DE1023141B - Device for testing standing waves - Google Patents

Description

Standing Wave Inspection Apparatus The invention relates to to a device designed to test standing waves and a rectangular one Includes waveguide, which in turn has a Krefbogen-shaped portion and has an adjustable probe. The main object of the invention is to provide a to create such a device in which the undesired energy losses are small being held.

Devices that are used to test standing waves with a rectangular, serve within a section of a circular arc-shaped waveguide, wherein the latter is assigned an adjustable probe, is known.

In the known Meßvornchtungen a waveguide piece is for example semicircular curved, with the broad side of the waveguide parallel to a runs through the center of curvature extending axis. The one with this measuring device existing probe can be rotated about the axis passing through the center of curvature will. It protrudes into a slot on the inner broad side of the waveguide.

So the probe is perpendicular to the one through the center of curvature running axis. In addition, the energy losses caused by the probe slot do not let it stop.

This is where the invention comes into play, which is based on a device For testing standing waves with a rectangular shape within a section of a circular arc running waveguide and adjustable probe. On such a device it consists in the fact that in the area of the bend section one to the axis in the center of curvature of the waveguide vertically extending waveguide wall pivotable about this axis is and carries the probe, which protrudes into a channel of the waveguide, the swiveling home ladder wall in every swivel position the opposite one, not completely covers pivotable hollow conductor part.

In the device according to the invention, the waveguide is around his Scaled side bent. So there are the waveguide narrow lines parallel to one axis going through the center of curvature. The probe also runs parallel to this axis.

It is also attached to a waveguide wall opposite the other waveguide walls can be adjusted.

This training results in the obvious advantage, that in the device according to the invention, the previously required slot in the waveguide wall becomes dispensable. As a result, there is also no need for the device according to the invention the energy loss, as it is otherwise with the known devices due to the probe slot arises.

It is particularly favorable if the pivotable waveguide wall at least in their cooperating with the non-pivotable waveguide part Area is formed in the shape of a segment of a circle.

In order to be able to regulate the penetration depth of the probe, it is recommended to to provide this axially adjustable and relative to a determining its axial position To put the regulating screw under spring tension.

Further advantages and features are in the description below of the drawing, which illustrates an embodiment of the invention. It shows Fig. 1 the device in plan view, Fig. 2 the device without pressure elements, Seen from the side, Fig. 3 the device without pressure elements, in Be th view, 4 shows a section through the cover plate at the point of separation of the upper and lower ones Plate, FIG. 5 shows a section along the line 5-5 in FIG. 1.

The device comprises a base 1, a portion of a rectangular waveguide which is bent about a vertical axis E. Of the Waveguide has two straight sections S and B and a middle, curved section C on.

The waveguide has a web 2 d, which extends upwards. The two side walls, the web 2 d and the lower wall of the waveguide are as separate parts 2 a, 2 b and 2 c formed. The top wall of the waveguide sets consists of three cover pieces that can be removed.

The two cover pieces 2a 'and 2b' are at the end parts 2a and 2 b of the waveguide attached, the third cover piece is ats circular cover plate excellent forms; it is denoted by D and can be around the axis E. to be turned around. The cover plate D covers the entire middle part C of the waveguide and the end parts A and B, the adjacent edges of the deck stacks 2 a 'and 2b' run in a circular arc, so that a tight sliding connection between the two Endldeckstücke and the cover disc D is created. The middle part 2 c of the waveguide is held concentric to the axis E by an inwardly protruding arm 2c ', which is mounted concentrically to the axis E via the pivot 3 in the base 1.

The ends of the curved waveguide section on the stirrup side are provided with coupling flanges 2 a "and 2b" are provided with further waveguides or devices for coupling.

The cover plate consists of a lower plate 4 and an upper one Plate 5, which are kept in contact with one another by suitable means. the lower plate 4 carries the sliding plate 6, which is made of metal with high conductivity, z. B. made of coin silver, and with the plate 4 by soldering or welding connected is. The plate 6 has a smooth sliding surface aulf, which the upper Areas of the parts 2 a 2 b, 2 c covers and together with the cover pieces 2 at 'and 2 b 'forms the upper wall of the waveguide.

The plate 5 carries a disk provided with a scale with a fixed vernier scale cooperates on the plate 8, which the Pillar 1 a takes up. The cover plate D has a hole that extends into the plate 4 extends, mounted on the pivot 3. The slide plate 6 is in diameter held slightly larger than the plate 4; in its thickness it corresponds to that the cover piece 2a 'and 2b'. The adjacent edges of these cover pieces run in this way circular so that they follow the Krelisbogen-shaped outline of the sliding plate 6 snuggle up.

The plate 5 is kept larger in diameter than the plate 4. It has a 5 cd toothing on the jacket side. The assembled cover plate D can by means of the pinion 9, which engages in the toothing 5 ci, about the axis E to be rotated. The pinion 9 is mounted in the column 11 via the shaft 10. The button 12 is used for actuation.

In the plate 4 and in the sliding plate 6 a hole 4 ci is provided, which is directed to directly after the web 2 d (Fig. 3). Through this hole protrudes the probe 13 in the channel of the waveguide. The probe 13 itself is made of a thin Wire formed attached to the end of the center conductor of a coaxial line is, which is embedded in the cover plate D and with a suitable detector connected is. This is accommodated in the tubular housing 14. The top The end of the housing 14 is designed so that the detector can be connected to a suitable circuit connected to indicate the type of rectified current or voltage can be.

The cover plate or the plate 5 represents a pivotable waveguide wall that cooperate in their with the non-pivotable waveguide part Area is formed in the shape of a segment of a circle. The swiveling wall supports at the same time the probe 13, which protrudes into a channel of the waveguide.

Moreover, in every position it does not cover those facing it pivotable waveguide part completely.

The rotatable cover plate D has a rectangular recess As provided, which is opposite the probe 13. Two channels open into this recess 15 and 16, which have a circular cross-section and are partially in the plate 4, partly in the Plate 5 are provided. They are parallel to each other on opposite sides Sides of the probe 13. These channels 15 and 16 are connected by a third channel 17 connected, which is located immediately below the detector housing 14. The channel 15 leads via the channel section 15 cd to the vertical bore 4a for the probe 13.

The probe 13 is from the lower end of a perpendicular Section 13a of the detector cable held by an inside the channel 15a attached horizontal section 13b is supported. The remaining parts of the center conductor of the coaxial cable still have a section 13 c in the channel 15 and a section 13 d in the channel 17, with the detector at the midpoint of the section 13d by a vertical connection protruding into the housing 14 connected. It thus forms the free end of the outgoing from the detector 14 Line 13a, 13b, 13c, 13d directly the probe 13. Another with the end The cable section 13e connected to the line 13d is arranged within the channel 16 and at plate D at 13 f near the inner end of the channel 16 to ground placed. The different sections of the cable conductor are covered by insulating beads 18, as shown in FIG.

A hollow tube serving as a tuning needle can be used in the longitudinal direction of the Channel 15 slidably moved to who. It is equipped with a longitudinal slot for the passage of the Head section 13 c provided, so that the hollow tube 19 is a considerable part of the head section 13 c can coat. Inside the channel 16 is another one Hollow tube, which is designated by 20, is provided.

The hollow tube 20 corresponds in its design to the hollow tube 19. Die slotted hollow tubes 19, 20 made of insulating material form para tuning elements to change the effective length of the detector 14 to the probe 13 and lines 13c, 13e leading to the ground connection point 13f.

The horizontal conductor section 13 b is arranged such that its Resilience strives to move the probe 13 in the vertical direction.

However, this movement is limited by an adjusting pin 21, which vertically adjustable in one provided in the plate 5 directly above the probe 13 Bore is installed. The adjusting pin 21 is made of dielectric material and is carried by an adjusting knob 22. Ule probe 13 is thus axially adjustable and stands opposite the adjusting pin 21 with button 22, which determines its axial position under springs of preload. The adjusting knob can be opposite by means of a thread the fastening collar 23 can be adjusted. By turning the knob 22 can therefore the depth of penetration of the probe into the channel of the waveguide can be changed.

To ensure good electrical contact between the sliding plate 6 and To obtain the hollow conductor parts 2 ci, 2 b and 2 c, the rotatable cover plate is used D pressed against these waveguide parts in a number of places. Serve for this Pressure elements formed by three rollers 24 ci, 24b and 24c mounted on balls (Fig. 1 and 5). These rollers are pressed against the cover plate D by springs pressed (Fig. 5). Each roller is carried by a slidable bar 25. The lower end of the bar 25 projects beyond the horizontal table part of the base 1, wherein a compression spring 26 surrounds the bar 25 and on the one hand on the table part, on the other hand is supported on a stop 25 b on the bar. Pull the springs 26 down the bar and thereby practice one Pressure on the rotatable Plate D from. Each bar 25 is secured against twisting by means of a bolt 27.

On the cover plate D are two bent downwards into the recess Since protruding arms 28 a and 28 b attached. These form stops to limit the Rotation of the cover plate D.

This ensures that the probe 13 does not go over the curved one Section C can be moved beyond.

In the device described above, the curved section extends of the waveguide over an arc of 900. However, this is not absolutely necessary. Rather, the arch can be larger or smaller. The only thing to note is that the curved portion of the waveguide has at least a length equal to the operating wavelength at the lowest measuring frequency. For a frequency band from 10 to 40 gigahertz the curved section could for example have a length of 50 to 90 mm.

PATENT CLAIM: 1. Device for testing standing waves with rectangular, within a section of a circular arc-shaped waveguide and adjustable Probe, characterized in that in the area of the bent section one to the axis (E) the waveguide wall running vertically in the center of curvature of the waveguide (5) is pivotable about this axis (E) and carries the probe (13, 13a), which in a channel of the waveguide protrudes, the pivotable waveguide wall in each pivot position the opposite non-pivotable waveguide part completely covers.

Claims (1)

2. Apparatus according to claim 1, characterized in that the pivotable Waveguide wall (5) at least in its with the non-pivotable waveguide part cooperating area is formed as a segment of a circle. 3. Device according to claims 1 and 2, characterized by Pressure elements (24, 25, 26) which resiliently resiliently form the pivotable waveguide wall against press on the non-pivoting waveguide part. 4. Device according to claims 1 to 3, characterized in that that a detector (14) is attached to the pivotable waveguide wall (5), via a coaxial line (13a, 13b, 13c, 13d) within the pivotable Waveguide wall (5) is connected to the probe (13). 5. Device according to claims 1 to 4, characterized in that that the probe (13) is axially adjustable and determines its axial position with respect to one Regulating screw (21, 22) is under spring tension. 6. Device according to claims 1 to 5, characterized in that that the free end of the detector (14) outgoing line (13 a, 13 b, 13 c, 13 d) forms the probe (13) directly. 7. Device according to claims 1 to 6, characterized in that that from the detector (14) a further line (13 e) connected to ground goes off. 8. Device according to claims 1 to 7, characterized by Abs ti mmelemente for changing the effective length of the detector (14) to Probe (13) and lines (13c, 13e) leading to the ground connection point (13 J). 9. Device according to claims 1 to 8, characterized in that that the tuning means as slotted hollow tubes made of insulating material (19, 20) are designed and longitudinally adjustable, the outgoing from the detector (14) Probe connection line (13c) and the line leading to the ground connection point (13f) (13e) protrude through the slots into the hollow tubes (19, 20). Documents considered: British Patent Specification No. 597 262, 722 343; U.S. Patent No. 2673,963; »Electrotechn. Zeitschr. «, Ed. A, 1952, H. 18, pp. 583, 584; Journal »IRE-Transactions of Microwave Theory and Techniques ", 1955, April, pp. 38 to 41.