly finely to acceleration due to its high relative density.
If, by changing its position, the locking means unblocks an unlocking space into which part of a lock can be inserted for effecting the unlocking action, then locking and unlocking can be achieved easily.
In a further embodiment of the invention, the safety means comprises a magnet which, by changing its position in the fuze, causes an unlocking action on passing through the apogee. A mechanical step in the unlocking action can be attained by a magnetically effected step, as a result of which an unlocking mechanism can be kept simple.
In order to avoid inadvertent and premature unlocking of the safety means, the safety means expediently requires previous unlocking depending on a different arming parameter before it is unlocked due to the apogee parameter being satisfied.
The reliability against inadvertent unlocking of the second safety means can additionally be increased by blocking the unlocking of the safety means by another safety means. For example, the safety means can only be unlocked following a previous unlocking action. For this purpose, the arming parameter is expediently effected by launching the projectile. Hence, the safety means can be unlocked only once the projectile has been launched.
A particularly reliable further safety means is a mechanical dual-bolt system which is unlocked by the launch acceleration.
It is possible to provide a reliably acting barrier if the barrier is a rotor and provision is made for the second safety means to lock the rotor.
The projectile reaches the apex of its trajectory at the apogee. Due to the design of a projectile, possibly additionally due to a rear control surface, the projectile changes its orientation at the apex and lowers the fuze downwards towards the earth. This change in direction can reliably be used as the apogee parameter.
If the safety means is arranged significantly in front of a point of rotation of the projectile which is caused, for example, by air drag, then slight lateral acceleration across the direction of flight of the projectile is effected by the change in direction. This lateral acceleration can be sensed mechanically or electronically as a feature of the change in direction and can be used as apogee parameter.
A further characteristic of the apex of the trajectory is the minimum velocity of a projectile fired steeply upwards. Since the projectile decelerates during its flight due to the air drag caused by the projectile, this deceleration is lowest at the minimum velocity. The minimum velocity is attained at the apex or, due to general deceleration of the projectile during flight, just afterwards, when the gravitational acceleration balances the general deceleration. If this acceleration minimum is detected, the minimum longitudinal acceleration component of the fuze about the apex can be used as the apogee parameter.
The velocity of the projectile can also be used as the apogee parameter if it is measured around the apogee by an evaluation means and the velocity minimum is identified. The evaluation means is expediently an electronic evaluation means.
An electrical or electronic sensor can in particular be advantageous for detecting and evaluating particularly small forces. Since its evaluation requires an electronic evaluation means, an appropriate evaluation means is already available when such a sensor is used and, in this case, it can also control the unlocking. The unlocking of the second safety means is expediently controlled electronically.
The direction of the Earth's magnetic field relative to a direction of the fuze can be measured, particularly when using an electronic evaluation means, and this can be used to deduce a change in the direction of the projectile. When the directional change per unit time reaches a maximum, then the projectile has reached the apogee or has just passed it. The direction of the Earth's magnetic field relative to a direction of a fuze and/or its change in direction can be reliably measured in this case and can be used as the apogee parameter, in particular by an appropriately prepared electronic evaluation means.
Other features which are considered as characteristic for the invention are set forth in the appended claims.
Although the invention is illustrated and described herein as embodied in safety and arming unit for a fuze of a projectile, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
Referring now to the figures of the drawing in detail and first, particularly, to
Due to a steep launch angle of more than 45° relative to the Earth's surface or to the horizontal, for example approximately 50°, the projectile 4 passes through a prominent reversal point at the apogee 8 or apex of the trajectory 2, where the fuze 6 is displaced from an upwards-facing orientation to a downwards-facing orientation, effected by the shape of the projectile 4 and possibly assisted by a control surface. This change in direction accelerates the fuze 6 as a function of the position of the projectile 4 on its trajectory. This acceleration is greatest at the apogee 8. If the reversal point, or the curvature of the trajectory 2 at the apogee 8, is particularly prominent, for example due to a steep launch angle of more than 45° with respect to the Earth's surface, then the acceleration can be detected and evaluated well in a region 10 around the apogee 8.
The longitudinal acceleration component 18 is illustrated in
The bottom-most curve represents the longitudinal acceleration component 18 during vertical flight in which the projectile 4 is stationary at the upper reversal point before descending. The middle curve is attained by a steep launch, for example of 50°, and the upper-most curve is attained by a flat launch. As the launch becomes steeper, the change in the acceleration becomes more pronounced at the apogee 8 or in the region 10, as illustrated in
The second safety means 38 furthermore comprises an evaluation means 44 and a sensor 46 having a probe 48 and a detection means 50. The probe 48 is a piece of elastic heavy metal which experiences a force, indicated by a double-headed arrow, because of a longitudinal acceleration component 18, and transfers it in an amplified manner to the detection means 50 due to appropriate mounting in the detection means 50. The force is detected by the detection means 50 and evaluated by the evaluation means 44 having an energy source 52 for this purpose which obtains its energy during flight from liquids which are mixed by the launch shock and then emit electrical energy for a short while. Since, during the launch, a very large force acts on the probe 48 in a downwards or backwards direction, a step 54 is incorporated in the part 22 at a short distance from the probe 48, by means of which the probe 48 can be supported during the launch shock. So as not to bend during the process, the probe 48 is designed to be sufficiently elastic to independently move away from the step 54 again after the launch shock and to be available for measuring the force.
The evaluation means 44 evaluates the profile of the force on the probe 48, searching for a minimum. This is based on the velocity minimum at the apogee 8, and minimum air drag associated with this. Noise in the profile, which can be generated by oscillations of the projectile 4 during flight, is suppressed or not evaluated by the evaluation means 44 in the process. Once the minimum is identified, the locking means 40 is pulled out of the recess 42 by a micro-motor. The safety means 38 is armed and the lock 34 is unblocked by means of this unlocking action, which is driven forwards by a spring 56, so that its tip is pulled out of the opening 36. The rotor 28 is now completely unlocked and is turned to its armed position, driven by a motor or a spring.
The armed position is illustrated in
In place of the probe 48, the sensor 46 can have a means for determining the angle between the direction of the Earth's magnetic field and a direction of the fuze 6. For this purpose, the sensor 46 may comprise a piece of magnetized or unmagnetized ferromagnetic metal, with force acting on it due to the Earth's magnetic field. The force and/or the direction of the force can be detected and evaluated as a variable linked to the angle. The evaluation means 44 is then primed for determining a maximum rate of change of the angle, and thus detects the apogee 8. The corresponding force, angle or the rate of change of the angle then forms the apogee parameter.
The rotor 60 houses a safety means 62 which unblocks the rotor 60 in conjunction with another safety means 32. The other safety means 32 can be a dual-bolt system which locks the rotor 60. The safety means 62 comprises a lock 64 in the form of a bolt which engages in a corresponding recess in the second part 24 of the housing 20 and holds the rotor 60 locked in the housing 20, even after the other safety means 32 has been unlocked. The safety means 62 furthermore comprises a sphere as locking means 66 and two holding means 68, 70 which hold the sphere from two opposing sides.
The sphere is held loosely between the lock 64 and a further bolt 72, with there being a small amount of play between the sphere and the locks 64, 72 so that the sphere is not jammed in. It rests in a bowl-shaped recess in the holding means 68 (with a small amount of play there too) and is held in an easily movable fashion in its locked position by the interaction of the holding means 68 and locks 64, 72, with the locked position preventing outward movement of the lock 64 from the recess in the second part 24 of the housing 20.
After the end of the launch acceleration of the fuze 6, the spring 78 pushes the upper holding means 70 upwards again, that is to say away from the sphere, so that the sphere is unblocked, as illustrated in
In this manner, the sphere remains held in its holding position for a short time after launch so that any instabilities of the projectile 4 in flight which are still present for a short time after launch, do not unlock the sphere prematurely. The sphere is only released once the flight of the projectile 4 has been stabilized. This makes it possible to ensure a safe separation distance.
If the sphere is unblocked by both holding means 68, 70, as illustrated in
At the apogee 8, or in the region 10, the lateral acceleration component 16 acts on the sphere and pushes it out of its locked position, as indicated in
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10 2007 060 567 | Dec 2007 | DE | national |
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Number | Date | Country | |
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20090151585 A1 | Jun 2009 | US |