EP1075729A1 - Generator for generating transient impulses of electrical energy - Google Patents

Abstract

Generators for generating transient impulses of electrical energy, so-called impulse generators, are used for example for igniting a gas in gas burners or as percussion fuses for projectiles. The high speed required for changing the magnetic flux density in the time can only be achieved with the help of considerable forces such as those produced for percussion fuses for example. Manually activated generators are not usually capable of inducing comparatively high stresses because of the limited force which is applied. Percussion fuses must also be protected against accidental activation. Prior to the generation of the impulse of electrical energy, the inducing magnet is therefore in a starting position situated at a distance from the induction coil. At least one stationary magnet is located in front of the induction coil. This magnet produces a magnetic field whose polarity is oriented in such a way that it presents an obstacle to the inducing magnet in front of the induction coil. Elements are provided for enabling the inducing magnet to overcome this magnetic field in the direction of the induction coil.

Description

 Generator for generating short-term electrical energy pulses

The invention relates to a generator for generating short-term electrical energy pulses according to the preamble of the first claim.

These generators are also known under the term "impact generators". They are used in particular where a voltage or current pulse is required for a short time, for example for igniting a gas in gas burners or as a detonator for projectiles. The generation of an energy pulse usually takes place through a brief change in the magnetic flux, caused by interrupting, closing or changing a magnetic circuit at high speed. In the book "Dauermagnete", K. Schüler, K. Brinkmann, Springer-Verlag, Heidelberg, 1970, in chapter 56.3, Ignition generators, examples of corresponding designs shown and described. Figure 56.6 on page 501 shows two versions for changing the magnetic flux. In version a), a stationary outer ring, consisting of magnet and coil, surrounds an iron core and the flux change takes place by moving the iron core relative to the coil and magnet, while in version b) a core magnet is used, which is moved relative to the coil. The basic diagram of a gas lighter is shown in Figure 56.7. The mode of operation of the generator is based on the fact that an electromotive force is generated in a winding when the magnetic circuit is opened. The armature is suddenly torn away from the pole shoes when the magnetic force is reached via an actuation button and an intermediate compression spring.

The change in the magnetic flux density over time is responsible for the magnitude of the voltage or current pulse. In the case of impact detonators, for example, as are known from Figure 56.6 of the specified literature reference, the high impact velocity of the projectile is used. Impact detonator must be carefully protected against unintentional activation before they are triggered as intended.

In the case of a manually operated generator, as is known, for example, from Fig. 56.7, the achievable rate of change of the magnetic flux density and thus also the achievable height of the

Voltage or current pulse less. For this reason, it is usually not possible to use, for example, the squib or the by hand-operated generators

To safely ignite the initial ignition charge of the propellant charge of a projectile or to generate a sufficiently high pulse in a magnet system of a projectile by means of induction, with which, for example, the electronics of a projectile control can be operated or an ignition timing can be set. As a rule, only current-fed induction coils that have been known for a long time are able to do this

(U.S. Patent 1,739,921). However, they require the constant availability of a power supply.

The object of the present invention is to present a generator with permanent magnets which is safe to handle and which delivers a high electrical energy pulse even when triggered manually.

The object is achieved according to the invention with the aid of the characterizing features of the first claim. Advantageous embodiments of the invention are claimed in the subclaims.

The structure of the generator according to the invention differs significantly from the prior art. The induction coil or coils and the inducing permanent magnet generating the magnetic field are initially spatially separated from one another. The inducing magnet is movable. At least one further magnet is arranged in a stationary manner in front of the induction coil or the induction coils. From this stationary magnet, a magnetic field with such an orientation of the Polarity creates that it represents an obstacle in front of the induction coil for the induction magnet, which it must overcome.

The magnetic field, which initially prevents the induction magnet from approaching the induction coil, is, according to the first embodiment of the invention, generated by a magnet, which is advantageous due to the effect of two magnets, which is stationary on the path of the induction magnet between its initial position and the Induction coil are arranged. The term "stationary" is not intended to rule out the fact that these magnets can be adjusted in a distance from the induction coil for optimal coordination of the acceleration of the induction magnet to the induction coil inducing magnet in its starting position in a direction away from the induction coil acts repulsive.

So that the inducing magnet can develop its intended effect, it must first overcome the repulsive force of the magnetic field of the stationary magnet or magnets. This position lies behind the so-called point of symmetry, usually behind the point at which the inducing magnet is arranged symmetrically to the stationary magnets and the similar poles of the inducing and the stationary magnets are exactly opposite one another. This creates an indifferent balance in relation to the forces of the magnetic fields for the movable, inducing magnet. Depending on the direction in which only a small force acts on the inducing magnet, this force is amplified many times over by the repulsive effect of the similar magnetic fields. If the inducing magnet is only pushed slightly beyond the point of symmetry by the means displacing it, the magnetic fields act repulsively on one another in such a way that the inducing magnet is accelerated in the direction of the induction coil. According to the present embodiment, the invention has the advantage that after overcoming the securing effect of the magnetic field of the stationary magnet, this magnetic field even supports the intended generation of an electrical energy pulse by accelerating the inducing magnet in the direction of the coil. The stronger the opposing magnetic fields are, the greater the repulsive forces and the greater the acceleration of the inducing magnet in the direction of the induction coil and thus the change in the magnetic flux in it over time.

An advantageous embodiment of the first embodiment of the generator according to the invention is constructed in such a way that the poles of the inducing magnet are arranged perpendicular to its direction of movement. The poles of the stationary magnets are also arranged perpendicular to the direction of movement of the inducing magnet. The poles of all magnets are in one plane. The facing poles of the stationary magnets have a different polarity. The poles of the stationary magnets that border the path of the inducing magnet have the same polarity as the poles of the inducing magnet that face them. This arrangement of the poles in relation to each other creates a strong repulsive effect on the inducing magnet.

However, according to a second embodiment of the invention, the magnetic field of the stationary magnet or magnets can also have an orientation of polarity such that it has an attractive effect on the inducing magnet in the starting position. For this purpose, the poles of the stationary magnet or magnets and the poles of the induction magnet, which lie in one plane, are aligned with one another in such a way that opposite poles are opposite one another. This means that the inducing magnet can be positioned in its starting position and is held there. To generate an electrical energy pulse, the attractive force of the stationary magnets must be overcome and the inducing magnet accelerated in the direction of the induction coil. The attraction is overcome with the means provided. The acceleration towards Induction coil advantageously takes place automatically after overcoming the attractive force if the induction coil has, for example, a core collecting the magnetic field lines, if possible a yoke with a gap which is closed by the inducing magnet. The magnetic field that builds up in the core accelerates the inducing magnet towards the induction coil.

The invention presents a generator for generating short-term electrical energy pulses, which according to the invention has a magnetic field that can perform a safety function that makes it difficult to trigger the generator unintentionally. If the inducing magnet is in its initial position, the magnetic field of the stationary magnet, because of its repulsive or attractive effect, prevents the inducing magnet from being able to move out of this position automatically.

The invention advantageously makes it possible to make the known impact detonators even safer. To trigger the ignition, the bolt which can be displaced by the action of force is generally connected to the inducing magnet. If the impact energy of a fired projectile is not sufficient to allow the induction magnet according to the first embodiment of the invention to overcome the repulsive force of the magnetic field of the stationary magnet in the direction of the induction coil, the impact bolt is also not pressed in. This is a sign that the generator has actually not been operated. In the case of a non-exploded projectile with the bolt pressed in, however, it can be assumed that the detonator was actuated but not triggered, so that this projectile represents a recognizable danger.

The other embodiment of the generator according to the invention, in which the inducing magnet is held by the magnetic field of the stationary magnet, also makes it more difficult to trigger an impact detonator. In this case, however, the distance that can be seen by the release bolt is less. The means with which the movable, inducing magnet can be brought out of its initial position in the direction of the coil can be matched to the magnetic field of the stationary magnet with regard to the force to be applied in such a way that manual triggering of the generator is possible and an electrical energy pulse nevertheless is generated, which is sufficiently high for the intended use, for example the ignition of a charge, the induction of a voltage for the operation of a timer or the control of a projectile.

According to an advantageous embodiment of the invention, a manually operated pushing device can be provided as the means for moving the inducing magnet out of its initial position. To overcome the initially repulsive or attractive force of the respective stationary magnet, the leverage of a manual trigger that acts on the pusher can be used. The generator of a weapon according to the invention can thus also be triggered by an operator without, for example, requiring an electrical energy source.

When the generator is actuated, the displacement of the inducing magnet from its starting position can advantageously be supported by a latent energy store. Such a latent energy store can be, for example, a prestressed spring which, viewed in the intended direction of movement of the inducing magnet, is arranged in front of the latter. The spring is kept tensioned and when a fuse is removed, the relaxing spring throws the inducing magnet beyond the point of symmetry of the repelling magnetic field into the area of the magnetic field in which it is accelerated towards the induction coil or releases it from the attraction of the stationary magnet. In both cases, the force of the tensioned spring must be higher than the repulsive or attractive force of the respective magnetic field of the stationary magnet, so that the securing effect of the magnetic field does not come into effect in this exemplary embodiment. As another latent energy accumulators can also be provided with propellant charges or gas generators, which, however, also require ignition before they take effect.

The intended use and the space available determine the shape and the equipment of the inductive part of the generator, which contains at least one induction coil. Three possible designs that advantageously have a simple construction are presented here.

The induction coil can be a cylindrical coil which has no core collecting the field lines of the magnetic field. It is a so-called air coil. In it, the inducing magnet can be moved in or through along its longitudinal axis. The magnetic field cuts the windings of the coil and induces a voltage in them. The level of this voltage depends on the speed at which the inducing magnet moves in the coil. The version presented here is simple in structure. If the inducing magnet remains mechanically connected to the means with which it can be brought out of its starting position towards the coil, it can also be pulled out of the coil again because the magnetic field is not amplified by a core. A bolt of appropriate length or, in the case of manual actuation, a pushing device is suitable as a means. The proposed design enables both a single use and a reuse if the generator is not arranged in a floor itself. In this version of the inductive part, an energy pulse is only generated when the inducing magnet is thrown into the coil either by the repulsive effect of the magnetic field of the stationary magnet or, if the version with the attracting magnetic field is selected, by means of a latent energy store.

According to a further embodiment of the inductive part, the

Induction coil be a rod core coil, the core of which collects the magnetic field lines. The coil encloses, for example, an iron core, which generally consists of layered, interconnected metal sheets. An iron core collects them magnetic field lines and thereby strengthens the magnetic field, so that the induced voltage is higher than in a solenoid without a core, a so-called air coil. As soon as the inducing magnet is positioned in front of an end face of the rod core, the intensity of the magnetic field in the coil changes and an electrical energy pulse is generated.

Another possible embodiment of the inductive part relates to an induction coil which is arranged on a core which has a gap which is closed by the inducing magnet. The core can have a U-shape, for example, and the magnet closes the gap between the two legs. Because the core is suddenly closed by a magnet, a magnetic field strengthened by the core with a high change in intensity and thus a high yield of electrical energy is created immediately. Another advantage of this arrangement is that a coil can be arranged on each of the U-legs. The two coils can be connected in series to add up the induced voltages.

Other designs are also possible in which the induction coil or the induction coils can be arranged on a simple or multi-membered, non-closed core, for example on an annular core or an E-shaped core, the inducing magnet in each case closing the gap.

The achievable level of the induced voltage is essentially influenced by the quality of the inducing magnet, ie by the strength of its magnetic field and by the material of the core which amplifies the magnetic field in the induction coil. Magnets made from metallic sintered materials, for example from NdFe (neodymium iron), and cores from laminated cores, the laminations consisting, for example, of an iron-cobalt alloy, are particularly suitable. The acceleration of the induction magnet in the direction of the induction coil is additionally advantageously supported in that the stationary magnet is arranged at such a distance from the core of the induction coil that the induction magnet is already in the gap on the way into the gap of the core occurs while it covers the stationary magnet or magnets at most up to half. A magnetic field is then already built up in the core, which attracts the inducing magnet. The attracting effect of the magnetic field building up in the core is added to the overcoming magnetic field with the repulsive effect on the induction magnet, as a result of which the acceleration effect on the induction magnet in the direction of the induction coil is increased. With the magnetic field with the attractive effect on the inducing magnet, the release from this magnetic field is supported.

In a further advantageous embodiment of the invention, a positive guide made of a non-magnetizable material is provided for the inducing magnet between its starting position and the induction coil. Such positive guidance can be, for example, a tube adapted to the dimensions of the inducing magnet. The positive guidance enables the induction magnet to be moved out of its initial position and from there on it can be safely forwarded to the induction coil. The positive guidance effectively prevents the inducing magnet from changing its position and orientation during its travel or from being deflected from its intended direction.

The higher the speed of the inducing magnet, the higher the change in magnetic flux density over time and thus the level of the induced voltage. For this reason, the induction magnet should be exposed to as little friction as possible on its way to the induction coil. It is therefore advantageous if the inducing magnet is covered with a material with a low coefficient of friction at least on the surfaces with which it rests on the positive guide. This material can be Teflon, for example. A sliding layer made of grease or oil serves the same purpose if it has no negative effects on materials or electronic components.

An advantageous low friction is also achieved if the positive guidance consists of a material with a low coefficient of friction or the inducing magnet is mounted on a slide made of a material with a low coefficient of friction. A combination of positive guidance, consisting of a material with a low coefficient of friction and an inducing magnet, which is covered at least on its sliding surfaces with a material with a low coefficient of friction or which is mounted on the slide, is particularly effective.

The invention is explained in more detail using exemplary embodiments.

Show it:

1 shows a generator, the induction coil of which is a cylindrical coil without a core, in longitudinal section,

1 a shows a cross section through the positive guidance of the generator at the level of the two stationary magnets,

2 shows a generator, the induction coils of which are rod core coils, in the end position in each case one pole of the inducing magnet being positioned in front of an end face of a rod core, in longitudinal section,

3 shows a generator with two series-connected coils on a U-shaped iron core, with the inducing magnet in the starting position and a manually operated pushing device, in longitudinal section, 4, the generator of FIG. 3, wherein the inducing magnet is in the point of symmetry of the repelling magnetic field,

Fig. 5 shows the generator of Fig. 3, wherein the inducing magnet is in the end position and

Fig. 6 shows a generator with an inductive part corresponding to the generator of Fig. 3, but in which the inducing magnet is held in its starting position by the attracting magnetic field of the stationary magnets.

A generator 100 according to the invention is shown schematically in section in FIG. The housing 2 also contains the positive guide 3 for the inducing magnet 4. In the present exemplary embodiment, the positive guide 3 has a rectangular cross section, as can be seen in FIG. 1 a, and is made up of the two side walls 5 and 6 and the base 7 and the cover 8 of the housing 2 is formed. In Figure 1, the cover 8 has been omitted to show the structure of the generator 100. The housing 2 is made of a non-magnetizable material with a low coefficient of friction. The side walls 5 and 6 have a greater wall thickness than the base 7 and the cover 8 because, on the one hand, they receive the two stationary magnets 9 and 10 in recesses 11 and 12 respectively provided for this purpose, which carry the induction coil 13, cut longitudinally here and serve as a fastening for the actuating device 14, which is provided as a means for moving the inducing magnet 4 out of its initial position 15. In the present exemplary embodiment, the induction coil 13 is a cylindrical coil without a core, a so-called air coil, and therefore has a cavity 31 around the center line 23.

The actuating device 14 consists of a rod 16 which is guided through the end wall 17 of the housing 2 and is connected to a carriage 18 on which the inducing magnet 4 is mounted. The carriage 18 is made of a material with a low coefficient of friction. It completely envelops the inducing magnet 4 and thus its sliding surfaces, the surfaces of the poles N and S, as can be seen from FIG. 1 a. 1 a shows a cross section through the positive guide 3 of the generator 100 at the level of the two stationary magnets 9 and 10. The slide 18 is located in the positive guide 3, easily displaceable. In the present exemplary embodiment, the actuating device 14 also includes two springs 19 and 20, which are pushed over the rod 16. The spring 19 is arranged between the end wall 17 of the housing 2 and the slide 18 and can be put under a predetermined tension by compression, while the rod 16 is held in the starting position shown by a device, not shown here. If this device releases the rod 16, it can be moved in the direction of arrow 21, the spring 19 being able to support this movement. The preload can be chosen so large that the force of the spring 19 is sufficient to accelerate the inducing magnet 4 beyond the point of symmetry 26 of the repelling magnetic field 24 of the stationary magnets 9 and 10 into the cavity 31 of the induction coil 13. The inductive magnet 4 dips along the common center line 23 from the positive guide 3 and the solenoid 13 into the cavity 31 of the solenoid 13 and, after generation of the energy pulse, reaches the end position 22 shown in broken lines, the movement of the carriage 18 being braked by the spring 20 and path 27 is limited by the length of stage 16. The voltage induced in the induction coil 13 is fed via the connections 32 of the induction coil to an amplifier circuit, not shown here, which belongs to the prior art.

In order to reach this end position 22, the inducing magnet 4 has to overcome the repelling magnetic field 24 of the stationary magnets 9 and 10 on its way 27 from the starting position 15 to the end position 22. The repelling magnetic field 24, the structure of which is represented by some field lines 25, is constructed as follows by the arrangement of the poles of the stationary magnets 9 and 10: In the present exemplary embodiment, the north pole N of the magnet 9 and the south pole S of the magnet 10 face the positive guide 3 and are oriented perpendicular to the direction of movement 21 of the inducing magnet 4. The poles can also have reversed polarity. The opposite poles N of the magnet 9 and S of the magnet 10 attract each other. Without the presence of the inducing magnet 4, the magnetic field 24 would be constructed symmetrically. The point of symmetry 26 lies in the middle of the opposing poles 9 and 10 on the center line 23 of the positive guide 3.

The magnetic field 28 of the inducing magnet 4 is also symmetrical, without the presence of the repelling magnetic field 24, as can be seen from the course of the field line 29 of the part of the magnetic field 28 which faces the end wall 17 of the housing. The inducing magnet 4 is arranged in the positive guide 3 such that a north pole N faces the north pole N of the stationary magnet 9 and its south pole S faces the south pole S of the stationary magnet 10. All magnets are in one plane. Where the inducing magnet 4 extends into the area of the stationary magnets 9 and 10, the magnetic fields 24 and 28 of the same type collide due to the polarity of the magnets which are assigned to one another. There is a strong repulsive force, as the bent field lines 25 and 29 are intended to illustrate. In the starting position 15, this force acts on the induction magnet 4 in the direction 30 away from the induction coil 13.

If the generator 100 is actuated by displacing the inducing magnet 4 by means of the rod 16 in the direction 21 onto the induction coil 13, the repulsive force of the magnetic field 24 of the stationary magnets 9 and 10 acts counter to the displacement direction 2 until the inducing one Magnet 4 is located at the point of symmetry 26 of the magnetic field 24. At this point, there is an indifferent equilibrium between the magnetic field 28 generated by the inducing magnet 4 and the magnetic field 24. A slight force acting on the inducing magnet 4 in the direction 21 towards the induction coil 13 brings it out of equilibrium and the magnetic field 24 acts the inducing magnet 4 in the direction repelling on the induction coil 13. The inducing magnet 4 is thrown into the cavity 31 of the coil 13 by the repulsive force of the magnetic field 24 along the path 27. The more intensive this process is, the higher the speed the field lines 29 of the magnetic field 28 of the inducing magnet 4 penetrate the windings of the coil 13 and the higher the induced voltage which is present at their connections 32.

FIG. 2 shows a generator 101 with a further exemplary embodiment for the inductive part. Features that correspond to the previous exemplary embodiment are identified by the same reference numerals.

The inductive part of the generator 101 differs from the inductive part of the generator 100 in that in the present exemplary embodiment two rod core coils 33 and 34 are provided as induction coils, each of which has a rod core 35 and 36 collecting the magnetic field lines, which in the present exemplary embodiment consists of layered sheets 37 exists. The induction coils 33 and 34 have a common axis 38 which is perpendicular to the center line 23 of the positive guide 3. The induction coils 33 and 34 are attached to the side walls 5 and 6 of the housing 2. The side walls 5 and 6 have openings 39 and 40, respectively, through which the rod cores 35 and 36 extend to the position which the inducing magnet 4 assumes in the illustrated end position after induction has taken place.

In FIG. 2, the inducing magnet 4 has left its starting position 41 shown in broken lines after being triggered by the actuating device 14. After he has overcome the magnetic field 24 generated by the stationary magnets 9 and 10 and has covered the path 27, he has applied to the end faces 45 and 46 of the two rod cores 35 and 36, respectively. He has induced a voltage in the two induction coils 33 and 34. The induced voltage can be connected via the respective connections 43 or 44 of the induction coils 33 or 34 either in parallel or in series with a device not shown here. but can be supplied by the prior art amplifier circuit. However, the induced voltages can also be used separately, for example to generate two separate signals.

A particularly preferred embodiment of the invention is shown in FIGS. 3 to 5. It is a generator 102 that can be triggered with the aid of a manually operated pushing device 47. The generator 102 differs from the generators 100 and 101 of the previous exemplary embodiments by the manually operable pushing device 47 and the inductive part. Features matching the previous exemplary embodiments are designated by the same reference numerals.

In the present exemplary embodiment, the inductive part of the generator 102 has a U-shaped yoke 48 made of layered sheets of an iron-cobalt alloy. The yoke 48 connects to the housing 2 with the stationary magnets 9 and 10 in such a way that its two legs 49 and 50 form the side walls of the positive guide 3. The positive guide 3 simultaneously encloses the gap 51 between the two legs 49 and 50, which is closed by the inducing magnet 4 during the generation of the energy pulse. An induction coil is pushed onto one leg of the yoke 48, the induction coil 53 onto the leg 49 and the induction coil 54 onto the leg 50. To increase the induced voltage, the two coils 53 and 54 are connected in series, which is why only two connections, 52 a and 52 b, are provided.

The pushing device 47 is composed of the actuating device 14 and the manual release 55. The illustrated manual release 55 shows only one of the possible designs. The housing 2 and the yoke 48 of the generator 102 are held on a carrier 56, to which a handle 57 connects. In this handle 57, a lever 59 is rotatably mounted in a recess 58. Its fulcrum 60 lies in the transition from the carrier 56 to the handle 57 Lever arm 61 carries at its end a half cylinder 62 which bears against another half cylinder 63 which is located on the end of the rod 16. When the pushing device 47 is actuated, the two cylinder surfaces roll on one another. The lever arm 61 is in its starting position on a bolt 64 as a stop. The other lever arm 65 is pulled to actuate the pushing device 47 by the fingers of the operator in the direction of the arrow 66, whereby the lever arm 61 moves in the direction of the arrow 67. As a result, the rod 16 is displaced in the direction of arrow 68. With a corresponding lever transmission, which is matched to the force which acts on the inducing magnet 4 through the magnetic field 24, the inducing magnet 4 is moved from its starting position 15, against the force of the magnetic field 24, in the direction of the induction coils 53 and 54 . When the lever arm 61 has been pivoted so far that the half cylinder 62 has reached the position 69 shown in broken lines, the inducing magnet 4 has already overcome the point of symmetry 26 of the magnetic field 24 on its path 27.

FIG. 4 shows the situation that the inducing magnet 4 is located in the point of symmetry 26 of the magnetic field 24. The structure of the magnetic fields 24 of the stationary magnets 9 and 10 and 28 of the inducing magnet 4 shows that there is an indifferent balance in the forces acting on the inducing magnet 4. Therefore, with further actuation of the lever arm 65 of the manual release 55, a small force is sufficient to move the rod 16 in the direction of arrow 68 and to push the inducing magnet 4 beyond the point of symmetry 26. Then the repulsive force of the magnetic field 24 acts on the inducing magnet 4, but now in the direction of the induction coils 53 and 54.

FIG. 5 shows the end position of the induction magnet 4 after closing the gap 51 between the two legs 49 and 50 of the U-shaped yoke 48 and generation of the electrical energy pulse. After the inducing magnet 4 was only slightly shifted from its position shown in FIG. 4 by the pushing device 47 in the direction of arrow 68, the repulsive force of the magnetic field 24 of the stationary magnets 9 and 10 and the attractive force acted on it Power of the magnetic field building up in yoke 48. An action on the induction magnet 4 by the operator was then no longer necessary, which is why the pivoting of the lever 59 was stopped shortly after the induction magnet 4 was moved beyond the point of symmetry 26 of the magnetic field 24. The spring 20 has braked the movement of the inducing magnet 4 before it reaches its end position. If the generator 102 is reused, the spring 20 avoids an unbraked impact of the induction magnet 4 on the induction coils 53 and 54 and thus damage to the coils and the magnet. It can be seen from FIG. 5 that the stationary magnets 9 and 10 are arranged at such a distance from the U-shaped yoke 48 of the induction coils 53 and 54 that the inducing magnet shown in position 4 'already enters the gap 51 , while it covers the stationary magnets 9 and 10 at most up to half.

A further exemplary embodiment for a generator 103 is shown in FIG. The inductive part, the arrangement of the induction coils 53 and 54 and the U-shaped yoke 48 correspond to the exemplary embodiment of the generator 102 according to FIGS. 3 to 5. More, with the

Features which correspond to previous exemplary embodiments are designated by the same reference numerals.

The generator 103 differs from the exemplary embodiments of the generators 100, 101 and 102 in that the inducing magnet 4 is arranged in its starting position 15 between the two stationary magnets 70 and 71. The poles of the stationary magnets 70 and 71 and the poles of the inducing magnet 4 are assigned to one another in such a way that the north and south poles face each other. The assignment of the magnetic poles is therefore exactly the opposite of that in the generators of the previous exemplary embodiments. The inducing one Magnet 4 is thus held in its starting position by the attractive force of the magnetic field 73 built up by the stationary magnets 70 and 71.

To trigger the generator 103, the inducing magnet 4 must first be released from the attractive force of the magnetic field 73 of these magnets 70 and 71 and then accelerated in the direction of the induction coils 53 and 54. For this purpose, the actuation device 14 is provided, which, as not shown here, can also be coupled to a manual actuation, as is shown in the exemplary embodiment of the generator 102, FIGS. 3 to 5.

If a force acts on the actuating device 14 in the direction of the arrow 72 that is large enough to overcome the acting attractive force of the stationary magnets 70 and 71 on the inducing magnet 4, the latter is pushed along the path 27 into the gap 51 of the U-shaped yoke 48 . The magnetic lines of the inducing magnet 4 are collected in the yoke 48 and the magnetic field is thereby strengthened. The inducing magnet 4 is attracted by the magnetic field that it builds up in the yoke 48 and accelerates into the gap 51 to close the core and thereby the magnetic circuit. During this process, the magnetic field in the induction coils 53 and 54 changes and a voltage is induced which can be tapped at the terminals 52 a and 52 b. Because the inducing magnet is only attracted and accelerated by the magnetic field it has built up, its speed with which it acts on the gap 51 of the yoke 48 is lower than when it is additionally accelerated by the repulsive action of the magnetic field of the stationary magnets .

Claims

claims

1. Generator for generating short-term electrical energy pulses, consisting of at least one induction coil and one assigned to it

Permanent magnets as induction magnets, the induction magnet and the induction coil being arranged to be movable relative to one another, so that when a partner moves, the magnetic field penetrates the induction coil to generate a voltage with changing intensity, characterized in that the induction magnet (4) is movable and the

Induction coil (13; 33, 34; 53, 54) are arranged stationary so that the inducing magnet (4) is in an initial position (15) spaced from the induction coil (13; 33, 34; 53, 54) before the electrical energy pulse is generated that in front of the induction coil (13; 33, 34, 53, 54) at least one magnet (9, 10; 70, 71) is arranged stationary, the one

Magnetic field (24; 73) with such an orientation of polarity (N, S) that it represents an obstacle in front of the induction coil (13; 33, 34; 53, 54) for the induction magnet (4) and that means ( 14; 47) are provided, with the aid of which this magnetic field (24; 73) can be overcome by the inducing magnet (4) in the direction of the induction coil (13; 33, 34; 53, 54).

2. Generator according to claim 1, characterized in that the stationary magnet (9, 10) between the starting position (15) of the inducing magnet (4) and the induction coil (13; 33, 34; 53, 54) is arranged that the Magnetic field (24) of the stationary magnet (9, 10) has such an orientation of the polarity (N, S) that it on the inducing magnet (4) in a pointing away from the induction coil (13; 33, 34; 53, 54) Repelling direction (30) and acceleratingly repulsive after overcoming its symmetry point (26) in the direction of the induction coil (13; 33, 34; 53, 54) and that the inducing magnet (4) with the aid of the means (14; 47) provided up over the Point of symmetry (26) of the magnetic field (24) in the direction (21; 68) on the induction coil (13; 33, 34; 53, 54) is displaceable.

3. Generator according to claim 2, characterized in that the poles (N, S) of the inducing magnet (4) are arranged perpendicular to its direction of movement (21; 68), that the poles (N, S) of the stationary magnet (s) ( 9, 10) on the path (27) of the induction magnet (4) are also oriented perpendicular to the direction of movement (21) of the induction magnet (4) and lie in the same plane as the poles (N, S) of the induction magnet (4) and that the poles adjacent to the path (27) of the inducing magnet (4)

(N, S) of the stationary magnet or magnets (9, 10) have the same polarity (N, S) as the poles (N, S) of the inducing magnet (4) facing them.

4. Generator according to claim 1, characterized in that the stationary magnet (70, 71) is arranged at the starting position (15) of the inducing magnet (4), that the magnetic field (73) of the stationary magnet (70, 71) is such Alignment of the polarity (N, S) has that it has an attractive effect on the inducing magnet (4) in its starting position (15), so that the inducing magnet (4) can be positioned in the starting position (15) and with the aid of the provided Means (14) of the inducing magnets (4) after overcoming the attractive force of this magnetic field (73) can be displaced in the direction (72) towards the induction coil (53, 54).

5. Generator according to claim 4, characterized in that the poles (N, S) of the inducing magnet (4) are arranged perpendicular to its direction of movement (72), that the poles (N, S) of the stationary magnet or magnets (70, 71 ) in the starting position (15) of the induction magnet (4) are also oriented perpendicular to the direction of movement (72) of the induction magnet (4) and lie in the same plane as the poles (N, S) of the induction magnet (4) and that to the starting position (15) of the inducing magnets (4) bordering poles (N, S) of the stationary magnet (s) (70, 71) have an opposite polarity (S, N) as the poles (N, S) facing them of the inducing magnet (4).

6. Generator according to one of claims 1 to 5, characterized in that the means (14) for displacing the inducing magnet (4) from its starting position (15) has a bolt or a rod (16) which or with the inducing Magnet (4) is connected.

7. Generator according to one of claims 1 to 5, characterized in that the means for displacing the inducing magnet (4) from its initial position (15) is a manually operated pushing device (47) which is in operative connection with the inducing magnet (4) .

8. Generator according to one of claims 1 to 7, characterized in that a latent energy store (19) with the means (14; 47) for displacing the inducing magnet (4) is in operative connection.

9. Generator according to one of claims 1 to 8, characterized in that the induction coil is a cylinder coil (13) designed as an air coil and that the inducing magnet (4) along the longitudinal axis (23) of the induction coil (13) into or through it this is movable through.

10. Generator according to one of claims 1 to 8, characterized in that the induction coil is a rod core coil (33, 34) and that a pole (N, S) of the inducing magnet (4) in front of one of the end faces (45, 46) of the Rod core (35, 36) can be positioned.

1 1. Generator according to one of claims 1 to 8, characterized in that the induction coil (53, 54) is arranged on a core (48) which has a gap (51) and that this gap (51) can be closed by the inducing magnet (4).

12. Generator according to claim 11, characterized in that the stationary magnet (9, 10; 70, 71) is arranged at such a distance from the core (48) of the induction coil (53, 54) that the inducing magnet (4 ' ) on the way (27) into the gap (51) of the core (48) already enters the gap (51) while it covers the stationary magnet (9, 10; 70, 71) at most up to half.

13. Generator according to one of claims 1 to 12, characterized in that for the inducing magnet (4) a positive control (3) between its starting position (15) and the induction coil (13; 33, 34; 53, 54) from a non-magnetizable Material is provided.

14. Generator according to claim 13, characterized in that the inducing magnet (4) on its sliding surfaces (N, S) is covered with a material with a low coefficient of friction.

15. Generator according to claim 13 or 14, characterized in that the positive guide (3) consists of a material with a low coefficient of friction.

16. Generator according to one of claims 13 to 15, characterized in that the inducing magnet (4) is mounted on a carriage (18) made of a material with a low coefficient of friction.