DE1034721B - Angled, rectangular waveguide - Google Patents

Description

The invention relates to waveguides angled over the broad side, so-called E-corners.

It is known that in order to avoid a larger point of discontinuity in the case of an angled waveguide its outer corner beveled. It is used to compensate for the remaining discontinuity Up to now it has been customary to add a reactance representing the discontinuity Reactance with the opposite sign in the form of a tuning stub or a membrane compensate.

It is also known to deflect round waveguides, which are used to propagate E ₀₁ waves, by continuously curved elbows. In this case, a tuning screw is arranged in the outer wall of the elbow, the task of which is to prevent other wave shapes from occurring in the elbow.

A disadvantage of the known angle pieces, however, is that the type of compensation is very strong is frequency dependent. The optimal values for the absence of joints with such a contra-angle handpiece provided waveguide can only be achieved for a relatively narrow frequency band.

With the invention, this disadvantage is eliminated and a broadband compensation of waveguide corners achieved. It is based on the following considerations: A small discontinuity in a waveguide comes in its effect of inserting a small reactive component at a certain point same in the waveguide; Furthermore, a small inductance corresponds to being connected in series with the waveguide practically a capacitance connected in parallel to the waveguide and vice versa. So can any discontinuity as a negative reactive component (reactance or reactance) acting at a certain point can be understood, and to compensate for it, an equal amount can be used in the same place large but positive dummy component must be attached. Such compensation is broadband. Conversely, an inevitable discontinuity in the waveguide, that of a series or Parallel inductance or capacitance, by suitable insertion of a negative reactive component be compensated at the point.

Conventional measuring methods for determining the ripple can be used in the desired frequency band the location of the reactive component corresponding to a discontinuity in the waveguide can be determined.

To understand this method, it is important to clearly distinguish between a negative one Reactance or reactance value and a negative reactance or reactance value switching element. As is known, a negative blind

Angled, rectangular waveguide

Applicant:

International Standard Electric
Corporation, New York, NY (V. St. A.)

Representative: Dipl.-Ing. H. Ciaessen, patent attorney,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Claimed priority:
Great Britain 12 January 1951

Leonard Lewin, Albert Edwin Pethick

and John Bernard Setchfield,

Aldwych, London (Great Britain),

have been named as inventors

represent conductance by a positive capacitance, i.e. by a capacitor. A negative blind reluctance, stand can also be represented by a negative inductance, but this cannot be represented by a actual switching element can be realized ^ " although, as already described, the effect of a small negative inductance by a corresponding located actual switching element can be achieved. A negative susceptance can either be by a positive inductance or by a non-objective negative capacitance.

Accordingly, an angled rectangular waveguide is created with the invention, in which the The increase in the wave resistance caused by the bending of the outer corner is compensated in this way is that the outer corner is cut away and reduced by one of the cross-section at this point inclined side wall is replaced, and which is characterized in that the distance of the inclined side wall from the inner corner of the waveguide larger than to achieve a maximum Voltage ratio required at the center frequency is selected and that an adjustable Screw in the middle of the sloping side wall of this section between the two adjacent ones Waveguide legs is inserted so far that this creates a positive parallel capacitance for adjustment and for complete compensation of the wave resistance present in the parting plane on the

809 578/325

The value that the two adjacent waveguide legs have is reached.

With reference to the drawing, FIGS. 1 and 2, which illustrate an embodiment, the invention explained in more detail.

1 and 2 show a waveguide angled over the broad side;

Fig. 2 is a view towards an open end of the corner, and Fig. 1 shows a section along that line Line 4-4.

The basis of the invention is explained as follows: If we assume that a small discontinuity is present at any point in a waveguide, this discontinuity has the same effect as a small reactive component at a certain point in the waveguide. If this reactive component corresponds to a small series inductance L , then the impedance Z that is present at the discontinuity is Z ₀ + j ω L, where Z _{0 is} the wave resistance of the waveguide and ω is the angular frequency.

The corresponding admittance value is approximated by

Currently ₀

where F ₀ = - = - if ω L is small compared to

Z is ₀ .

The susceptance term can be viewed as being a small negative capacitance LY ₀ ^{2 turned on in} parallel with the waveguide. This can be completely neutralized by connecting a positive capacitance equal to LF ₀ ² to the waveguide in parallel. The neutralization is frequency-independent. In the same way, a discontinuity, which corresponds to a small parallel capacitance, is equal to a negative series inductance, and could be compensated for by an identical positive inductance which is connected in series with the waveguide.

1 and 2 show a rectangular Hohdleiter angled over its broad side, a so-called Ε corner. When the outside angle is tapered according to known practice, the point of discontinuity is for the transmission of narrow frequency bands usually already sufficiently small. For the Transmission of wide frequency bands with small ripples, however, requires additional compensation. As such, the exact dimensions of the bevel can theoretically be easily determined. However, the tolerances of these dimensions are very tight, so that it is difficult in practice to produce all of them To give corners the same electrical properties.

According to the invention, the depth of the corner portion is chosen so that it is parallel to the waveguide a small negative capacitance occurs, and this is then replaced by an adjustable positive capacitance which is formed by a screw, neutralized.

The Ε corner shown in FIGS. 1 and 2 consists of two short waveguide parts 10 and 11, the flanges 12 and 13 have fastening holes 14. The outer angle is cut off and through a plate 15 closed, through which a screw 16 protrudes, which along the central bisector line is centered.

The perpendicular distance d between the plate 15 and the inner angle 17 is somewhat greater than it would be chosen in the absence of the screw 16 in order to obtain maximum ratios in the middle of the frequency band for which the corner is designed. A small increase in the dimension d is practically equivalent to the inclusion of a small negative capacitance in parallel with the waveguide at the corner, which can then be neutralized by suitable adjustment of the screw 16, which represents a positive capacitance at the corner.
As a result of manufacturing variations, the

ίο vary effective parallel negative capacitance over a small range, and provided that the delay in d is sufficient to cover the variations, screw 16 can always be adjusted to produce the desired result.

In practice, when the Ε-corner is accurately made, there is a very good match to the waveguide, but small changes in d produce an essentially uniform mismatch across the

ao whole frequency band. By making d a little too large, the screw 16 can always be adjusted so that the exact fit is restored over the entire band.

For a waveguide with the dimensions

As 50 x 16 mm and a frequency band of 7 to 8.4 cm wavelength to be transmitted, the dimension d in the absence of the screw was 13.67 mm, while the exact dimensions for the electrical requirements deviate from this value by 0.025 to 0.05 mm could. Maintaining this precise value d during manufacture was very difficult, so d was increased to 14.25 mm and a screw 16 was also provided. In this case the limits for d could be widened to ± 0.25mm and all corners could then be adjusted by means of the screw to meet the electrical requirements.

It will be understood that it is necessary to build up the corners in exactly the same manner as shown in Figs. These figures do not contain any construction details. It is Z. B. It is not necessary to cut off the outer angle and cover the opening with a plate. The whole corner could also be poured to have the necessary internal shape. If it has been stated so far that the outer angle is cut away, this only means that the corner has the inner formation, as shown in FIGS. 1 and 2 is shown.
The screw 16 should have lock nuts (not shown) so that it cannot change after the final adjustment.

Claims (3)

Patent claims: 1. Angled rectangular waveguide in which the angled outer corner Occurring increase in the wave resistance is compensated in such a way that the outer corner cut away and replaced by an inclined side wall reducing the cross section at this point is, characterized in that the distance between the inclined side wall from the inner corner of the Waveguide larger than to achieve a maximum voltage ratio at the center frequency required is chosen and that an adjustable screw in the middle of the bevel Side wall of this section between the two adjacent waveguide legs like this It is far inserted that this creates a positive parallel capacitance for adjustment and complete Compensation in the parting line existing wave resistance to the value that the two adjacent waveguide legs have, is reached. 2. Waveguide according to claim 1, characterized in that that the screw is centered along the central angle line. 3. Waveguide according to claim 1 or 2, characterized in that the screw with lock nuts is provided. Documents considered: French patents nos. 950 269, 950 844, 781, 961 087, 962 827, 982 404, 982 997, 984 968; U.S. Patent No. 2,411,338; British Patent No. 637 109; "Electrical engineering", January 1948, p. 6. Older patents considered: German Patent No. 871 324. 1 sheet of drawings