DE1094368B - Electrical capacitor with variable capacitance built up as a capacitive voltage divider - Google Patents

Description

Electrical capacitor constructed as a capacitive voltage divider variable capacitance The invention relates to a capacitive voltage divider built-up electrical capacitor of variable capacitance with electrically from each other separate stator, rotor and earth plates.

An electrical one is required for capacitive voltage division Capacitor, the partial capacitance of which is within wide limits compared to a fixed capacitor, if possible with a logarithmic characteristic, it must be changeable. Furthermore the input capacitance should remain constant when the partial capacitance is changed. About that In addition, it is desirable to have a maximum capacity that is as large as possible, i.e. small basic attenuation, to own.

Build a capacitive voltage divider using a Hollow tube on, you get a logarithmic characteristic with arbitrary small partial capacitance, but no constant input capacitance and also not a large one Maximum capacity.

The variable capacitor, in turn, has an arbitrarily high maximum capacity and can receive constant input capacitance in its form as a differential capacitor, However, it is difficult to arbitrarily and logarithmically determine the partial capacity To reduce the characteristic curve.

For example, a differential variable capacitor has become known, which consists of three sector-shaped plate groups, each one Have central angles of 1200 and are composed to a circular shape. Included at least one of the plate groups is arranged to be movable about a central axis, so that, depending on the angle of rotation, a change in the proportions the change in partial capacity given to the opposing areas. In this case, however, it is not possible to reduce the partial capacitance with a constant input capacitance in a large range, especially in the direction of extremely small values.

Another known differential variable capacitor consists of two semicircular solid plate groups that form a circular shape complement, while another sector-shaped plate group around the central Axis is rotatably arranged. This is done by symmetrical shortening of some Plates of the two fixed plate groups achieved that the change in the partial capacity when rotating the movable plate group from the one zero position is essential takes place more slowly than when turning from the opposite zero position. but in this embodiment too, a constant input capacitance is only within to achieve a limited range of the changeable partial capacity.

In the Regelkondeusator according to the invention, all four advantages are like constant input capacitance, partial capacity adjustable to very small values, large maximum capacity and logarithmic characteristic, achieved with a simple structure.

The electrical capacitor constructed as a capacitive voltage divider variable capacitance according to the invention, the electrically separated from each other Possesses stator, rotor and earth plates, is characterized according to the invention that the earth plates at a certain distance from the rotor axis a recess for have the stator plates and when the rotor is swung out between the rotor edge and the Stator plates a cavity with regular, preferably exponential field weakening form and that the rotor, according to the desired capacity profile, through corresponding plate cut when unscrewing from the stator first insert the Stator immersed surface and then changes the distance of its edge from the stator.

In particular, for a logarithmic capacity curve, the Plate section of the rotor designed so that the rotor edge in the in the stator immersing area represents a logarithmic spiral, which with decreasing Radius merges into an Archimedean spiral.

For a given non-logarithmic relationship between the angle of rotation and partial capacity then follows accordingly both the change in area in the Stator immersed rotor area as well as the exponential function of the distance between rotor edge and stator this given relationship.

In a further embodiment of the invention it is provided that the stator plates on the side facing the rotor axis towards the rotor axis in per se shield in a known manner. The stator plates expediently have the in itself be known shape of a sector of a circle, its opening angle for example is about 600.

A further development of the invention provides for the strength of the dielectric steadily between the stator and the immersing rotor in a manner known per se or to be made gradually changeable.

According to the invention, this is done by attaching additional metal or insulating plates on the stator and / or rotor. These are preferably additional plates adjustable arranged.

In the formation of the capacitor according to the invention, the essential Advantage achieved by the mutual arrangement of the rotor, stator and earth plates on the one hand there is a practically constant input capacity, while on the other hand after the rotor has been unscrewed from the stator, a defined decrease in the partial capacity takes place to the smallest values, the mode of operation of the arrangement in this case that corresponds to a high-tube voltage divider.

This is due to the fact that the plate section of the rotor after an essential feature of the invention is designed so that in a predetermined desired relationship between the partial capacitance and the angle of rotation during the pivoting out of the stator initially the one that plunges into the stator Area decreased after this connection, while after the complete pivoting out of the rotor from the stator is the exponential function of the distance to the red rim decreases from the stator according to the same relationship.

For the common case that a logarithmic relationship between the partial capacity and the angle of rotation is desired, the panel cut is then used of the rotor designed in such a way that the rotor part immersed in the stator the edge curve is a logarithmic spiral outside this range merges into an Archimedean spiral for smaller radii.

Assuming that with a the angle of rotation of the rotor, k a Constant of proportionality, C the partial capacity of the rotor against the stator, CO the maximum capacity, F the rotor area immersed in the stator, F0 the total Rotor area, x the distance of the rotor edge after emerging from the stator and fl is the degree of attenuation of the electric field between the earth plates, becomes the logarithmic relationship between the angle of rotation that is desired for example and the partial capacity expressed by the relationship in = ka CO. For those in the The area immersed in the stator results from the fact that the capacitance is proportional to the area is, the following dependency on the angle of rotation a: ln = ka.

F0 After the rotor surface has swung completely out of the stator there is a dividing effect, as it is with a capacitive hollow tube voltage divider occurs. The partial capacitance C is the distance x of the rotor edge from the stator dependent in the following way: C ~ es If one puts this relation in the formula for the desired logarithmic relationship between the partial capacity and the angle of rotation a, the relationship between x and a is as follows: k x a. fl through this However, an Archimedean spiral is described in the equation.

In the case of any given relationship between the partial capacitance and the angle of rotation, which is generally determined by the relationship is given, the relation and taking into account the dependency C - ePz for the relationship between the distance between the rotor edge and the stator and the angle of rotation a, derive the equation f (ez ka.

In the following the invention is based on a preferred embodiment explained in more detail.

Fig. 1 shows a section through the rotor axis, Fig. FIG. 2 shows a partial bottom view, while FIG. 3 shows a simplified circuit diagram is specified.

In Figs. 1 and 2, the earth plates 3, the stator plates 2 and the rotor plate 1 is shown clearly recognizable in their mutual assignment. The stator plates 2 are in the illustrated embodiment in the form of a Circle sector formed with an opening angle of 600, for example, and in a corresponding sector-shaped cutout 5 of the earth plates 3 is arranged. The attachment of the stator plates 2 to the earth plates 3 takes place here via a insulating bridge 4. The rotor plate 1 is arranged so that it can rotate about the rotor axis 7, that, depending on the position of the rotor axis 7, they are more or less in the stator plates 2 is immersed and otherwise moves between the earth plates 3. As a driving force For the rotor axis 7, a clutch disk 11 can be arranged accordingly Coupling pins 12 may be provided, which are spring-loaded onto the rotor axis 7, for example is. As can be seen from FIG. 1, the rotor is mounted by means of a Bearing body 13, which in turn is attached to the earth plate 3 facing the drive element is screwed on. The guided in a dimensionally accurate bore of the bearing body 13 The rotor axis 7 expediently has a collar 14 which is slotted on one side and clamped to the rotor axis 7 by an indicated screw connection 15 is. This collar 14 lies on insulating washers both to the Drive member facing earth plate 3 as well as on a guide surface of the bearing body 13 and thus prevents longitudinal displacement of the rotor axis 7. The fastening od the whole capacitor on a chassis. Like. Can preferably with the help of two nuts 16, 17 are made, which in a threaded extension piece of the bearing body 13 are provided.

As can be seen from FIG. 3, the input voltage Ur is between the earth plates 3 and the Rotor 1 fed what is useful over terminals 8 and 9 take place while the output voltage or the derived partial voltage U2 is removed between the earth plates 3 and the stator plates 2, what about the Terminals 8 and 10 happen. As a result of the arrangement made between the individual Plates is the input capacitance, i.e. H. the capacitance between the rotor 1 and the earth plates 3 approximately constant and regardless of whether the rotor is only is located between the earth plates 3 or also between the stator plates 2. The chosen arrangement of the stator plates 2 achieves in particular that they are to some extent embedded in the earth plates 3 and thus against the rotor axis 7 are largely shielded.

The rotor 1, which opposite the earth plates 3, the high-frequency basic voltage leads, has such a plate section in the illustrated embodiment, that its partial capacitance to the stator decreases logarithmically when unscrewing. First the rotor dips between the two stator plates with a maximum capacity of for example 6pF. When turning out by 900, the immersed surface takes up and thus the capacity logarithmically. The capacitance is then about 0.6 pF, while the rotor is almost completely immersed in the two parallel plates of the earth. The further logarithmic decrease in the partial capacitance to 0.006pF is achieved by that on the following 1800 angle of rotation the radius of the rotor according to an Archimedean Spiral decreases so that, seen from the stator, it is located between the earth plates withdraws. All in all, you have three powers of ten of the partial capacity of about 2700 angular rotation.

If the stator 2, the opposite of the earth plates 3, the divided voltage leads, does not have a very large capacity to earth, but z. B. only with the If the grid capacity of the next tube is loaded, the rotor input capacity would increase decrease when immersing in the stator. For a certain load capacity in the case of the present capacitor, this reduction in capacitance is compensated for by that by appropriate plate training and / or air gap change or by additional metal or insulating plates in the stator reduce the partial capacitance when immersed of the rotor is increased accordingly.

PATENT CLAIM: 1. Electrical constructed as a capacitive voltage divider Capacitor of variable capacitance with electrically separated stator, Rotor and earth plates, characterized in that the earth plates (3) in certain Distance from the rotor axis (7) a recess (5) for the stator plates (2) have and with swiveled out Rotor (1) between the rotor edge and the stator plates (2) a cavity with regular, preferably exponential field weakening form and that the rotor (1), according to the desired capacity profile, through corresponding plate cut when unscrewing from the stator (2) first the in the surface immersed in the stator and then the distance between its edge and the stator (2) changes.

Claims (1)

2. Capacitor according to claim 1, characterized in that for one logarithmic capacity curve of the plate section of the rotor (1), as far as it is in the stator (2) is immersed, approximately forms a logarithmic spiral, which with as the radius becomes smaller, it merges into an Archimedean spiral (Fig. 2). 3. Capacitor according to claim 1, characterized in that at one given non-logarithmic relationship between angle of rotation and partial capacity both for the change in area of the rotor area immersed in the stator (2) and also for the exponential function of the distance between the rotor edge (1) and the stator (2) the same relationship exists. 4. Capacitor according to claim 1, characterized in that the stator plates (2) on the side facing the rotor axis (7) in a manner known per se are shielded from the rotor axis. 5. Capacitor according to claim 1 to 4, characterized in that the stator plates (2) have the known shape of a sector of a circle. 6. Capacitor according to claim 5, characterized in that the opening angle of the district sector is approximately 600. 7. Capacitor according to claim 1, characterized in that the strength of the dielectric between the stator (2) and the immersed rotor (1) in is known to be continuously or gradually changeable. 8. Capacitor according to claim 7, characterized in that the change the strength of the dielectric in a known manner by attaching additional Metal plates or insulating plates on the stator (2) and / or rotor (1) takes place. 9. Capacitor according to claim 8, characterized in that the additional plates are adjustable. Documents considered: German Patent No. 713 183; Austrian Patent No. 133 629; British Patent Specification No. 201 720, 239 333, 260 035, 290 219, 326 572, 461 547; U.S. Patent No. 1,525,778.