DE351810C - Magnet-electric machine with static induced windings and a static magnet system - Google Patents

Description

Magnetic electric machine with static induced windings and resting magnet system. The magneto-electric machine according to the invention draws due to the high utilization of the magnetic flux and almost no scatter the end.

The magnetic circuit is always closed, so that the machine retains its magnetism for a long time. The machine is also easy to assemble and take it apart again and can be used for a wide variety of purposes be e.g. B. to ignite explosion engines, for ringing telephones etc.

The drawing shows schematically an embodiment of the invention represent.

Fig. I shows one through the axis of the two rotors of the machine laid cut. Figs. 2 and 3 illustrate two cross-sections along the line A-A of Fig. I; in Fig: 3 it is assumed that the two runners go against the position shown in Fig. 2 are rotated; Fig. ¢ is a view of one of the the discs composing the pole pieces.

i denotes two z. B. cylindrical permanent magnets that. parallel arranged to each other and have the same poles on the same side; they form the middle part of the machine.

On both ends of the magnets i, over one 2.5 times The extension corresponding to its length is made up of two bundles of disks of soft iron 3 attached, which sit on two diamagnetic guide pins 2 at the same time. These Disks (Fig. 4) are oblong and round and have two openings for receiving the Magnets, two openings 2 'for the guide pins 2, finally two openings 4., which in one to that of the openings lie on the vertical axis, from which they are equidistant in a symmetrical arrangement.

According to Fig.4, part of the edge of the openings d. circular before to form a pole piece.

The complete pole pieces result from assembling several Washers 3 according to fig. Q ..

Screw nuts 6 of guide bolts 2 press the iron washers 3 against a reinforcement 7 of the bolts 2.

The machine also contains two runners, one of which is from a bundle elongated rectangular disks of soft iron 8 is formed. These disks are separated from each other by a thin layer of insulation, as is the case with the anchors of the ordinary dynamo-electric machines, and: the disk bundles are located between two pieces of bronze that run the entire length of the bundle. A bronze roller 9, which is provided with a longitudinal gap, can be used for this purpose. in which the discs 8 fit exactly. The. Bundles are made in the lathe to the diameter brought the rollers 9; then the disks and the bronze piece together become hers The whole length is turned down on a cylinder, the diameter of which is a small one (about 1/4 mm) smaller than the circular part of the openings d. is.

At the ends of the two runners, their axes of rotation parallel to the axis der: are magnets, pins for drive wheels are arranged io. From Fig. 2 and 3 it follows that the metallic cross-section of the rotor is circular, the magnetic penetrable cross-section, however, is a rectangle, the two short sides of which are arched are.

The same runners are both driven by wheels at the same time driven, which are keyed on one of the rotor ends; they move with a quarter turn phase shift bong, d. H. if, as shown in Fig. 3 is the case, a runner, namely the lower one in that figure, with its iron part the pole piece 5 is just opposite, then the other runner is with the Bronze part in front of the pole pieces, d. H. in a position similar to that of the first Rotor is delayed by 90 °.

The runners are surrounded by two fixed coils i, i, i2, namely on the free part between the pole pieces, which makes up approximately% of the total length; they are made by inserting the frontal insulation into openings in the disk bundles bronze plates delimiting the inside held in place (Fig. i).

The machine works in: The following way: At the one shown in Fig. 3 Position, the entire power flow of the two permanent magnets i goes through the lower rotor, that of the pole pieces with the largest magnetically penetrable area under formation facing the smallest air gap; this can z. B.% mm.

Not the slightest part of the lines of force can penetrate the other rotor, due to the strong resistance of the air gap, which increases with the dimensions shown from 21 / _ mm (namely with the pole horns) to 5 xnm (center of the pole pieces), i.e. in Mean 1 5 times larger than the air gap of the other rotor.

However, if the lines of force from the polar horns into the iron end upper Penetrate the runner, they are the insulating layers located between its panes in the way, which thus offer a guarantee that there are no lines of force in this runner appear.

The flow of force which comes from the North Pole shoe (e.g. the one in Fig. I on the right drawn) penetrates the lower runner, flows through this runner in the Longitudinal direction, in order to move across the small air gap at the opposite end that belongs to your south pole shoe (shown on the left in Fig. i).

After a quarter turn, the two runners have the one shown in Fig. 2 Position taken up again. In .your lower runner is the power flow from his largest values dropped to zero and in the upper runner from zero to the largest Value increased. During the quarter turn, the magnetic current is always closed; the flow of force at the limit positions of the runners is one-sided to one of directed to them and distributed to both runners for i the 'middle positions.

In the following quarter turn, the same changes in the flow of force take place between the two runners, but in the opposite sense, d. H. while in the lower rotor the magnetic flow rises from zero to its maximum value, it falls to zero in the upper of its highest values. On the second half turn occurs exactly the same as with the first half turn, so that with a full turn both runners the magnetic flow changes four times and accordingly in the coils two full current periods arise.

The direction of the flow of force is never reversed in the runners, but it is subject to strong fluctuations. The electricity generated is alternating current. - At the same speed of rotation of the rotors of this machine of the double drive of an ordinary two-pole magneto-electric machine, the coils of the present machine supply: a current of double frequency. The ends of the armature windings are connected to one another in such a way that the induced electromotive forces add up. Ample space is provided for both coils, which allows the arrangement of a double winding, namely one for high and one for low voltage.

Depending on the drive, the rotor can move in the same direction or turn opposite to each other: this remains however without influence the effect of the 1, Zaschine. In the illustrated embodiment, the Runner driven by a middle wheel 13 that connects the two to the axles the rotor is in mesh with the toothed wheels ro. The runners spin consequently in the opposite direction.

The shape of the different parts of the machine as well as the structural ones Details can be changed from get compared to the example shown.

The size of the magnetically penetrable Winkelg of the rotor is in any case 60 °. I. Let us first consider the case that the pole pieces 5 each include an angle of go °. There will be one of the runners, e.g. B. B (Fig. 5) considered at the time when its effective iron sheets normal to the center line the pole pieces lie.

The electromotive force arises as soon as the rotor has turned through an angle of 150 ' and has moved away from the neutral axis. In this position the runner's iron is about to step under the pole pieces. From this moment on, the magnetically penetrable surface for the angular rim of 60 ° constantly increases; and since the air gap remains the same, this increase can be regarded as proportional to the angle, which in turn is proportional to the time with regard to the speed of the rotor.

From this it follows that from the moment counted as origin in the position corresponding to i5 °, an electromotive force of the value zero arises and during the following 60 ° a constant, negative electromotive force Force (with increasing magnetic flux) is generated.

During the following rotation of 30 ° the magnetically penetrable one changes Not surface, because the iron of the runner is still fully opposite the pole pieces. So there comes a time when the electromotive force is equal to zero.

As the rotation continues, the magnetic area and decreases consequently the flow of forces according to a uniform law with respect to time to the angular space of 60 °, so that a constant, positive electromotive force arises. 65 After the rotor's iron has left the pole pieces, it turns moves through an angle of z5 ° in the power flow zone zero and returns to the starting position return. In the corresponding period of time, the electric motor table force is zero. The rotor has made half a turn (r8o °).

To the procedure described graphically represented (Fig.6), taking into account that fully is due to secondary Erscheinun- 75 gene, the electromotive force does not perfectly constant, equal to zero in the above-mentioned periods, in addition to the theoretical angle line another line is drawn, which in its connections and curvatures approximates the practically achievable current form.

It will now be examined what is happening in the other runner at the same time the machine (Fig. 7). $ 5 At the beginning of the time, i.e. H. at the point in time where the first runner B was with its axis in the neutral line, stood the effective iron sheets of the second rotor B 'parallel to the center line of the pole pieces. 9o No electromotive force is generated during a rotation of Z5 ° because the Power flow here remains constant. But as soon as the iron from B 'closes the pole pieces begins to leave, a positive, constant electromotive force arises, which lasts over the entire angular space of 60 °.

An electromotive force is then applied for an angular space of 30 ° generated by the value zero, because B 'is outside loo of the power flow; and during the following 60 ° there is a negative, constant force. After a turn of z5 °, during which the electromotive force is zero, becomes the starting position reached (half a 1o5 turn of the rotor).

Reversing the connection of the coil ends can result in addition of the two electromotive forces arising at the same moment, one electromotive force 11o force achieved «-earth, which is twice as large as the shape indicated by Fig. 8 and which results from the addition of the force 7 and the inverse force 6.

The highest '\ N'ert of the resulting electromotive force arises after a rotation of 45 # 'in relation to the starting position. Do the two Then the position at which the greatest electromotive force is achieved in relation to the lao pole shoes, with your iron, stand halfway across from the flow of force and half outside the magnetic Flow, with one of the runners is about to step into the area of the pole pieces and the other is about to leave it.

II. Let us now consider the case where the pole pieces are at an angle of 60 °, d. H. an angle equal to the penetrable arcuate surface; included the same origin of time and angle will be taken as a basis and the mode of operation of rotor B tested (Fig. g and graphic representation of Fig. i o).

. With a rotation of 30 ° the electromotive force is the same Zero. At the following 60 ° there is a negative, constant electromotive force Force. Then there is no longer any period for which the electromotive force is equal to zero, because the iron that immediately leaves the pole pieces in the following 6o ° generates a positive electromotive force.

This results in a rotation of 30 ° in a neutral zone (and accordingly a force zero) for the return to the starting position.

We will now examine what is happening at the same time with regard to the runner B 'takes place (graphic representation of Fig. I i).

At the beginning the power flow has its greatest value. Once the rotation begins, an e'ectroinomotive force is generated which during the rotation of 60 ° remains positive and constant. Then follows a rotation of 60 ° in the neutral Zone and a corresponding period of time where the electromotive force is zero is.

During the next 60 ° the electronic motor force is below Return to the starting position negative and constant.

Again, it is useful to reverse the connections to the highest one Achieve power of the electromotive force zii.

Fig. 1a illustrates the electromotive force that results from the connection of the force i i results in the finite inverse force io. The highest The value of the electromotive force arises around d5 ° from the starting point remote position, although the electronic motor generated by the two coils Forces are at most 60 ° for B and 30 ° for B 'from the angular origin.

The greatest electromotive force arises in relation to the pole pieces, if the penetrable arcuate surface of the rotor B by i5 ° between the pole pieces has occurred, d. H. to r !, their angle, and if the penetrable arc surface of the rotor B 'by .15 °, i.e. H. at 3/4 of its angle, which has left the pole pieces.

Include the pole pieces as well as the penetrable surface of the rotor every 90 °, then the electromotive force is no longer equal to zero in any point.

Claims (5)

PATENT CLAIMS: i. Magnetic electric machine with dormant induced Windings and resting, made up of one or more rod-shaped rods arranged in the same direction @lagneten existing magnet system, characterized by two pole shoes each on the north and south pole of the magnet system and by rod-shaped force line guide pieces for production the magnetic connection between one pole piece each of the north and south pole, where each one of the force line guide pieces within an induced coil around its longitudinal axis running around. a. Machine according to claim i, characterized in that the force line guide pieces are arranged between non-magnetizable side pieces of circular segment-shaped cross-section and consist of rectangular magnetizable sheets of equal length and different width, so that two rod-shaped bodies of circular cross-section are formed which are rotatable about their longitudinal axis. Machine according to claim 3 or '2,. LI characterized in that the effective iron sheets of the two armatures are perpendicular to one another, and that the induced coils attached between the pole pieces encompass the central part of the armatures. d .. Machine according to claim i to 3, characterized in that the poles of the same name of the permanent magnets through perpendicular to the axes of the same and the anchor lying between disks diamagnetic material enclosed bundles connected to magnetic disks are, which have symmetrical openings for receiving the bar magnets and the armature. 5. Machine according to claim 3, characterized in that the pole arcs of the armature and field magnets are dimensioned so that at the same speed of rotation the armature the magnetic circuit is constantly closed.