DE509954C - Process for generating strong electrical surges - Google Patents

Description

The invention relates to the generation of occasionally or periodically required strong Power surges for only short periods of time, e.g. B. for signaling purposes or for generation short-term, very strong magnetic fields. The invention relies on the connection an alternator with a switch in a special manner, described in more detail below.

When an alternator hits a small impedance on the order of the Producer itself is shorted, so it is known that for the first few Waves a very strong current, the surge short-circuit current, flows through the circuit. For the The relationship between surge short-circuit and continuous short-circuit currents is roughly equivalent to the following equation:

Impulse short-circuit current armature self-induction + armature feedback

Permanent short-circuit current

The effect decreases during the period that the armature short-circuit current generated power flow needs to the effective flux of lines of force from the field windings to diminish; the decay of the excitation field takes a certain time due to the appearance of an additional induced Current in the excitation circuit and as a result of induced currents in the iron core.

If the anchor reaction is large compared to the anchor self-induction, This allows the energy given off to the short circuit at the moment of the short circuit will be very large and exceed the normal output of the power generator by 50 to 100 times.

The invention consists in that the generated in such a way by the generator Energy only for the duration of a maximum of one full period by one automatically working and synchronously operated switch is used, which is arbitrarily in

Anchor self-induction

Gear can be set and then automatically closes the circuit, namely expedient only during the first half-wave of the current. The achievable in this way strong energy is not drawn directly from the generator's prime mover, but rather from the kinetic energy supplied in the rotating parts, possibly also in an additional Flywheel, is accumulated.

The invention is illustrated in more detail in the drawings, namely show

Fig. Ι and 2 curves of current, power flow and electromotive force,

Fig. 3 and 4 sections through an alternator,

Fig. 5 to 7 representations of a gearbox and

Fig. 8 another version of a switch.

In Fig. Ι the curve E represents the electromotive force in the development

* -TE-

of the power generator is induced. At time B, when the electromotive force is zero, a maximum power flow Φ goes through the generator winding, and preferably at this point the machine is short-circuited by an automatic switch via the working circuit, so that the current / arises. The switch keeps the circuit closed until the point (Fig. I) where the current has dropped to zero. Since both the machine and the external load circuit have inductance, this point is shifted by the distance C, A from point C, the point of passage of the electromotive force curve E through the abscissa axis. The interruption of the current at point A is easy to carry out because the current at this point is practically zero, a fact that makes this method of obtaining electrical impulses superior to those in which a DC machine is used, because the task of interrupting a strong one Stromes is always difficult to solve. From the general theory of short-circuiting alternators, it is known that the current amplitude is greatest when the circuit is short-circuited at the moment the electromotive force is zero, and consequently less when the short-circuit occurs at any other point in time. For this reason, the current is switched on at point B in Fig. Ι. The shape of the current curve that is achieved in these half-waves depends on the shape of the magnetic field wave that is generated by the excitation winding in the alternator. Due to the special arrangement of the windings, as shown in Figs. 3 and 4 and indicated with the reference character P , it is possible, for example, to obtain the two different field configurations, as shown by the curve Φ in Figs. 1 and 2. The excitation field according to Fig. 4 generates an electromotive force E, which results in a current with a flattened waveform, as shown at / in Fig. 2. A power generator with either a rotating field or a rotating armature can be used to carry out the method, preferably a high-speed device and of such an arrangement that the power generator impedance is made as small as possible. The maximum output of the machine is approximate

'" Max -

Φ ² ω ²

where χ is the impedance, w is the angular velocity and Φ is the total flow of force through the winding. It is also desirable, for high power, that the flux of force be as strong as possible, and unless a particular surge waveform is required, the most efficient winding is that shown in FIG. In order to reduce the impedance of the generator and to increase the power flow through the winding, it is advisable to design the generator with the smallest possible air gap, to shield the exciter winding with a damper cage D (Fig. 3 and 4) and to arrange the armature winding so that it has as little spread as possible. This can be done by sheathing the winding, in particular the end connections, with copper, for example by enclosing it in a copper jacket. By means of such arrangements it has proven possible to achieve current surges from a power generator with a continuous output of 1500 kilowatts, which correspond to an energy of 200,000 kilowatts. The power generator must naturally be designed to be particularly resistant, because large dynamic forces occur during the short circuit. The switch that is necessary for the surge short circuit can be designed in various ways. Two preferred forms are shown here, both of which are operated directly from the power generator shaft.

The switch according to Fig. S to 7 has a disk α made of insulating material, such as. B. VuI-kanfiber or hard rubber, with a conductive segment b on the circumference. This pulley is driven by the generator shaft either directly or by any mechanical means such as wheels or chains. A brush c rubs on the disk α and is adjusted so that the electromotive force is zero at the moment when the conductive segment b comes under the brush, so that the circuit is closed at the right moment. A second grinding brush g is arranged in such a way that it leaves the segment at the moment when the current drops to zero. Thus, the segment only closes the circle for the time interval that corresponds to the distance BA in Figs. 1 and 2. The contact brush g is pivotally arranged and remains on the disk and the segment f only for a dealing of the shaft by a cam and e _1Χ5 the linkage, e pressed '. The cam e is designed as a half nut which is carried along in the axial direction by a screw thread k on the shaft. The rod f, which carries a roller m , is pressed down to a limited extent _{by iao a spring.} It affects the vibrating

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arm e ', which presses the brush g against the disk a against the action of a spring η. If you want to achieve the current surge, the half nut is placed by hand on the shaft to the left of the middle position shown in Fig. 5. It is then pushed to the right by hand until it is caught by the thread. This leads it automatically through the middle position, during which it lifts the roller m and thus makes the necessary contact. A guide piece e ² sliding in a slot in the machine frame prevents the half nut from rotating. In order to generate a second current surge, the half nut is removed, placed again on the shaft to the left of the middle position in Fig. 5 and brought into engagement with the screw thread.

In another embodiment, the short circuit switch is operated by a camshaft and a lever system as shown in FIG. A cam 1 with running surfaces of three different diameters is rotated by the shaft of the power generator either directly or via chain wheels or other gears. The cam pushes a rod 3 by means of a lever 2 when it hits the running surface 1 ″, which is pressed against the cam by a strong spring 4. The bumper acts via an intermediate rod 5 on the articulation point of the two vertical toggle links 6, 7 and presses the link 6 and thus the vertical switching rod 8, which carries a copper plate or bridge 9 isolated at the lower end, onto the two brush contacts 10 in the main circuit of the Generator down. When the lever 2 runs onto the running surface i ^b , the plate is pulled upwards by springs 12, which consequently force the toggle lever to the other side of its dead center position. The rod 5 articulated at the knee point of the toggle lever is articulated to an arm 15 which is carried by the armature of an electromagnet 14, whereby the rod 5 can be brought into or out of register with the end of the bumper 3. A trigger or trigger 11 equipped with a starting magnet or solenoid 13 is able to keep the lever 2 locked in its extreme position. The switch just described works as follows:

Assume that the cam 1 rotates freely, the lever 2 is kept away from the cam by the trigger 11 and the end of the impact link 5 lies below the end of the bumper, as shown in dotted lines. The knee joint members 6 and 7 are then brought to the right-hand side of their dead center position, and the bridging plate 9 is lifted off the brushes 10 by the springs 12. To achieve a current surge, the magnet 13 is now excited first, for. B. by actuating a push button switch, so that the trigger 11 releases the cam lever 2, which now grinds on the cam, whereby the rod 3 is moved back and forth. Then also the electromagnet 14 is excited, which now by means of the member 15 lifts the connecting piece in the axial direction of the bumper at the moment when the lever 2 is on the cam part with the smallest radius. Before this movement of the rod 5, the reciprocating bumper cannot reach the parts 6 and 7. By lifting the piece 5, however, the push rods 3 and 5 are coupled and when the cam continues to move, when the lever 2 reaches the central cam part i ^a , the handlebars 6 and 7 are stretched and the short-circuit switch is closed. The cam is set with respect to the generator so that closure occurs the moment the generator voltage passes through zero. The contact now continues until the second cam rise i * reaches lever 2 and causes the toggle links to move over to the other dead center side, i.e. to the left, whereby the switch opens again, namely at the moment when the current is essentially again has reached the value zero. Now the electromagnet 13 is de-energized and the lever 2 is again blocked by the trigger 11. To bring the switch back in readiness to achieve a second current surge, the toggle links must be turned to the right. In order to be able to do this without closing the circuit, the auxiliary switch 14 provided is opened beforehand.

With the above-described second embodiment, the moments of contact and interruption controlled by the pressure from the cam, and a movement of the in the same direction Bumper causes closure like opening, no The lever is only in contact with the cam during handling. By application of a switch of the type shown is the speed at which the air gap grows between the contact points, twice as large as in the case of a single contact. The cam elevation must be carefully measured, and indeed the elevation for the contact can be made from the outset be finally determined, while the interrupt increase is made expediently adjustable, since the moment

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the interruption depends on the impedance of the load.

Because the moment of the interruption cannot be determined exactly beforehand can and even with careful adjustment always a small current at the moment of There will be an interruption, so the arcing will expediently through a capacitor is reduced, which is arranged in parallel ίο to the point of interruption or by a blowing device in the interruption gap or by a combination of both means. Obviously prompted in In both cases, the switch has only a single contact closure and a single interruption and then requires reinstatement. In general, this cannot rather than being made up of the transient conditions that result in the short circuit follow, are eliminated again. However, automatic 'from a control process' Dependent facilities may be provided, which switch the switch automatically after each Prepare or set the interruption again. This can, if desired an uninterrupted series of current surges can be achieved, with the pauses between the power surges must be large enough to cope with the transient short circuit conditions can subside.

It should be noted that it is not absolutely necessary that the switch be in the Zero point of the voltage wave is closed, since current surges can also be achieved, when the switch is closed at another point on the shaft, albeit with a correspondingly lower strength. What is desirable, however, is that the switch is then opened when the current goes through zero, otherwise strong arcing and damage occurs.

Claims (9)

Patent claims: i. A method for generating occasionally or periodically required short-term strong electrical current surges, e.g. for signaling purposes, characterized in that an alternating current generator is short-circuited for a period of time by means of a switching device that can be switched on at will and then inevitably working via a working circuit of low impedance, preferably of approximately the impedance of the current generator , which comprises at most a whole period of the alternating voltage and is preferably between half a period and a whole period.
2. The method according to claim 1, characterized by switching on at the moment when the alternating voltage is essentially still zero, and switching off at the moment when the current after a single half-wave has again reached the zero value as possible. 3. Switching device for performing the method according to claim 1 and 2, characterized in that between a switch located in the short-circuit circuit 7 »ter (b, e, g), a switch linkage (f, e ', Wi) and one with the generator shaft synchronously operated driver, which interacts with the switch linkage in certain time segments of the period of the alternating voltage, a control element can be switched on at will, which couples the driver and switch. 4. Apparatus according to claim 3, characterized in that the clutch mediating, arbitrarily switchable control element with continuation of his Movement automatically decoupled by the driver. 5. Apparatus according to claim 3, characterized in that the shift linkage is designed so that when it continues its movement under the action of the control member, the switch opens automatically. 6. Switching device according to claim 3 and 4, characterized by a synchronously operated with the power generator shaft disc (a) with a contact segment (b) and a pair of cooperating brushes (c, g) over which the short circuit runs and one (g) of the disc can be lifted off by a gear mechanism (m, f, e ') by means of a cam gear, which consists of a thread (k) running around the disc and a cam part (e) in the form of a half nut. 7. Apparatus according to claim 3 and 5, characterized by a spring action brought into the open position toggle linkage (6, 7), which from the an opening kink position in the opposite, via the one causing the closure Extended position is moved by means of a synchronously operated cam (1) which Via a feeler lever (2) and one that is pressed off the toggle lever by spring force Bumper (3) and one arbitrarily switched on between this rod and the knee lever Swivel member (5) moves the toggle lever. 8. Switching device according to the preceding claims, characterized in that that the re-setting of the switching device and the triggering of the switching process automatically in particular happens according to the electrical conditions of the circuits. 9. Power generator for "exercising the method according to claim 1, characterized in that that the impedance of the machine by artificial means, such as by damper windings or sheathing of the conductors lying outside the effective iron with a copper jacket is reduced. 1 sheet of drawings