DE1153979B - Device for influencing the deflection characteristics of moving coil instruments for aperture controls - Google Patents

Description

Device for influencing the deflection characteristics of moving coil instruments for aperture regulator The invention relates to a device for influencing the Deflection characteristics of moving coil instruments for built-in cameras automatic aperture controls.

In such devices, the adjustment of the deflection characteristics prepares of the moving coil instrument to the given movement characteristics of the movable one Aperture elements difficulties. These lie in the fact that the free aperture must be halved when doubling the brightness of the receiving motif. Should Arrangements are used in which at least one aperture lamella firmly with the rotating coil is connected or where the aperture blades are connected via a simple gears working with constant transmission are driven by the moving coil, this inevitably results in the size of the adjustment movements of the diaphragm blades must decrease sharply with increasing brightness. The one doubling the brightness However, the associated deflection of the moving coil increases with uncorrected instruments, starting from the lowest measurable brightness, first on, and then in the range to become a little smaller again with greater brightness. The deflection characteristic of the moving coil instrument is therefore required in the low brightness range Movement characteristics of the diaphragm blades are opposite while they are in the field high brightness levels tend to match the movement characteristics of the diaphragm blades matches, but delivers far too large rotary movements.

The measuring range of low brightness is especially important with aperture controls for cinema cameras often not used or only partially used, because in this area for the given exposure time and the commonly used film speeds Do not set any apertures necessary to carry out properly exposed Recordings are sufficient. The invention therefore sets corrective interventions in the area less Brightness not necessarily ahead.

To overcome the difficulties explained above are for example Arrangements have already become known in which the moving coil increases with increasing current strength supplied by the photo element in the direction of decreasing magnetic field strength emotional. But even with this measure it is often not possible to reduce the rashes to reduce the size of the moving coil with relatively large currents sufficiently. Farther The use of such an inhomogeneous magnetic field results in the disadvantage that with large deflections of the moving coil there is a less stable equilibrium, so that small balance errors cause a relatively large angle error. This then leads precisely to the deflection area assigned to the large brightnesses the already small aperture differences of the diaphragm lead to relatively large diaphragm errors.

According to the invention, these disadvantages are avoided in that a known per se, rigidly connected to the moving coil correction magnet and at least an also known per se, cooperating with the correction magnet, fixed to the device mounted counter magnet are provided and the magnets are arranged such that between the pair of magnets one assigned at least to the high brightness The end of the deflection range effectively repels the deflection direction of the rotating coil opposing force occurs.

Although it is already used in display and writing devices for electrical Known measuring devices to arrange magnetized or magnetizable parts in such a way that as a result of the field achieved in this way, additional values are added for settings close to zero Forces striving for the zero position become effective. This enables a safe Adjustment to the zero point can be achieved. An influence on the effective for display This should not cause deflections in the device. Furthermore is a Known measuring instrument whose rotatable system exerts an actuating force on one Hanging wire is connected. To compensate for the restoring force of the hanging wire, Para- or diamagnetic bodies are provided, which are in a magnetic Move field. It is therefore also not a facility for change the Deflection characteristics of the measuring instrument; apart from that, it is also used ferromagnetic bodies not recommended.

Furthermore, the correction magnet and a counter magnet can advantageously be arranged so that between the pair of magnets associated with the small brightnesses At the beginning of the deflection area a repulsive one, the deflection direction of the moving coil rectified force is effective.

According to a further embodiment of the invention, the correction magnet and two magnets, each assigned to one end of the deflection area, arranged in such a way that that on the correction magnet in the zero position, in which there is no current through the moving coil flows, two equally large opposing, repulsive forces act.

The correction magnet and / or a counter magnet are expediently preferred by shifting in the radial direction or in the direction of movement of the correction magnets arranged adjustable relative to the axis of rotation of the moving coil.

The correction magnet is advantageous outside the range of rotation of the Moving coil on a rod-shaped carrier firmly connected to the coil, which is preferably an instrument pointer or a diaphragm blade is arranged.

According to the invention there is the advantage that the deflection characteristic of a moving coil instrument without adversely affecting the accuracy of the display can be influenced to a large extent.

The device according to the invention is not intended for use in diaphragm controls limited, but can also be used in exposure meters for cameras with automatic Exposure time and aperture control or use with handheld exposure meters Find.

Several exemplary embodiments of the invention are shown in the drawing. It shows Fig. 1 a first embodiment in a view from above, Fig. 2 shows a section along the line 11-II in FIG. 1, FIG. 3 shows a further exemplary embodiment also in a view from above, FIG. 4 a section. along the line IV-IV in Fig. 3, Fig. 5 to 8 are schematic representations of further exemplary embodiments and FIG. 9 shows a diagram of the movement relationships of the moving coil as a function of the measured brightness.

In the embodiment according to FIG. 1, there is a magnetic yoke ring 1 by means of bearing screws 2, a moving coil 3 is rotatably mounted about an axis 4. Of the Return ring 1 is firmly connected to a core magnet 6 via a carrier 5. On the moving reel 3, known per se, not shown in the drawing, continue to engage Return springs that tend to move the coil against the direction of the arrow a in the zero position shown in Figure 1, in which no current through the coil 3 flows to adjust.

A diaphragm lamella 7 is rigidly connected to the axis 4 of the moving coil 3. The diaphragm lamella 7 has at one end in the area of the indicated by dashed lines Lens 8 has an approximately triangular aperture surface delimiting incision 9 on. At the opposite end of the diaphragm lamella is a rod-shaped carrier 10 attached. The tip of the carrier 10 can be adjusted to display the respective Aperture opening with a scale, not shown, applied to the aperture values are to work together.

In addition to the diaphragm lamella 7, another is rotatable about an axis 11 Aperture lamella 12 stored. To drive the diaphragm blade 12 is rigid on the Axis 4, a lever 13 is attached, which is connected to the diaphragm blade 12 in a Curve guide 14 engages.

A correction magnet 15 is placed on the carrier 10. On a the circuit board 16 carrying the return ring 1 are also still at the two ends the deflection area of the correction magnet 15 arranged on the carrier 10 is two Counter magnets 17, 18 arranged. The counter magnets 17, 18 are approximately the same Distances from the axis 4 as for the correction magnet 15. The correction magnet 15 and the carrier 10 can form the counterweight for the diaphragm lamella 7.

The counter magnets 17, 18 are each attached to a holder 19, 20. Each holder is connected to the circuit board 16 by means of three screws 21, 22. The screws have heads with beveled side surfaces. The side edges of the holders 19, 20 resting on the heads of the screws 21, 22 are also inclined in accordance with the bevel of the heads of the screws. This design of the holders 19, 20 or the heads of the screws 21, 22 is used to adjust the holders 19, 20 and thus the counter magnets 17, 18 in or against the direction of the arrows b and c. This adjustment is made for adjustment, in such a way that the screws 21 and 22 are tightened to different degrees.

The correction magnet 15 is magnetized, for example, so that its North Pole facing axis 4. With the specified direction of magnetization of the Correction magnets 15, the magnets 17, 18 are also arranged so that their North poles facing axis 4.

In the rest position, the arrangement takes the one shown in FIG Location a. In this position, the magnets 17, 18 exercise the same size, but in opposite directions directed forces on the correction magnet 15. Now flows through the rotating coil 3 a current supplied by a photocell, not shown, the strength of which is from the brightness depends, the moving coil 3 rotates overcoming the force the return springs in the direction of arrow a. Here the correction magnet arrives 15 progressively further out of the field of the counter magnet 18 and into the field of the counter magnet 17 into it. Since this endeavors to fix the correction magnet 15 repel, is on the correction magnet and thus the carrier 10 and the moving coil 3 exerted a force opposite to the direction of rotation.

The magnitude of this force, which is always much smaller than the force which adjusts the moving coil in the direction of arrow a, is dimensioned, grows at Approach of the correction magnet 15 to the counter magnet 17 continuously. Through this repulsive effect of the counter magnet 17 is the rotation of the rotating coil 3 in the large brightnesses associated deflection area decelerated so that the same Changes in brightness associated with the angle of rotation of the coil 3 in the subject matter of the invention smaller than at the known moving coil devices are. It can be An adaptation of the characteristics of the moving coil instrument over a larger brightness range to achieve the required characteristics of the aperture.

By means of the counter magnet 18, the effect of the counter magnet 17 in the position in which no current flows through the coil 3, canceled, so that the Moving coil in spite of the force exerted on the correction magnet 15 in the same Zero position that you would assume if there were no correction and counter magnets would be provided.

In the embodiment according to FIG. 3, a moving coil instrument is included an external magnet 25 is provided. The external magnet 25 has two pole schools 26, 27 on, between which a rotating coil 29 is rotatably mounted about an axis 28. Rigid A diaphragm lamella 30 is placed on the axis 28 and is inserted into the beam path a lens 31 protrudes.

A rod-shaped carrier 32 is firmly connected to the diaphragm lamella 30. The carrier 32 could, however, also by a corresponding extension of the lamella 30 must be replaced. It is difficult to move on the rod-shaped carrier 32 a holder 33 for a correction magnet 34 is attached. The counter magnet for the In this exemplary embodiment, correction magnet 34 forms an extension 27 a of the pole piece 27. The arrangement is made so that the extension 27a forms a north pole, for example. The correction magnet 34 is then magnetized in such a way that that its north pole of the extension 27a of the pole piece 27 faces.

Supplies the photocell connected to the rotating coil 29 as a result of the incidence of light Current, the moving coil 29 rotates in the direction of arrow d and thereby increases the diaphragm lamella 30 and the carrier 32 with. This becomes the correction magnet guided in the direction of the extension 27a of the pole piece 27. The further the correction magnet 34 is introduced into the field of the extension 27a forming the counter magnet, the greater the force that tends to oppose the correction magnet 34 to adjust the direction of the arrow d. This measure, in turn, is the The deflection angle of the rotating coil from light value to light value in the great brightness associated end of the deflection area steadily decreased.

Due to the displaceable mounting of the holder 33 and thus of the correction magnet 34 on the carrier 32 there is still the possibility of an adjustment of the magnet 34 by displacement along the carrier 32 in or against the direction of the arrow undertake and thereby the between the magnet 34 and the extension 27 a of the To influence pole piece 27 acting force.

5 shows a further arrangement for influencing the deflections of the moving coil in the end of the deflection area associated with high brightnesses. For this purpose, a correction magnet 35 is placed on the carrier 10, which is rotatable about the axis 4, which in turn cooperates with a fixed counter magnet 36. The two magnets 35, 36 are magnetized here so that the same poles, for example as in the Drawing indicated the north poles facing each other. The direction in which the carrier 10 and thus the moving coil adjust with increasing brightness, is indicated by the arrow f. When rotating the moving coil and thus the correction magnet 35 there is a strong reduction in the deflections from light value to light value Moving coil when the correction magnet 35 approaches the counter magnet 36.

FIG. 6 shows an arrangement similar to the invention according to FIG. 1. In this case, a correction magnet 37 is again arranged on the carrier 10. The direction of rotation of the carrier 10 from its zero position is again indicated by the arrow f. The correction magnet 37 and a counter magnet 38, which is provided at the end of the deflection area associated with the high brightness, are arranged in such a way that they face the same poles, for example the south pole, of the axis 4. In contrast, a second counter magnet 39, which is located at the end of the deflection area associated with the small brightnesses, is reversely magnetized and arranged so that the correction magnet 37 in the zero position, in which no current flows through the coil, at the end of its z . B. is limited by a known stop deflection range. This measure ensures that, in addition to shortening the angle of rotation of the moving coil when the brightness is high, the characteristics of the instrument become steeper in the initial area, so that the lamellar movement required in this area can be achieved without using other measures to influence the moving coil characteristics.

In the embodiment according to FIG. 7, a correction magnet 40 , which interacts with a fixed counter magnet 41 , is again attached to the carrier 10. The counter magnet is arranged outside the pivoting path indicated by dashed lines and at the end of the stop area of the correction magnet 40. The direction of magnetization of the magnets 40, 41 is selected so that the same poles of the magnets 40, 41, for example the north poles, face one another. Since the magnets 40, 41 are arranged at unequal distances from the axis of rotation 4 on radii starting from this axis, they turn unequal poles toward the axis 4. In this embodiment, the shortening of the deflections of the moving coil when moving in the direction of arrow f is less than in the previously described embodiments. The compression of the deflection area of the moving coil is therefore less with high light values.

Of course, in the embodiments according to FIG. 5 and 7 effective counter magnets can also be provided at the beginning of the deflection area.

In the exemplary embodiment according to FIG. 8, a correction magnet 42 is provided and two of the two ends of the deflection area of the bearing on the carrier 10 Magnets 42 associated counter magnets 43 and 44 are provided, which consist of oxide magnets exist whose dimensions in the magnetization device are smaller than perpendicular to are. The magnetization direction of the magnets is again chosen so that the magnets 42 and 43 or 42 and 44 face each other with the same poles. Each of the magnets 43 or 44 therefore exerts a repulsive force on the correction magnet. Through this a stable zero position of the moving coil is ensured on the one hand and on the other hand when pivoting in the direction of the arrow fine similar effect as by the arrangement according to FIG. 1 achieved. The diagram according to FIG. 9 shows the dependency the angle of rotation of the rotating coils of various light meters on the strength of the light falling on the photo element. The light intensity is both in Lux as well as in light values, based on a film sensitivity of 18 ° DIN the abscissa, and the angle of rotation of the coil in degrees plotted on the ordinate. Curve I shows the characteristics of a conventional, known moving coil instrument for automatic diaphragm controls, in which the correction of the deflection characteristic is caused by the shaping of the pole pieces. Curve 1I shows the effect of a correction magnet, the one with only one end of the stop area assigned to the high brightness provided counter magnet cooperates. The curve III leaves the additional influence the moving coil characteristic by a further attractive, for example according to Fig. 6 arranged counter magnets recognize.

Claims (17)

PATENT CLAIMS: 1. Device for influencing the deflection characteristics of moving coil instruments for automatic diaphragm controls built into recording cameras, characterized in that a correction magnet (15, 34, 35, 37, 40, 42, known per se, rigidly connected to the moving coil (3, 29) ) and at least one counter magnet (17, 18, 27a, 36, 38, 39, 41, 43, 44), which is also known per se and interacting with the correction magnet, is provided and the magnets are arranged in such a way that between the magnet pair ( 15, 18, 34, 27a, 35, 36, 37, 38, 40, 41, 42, 43) at least at the end of the deflection area associated with the high brightness, an effective repulsive force that is opposite to the deflection direction of the rotating coil (3, 29) occurs. 2. Device according to claim 1, characterized characterized in that the correction magnet (15; 42) and a counter magnet (17; 44) on the beginning of the deflection area associated with the small brightnesses is arranged in this way are that between the pair of magnets a repulsive, the deflection direction of the rotating coil rectified force occurs. 3. Device according to claim 1, characterized in that that the correction magnet (37) and a counter magnet (39) are arranged so that between the pair of magnets at the beginning of the deflection area associated with the small brightnesses an attractive force that opposes the direction of deflection of the moving coil is. 4. Device according to claim 1 or 2, characterized in that the correction magnet 15; 42) and two counter magnets (17, 18; 43, 44) are arranged so that on the correction magnet in the zero position, in which no current flows through the coil, two equal, opposite, repulsive ones Forces work. 5. Device according to at least one of the preceding claims, characterized in that the correction magnet (15; 34; 35; 37, 42) and at least one counter magnet (17, 1 # 3; 36; 37, 38, 43, 44) in the same Distances from the axis of rotation (4) of the moving coil are arranged. 6. Device according to at least one of the preceding Claims, characterized in that to generate a repulsive force between the correction magnet (35; 42) and at least one counter magnet (36; 43, 44) both Magnets are magnetized approximately in the direction of rotation of the correction magnet and have the same poles the magnets are facing each other. 7. Device according to at least one of the claims 1 to 5, characterized in that to generate an attractive force between the correction magnet and at least one counter magnet have unequal poles of the magnets facing each other. B. Device according to claim 5, characterized in that that to generate a repulsive force between the correction magnet (15; 37) and at least one counter magnet (17, 18; 38) both magnets approximately perpendicular to the direction of rotation of the correction magnet magnetized and the same poles of both magnets of the moving coil are facing. 9. Device according to claim 3, characterized in that for Generation of an attractive force between the correction magnet (37) and the counter magnet (39) both magnets magnetized approximately perpendicular to the direction of rotation of the correction magnet and unequal poles of both magnets face the rotating coil. 10. Establishment according to at least one of claims 1 to 4, characterized in that the correction magnet (40) and at least one counter magnet (41) at unequal distances from the axis of rotation (4) the moving coil is arranged on radii extending from this axis and for generation a repulsive force facing unequal poles of the two magnets of the axis of rotation are, where the difference in the distances corresponds approximately to the length of a magnet. 11. Device according to at least one of claims 1 to 4, characterized in that that the correction magnet and a counter magnet at unequal distances from the axis of rotation the moving coil is arranged on radii extending from this axis and for generation an attractive force facing the same poles of the two magnets of the axis of rotation are, where the difference in the distances corresponds approximately to the length of a magnet. 12. Device according to at least one of the preceding claims, characterized in that that the correction magnet (z. B. 34) and / or a counter magnet (z. B. 17, 18), preferably by shifting in the radial direction (c, e) or in the direction of the pivoting movement the correction magnet (b); with respect to the axis of rotation (4) of the moving coil, adjustable are arranged. 13. Device according to at least one of the preceding claims, characterized in that the correction magnet and / or the counter magnets consist of oxide magnets exist whose dimensions in the magnetization device are smaller than in the direction perpendicular to it. 14. Set up after at least One of the preceding claims, characterized in that for adjusting the counter magnets (17, 18) preferably fastened to holders (19, 20) with retaining screws (21, 22) are provided with conical heads. 15. Setup after at least one of the preceding claims, characterized in that the correction magnet (z. B. 15; 34) outside the range of rotation of the moving coil (3) on a rod-shaped fixed with the coil connected carrier (10; 32), which is preferably an instrument pointer or forms a diaphragm lamella, is arranged. 16. Set up after at least one of the preceding claims, characterized in that the counter magnet is designed as an elongated pole piece (27a) of the instrument magnet (25). 17th Device according to at least one of the preceding claims, characterized in that that the magnetic fields of the correction magnet and each counter magnet are essential are weaker than the field of the instrument magnet. Considered Publications: German patent specifications No. 513 626, 650 209.