ES2790392T3 - Device for supplying power to the fuzes - Google Patents

Abstract

Projectile comprising an active charge contained in it, which is initiated by a fuse arranged in the projectile, and a device for supplying energy to the fuse, with a cylindrical cavity (3), which is located in a casing (5), with at least one coil (2), which is arranged in the housing (5) around the cavity (3), and a magnet (1) that is shorter than the length of the cavity (3) and which can move along along the length of the cavity (3), where at least one air passage (13) is arranged in the casing (5), characterized in that the cylindrical cavity (3) and the casing (5) are arranged inside of the projectile, and because at least one air duct (12) is arranged in the projectile, which is connected to the air passage (13) to allow the exchange of air with the cavity (3).

Description

DESCRIPTION

Device for supplying power to the fuzes

The present invention relates to a device for supplying power to fuzes, such as those used in projectiles and ammunition. Such a projectile according to the invention has an active charge that must be initiated for the active charge to deploy its effects. That active charge can be an effective charge that gives rise to flash and / or explosion effects. However, it can also be an ejection charge to eject active bodies like parachutes, camouflage clouds and the like. Penetrating devices may also be provided as active media ejected by the active charge.

To initiate an active charge, a fuse is provided on the projectile, which is electrically operated according to the invention. The fuze initiates the active charge by means of an electrical impulse.

In order to supply energy to fuses of this type, multiple systems are known according to the current state of the art. In order for the fuse and the projectile to function autonomously, the energy supply is designed in such a way that this firing impulse is only caused by the forces acting on the projectile during the firing of the projectile. It is known that a magnet is set in motion due to the acceleration of the projectile during firing and that the movement of the magnet is driven through a coil. The resulting moving electromagnetic field in the coil can generate an electrical pulse that can be used to supply power to the fuze. Power supply devices of this type are commonly known by the name of flyback generators.

Such a device for supplying power to the fuzes is disclosed in DE 25 56 250 C2, for example. Here, the accelerating force acting on the projectile during acceleration is used to set the magnets in motion within a cylindrical element. For this, the inertia of the magnets is used.

The magnets move through a coil and thus generate the electrical impulse necessary for the electrical supply to the fuze.

Furthermore, it is known that a locking element is associated with the magnet in such a way that it only sets in motion when a certain force is applied to it. This is to increase the effectiveness of the power generation, as well as to prevent early or unwanted power generation and therefore ignition of the active load. Such a lock is known, for example, from US 7,478,595 B1.

Such devices are also known to harness the acceleration energy of a projectile, or the rotational energy of the projectiles stabilized by the spin, to supply energy to the fuzes. The two applications of such a device for supplying power to fuzes are known from US 4,091,733 A, for example. Projectiles with similar energy delivery devices are also known from DE 4032 844 C1, FR 2070 389 A5 and JP 2002 054897 A.

The effectiveness of such a power supply to the fuzes is determined by the speed with which the magnet moves through the coil. The size of the magnet and its magnetic field are also a determining factor.

In the devices known to date from the state of the art for supplying energy to the fuzes, a magnet moves inside a cylindrical element, the magnet being shorter than the length of the cylindrical element. The free volume inside the cylindrical element, which is not occupied by the magnet at rest, is available for the movement of the magnet.

The principle of operation of such a device for supplying energy to the fuzes is always the same, namely that the acceleration during the firing of the projectile or the centrifugal force during the rotation of a projectile stabilized by rotation move the magnet through the cylindrical element and along a coil. An electrical impulse is induced in the coil by the moving electromagnetic field of the magnet. This electrical energy can be used to power an electric fuse.

However, as the cylindrical element in which the magnet moves is usually filled with air, the magnet displaces its air in front of it as it passes through the cylindrical element, which inevitably leads to compression of the air in front of the magnet to as it moves. The air thus compressed acts as a force that opposes the movement of the magnet, so that the movement of the magnet is slowed down. This also reduces the speed of the magnet and therefore reduces the efficiency of such a device in supplying power to the fuses.

The aim of the present invention is therefore to increase the amount of energy of conventional devices for supplying energy to fuzes, in particular recoil generators, and thus improve their efficiency. However, since unlimited space is not available in the corresponding projectiles, this increase in effectiveness should not be achieved by increasing the construction components.

This objective is achieved by means of the features of the main claim. According to the invention, there is provided a device for supplying energy to fuzes in a projectile containing an active charge that is initiated by the fuzes. In this case, it is an electric fuse that can initiate the active charge with the help of electrical energy. To generate the electrical energy, a cylindrical cavity is provided in the projectile, which is located within a casing. The housing limits, as it were, the cylindrical cavity and is preferably made of plastic.

At least one coil is provided in the housing, which is arranged around the cavity. As a result, the coil is arranged, at least in a partial region of the housing, around the cylindrical cavity. The coil does not need to surround the entire length of the cylindrical cavity, but only a partial area.

A magnet is provided in the cylindrical cavity which is shorter than the length of the cavity. This magnet preferably also has a cylindrical shape, and in particular with a diameter such that it can be inserted into the cylindrical cavity and, since the magnet is shorter than the length of the cavity, it can move up and down within she. The movement of the magnet therefore occurs in the longitudinal direction of the cylindrical cavity.

The cylindrical cavity is filled with a gas, preferably air. In order to prevent air from accumulating or compressing when the magnet moves in the cylindrical cavity, which happens when the magnet moves in the direction of magnet movement, at least one air passage is provided in the housing. On the side of the magnet opposite to the direction of movement, a suction effect continues, because here the air expands. Therefore, an air passage must also be provided here to supply air to the cavity.

An air passage of this can be done by means of a simple hole or by inserting a housing element with a recess so that air can flow through the housing element. For example, a perforated disk can be used for this purpose. In an example of a preferred embodiment, a perforated disc is inserted in the foot of the cylindrical cavity and another in the head so that air can escape, or be supplied to the cylindrical cavity, on both sides of the magnet.

So that air can escape or be supplied through the air passages in the cylindrical cavity, at least one air duct is provided in the projectile to allow an exchange of air with the cavity. For this, the air passages are arranged in such a way that air can be supplied or removed.

For air ducts of this type, grooves and other recesses can be provided in the projectile, so that after the projectile has been fired, air can be exchanged with the cavity through these air ducts. In the simple construction form, the air ducts connect the cavity with the outer wall or shell of the projectile in order to use air from outside the projectile.

In a special embodiment, air dampers are also provided in the projectile, with which said air exchange is made possible. These air dampers are located in the projectile and are arranged in such a way that the air from the air dampers is supplied to the air passages through the air ducts, or the air can be removed from the air passages .

Any cavity in the projectile itself or within the shell of the projectile is suitable for such an air damper. Such an air damper does not have to be particularly large, since the amount of air displaced by the magnet is quite small.

To ensure that the magnet does not move directly when the projectile is fired or charged, thus initiating early ignition, a safety element is preferably provided in the cylindrical cavity, which can limit the movement of the magnet in the cavity. A safety element of this type according to the invention prevents the movement of the magnet, and the release of the magnet does not occur until a certain force is applied to it. This force can be the acceleration force with which the projectile is fired or the centrifugal force acting on the magnet when a spin stabilized projectile is fired.

A safety element of this type could be spring loaded, in such a way that a bolt slides inside the cylindrical cavity and prevents the movement of the magnet and, starting from a certain force that opposes the force of the spring, either centrifugal force or acceleration force, the bolt is displaced out of the cylindrical cavity, thereby releasing the magnet.

In a preferred embodiment, a controlled break point is inserted into the cylindrical cavity as a security feature. Preferably, this is also made of plastic and prevents the magnet from moving. However, from a certain force acting on the breaking point controlled through the magnet, it breaks and releases the movement of the magnet.

In both cases it is possible to configure the security element in a variable way, so that the movement of the magnet is released from a certain force. With the help of the mass of the magnet and the acceleration force or the force centrifuge acting on the magnet, it is then possible to calculate how the safety element should be designed to stop the movement of the magnet up to this force. The controlled breaking point can then be dimensioned to break only from the calculated force and a spring can have a corresponding spring force.

If the device according to the invention for supplying energy to the fuzes by means of the accelerating force is to initiate the active charges contained in the projectile, the housing and the cylindrical cavity of the device are arranged in the longitudinal direction of the projectile. This means that the casing is arranged within the projectile or within the shell of the projectile, respectively, in such a way that the longitudinal alignment of the cylindrical cavity coincides with the longitudinal alignment of the projectile. Thus, the cylindrical cavity is arranged in the direction of flight of the projectile. This allows the acceleration force to act on the magnet during firing.

On the contrary, the device according to the invention is arranged radially in the transverse direction in a projectile, which is stabilized by spin and which must be activated by the centrifugal force generated during the rotation of the projectile. The structure of the device according to the invention is the same in both cases, except that when it is fired by centrifugal forces, the casing and the cylindrical cavity are arranged in the projectile in a radial direction so that the centrifugal forces generated can act on the magnet.

In order to damp or store the electrical energy generated by the movement of the magnet through the coil, in a preferred embodiment at least one capacitor is provided in the projectile, which is electrically connected to the coil and to the fuse. The electrical energy then generated by the magnet as it moves through the coil can thus be temporarily stored in the capacitor and is then available to the fuze to initiate active charging. The capacitor also acts to smooth out the generated energy pulse.

In addition, a delay in ignition of the projectile can be provided. In this case, the fuse is made in such a way that the active load does not start immediately when the electrical energy is applied, but only after a certain time has elapsed. This means that active charging does not start immediately when shooting, but only later.

To allow the magnet to move in the cylindrical cavity and to guide it in it, it is sufficient to insert an equally cylindrical magnet into the cavity. If the diameter of the magnet is chosen so that it can fit into the cavity, the cavity itself acts as a guide for the magnet. However, in the preferred embodiment, additional guides are provided in the cavity that guide the movement of the magnet in the cavity. They can be ribs arranged in the cavity, which can fit into the corresponding grooves of the magnet. However, a central core is also conceivable in the cylindrical cavity, in which the magnet is guided through a hole in the magnet.

For the safety of the fuse and to protect it from negative voltages, it is also proposed to introduce at least one diode between the coil or capacitor and the fuse. This prevents any voltage opposite to the operating voltage of the fuze from reaching the fuze and possibly damaging it. Likewise, diode can be used to prevent discharge of the capacitor through the coil.

Other characteristics of the present invention appear from the attached drawings. It shows:

Fig. 1: - perspective representation of a projectile with air dampers

Fig. 2: - perspective section through a projectile according to the invention

Fig. 3: - detailed drawing of a device according to the invention on the projectile

Fig. 4: - device according to the invention without projectile

Figure 1 shows a projectile with a device according to the invention. Any large-caliber ammunition is conceivable as a projectile, as are projectiles that are discharged from launchers. As can be seen in Fig. 1, the outer casing of such a projectile consists of a jacket 20 and free spaces therein. These free spaces can be used as air dampers 10 according to the invention.

In figure 2 you can see the movement of a magnet for a device of the invention. In this case, the magnet 1 is movably mounted in a cylindrical cavity 3, the magnet 1 being shorter than the cavity 3. This allows the magnet 1 to move in the cavity 3.

The device of Fig. 2 is provided in the longitudinal direction of the projectile, in such a way that when the projectile is fired, due to the inertia of the magnet 1, it moves through the cavity. The cavity 3 is limited by a housing 5 in which at least one coil 2 is inserted. The coil 2 is arranged in the housing 5 in such a way that the coil 2, at least in some areas, is arranged around the cylindrical cavity 3.

When magnet 1 moves through cavity 3 due to the acceleration acting on it, it moves beyond of coil 2 and the movement of the magnet's magnetic field past coil 2 induces an electrical voltage in coil 2. This induced voltage can be used to help a fuze initiate an active charge on the projectile.

So that the movement of the magnet 1 in the cavity 3 does not adversely affect the movement of the magnet 1 due to the air congestion created during the movement, air diffusers 13 are provided. They are located at the ends of the head and foot. from cavity 3. Air can escape from cavity 3 or can be drawn into cavity 3 through air vents 13. Outgoing air stream 11 or incoming air stream 11 is supplied to air diffuser 13 through the air flow paths, for example via slots.

When the magnet 1 moves through the cavity 3, then the air is forced out of the cavity 3 in the direction of movement of the magnet 1, that is, through the air passage 13. The air current 11 is then carried to an air damper 10 through the air guides 12. Similarly, on the opposite side of the cavity 3, that is, the side opposite the direction of movement of the magnet 1, the air is also attracted towards the cavity 3 through an air passage 13 by the suction effect of the moving magnet 1. This air also comes from an air damper 10, thereby creating an air stream 11 that extends from the damper of air 10 through the cavity and back to the air damper 10. Only one air damper 10 or in each case one air damper 10 can be used for the exhaust air and one for the intake air. This air stream avoids the braking effect caused by accumulated or expanded air in the cavity. This increases the efficiency of the device and the amount of electrical energy that is generated.

Figure 3 shows a device according to the invention, where the magnet 1 is in its rest position and is kept in its rest position by means of a security element 4. The security element 4 guarantees that only after As long as a certain force is exerted on the magnet 1, it moves through the cavity 3. This prevents the generation of tension due to the movement of the magnet when the projectile is charged. It also prevents the early initiation of active charging.

The security element 4 is here realized as a controlled breaking point. This means that from a certain force of magnet 1 on the controlled breaking point, it breaks and releases the movement of magnet 1. The air passage at the end of the cavity is also visible, through which the air is supplied to the cavity or carried out of it.

Finally, Fig. 4 shows once again the structure of the device with the housing 5 according to the invention. The internal cavity 3 has a cylindrical shape and is partially filled with magnets 1. The magnet 1 also has a cylindrical shape and is conducted in the cavity 3 through the mutually matching diameters of the cylindrical cavity 3 and the magnet 1. The magnet 1 can thus move along the cavity 3. The safety element 4 protects the magnet against unwanted movements.

The present application is not limited to the prescribed features, but other embodiments are conceivable. For example, the cavity housing could be designed as a magnet yoke. Also, the cavity could be made of a material other than plastic. Here it is only important that the housing material does not conduct magnetic fields.

List of reference signs

1. Magnet

2. Coil

3. Cavity

4. Security element

5. Housing

10. Air damper

11. Air stream

12. Air stream

13. Air passage

20. Shirt

Claims (16)

1. Projectile comprising an active charge contained in it, which is initiated by a fuze arranged on the projectile, and a device for supplying energy to the fuze, with a cylindrical cavity (3), which is located in a housing (5), with at least one coil (2), which is arranged in the housing (5) around the cavity (3), and a magnet (1) which is shorter than the length of the cavity (3) and which can move along the length of the cavity (3), where at least one air passage (13) is arranged in the housing (5), characterized because the cylindrical cavity (3) and the casing (5) are arranged inside the projectile, and because at least one air duct (12) is arranged in the projectile, which is connected to the air passage (13) to allow the air exchange with the cavity (3). Projectile according to claim 1, characterized in that the housing (5) is arranged within a jacket of the projectile. Projectile according to claim 1 or 2, characterized in that at least two air outlets (13) are arranged in the housing (5), namely at the ends of the head and foot of the cavity (3), to allowing a stream of air (11) through the cavity. Projectile according to one of the preceding claims, characterized in that at least one air damper (10) is provided in the projectile, with which air exchange is made possible. Projectile according to claim 4, characterized in that the projectile has a jacket (20) delimiting the air damper (10). Projectile according to any of the preceding claims, characterized in that a holding element (4) is provided in the cavity, which can limit the movement of the magnet (1) in the cavity. Projectile according to claim 6, characterized in that the safety element acts as a controlled breaking point and breaks from an adjustable force acting on it to remove the limitation of the movement of the magnet (1). Projectile according to any of the preceding claims, characterized in that the casing is made of plastic. Projectile according to one of the preceding claims, characterized in that the housing (5) and the cavity (3) are arranged in the longitudinal direction of the projectile. Projectile according to one of the preceding claims, characterized in that the housing (5) and the cavity (3) are arranged in the transverse direction of the projectile. Projectile according to one of the preceding claims, characterized in that the projectile has at least one capacitor, which is electrically connected to the coil (2) and to the fuse. Projectile according to one of the preceding claims, characterized in that a delay of the ignition of the projectile is provided. Projectile according to one of the preceding claims, characterized in that the magnet (1) can be moved in the cavity (3) by means of guides. Projectile according to one of the preceding claims, characterized in that at least one diode is provided between the coil (2) and the fuze for supplying energy to the fuze. Projectile according to one of the preceding claims, characterized in that an air passage (13) is designed as a hole. Projectile according to one of the preceding claims, characterized in that an air passage (13) is designed as a perforated disk.