DE503524C - Method for generating mechanical vibrations of a body by means of an electromagnet excited by an alternating current source via a current-controlling valve - Google Patents

Description

Method for generating mechanical vibrations of a body energized by means of an alternating current source via a current-controlling valve Electromagnets The invention relates to a method and apparatus for generating a reciprocating vibratory movement by means of one of a Alternating current duels via a current-controlling valve energized electromagnet.

There are already devices known in which current pulses of Alternating currents are used to convert an armature into one excited by the current pulse The coil is pulled in by the magnetic attraction force during the return movement of the anchor takes place under the tensile force of a spring.

The vibratory movements generated by the known devices differ from the frequency of the alternating current used because the electricity only for. while generating movement in your one sense serves the movement in your opposite sense brought about by mechanical means will. As a result, the frequency of such systems is a function of both the number of periods of the stroke as well as the natural frequency of the for the return movement of the anchor used mechanical device, whereby on the one hand the mechanical Force effect, for which the oscillatory movement is used, reduced and on the other hand, the power consumption is increased. It is extremely difficult to do this Eliminate inconveniences by creating a resonance between the two vibrations.

The method according to the invention used for the forward and Backward movement of a core or an anchor only has the attractive effect the current pulses of the alternating current used, through which a movement of the Armature is brought about within a coil in one direction or the other. This is done in such a way that the body or core during the same current direction consecutive full periods of alternating current in alternating directions from the power flow of an excitation coil in the rhythm of the number of periods of the alternating current is drawn into the coil and, as a result of the energy given to it, its movement continues to the respective end position. In doing so, the training of the negative Wave part of the Stroines, however, through the rectifier switched into the circuit prevented. When the anchor has reached its end position, the next positive wave part of the current effective, through which the armature in turn after the center of the coil, i.e. in the opposite direction, is attracted, whereupon the previously described work cycle is repeated. The guide channel for the anchor is designed so that the air gap between the core and the iron body of the The excitation coil is smaller in the middle position of the core than in the two end positions of the core.

According to the new method, each full period corresponds to the one used Alternating current a longitudinal movement of the core, so that during a period a forward gear, reverse gear during the next period and again in the following period the core moves forward. To achieve perfect synchronicity between to bring about the mechanical movement of the core and the number of periods of the alternating current, the core and the length of its movement is dimensioned so that the magnetic attraction force can produce the required acceleration that drives the core within the The expiry of a period allows a longitudinal movement to be completed.

It can therefore be seen that only one only solenoid is required.

The use of an electrical rectifier or electrical Valve in the circuit of the solenoid offers the advantage of the new method, that the duration of the positive current phase compared to the positive voltage phase can be extended significantly because the inductance of the circuit has a Distortion of the current phase with respect to time is brought about. According to the invention the course of the current phase for the intended Purpose are favorably influenced.

In the accompanying drawings there are several embodiments of FIG Devices illustrated which are used to carry out the new method.

Fig. I shows schematically an electric impact tool, partially cut, with the associated operating and control circuits.

Fig.2 is a longitudinal section on a larger scale.

FIG. 3 is a cross-section along line III-III of FIG. 2.

Fig. D. represents one of the radial dividing disks of the electromagnet in side view. Fig. 5 is a bottom view of Fig. q .. Fig.6 shows schematically an embodiment that differs from Fig. i.

Fig. 7 a further schematically illustrated embodiment. FIG. 8 illustrates the waveform of the work coil 25a of FIGS. 6 and 7 feeding current.

The method according to the invention is shown in Figs. I, 2 and 6 on the Exemplary embodiment of a striking tool illustrated as a whole in is denoted by i in the figures. A handle is located in a housing, into which the sleeve 3 made of non-magnetic material is screwed, around the longitudinally displaceable core q. made of magnetic material. At the end of the sleeve located on the handle is a resilient stop 5, which only serves to reduce the impact of the core q. catch at the end of its stroke or to attenuate.

Around the guide sleeve 3 are a number of radial core lamellas 6 arranged, each of which consists of two L-shaped angle pieces 7 and 8, the outer ends of which are connected to one another by a rod 9. The leg ok of each elbow 7 leans against the front of the handle 2 while the leg i i of each elbow 7 touches the guide sleeve 3. The thigh 12 of each elbow 8 leans against the face plate 13, which is parallel to the Outer web of the handle 2 runs, and the leg 14. of each elbow 8 rests against the guide sleeve 3, directly opposite the leg i i, but maintaining a distance so that within the magnetic The course of the force lines coaxially with the guide sleeve 3 is left a gap. The opposite ends of the legs i i and 14 converge against the guide sleeve 3 and each engage a pin 15 in. a hole 24 of the guide sleeve 3 a.

The end plate 1,3 merges into the central hollow cylinder 16, the is coaxial with the guide sleeve 3 and contains the sleeve 17 in which -the firing pin 18 of tool i9 goes back and forth. The latter can be a chisel, a riveting hammer or the like. The inner end of the firing pin 18 lies in the track of the magnetic core when it runs off the stop 5. A jacket 43 encloses the inner body of the tool i <The handle 2 has a trigger 2o, by means of the connector 21 the contact between the poles 22 and 23 within of the handle 2 manufactures.

25 is the working coil of the electromagnet. It's around the thigh i i and 14 of the elbows 7 and 8 and is wound by the legs io and 12 flanked while a beveled portion between the ends of the legs i and i 14. protrudes. the Bars 9 are across the outer surface of the coil placed and attached by rivets or pins to the outer ends of the legs io and 12. In this way, the coil with its inner annular rib is at certain intervals carried by the C-shaped core lamellae 6.

26 denotes a rectifier, one electrode of which consists of the anode 27, while the other electrode is the coil or cathode 28. The latter is fed with electricity via the transformer 29 from the power supply lines 30 and 30 '. The anode 27 is connected by the wire 31 to the movable switching element 32, which responds to the electromagnet 33, which in turn is connected to the cathode by means of the wire 34 and is located between the power supply line 3o and the contact pole 22. The cathode 28 is connected to the node 35. One end of the wire of the coil 25 is fastened by the wire strand 36 to the fixed Kontaktpo137 opposite the switch member 32, while the other end of the wire of the coil 25 is connected by the wire 38 to the power supply line 30 '. The contact pole 23 is connected to the wire 38 at the node 39 .

As soon as the trigger is moved 2o, over down to the contact bridge 21 from the pole 22 to the pole 23, current flows from a current supply line 3o by -the wire 3d, the coil: by the magnet 33, the contact pieces 22, 21 and 23, further. the wire 38 to the power supply line 3o '. This current causes the switch 32 to close so that the coil 25 is connected in series with the supply lines and the anode and cathode of the converter 26. The cathode is heated by electricity from the LTmforiner.

When the anode and cathode of the rectifier are connected to the coil 25 in Connected in series, current surges can only pass through in a certain direction the lines 30 and 30 'reach the coil 25, while the intermediate in the opposite direction effective half-waves of the current through the device 26 are intercepted.

After the apparatus has been connected to the AC power source is, the rectifier 26 only the positive current phase through the solenoid 25 let through, which accordingly in each period of the alternating current through a positive current is excited. If the core .I is located in its left end position, the moment in which the coil is excited the core is pulled to the right in the middle of the sleeve 3, so the pin 15 of the Iron body of the coil through the core d. completely closed by iron and the resistance of the magnetic flux reaches its lowest value. Around this moment the end of the positive current phase is reached, the current decreases at the same time as the magnetic force of attraction to the zero value. The core will therefore move on due to its kinetic energy and at the end of its after right stroke on the buffer 5 come to rest.

The resistance of the coil, the current excitation, the magnetic attraction force, the mass of the nucleus q. and the length of its stroke are matched to each other so that the movement of the core just takes the duration of a full period of the alternating current takes. While through the rectifier the negative current phase of the alternating current has been extinguished, the core d. his rightward movement completed. A new period of the alternating current then begins. The rectifier sends again the positive phase of the current in the magnetic coil, whereupon its magnetic Tightening the core, I now pulls to the left, since it is reducing the magnetic resistance, namely a shortening of the air gap between acts towards the two ends 15, 15 'of the iron body.

Is the core d. about in the middle of the sleeve 3, so is the lowest value of the magnetic resistance reached. At the same moment it sinks positive current pulse to the zero value and the magnetic attraction force disappears, while the core, as a result of its kinetic energy, again passes through the middle layer shoots out and at the end of its leftward stroke against the firing pin 18 of tool i9 beats. In the time in which the core completes its left stroke has, is also the negative current phase canceled by the rectifier and thus the second period of the alternating current has expired. The third period begins and renews the game according to the second period. As long as the AC power source remains connected, the game is repeated in such a way that always within a Period of the alternating current is a longitudinal movement of the nucleus to the left or to the right takes place, depending on the end position in which the core is currently located.

The core becomes, as can be seen from the above description, accordingly only by: magnetic tensile forces moved both forwards and backwards, whereby any other mechanical devices not used for movement will. Of the The resilient buffer only serves to reduce the impact of the Core at the end of its stroke. As a result, the core will vibrate longitudinally offset, which of the number of periods, or for a full left and right oscillation correspond to half the number of periods of the alternating current used.

To follow the curve of the magnetic current phase one for the operation of the Giving the device a favorable shape can influence the positive current phase can be achieved in the following manner. It will be possible to use the positive current phase to lengthen their duration by a considerable amount compared to the tension phase, so that the magnetic pulling force can be better utilized.

In FIG. 6, 26d designates a hot cathode rectifier, one electrode of which consists of the tubular anode 2711 bent lengthways. The second electrode is the hot wire or cathode 28a. The rectifier also has a control device d.2, which is designed as a coil which surrounds the solenoid valve body 26a and, with the coil 4, lies within a common closed circuit. The anode 27a is connected by means of the wire 3 1 to the movable switch member 32, which responds to the electromagnet 33, the coil of which is in series with the wire 34 which leads from the power supply line 30 to the contact pole 22 in the handle 2 of the tool i . The cathode 28a is connected to the wire 34 at the node 35. One end of the wire of the coil 2511 is connected by the wire 36 to the fixed contact po137 belonging to the movable switch member 32. The other wire end of the coil 25a is connected by the wire 38 to the power supply line 30 '. The contact pole 23 is connected to the wire strand 38 at the node 39.

As soon as the trigger lever 12o is actuated and the contact bridge 21 connects the poles 2-2 and 23, current flows from the one power supply line 3o through the wire 3.4, then through the coil of the magnet 33, through the contact parts 22, 21 and 23 and the wire 38 to the other power supply line 30 '. This current causes the switch 32 to close, so that the coil 25a is connected in series with the power supply lines 30 and 30 'as well as with the anode 27a and the cathode 28a of the hot cathode rectifier 26a. The hot cathode of the rectifier is heated by the current supplied by the transformer 29.

When the core d, moves toward the center of the coil in either direction, the current in the coil 25d increases at the same time. This results in an induction current in coil 41, which closes via coil 42 and in turn influences the current in rectifier 2611. The coil 42 also causes a sudden increase in the current in the coil 25a both at the beginning of the current phase moving the core and at the end of it. This is illustrated by the current curve in FIG. The current increases very quickly, almost suddenly, at the points it of the waves ir, v, and w , and also suddenly decreases near the ends at the points o. This diagram line of the current is valuable insofar as it enables automatic control of the core if it accelerates or slows down its speed compared to the number of periods of the supplied alternating current. If the core lags, the points n and o slide down from the wave crests of the diagram to the zero line. This increases the length of the pull-in periods of the core at both ends of the positive half-wave. If, on the other hand, the core exceeds its normal speed, points ya and o will rise at the wave crests and shorten the time of action of the coil 25a on the core.

In Fig. 7, the coils 33a and q2a set the switch 37a and the movable switch member 32a schematically represents a mechanical rectifier, the instead of the electrical rectifier 26a and the switching elements 32, 33 and 37 of Fig. 6 can be used. As with the known mechanical rectifiers Switching element 32a controlled so that it closes at the beginning of a half-wave of the current, opens at the end and remains open until the end of the next half-wave, whereupon the game repeats itself as long as the switch contacts 2i, 22 and 23 (Fig. 6) are closed being held. The current wave generated by the coil d.2a neutralizes the current generated by the coil 33a and thereby controls the switch 32a synchronously with the number of periods of the supplied alternating current. The action of the coil 42a on Switch 32a is the same as that of coil .I2 of the electric rectifier 26a. The curve according to Fig. 8 also applies to the device according to Fig.; ztt.

Claims (4)

PATENT CLAIMS: i. Method for generating mechanical vibrations of a body by means of an electromagnet excited by an alternating current source via a current-controlling valve, characterized in that the body or core during the positive waves of successive full periods of alternating current in alternating direction in .den power flow of an excitation coil in the rhythm of the number of periods of the alternating current is drawn and, as a result of the energy given to it, continues its movement into the respective end position during the intervening negative current waves suppressed in a known manner by the valve. 2. Device for performing the method according to claim i, characterized in that the air gap between the core and the iron body the excitation coil is smaller in the middle position of the core than in the two End positions. 3. Device according to claim 2, characterized in that for the Movement of the nucleus in one direction as well as in the opposite direction is only one Solenoid is used. q. Device according to claims 2 and 3, characterized .by one Auxiliary circuit through which the duration of the excitation of the coil is regulated automatically will. 5. Device according to claim: 2 to d., Characterized by one in the magnetic Force field of the excitation coil (25a. Fig.6) lying coil (.4; i) and through a das Valve influencing coil (d.2), through which the auxiliary circuit is influenced. 6. Impact tool for performing the method according to claim i, characterized in that that by a magnetic coil (25) in an iron body (6, 9, f o, i i, 12, 1.1.), which has iron-free gaps for the purpose of forming poles, a magnetic one Field is generated in which a. Iron core (.4) moves in its central position the pole (15) spanned. ;. Striking tool according to claim 6, characterized in that that the coil (25) is surrounded by radially arranged legs of the iron body. B. impact tool according to claim 6 and 7, characterized by a known per se resilient stop (5) at the inner end of the path of the impact core for braking the shock movement given to it. 9. Striking tool according to claim 6 to 8, characterized by guiding the iron core (d.) in guide sleeves (3) made of suitable, not magnetic material, which recesses for the passage of poles (15) of the Own iron body. ok Striking tool according to Claims 6 to 9, characterized by a tubular extension (16) and a guide sleeve located in the same (17) for the front section (18) of the firing pin carrying the tool (i9). i i. Striking tool according to Claims 6 to 10, characterized in that the front tubular extension (16) by means of an end plate (13) with an iron body the jacket surrounding the coil (d.3) is connected, with which on the opposite The end of a body carrying the guide sleeve (3) and the resilient stop (5) is connected is, which is designed as a handle (2) at the rear end. 12. Impact tool according to claim i i, characterized by the arrangement of a main stream controlling Switch (21, 22, 23) with switch lever (2o) on the handle (2) of the body. 13. Impact tool according to claims 6 to io, characterized in that the feed current of the excitation coil (25, Fig. I) via an electric valve (26, 27, 28) and a magnetic switch (33) is performed, the excitation coil of which is controlled by the switch (2o to 23) will. 1. 4. Striking tool for performing the method according to claim i and according to Claim 3 and 5, characterized in that the rectifier is operated mechanically is.