DE1591419C - Continuously variable high frequency voltage divider - Google Patents

Description

The invention relates to a continuously variable high-frequency voltage divider one enclosed on all sides by a shielding housing Surface resistance strips and a sliding contact that can be moved along this.

With simple rotary potentiometers, such as those used as voltage dividers for direct or low frequency voltages are used and where there is not a predetermined wave resistance curve arrives along the surface resistance strip, it is known to put the resistance strip in a pot-like to arrange stationary shielding housing closed on all sides and the mechanical rotating shaft for the sliding contact and the electrical supply and discharge lines through the housing walls to lead outside. In high-frequency voltage dividers, in which the housing walls in a predetermined Distance must surround the resistance strips on all sides in order to have a predetermined wave resistance curve To make it possible to borrow along this resistance strip, the shielding housing has hitherto been made of one outer, round, cup-shaped housing surrounding the partially annular surface resistance strip and an inner, relative to the outer pot rotatable shielding cylinder is formed. This Ab-umbrella cylinder has a laterally protruding extension, which the on the surface of the resistance strip sliding sliding contact carries. Is through an opening in the jacket of the shielding cylinder this sliding contact is connected to the interior of the cylinder, and from here is via a suitable Front sliding contact of the voltage divider tap led through the shielding housing to the outside. The shielding cylinder is similar from the outside together with the sliding contact by a suitable shaft as with the usual low-frequency rotary potentiometers. Between the rotating shielding cylinder and the outer, fixed shielding pot are at the contact points more or less good sliding contacts provided. In addition, there is usually still between the beginning of the resistance strip and that adjacent end of the partially annular resistance strip in the Housing annular gap between the shielding cylinder and the outer housing pot, a shielding wall is provided, which is firmly connected to the outer housing pot and via suitable sliding contacts on the The circumference of the rotatable shielding cylinder is applied. The surface resistance strip in the annular gap has a continuous grounding on the outside strip, which is galvanically connected to the outer housing. The attenuation curve is mostly chosen exponentially.

At very high frequencies, these known high-frequency voltage dividers can no longer be implemented with high, in particular frequency-independent, attenuation values, since at high frequencies the divided shielding housing with the various sliding contacts between the housing parts no longer provides a shield that is completely tight for maximum frequency between the input end of the resistance strip and the other sections of the resistance strip guaranteed.
. The object of the invention is to create a continuously variable high-frequency voltage divider with, in particular, an exponential attenuation curve, which enables extremely high attenuation values to be set, e.g. B. allows 120 dB.

This task becomes, starting from a continuous variable high frequency voltage divider of the type mentioned at the beginning, according to the invention solved in that in the housing wall opposite the grinding surface of the resistance strip a slot that extends along this grinding surface and is relatively deep compared to its width is formed, through which the supply line to the displaceably arranged in the interior of the housing Sliding contact is passed through.

In the high-frequency voltage divider according to the invention the shielding housing surrounding the resistance strip consists of rotary potentiometers known way from a completely closed, stationary housing without any Sliding contacts between individual housing parts, so that the housing is high-frequency in a known manner can be made completely tight. A direct coupling between the input and the Sections of the resistance strip that are remote from this are thus avoided with certainty, and In this way, attenuation values of 120 dB and more can be achieved even in the MHz and GHz range. The space of the shielding housing surrounding the surface resistance strip can according to the known Dimensioning rules for a predetermined wave resistance curve along the resistance strip can be dimensioned very easily. Through the in waveguide arrangements known measure, the slot for moving the inner Forming the sliding contact very narrow and deep becomes a good high-frequency shield despite the slot of the inside of the housing.

The structure of the invention makes it possible according to a development of the invention that the Resistance strips not only on one long side, as in known constructions, but on can be earthed on both long sides. This results in a special from an electrical point of view favorable symmetrical structure. It also compensates for inhomogeneous areas of the sheet resistance and an improvement in the ground contact is achieved, resulting in even higher attenuation values possible are.

The voltage divider according to the invention can be used in are designed in a known manner in the manner of rotary potentiometers, but a structure is also according to Type of sliding resistors with a straight resistance strip and one along a straight line Slidable sliding contact possible. The sliding contact is in the latter case, for. B. in known Via a suitable spindle drive or the like, it can be displaced along the straight slot in the interior of the housing. In the case of round three-phase voltage dividers, it can be advantageous if the circular slot is at least partially through a together with the Sliding contact rotatable shielding plate sliding on the outside of the housing is covered.

In the known high-frequency voltage dividers, the one that interacts with the resistance strip Contact nipple mostly simply in a cylindrical hole of a contact spring over a cylindrical one Holding section used with more or less large play .. The guidance of the nipple in the contact spring is therefore relatively imprecise and often gives rise to malfunctions. According to a

Further development of the invention is therefore proposed that the contact nipple with a conical Form holding section and use it in a conical bore of the sliding contact carrier. In some cases it can ultimately be of advantage if it is located directly within the housing a measuring diode is arranged on the connection electrode for the high voltage. This results in a particularly compact overall structure, and by means of the measuring diode to arranged in the housing the high voltage of the voltage divider can be measured precisely in a simple manner. The measurement In the known voltage dividers, this upper voltage was only outside the shielding housing possible relatively far from the actual starting point of the resistance strip.

The invention is explained in more detail below with reference to schematic drawings of an exemplary embodiment.

Fig. 1 shows a rotary voltage divider according to the invention _ao in plan view with partly broken away housing top;

FIG. 2 shows a section along the line AA according to FIG. 1;

Fig. 3 shows in detail in a side view the as inventive holder of the sliding contact nipple.

The continuously variable high-frequency three-phase voltage divider shown in the figures consists from a shielding housing 1 closed on all sides and one in a closed annular space 1 ', the is interrupted by a transverse wall 1 ″, arranged partially annular surface resistance strips 2. The housing 1 consists of a base part 3 with a screwed-in annular groove 4 in which there is an intermediate layer of the flat resistance strip ring 2, a ring 5 also provided with an annular groove 7 is inserted is. The parts are preferably held together by a cover 6 and suitable screws. The interposed resistance strip ring 2 is thus in one formed by the annular grooves 4 and 7 Annular space, which by suitable cross-section dimensioning according to the known rules for Formation of a predetermined wave resistance curve is dimensioned.

In the housing wall 10 of the housing base part 3 opposite the resistance layer 2 is a annular slot 11 is formed which, depending on the angular range of the resistance strip ring, is only partially annular is. The feed line 12 for the sliding contact 13 protrudes through this slot 11 from 5 "" outside In the embodiment shown, a shaft 14 is rotatably mounted in the center of the housing base part 3, on the top of which a grinding arm IS is attached, to which a very thin coaxial feed line 12 is attached. The actual sliding contact 13 is mechanically connected to this sliding arm 15 via a pin 16 connected so that when the shaft 14 rotates along the surface of the resistance strip 2 is movable. The outer conductor of the coaxial supply line 12 is at the exit end from the slot 11 electrically connected to a slide spring 17 which rests slidably on the surface of the housing wall 10. The inner conductor of the coaxial supply line 12 is As shown above all in FIG. 3, electrically connected to a contact spring 18 fastened in an insulated manner on the pin 16, at the free end of the actual contact nipple 19 is attached. The nipple 19 has a conical holding portion with which it is attached to a guide part 20 attached to the spring 18 a conical hole is used. .

The inner conductor of the supply line 12 is through the upper cup-shaped part 21 of the shaft 14 out and is there with a sliding contact spring 22 in connection, which in turn with a in the center of the cover 23 of the housing arranged, outwardly guided contact pin 24 cooperates. The outer edge of the pot 21 is in sliding contact with the cover 23. The supply line is in this way through the housing by a rotary coupling designed in the manner of a coaxial line outwards. .

In some cases it can be advantageous to place the slot 11 in the areas outside the lead-through point for the supply line 12 through a cut-off plate rotatable together with the shaft 14 and the arm 15 25 to cover that via suitable sliding contacts on the outer surface of the housing base part 3 is sliding.

The connection of the resistance strip 2 to the high voltage takes place via a with the resistance layer connected terminal electrode 8, which through a bore 26 laterally through the housing after is led outside. The outer conductor of the supply line is directly connected to the shielding housing in connection. The resistance layer 2 of the sheet resistance strip is outside and inside over Grounding strips 27 and 28 are galvanically connected to the side walls of the shielding housing. In some In some cases it can also be advantageous to have a device shown in FIG. 1 schematically To connect indicated measuring diode 30 and the rectified measuring voltage through a hole lead directly out of the housing. In this way the voltage division can be the basis lying upper voltage measured very precisely directly at the beginning of the resistance layer will.

Claims (8)

Patent claims: 1. Continuously variable high-frequency voltage divider with a surface resistance strip enclosed on all sides by a shielding housing and a sliding contact which can be displaced along this, characterized in that in the housing wall (10) opposite the sliding surface of the resistance strip, a slot (11) extending along this sliding surface and which is deeper in relation to the width ) is formed, through which the supply line (12) to the \ m interior of the housing slidably arranged sliding contact (13) is passed. . '■ 2. High-frequency voltage divider according to claim 1 with a laterally full-sided earthed sheet resistance strip of in particular an exponential resistance curve, characterized in that the sheet resistance strip (2) is galvanically connected on both long sides to the shielding housing (3, 5) (earthing strips 27, 28). 3. High frequency voltage divider according to claim 1 or 2 with one in an annulus a round shielding housing arranged annular surface resistance strips, thereby characterized in that the circular slot (11) in the cut-off housing is at least partially through one that rotates together with the sliding contact (13) and slides on the outside of the housing Shielding plate (25) is covered. 4. High-frequency voltage divider according to claims Γ to 3, characterized in that the feed line (12) passed through the slot (11) to the sliding contact (13) is a thin coaxial line. 5. High frequency voltage divider according to claim 4, characterized in that the Outer conductor of the coaxial line (12) with one on the inside of the housing along the contactor edges sliding contact spring (17) is connected. 6. high frequency voltage divider according to claims 1 to 5, characterized in that the housing space (4, 7) surrounding the resistance strip (2) is dimensioned according to a desired wave resistance. 7. High frequency voltage divider according to one or more of the preceding claims, characterized in that the contact nipple (19) sliding on the resistance strip (2) is inserted with a conical holding portion in a conical bore of the displaceable sliding contact carrier (18, 20). 8. High frequency voltage divider according to one or more of the preceding claims, characterized in that within the shielding housing directly on the connection electrode (8) of the surface resistance strip (2) a measuring diode (30) is arranged for the high voltage. 1 sheet of drawings