DE257284C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 257284 - CLASS 21 d. GROUP

ERNST FÄSZLER in FRANKFURTa. M.

Iron bodies is produced.

Patented in the German Empire on September 15, 1911.

The present invention relates to the operation of such striking tools in which the impact effect brought about by electromagnetic attraction of iron bodies will. Such a tool is shown schematically, for example, in FIG. It means ι the iron body of an electromagnet, 2 the magnetizing coil, 3 the swing armature. Due to the magnetic Attraction will pull the anchor 3 down and hit the head of the a hole in the core passed through tool 5 (chisel). After completing the Shock, the excitation current must be interrupted, whereupon the armature by the spring 4 is withdrawn again.

The periodic current interruption can be carried out in a known manner in the case of direct current operation by a self-breaker connected to the device, but this has unavoidable sparking has hitherto prevented the practical use of such hammers. For AC operation, a Self-breaker not applicable at all, as the switching on and off is irregular Way, once near the zero value and once near the maximum of the voltage curve would, so that the hammer would be impossible to work evenly.

The object of the present invention is the periodic activation and interruption the power supply through a breaker operating synchronously with the alternating current or by using a special type of alternator in such a way that that a cheap and regular working of the hammer and sparkless operation achieved will.

To understand the phenomena occurring here, it is necessary to go into the recently discovered knowledge of so-called switch-on phenomena with alternating current (see ZBLinke, Elektrotechnisches Archiv 1912, No. 1). In Fig. 2 the course of voltage E and current i of a purely inductive circuit is shown, which is permanently connected to an alternating current source. The curve i should at the same time also represent the course of the magnetic field, with the proportionality between current and field being assumed for the sake of simplicity. The time intervals mean ¹ thousand seconds, corresponding to a frequency of 50.

If you switch on a synchronous breaker in such a circuit, which always closes the circuit at point 5 and opens it again at point 15, you get magnetic impulses with an amplitude of 2.5 and a duration of ¹ Z ₁₀₀ seconds, with pauses of
alternate.

If, on the other hand, the circuit is closed at time 0, the current curve changes,

V ₁₀₀ seconds duration

as experience has shown, in the manner represented by curve * in Fig. 3; the maximum of current and field now has the amplitude 5, and the time datum of the magnetic impulse has ^{risen to 2} J ₁₀₀ seconds. So there is now a much larger amount of magnetic energy available. It will therefore be useful for hammer operation, if you want to achieve the maximum of the magnetic effect, to close the circuit always approximately at the moment in which the voltage has zero value, and only approximately after the expiry of two voltage waves, i.e. one full period to open again. The increased magnetic effect or increased current consumption that occurs when an inductive circuit is switched on at the moment of the zero value of the voltage wave is known per se and is referred to as "switch-on phenomenon". This phenomenon, which was previously only perceived as a disruption, is thus usefully utilized by the present invention. Of particular importance is the lengthening of the duration of the magnetic pulse, since the time of ¹ AoO second would not be sufficient to give a hammer of the required weight a considerable speed.

As can be seen, at time 20 (Fig. 3) both current and voltage have reached the value 0, so that the interruption can now take place completely free of sparks. It has to be show that spark-free power interruption is always possible if the time interval during which the circuit is closed with respect to a zero point of the E.M.K. curve is located approximately symmetrically, as it is so z. B. in Figs. 2 and 3 in relation is the case at time 10. It is then the magnetic field z. B. by the positive voltage wave (or by part of it) generated and by the corresponding Part of the negative voltage wave is "sucked off" again, so that the field and, accordingly, the excitation current are approximately zero at the moment of the interruption.

The curve i assumes a purely inductive circuit, but this is practically impossible because there is always a certain resistance. The actual current curve, taking into account the resistance, is shown by curve i ¹ ; In reality, the spark-free power interruption must take place at about point 18.

The curves (Fig. 2 and 3) initially relate to a circuit with invariable self-induction, such as a choke coil. If we now go over to the consideration of a hammer tool according to FIG. 1, we have to consider the variability of the self caused by the movement of the armature . consider induction. The resulting curve of current i and magnetic field B is shown in FIG. Curve e shows the back EMF generated in the coil. The sharp kink in curve i at time 10.5 is the moment when the armature strikes the chisel head. The current could be interrupted shortly afterwards, but this would create a spark. Therefore one has to wait until the current (and the magnetic field) has been "sucked" out of the apparatus by the negative voltage wave and then interrupt the circuit, i.e. at about 17.5. Exact adherence to this moment is, however, not of particular importance, since the current strength from about time 17 to 23 is so low that harmful spark formation cannot occur during the interruption. This long duration of the almost currentless time interval is a particular advantage of the method.

The operation of the apparatus cannot be done in such a way that the circuit is always closed at the beginning of the positive voltage wave and opened shortly before the end of the negative wave, but the armature must also be given time to return to the starting position, which As shown in Fig. ι, can be done under the influence of a spring or by any other means, such. B. a second electromagnet. In order to gain the time required for the armature to move back, the synchronous interrupter is arranged so that it does not close the circuit at the start of every positive voltage wave, but only at the start of every second or third etc. positive voltage wave. Would z. B. made contact at frequency 50 in each third period during _^18/1000 seconds so would ⁴² / _1O oo seconds are available for the return path, which is about the practical conditions. However, the circuit can also be closed alternately at the beginning of each positive wave and the next but one negative wave, so that ³ V ₁₀₀ O seconds remain for the return path. In the former case, the hammer ⁸ would% = i6 run ^{_2/3 of} beats per second, in the latter case ^5% ₅ = 20 beats per second. These are practically useful values, as they are also used in the known pneumatic hammers. The usual frequency 50 can therefore be used well for hammer operation by means of the present method.

Should a lower frequency, e.g. B. 25, are used for hammer operation, so it is for Achieving a sufficiently high number of strokes is more useful, not a full period for the Blow to use but only part.

The circuit is closed, ζ. Β. at time 5, the field then increases up to time io and then decreases again until it reaches the zero value again a little before time 15. At this moment, the current can be interrupted without sparking, since the current is - 0 when the voltage is still at its maximum value; however, the favorable switch-off moment must now be paused sharply, since otherwise a strong field from the opposite direction would quickly arise. With this operating mode and frequency 25, the current surge lasts again about ¹⁸ / xooo seconds. The circuit can then be kept open for a little longer than one period, i.e. about ⁴ V ₁₀₀₀ seconds, so that the same time is available for the return journey as with frequency 50 and the full period is used for the stroke.

The same operating mode can also be used with advantage at frequency 50, if very light hammers are to be operated with which only a low power per stroke, but a very high number of strokes is required.

Any construction with oscillating or rotating contacts can be used for the synchronous interrupter; it is only necessary that the moments of the current short-circuit and the interruption are precisely adjustable. A rotating interrupter 6 is shown schematically in FIG. 1, for example; it can be driven either by a synchronous motor or by the alternating current generator itself. If the interrupter disk is coupled directly to it, the number of poles must be selected accordingly; should z. B. the circuit must always be closed during one period and open during two periods, the number of poles must be 6. and the contact disc must ^{make contact during 1} J _{3 of} the revolution. If the number of poles differs, the contact disc must be driven by toothed wheels or a toothed chain. This arrangement is shown schematically in FIG. 1; it means 6 the rotating breaker and 7 the alternator.

If the circuit is always closed at the beginning of a positive (or negative) voltage wave, the operation of the apparatus is carried out by current surges in the same direction. You can then toggle it on and off also use a rectifier, e.g. B. an electrolytic valve cell or a mercury vapor rectifier, naturally any spark formation is absolutely avoided. But since the valve cell controls the circuit every positive voltage wave would close while only every second or third used is to be used, a mechanical breaker must also be used, which then only disconnects the circuit when it is de-energized Need to open state, so that sparking is excluded. .

It has been shown that the opening of the Sirom circle at i - 0 (at point 17.5 in FIG. 4) is not always useful, since remanent magnetism is still present in the hammer magnet, which may hold the armature in place. For this reason it is advisable not to interrupt at point 17.5, but a little later, so that a negative current pulse reaches the magnet, which cancels the remanence. As can be seen, the interruption will then expediently be relocated to point 22.5, where again i - 0 . However, you can also interrupt at point 17.5 (which occurs automatically, for example, in the case of an electrolytic rectifier) and permanently bridge the interrupter by means of a relatively high resistance, which allows the low current required to cancel the remanence to pass.

It is also possible to operate the hammer in the manner described, without using any interruption device. You need an alternator for this special type, which generates the shape of the voltage curve shown in FIG. There is nothing from the foregoing further understandable that when connecting an electromagnetic hammer to such Alternating current generator in the hammer coil in regular succession, strong current pulses (for the working stroke), weak current impulses in the opposite direction (to cancel the remanence) and currentless pauses (for the return path of the hammer) arise. The relative The duration of the current impulses and the pauses can be chosen arbitrarily by a suitable construction of the alternating current generator will.

Claims (6)

Patent-to sayings: i. Procedure for operating electromagnetic impact tools using alternating current sources, in which the impact effect is produced by electromagnetic attraction of iron bodies and where the power supply to the excitation coil of the tool through one with the alternating current synchronously operating breaker or by using an alternating current with a special curve shape, characterized in that the excitation coil is approximately symmetrical about a zero point of the E.M.K. curve lying time interval is fed with current, the magnetic field within this time interval arises and again completely or almost disappears and the Power is then interrupted or weakened to return the armature to allow in the starting position. 2. The method according to claim i, characterized in that the activation of the Current approximately with the beginning of the positive (or negative) voltage wave and the interruption approximately after expiry the subsequent negative (or positive) voltage wave takes place. 3. The method according to claim 1, characterized in that the excitation coil only Current pulses are fed in one direction, with an AC rectifier as an interrupter of any kind is used. 4. The method according to claim 3, characterized by the series connection a mechanical breaker with an electrolytic or mercury vapor rectifier, the mechanical breaker opens and closes the circuit at the moment when the current is flowing already interrupted by the electrolytic or mercury vapor rectifier is. 5. The method according to claim 1 to 4, characterized in that the interrupter is bridged by a resistor that allows enough current to pass after the interruption cancel the remanent magnetism of the hammer magnet. 6. The method according to claim 1, characterized by the use of a Alternating current, whose voltage curve is made up of individual groups of one positive each and a negative wave exists, whereby between the individual groups accordingly long intervals lie in which the voltage is completely or almost equal to zero. For this purpose ι sheet of drawings.