DE1065035B - Device for increasing the mechanical strength of a gas-tight window in waveguides - Google Patents

Description

In waveguide technology, it is often useful if the pressure or the type of a waveguide section filling gas is different from the pressure or the composition of the surrounding atmosphere. In this case, however, it is necessary that the waveguide section in question, at least on one of its Ends, through a permeable to the electromagnetic energy and at the same time to the gases tight membrane or window is complete.

The invention relates to windows of this type; it extends in particular to windows that the output conductor of a detachable, high-frequency electron tube under vacuum from a Disconnect the waveguide connected to a consumer. The invention also includes windows that are used for Insulation of a piece of waveguide to be filled with a pressurized gas is used, so that this Can transmit waves of greater amplitudes or risk of breakdown.

Now, however, the influence of the reflective phenomenon occurring on the pane consisting of an insulating material and forming such a window must be reduced as far as possible. An extremely thin washer is usually used to meet this requirement. However, this leads to a considerable reduction in the mechanical strength of the window, which is all the more uncomfortable as it often has to withstand a pressure of the order of several kg / cm ² , and this in areas that, for example in the case of a frequency of 3000 MHz used standardized waveguide, can reach ^{30 cm 2.}

Although known means can be applied to the use of a thick window with a relatively high reflection coefficient disadvantages in a certain amount Reduce measure. For this purpose one must use adapting elements which are located in the vicinity of the Window are to be arranged in a certain way. Unfortunately, this procedure results in that the useful bandwidth of the system enclosing the window is narrowed.

The invention has now set itself the task of providing a device for increasing the mechanical To create strength of a gas-tight window in waveguides, which includes the useful bandwidth of them System only insignificantly.

The invention makes use of the fact that one in a waveguide perpendicular to the electrical Field arranged conductive wall of low strength practically does not affect the field. According to the invention the device has one or more perpendicular to the window whose strength is to be increased standing thin metal plates, which against the

Device for increasing
mechanical strength
a gas-tight window in waveguides

Applicant:
Compagnie Frangaise Thomson-Houston,
Paris

Representative: Dipl.-Ing. C Clemente _j patent attorney,
Deggendorf, Kranke'nhaüsstr. 26th

Bean opting priority: France from March 18, 1958

Ernest Rostas _r Paris,
has been named as the inventor

the lower pressure exposed window surface rest in a supportive manner. The cross-section of each platelet in each plane parallel to the window must be designed so that its longitudinal outlines in each point perpendicular to the direction of the electric field of the transmitted wave.

The insertion of these platelets into the waveguide does not cause any noticeable effect on the electrical Field. The wave resistance of the waveguide is also only an insignificant one Subject to change. This change can even be made particularly easy in the case of a rectangular waveguide remove. In this case, the support plates of the window are parallel to the broad sides of the waveguide. This should be within its area lying in lateral alignment with the support plates Height, d. H. have a narrow side length that is one of the total thickness compared to its normal height the support plate is increased by the same amount. The plates parallel to the broad sides of the waveguide are attached to the inner surfaces of the walls forming the narrow sides of the waveguide. These platelets can withstand fairly high forces without any disadvantage, even with very low strengths are directed parallel to the waveguide axis and are transferred to their end faces. You can therefore effectively support a window of extremely small thickness, which without such support under the

909 627/296

Claims (5)

1 influence of the pressure difference existing between one and the other side of this window would be deformed or even destroyed. Based on these arrangements, windows can be used that consist of a membrane or even a very thin film made of flexible material, for example mica or polytetrafluoroethylene, known as "Teflon" and possibly reinforced by a glass fabric. ίο The electric field prevailing in the waveguide is slightly disturbed in the vicinity of the contact surfaces between the support plates and the window, and the strength of this field increases noticeably at certain points adjacent to these surfaces. As a result, breakdowns can occur between the metal and the insulating material if the energy inherent in the transmitted wave becomes very large. This disadvantage can be avoided if further plates are arranged on the side of the window subjected to the higher pressure as an extension of the support plate. These additional compensation plates are arranged at a certain distance from the window, which is small compared to the length of the wave propagated in the waveguide. The electrical length, measured in the direction of the waveguide axis, of the unit formed by one support plate and one compensation plate, taking into account the capacitance between these plates, is preferably approximately π, measured in radians, which corresponds to a geometric length of about 112. This condition is usually sufficiently satisfied, to a reasonable approximation, when the electrical length of each plate is approximately π / 2 radians, which corresponds to a geometric length of approximately A / 4. In the drawing, an embodiment of the device proposed by the invention is illustrated schematically as an example. 1 shows a longitudinal section, drawn along the line B-B 'of FIG. 2, of a coupling connecting two waveguides, the two flanges of which are separated by a window and which has a device according to the invention. Fig. 2 shows a cross section of the coupling of Fig. 1 in the plane A-A '. The two waveguides 1 and 2 have a rectangular cross section, and it is assumed that only the waveguide 2 is filled with a gas under pressure. The outgoing ends of the two waveguides are equipped with flanges 3 and 4 of the usual shape, of which the flange 4 has an HF trap 5. In the waveguide 1, support plates or disks 6, 7 and 8 are soldered or welded to the walls of its narrow side. The end faces of these platelets, d. H. the surfaces provided for support lie in the outside plane 9 of the flange 3. Compensation plates 11 and 12 are arranged in the waveguide 2, the outwardly directed end faces of which lie in the plane 13 of the flange 4. This plane 13 is located just behind the final plane 14 of the flange 4, so that the compensation plates do not touch the insulating window 15 directly. The thickness of the platelets is such that their total thickness is equal to the sum of the wall thicknesses of the lower and upper walls of the waveguide. Its length, measured in the direction of the waveguide axis, is approximately a quarter of the length of the wave guided in the waveguide. The walls 16, 17, 18, 19 of the two waveguides forming the broad sides end within the flange structure in alignment with the free ends of the platelets located on their side. Due to this dimensioning, the free cut surface of the waveguides and their wave resistance remain unchanged in terms of size due to the presence of the platelets. The pane of the insulating window 15 is covered by an insulating film, e.g. B. made of mica, the thickness of which can be of the order of 0.1 mm. The film is clamped between the surfaces 9 and 14 of the two flanges. The tight seal is brought about by elastic sealing rings 20 and 21 which are inserted into circumferential grooves 22 and 23. The dimensions of these grooves are kept so that the respective sealing ring between the insulating film and the walls of the groove is in a compressed state when the surfaces 9 and 14 of the two flanges touch. For the sake of clarity, the clamping elements are not shown in the two figures. Patent claims: 1. Device to increase the mechanical strength of a gas-tight window in waveguides, characterized by one or more perpendicular to the window and at the one surface exposed to lower pressure supporting metal plates, their respective cross-sections is formed in each plane parallel to the window such that its longitudinal outlines at each point perpendicular to the direction of the electric field of the transmitted wave get lost. 2. Apparatus according to claim 1, characterized in that the waveguide is rectangular, a TE ₁₀ - or TE ₀₁ -wave forward and further in the vicinity of the window within its lying with the support plate in lateral area its in the direction of the electrical lines of force measured height is increased by an amount equal to the total thickness of the support plate. 3. Apparatus according to claim 1 or 2, characterized in that the higher pressure exposed side of the window is equipped with compensation plates, which are in extension the support plate in a small compared to the length of the wave propagated in the waveguide Distance from the window are arranged. 4. Apparatus according to claim 3, characterized in that in the vicinity of the window in Direction of the electrical lines of force measured height of the waveguide within it with the Compensation platelets in a laterally aligned area around one of the total thickness of these Platelet is enlarged by the same amount. 5. Apparatus according to claim 3 or 4, characterized in that the measured in the direction of the waveguide axis electrical length of the unit formed by a support plate and a compensation plate, taking into account the capacitance between these plates is approximately equal to π radians. 1 sheet of drawings