DE838019C - Electromagnetic oscilloscope - Google Patents

Description

The invention relates to an electromagnetic oscilloscope for recording rapidly changing electrical currents, whichever is more, on a suitable suspension attached soft iron armature on the one hand a fixed magnetization, which is from a permanent magnet is generated and has an effect in the direction of one of the symmetry elements of this anchor, and on the other hand, subjected to magnetization

ίο becomes which one excitation winding flowing through Current is proportional and acts in a direction similar to the aforementioned direction runs vertically.

The invention aims to be considerably less extensive the working conditions of such a device by achieving a very high natural frequency the 1> movable system, a very good, n damping, the lowest possible power consumption in the excitation development, a very good display stability and the resulting possibilities regarding the recording media.

The electromagnetic oscilloscope according to the invention is characterized in that on the one hand the movable system consists of a soft iron anchor of parallelepiped shape, the bases of which Rhombuses form those to the sides, which in turn to the end faces of two solid pole pieces are parallel, stand perpendicular, and that on the other hand, the counter torque by a torsion bar is generated, which is inserted at one end 'into the movable anchor and its more effective Part about half is contained inside this anchor.

Further details and advantages of the invention emerge from the following description of a Execution example on the basis of the drawing.

Fig. 1 shows a schematic perspective view of an oscilloscope according to the invention; Fig. 2 shows a schematic view of the device in plan;

Fig. 3 shows a section of the main part of the oscilloscope;

Fig. 4 shows a perspective view of the movable Systems;

5 and 6 show in plan view and in

ίο section a preferred embodiment of the Torsion bar;

Fig. 7 is a diagram showing the movements of the movable system as a function of a size proportional to the drive torque.

The movable armature 10 consists, as mentioned above, of a soft iron part of parallelepiped Shape whose bases are rhombuses that are perpendicular to the sides, which in turn are parallel to the end faces of two fixed pole pieces 15 and 15 '. The torsion bar ii, which forms the suspension of the movable armature 10 and for generating the counter torque serves, is arranged in the axis of symmetry of this anchor.

The two pole pieces 15 and 15 'consist of

U-shaped soft iron sheets and are with four Windings 16, 17, 16 'and 17' are provided. That with

The end of the pole piece provided with the winding 16 ' 15 'is shown broken off in FIG. These windings magnetize the moving armature 10 proportional to the current flowing through it. The magnetic generated by these windings For a given polarity of the excitation current, flows are in the direction of the arrows 18 ' (Fig. 2) directed so that the magnetization in the El> ene of the larger diagonal of the movable Anchor takes place. Furthermore, a permanent magnet 13 is provided, the flow of which through the soft iron yokes 14 and 14 'the movable armature in a direction indicated by the arrows 18 (Fig. 2) interspersed parallel to the smaller diagonal of the movable armature.

The movable armature 10 is according to its plane of symmetry pierced by a smooth bore 19. The torsion bar 11 is on both of them Ends of two cylindrical parts 20 and 20 'which are precisely ground. The end 20 is in the bore 19 of the movable! Anchor pressed tightly, so that a larger section the effective part of this rod is located inside the anchor. The end 20 'is also pressed tightly into a smooth bore which is provided in a carrier 12 on which the Pole pieces 15 and 15 are fixed.

The metal forming the torsion bar 11 is very hard, e.g. B. hardened 'carbon steel, so that its ground end parts easily blend into the softer metals that make up the movable armature 10 and form the carrier 12, the hole diameter of the movable armature and the carrier 12 is slightly smaller than the diameter of the end portions of the rod. The anchor can for example made of annealed nickel steel with low magnetic hysteresis and the bridge made of brass or Bronze. Provided that the cross section of the torsion bar in its effective Part is sufficiently smaller than its cross-section at its inserted ends, one can be sure that that the mechanical stress on torsion at the time of insertion remains moderate, from which it follows shows that no permanent deformation occurs and the zero position of the system is completely stable remain. The torsion bar 11 should have a relatively small torsional moment, but a large one Have flexural strength so that the movable armature 10 with respect to the fixed pole pieces 15 and 15 'despite the significant magnetic attraction forces exerted on this armature, stays well centered. For this purpose, the torsion bar 11 is preferably given a cruciform Cross-section as indicated in Figs. 5 and 6 with the end portions 20 and 20 'remaining cylindrical, in order to facilitate their insertion into the armature 10 on the one hand and into the support piece 12 on the other hand.

The mobile system of the oscilloscope according to the invention enables its use a particularly favorable recording organ (Fig. 3 and 4), through which the movement of this moving system can be recorded on a blackened film, which is more uniform Movement shifts and is swept by the writing organ. This writing organ consists of a light metal tongue 21 in a triangular shape. This triangular shape makes the smallest Moment of inertia with maximum strength in the direction of movement. The tongue will be at the end of the moving system attached as rigidly as possible, z. B. by means of two screws 22 and 22 ', for this purpose the anchor is extended upwards so that the tongue with respect to the Windings is exposed.

At its end, the tongue has a very sharp point 23 that strikes the blackened film with it a pressure is applied, which is due to the elasticity of the tongue and its deflection is determined. So that the tip is not worn out by the friction on the belt they are made from a material of the highest hardness, such as diamond, sapphire, or from a metal carbide. The tip 23 draws an extremely fine, transparent background on the black background of the film Line, the width of which is on the order of a hundredth of a millimeter. Man can therefore draw diagrams of an amplitude with an extremely satisfactory fineness, which is less than or equal to one millimeter. The film can then be enlarged with a magnifier Observations are similar to those used for reading documentary microfilms to be used.

The small width of the track as well as the small dimension of the amplitudes make it possible to side by side a large number of writing organs on a film of normal dimensions

to arrange. This arrangement in conjunction with the fact that the rate of displacement of the film is chosen on the scale of the amplitudes make it possible to save considerably on recording filters and to save a large number of diagrams that are completely synchronized and, since they do not overlap, are easy to read.

When the movable armature io is in its middle position, the four air gaps are the same. The magnet 13 generates a constant induction in the pole pieces 15 and 15 ', which is referred to as the nominal induction B _n l> and which adds an induction 15, - algebraically, generated by the four windings 16, 17, 16' and 17 ' and is proportional to the current flowing through these windings (Fig. 2). The resulting induction is therefore equal to B _n + B ₁ at the poles 15 _α and i5 _ft 'or equal to B _n - B ₁ l> ei the poles 1S ₆ ao and 15, /. Since the attraction force exerted by the surface of each pole on the opposite surface of the armature is proportional to the square of the induction, the magnetic torque is proportional to * 5 (/ J ₁₁ + H ₁ ) * - (/ '"- I'd ² = 2B _n B ₁ .

This torque is then proportional to Bj and thus to the current which flows through the windings 16, 17, 16 'and 17'.

However, when the movable anchor deflects from its central position, it changes in everyone Pole piece the induction resulting from the magnet, so that the torque with the deflection angle fluctuates.

With the electromagnetic oscillographs used up to now, it has always been set up in such a way that the deflection of the movable anchor was negligibly small in relation to the air gap so that the magnetic torque does not change with the deflection angle. It has now been established that the oscilloscope described above is the movable one Anchor by a much larger dimension, e.g. B. 20 to 25% of the air gap, can knock out without the deflection therefore ceases to be proportional to the current of the windings.

This organ> Engage consequences of the utmost important _<ACTION:

1. First of all, the air gaps can be extremely short and, since the ampere-turns that go to the Krzeugung a given torque are required, proportional to the length of the air gap are, they can be reduced in size considerably, making the for The excitation of the windings required is reduced, which is increased by the square of the Ampere turns changes.

2. The change in the magnetic flux which occurs in the pole pieces as a result of free oscillation of the movable armature is much larger, thus also the one induced in the windings Tension. This makes it possible to use the lx? Movable system through a parallel to these Windings provided to attenuate the external short circuit, as with the usual measuring devices of the Construction with magnet and movable frame, while all oscilloscopes used so far need a viscous liquid such as oil for dampening. The attenuation by induced currents but is superior to oil damping in that it does not require a tight container and with the Temperature fluctuates very little.

3. Because the air gaps are very short, the magnet can easily be dimensioned so that the nominal induction B _n is high despite the very small dimensions of the magnet. However, the torque exerted on the movable armature is proportional to B _n for a given AW number, and this results in an additional reason to reduce the AW.

These results are shown in the oscilloscope according to the invention, as set out below, achieved:

I. The suspension of the movable system gives an extremely high strength in the bending direction due to the use of a rod as Torsion spring and the penetration of a considerable part of the effective part of this Rod into the interior of the armature so that the axis of the movable armature does not experience any displacement, although the side magnetic forces are considerable.

II. The movable armature, its cross-section is diamond-shaped, has a relatively low moment of inertia. Also, as a result the shape of this cross-section avoided saturation in the armature, although the magnetic one The river that permeates it when it moves away from its middle position is considerable. the Induction is practically the same at all points of the anchor, since the flux which the anchor in interspersed with a given cross-section, the closer this cross-section is to the Center is located.

One performs a full analysis of the operation of an electromagnetic oscilloscope by, so you can calculate the torque, which is due to the magnetic attraction forces of the Pole pieces on the movable armature depending on the deflection of the · movable Armature on the one hand and depending on the current flowing in the windings on the other hand is exercised. The corresponding curves are shown in FIG.

The deflections of the movable armature as a percentage of the deflection are plotted as the abscissa, l> ei which the end of this armature touches the end of the fixed pole pieces.

As. Ordinates are the torques, or more precisely the ratios of the torques to the Square of the nominal induction, plotted.

The different curves are drawn for different values of the current in the windings, whereby these values are determined by the

ratio k =

D.

between the induction generated by the current and the nominal induction.

The result is a normalized system of units.

The curve k = ο is the curve of the magnetic torques when the windings are not energized.

The straight line represents the mechanical torque

which is generated by the suspension.

The straightening torque is the difference between

these two torques, since they are in opposite directions

ίο act, whereby the mechanical torque strives is to return the mobile system to the central position, while the magnetic Torque tends to remove the moving system from the middle position.

If currents with different values flow through the windings, the equilibrium position of the movable armature is determined by the intersection of the straight line of the mechanical torque with the curves of the magnetic torques for the corresponding values of k. So that the deflection of the moving system is proportional to the current, the intersections of the straight lines with the curves must have the same distances for values of k in arithmetic progression. This applies practically up to a deflection equal to 25%) of the nominal air gap e ". Under these circumstances 1. the magnetic torque in the absence of a current can be greater than half the value of the mechanical

D.

nical torque, 2. the ratio k = -g reach the value 0.15 at the deflection which corresponds to the maximum value of the scale. This maximum value is indicated by the vertical straight line in FIG.

Claims (10)

Patent claims: 1. Electromagnetic oscilloscope for recording rapidly changing electrical signals Processes, characterized in that on the one hand the movable system from a Soft iron anchor in the form of a parallelepiped, the bases of which are diamonds, the are perpendicular to the sides, which in turn are parallel to the end faces of two solid, with the excitation coils of wound pole pieces run, and that on the other hand, the counter torque is generated by a torsion bar, which at its one end in the movable Anchor inserted and its effective part more than halfway inside this anchor is included. 2. Oscillograph according to claim 1, characterized in that the torsion bar at his one end inside the movable armature and at its other end in a beam is inserted to which the pole pieces are attached. 3. Oscillograph according to claim 1 and 2, characterized characterized in that the made of hard metal torsion bar on both of them Ends is ground and these ends are pressed tightly into smooth bores that are in the anchor or in the carrier, which are made of softer metals, are provided. 4. Oscillograph according to claim 1 to 3, characterized in that the torsion bar has a cruciform cross-section. 5. Oscillograph according to Claim 1 to 4, characterized in that the writing element consists of consists of a triangular light metal tongue, which at its end with a very fine Tip made of an extremely hard material and at its base at the free end of the movable armature is attached, the pressing force of the tip only through the elasticity the tongue and its deflection is determined. 6. Oscillograph according to claim 1 to 5, characterized in that the recording occurs on a blackened film that shifts with uniform motion and is swept by the writing organ. 7. Oscillograph according to claim 1 to 6, characterized in that several movable ones Systems are provided, each of which is provided with a writing element, the Arrangement is made so that the writing organs are mounted side by side on the film are. 8. Oscillograph according to claim 1 to 7, characterized in that the movable armature at the maximum value of the measuring range executes a deflection of at least 20% of the The deflection corresponds to the contact between the armature and the pole pieces. 9. Oscillograph according to claim 1 to 8, characterized in that the magnetic Moment of the magnetic attraction forces of the end faces of the pole pieces against the movable armature in the absence of a current is exerted in the excitation windings, is at least 30% of the mechanical torque, which generated by the torsion bar. 10. Oscillograph according to claim 1 to 9, characterized characterized in that the in the movable armature from the current in the excitation windings generated induction at a current intensity corresponding to the maximum value of the measuring range, at least 10% of that of the Magnetic induction. 1 sheet of drawings 5137 4.