DE734971C - Electrical quotient measuring device with circular scale and two coils that can be rotated in magnetic fields arranged axially one above the other - Google Patents

Description

Electric quotient measuring device with circular scale and two axially one above the other arranged magnetic fields rotatable coils There are electrical quotient measuring devices known with a circle scale; .at those with a so-called unipolar magnetic field oscillating measuring coil is mechanically coupled to a directional coil, which is connected to at least one of its coil sides moves in an inhomogeneous magnetic field. Thereby move the two rotating coils in magnetic fields, the starle of which grows on one side, namely so; that in the direction of the movement of the moving coils the strength of one magnetic field decreases; while that of the other magnetic field increases.

This known arrangement has the disadvantage that the sensitivity des: measuring mechanism that is of the same size. as a moving coil instrument with a homogeneous magnetic field is trained. On the other hand, you get a quotient eating device with a circular scale, the in terms of sensitivity is not inferior to a corresponding moving-coil instrument and it can be built in such a way that it is also essentially the same - the same mechanical Has a quality factor, using two magnetic fields arranged axially one above the other rotatable coils, of which: the one, the measuring coil, in a homogeneous, so-called unipolar and the other, the directional coil; oscillates in an inhomogeneous magnetic field; according to the invention in that the strength of the magnetic field; in which the directional coil benvegt, from the middle to both sides with opposite The direction of the line of force rises and between the two magnetic fields. ans magnetizable material existing> face plate is provided. The magical screen the purpose of preventing date the line of force distribution in the Magnetic field in which the measuring coil moves, the distribution of the lines of force _ in your Magnetic field for the directional coil disruptively influenced. This is therefore particularly important because this field is near the middle position; the directional coil is very weak, so that a relatively small (, of your axially arranged magnetic field for the force line spread originating from the measuring coil, the field distribution for the directional coil would change in an improper manner.

A shielding against external external fields is thereby preferably achieved causes the scale plate to be made of magnetizable material. Around to be able to adjust the zero position of the pointer within certain limits. is it appropriate to arrange the magnet system of the directional coil so that it can rotate in four directions with respect to that of the measuring coil.

There are quotient measuring devices in which the measuring coil in an essentially homogeneous and the directional coil in an inhomogeneous, and also from the middle to both sides riding opposite lines of force increasing part of the same magnetic field. But that is not the case uni measuring devices finite a circular scale, rather the deflection angle is proportional small.

In the arrangement according to the invention, one of the directional coil generated Direct current is a torque that tends to move the coil in the central zone of the To keep the magnetic field. This torque acts like that of a straightening spring, which strives to keep the "pointer of the measuring mechanism in the middle position.

In this way one obtains a kind of a through the measuring mechanism of the measuring coil given normal moving coil measuring device finite circular scale. its measuring mechanism by the directional moment is held in the middle position. The quotient meter according to the invention is primarily suitable for use in differential circuits, in particular in connection with remote transmitters finitely adjustable resistors or resistance thermometers in 'bridge circuit. You can use the invention with advantage, for. B. Also for speed measurements and the like following a transmitter built in the manner of a direct current generator Use with changing direction of rotation: If necessary, you can use the field distribution in the magnetic field of the directional coil I -by using a specially designed one Influence the line of flux return when magnetizing. In most cases is (read "but not required. (relatively simple arrangement results when the effective side of the directional coil is in your annular gap between one circularly curved magnet and an annular yoke. An arrangement that is particularly recommended in your Lall, where it is as linear as possible Scale division is required, is that the effective side of the directional coil in the annular gap between the correspondingly hollowed-out pole faces of the opposite name two finite a small space next to each other on the way of the directional coil subsequent pole pieces on the one hand and an annular power line connection on the other hand emotional. whose cross section is covered by the directional coil. .V A particularly cheap Mass distribution is obtained when the pointer of the measuring device is on the same side how the directional coil is arranged and how the weight ratios are rooted that the center of gravity of the movable measuring mechanism is approximately in the axis of rotation. Through this the result is a measuring device that also has a mechanical quality factor corresponding moving coil measuring device is essentially equivalent.

In the drawing, FIGS. 1 to 3 show schematically different embodiments the magnet arrangement for the directional coil, while FIG. 6 shows a section through a measuring device . According to the invention when using an arrangement according to FIG.

In the embodiment according to FIG. I, the directional coil z comprises the cross section an annular iron core? which is arranged coaxially to the axis of rotation 3. Coaxial with this is a permanent magnet -. bent, whose marked with \ "and S. Poles face each other at a certain distance. This creates in your Annular gap between your magnet 4 and your iron core 3 eire magnetic field. that from the center out to both sides with the opposite direction of the lines of force increases.

If a direct current flows through the directional coil i, then so it seeks, as indicated, to adjust itself to the central zone. This arrangement acts similar to a straightening spring, the torque of which comes from the center of the scale in the case of deflection, corresponding to the size of the pole encircling angle after both Pages increases. M = tight now the directional coil nlit the measuring coil one for the same Deflection angle suitable Irehsf, iuhneßwerlcs is coupled, where i is the measuring coil moved in a homogeneous magnetic field, let the scale run through the Distribution of the lines of force along the curved magnet d. certainly.

The arrangement shown in Fig. 2 is, so to speak, a reversal the arrangement of Fig. i, wherein the directional coil i comprises a magnet 5, whose Outer surface is circular and coaxially curved to the axis of rotation. The line of force inference is then carried out by an iron ring 6 surrounding the magnet on the outside the effect and also the distribution of the lines of force in the annular gap essentially the same as in the arrangement according to FIG.

It has now been shown that the field strength in this case of the 'The problem is not linear, but increases more and more steeply towards the ends of the pole. if If a linear scale division is required, the magnetization must correspond accordingly take place unevenly. This can be achieved, if necessary, by during magnetization the magnet is closed by a piece of iron in such a way that that there is an air gap that increases from the litte to both sides.

You can also use this to create an approximately linear scale achieve that the cross-section of the magnet from the center to both sides decrease or the width of the annular gap can increase. One such arrangement is for example shown schematically in FIG. This arrangement is different differs from the one shown in Fig. i in that the cross-section of the magnet 7, the outer circumference of which, as in the embodiment according to FIG is coaxial, tapers towards the poles 2, the magnet being off-center on the inside is ground to the axis of rotation.

An arrangement in which the effective side of the directional track is in the Annular gap between the unevenly magnetized pole faces of two pole pieces and an iron core encompassed by the directional coil is moved, is shown in Fig. d. shown. In a soft iron ring 8 serving as an external power line connection there are two ring segment-shaped Pole pieces Io made of magnetically hard material e = inlaid in such a way that: on the one hand a narrow and on the other hand a somewhat wider air gap remains between them. Coaxially to this is an iron ring 2 encompassed by the directional coil i, which forms the inner Force line connection forms.

In this case, too, the directional coil deflects in the area of the deflection a magnetic field, - its strength from the drawn center position towards both Sides increases, but in contrast to the arrangement according to FIG. I, the field strength increases here from the middle position to both sides very quickly, and you can get one approximately linear scale division z. B. can be achieved by magnetizing the assemblies uses an iron core which is designed so that an air gap arises, the width of which is greatest in the middle.

A particularly expedient embodiment of the subject matter of the invention is shown in FIG. This differs from the arrangement according to FIG. 4 in that that the two pole pieces II, 12 inserted into the outer iron ring g are off-center on the inside are ground out. This ensures that the length: of the lines of force in the Pole pieces and thus the field strength increases from the center to both sides and at the same time the width of the annular gap decreases.

In FIG. 6, an exemplary embodiment of the subject matter of the invention is shown in a central section through the axis of rotation, the arrangement according to FIG. 5 being selected. On the base plate 13 of a cylindrical housing 15 covered by a pane of glass 14, a known unipolar magnet arrangement is fastened with an iron plate 16 in between. This consists of a cylindrical tube 17, to which a bottom 18 is connected, which is provided with a hole and consists of a material of high coercive force. In: the hole provided in the bottom i8 is a circular disk i9, which is followed by a web -2o. This carries a pole ring 21 at the top, which is encompassed by a rotating coil 22 serving as a measuring coil. The parts 19 to 21 are expediently made of soft iron. The upper edge of the tube 17 is designed so that the effective side of the measuring coil 22 moves in a homogeneous magnetic field.

The measuring coil 22 is supported by holders 23 on a measuring mechanism shaft 2: a. attached, : on the one hand in the plate i9 and on the other hand in one attached to de.m web 20 Arm 25 is mounted. By means of two slightly nacligieliige bands 26 the 1leßstrom the coil 22 is supplied.

An arm 27 is connected to the measuring coil 22 by a pin 28, which lies in the continuation of the measuring mechanism shaft 2- [and, uni 180 1, offset from the measuring coil, carries the directional coil i by means of two holders 29. This comprises the ring-shaped iron core 2 which, in the central position of the straightening coil, contains a gap closed by a filler piece to facilitate the introduction of the straightening coil. The core 2 is by means of an intermediate piece 30 in the. outer iron ring 8 held, in which the pole pieces 1i, 12 are inserted. The iron ring 8 is extended downwards and engages over the tube 17 in such a way that the entire magnet arrangement of the straightening coil can be rotated with respect to the actual measuring mechanism, in order to precisely set the position.

In the tube 17 an iron plate 31 provided with an edge is also inserted, which serves to shield against the magnetic field of the measuring coil and is provided with a slot 32 to facilitate assembly. Above the magnet arrangement of the steering coil an existing sheet-iron scale plate 3 ¢ is attached to a worn by your ZwischenstÜcl <30 arm 33, in front of a service associated with your pin 28 pointer passes, 35 extending in the direction of the steering coil. The current is supplied to the straightening coil i by means of two belts 36 which can be moved as easily as possible.

If z. B. a temperature between the. Limits from - 30 ° to -1- 5o ° is to be measured by means of a resistance thermometer, one uses preferably a bridge circuit known per se, with one of the bridge branches consists of a wire coil exposed to the temperature to be measured, the resistance of which changes with temperature. The bridge circuit is then balanced so that the diagonal current at + Io ° disappears. The pointer 35 is then at + Io ° in the middle of the scale, and you get to the left up to - 30 ° and to the right up to -1-- 5o 0 an approximately linear scale division.

The sensitivity of the measurement is exactly the same as when the straightening coil would be replaced by a straightening spring with the same straightening force. If Now the weight of the directional coil i is dimensioned so that it is together finitely your pointer 35 the measuring coil 22 holds the balance, so are special additional counterweights not necessary or only necessary to such an extent that also the quality factor of the measuring device that of the corresponding moving coil device is not significantly inferior.

Claims (18)

PATENT CLAIMS; i. Electrical quotient measuring device finite circular scale: and two coils rotatable axially one above the other, of which one, the measuring coil, vibrates in a homogeneously unipolar and the other, the directional coil, vibrates in an inhomogeneous magnetic field, especially for use in differential circuits, characterized that the strength of the magnetic field in which the directional coil (i) moves. from which: litte rises on both sides with opposite direction of the lines of force and a shield plate (3i) made of magnetizable material is provided between the two magnetic fields. 2. Measuring device according to claim i, characterized characterized in that the field distribution in the magnetic field of the directional coil (i) by Use of a specially designed power line yoke when magnetizing being affected. 3. Measuring device according to claim i or characterized in that the effective side of the directional coil (1) is in your annular gap between a circular curved magnet and an annular yoke. .l. Measuring device according to claim 3, characterized by an equiaxed arrangement of the magnet (d.) and the annular yoke (2). 5. Measuring device according to claim 3 or .1, characterized in that the directional coil (i) has the cross-section of the annular Force line connection (-) includes and the circular magnet outside the ring-shaped Force line connection is arranged. 6. Measuring device according to claim 3 or characterized in, that the directional coil (i) has the cross-section of a circularly curved magnet (.,) falls over and an annular power line connection (6) is arranged outside of the magnet is. 7. Measuring device according to claim 3, characterized in that the width of the annular gap enlarges in both directions from the central zone. B. Measuring device after Claim 7, characterized in that the outer periphery of the bent magnet (;) with the one encompassed by the directional coil (i) and serving as a force line return inner annular core (2) equiaxed and the inner circular circumference of the Magnet is off-center. 9. Measuring device according to claim i or 2_ characterized in that that the effective side of the directional coil (i) is in your annular gap between the hollowed out dissimilar pole faces of two finite one on the way of the directional coil small space between adjoining pole pieces on the one hand and an annular one Kraftlinienschluß (2) on the other hand moved, the cross-section of the directional coil (i) is included. ok Measuring device according to claims 2 and 0, characterized by a equiaxed, # Arrangement of the cylindrical pole faces and the inner ring-shaped force lines (z). i i. Measuring device according to claim 9, characterized in that the annular gap would be from the: middle position of the directional coil narrowed on both sides. I2. Measuring device according to claim II, characterized by an eccentric arrangement of the cylindrical pole faces of the pole pieces (11, 12) and the inner ring-shaped power line connection (2). 13. Measuring device according to claim (12), characterized in that the two pole pieces (11, 12) with their cylindrical outer surfaces coaxial with the inner ring-shaped Force line connection (2) are arranged. 1d .. Measuring device according to claim 13, characterized in that that the two pole pieces (11, 12) with their outer surfaces in a cylindrical, ring (8) made of magnetizable material serving as the outer force line connection ' are used. i5. Measuring device according to one of Claims i to 1d., Characterized in that that the directional coil (i) is arranged offset by 180 ° with respect to the measuring coil (22). 16 .. Measuring device according to claim 15, characterized in that the pointer (35) of the measuring device is arranged on the same side as the directional coil (i) and the weight ratios -Are chosen so that the center of gravity of the movable measuring mechanism is approximately in the Axis of rotation loves. 17. Measuring device according to claim 16, characterized in that the Magnet system of the directional coil (i) on the other hand by a magnetizable Material existing scale plate (34) is shielded. 18. Meter after a of claims i to 1;, characterized in that the magnet system of the directional coil (1) with respect to which the measuring coil (22) can be twisted and rotated in order to set the zero position.