DE202014011153U1 - Slot waveguide - Google Patents

Abstract

Slotted waveguide (1), having a longitudinally extending (L) cavity (2) for guiding electromagnetic waves, which is bounded by lateral, electrically conductive walls (3), wherein at least one lateral wall (4) in the longitudinal direction (L) the slotted waveguide (1) for slotting the electromagnetic waves is slotted along the slotted waveguide (1), characterized in that the slit waveguide (1) has in cross section at least two outer sections (2a, 2b) and a central section (2c) connecting them; wherein the middle section (2c) at least in sections or over its entire width (C) has a, in particular constant, height (D) and the outer sections (2a, 2b) have a height or radius (B), the height (H) of the middle portion (2c) is smaller than the height or radius (B) of at least one outer portion (2a, 2b), and that a boundary wall (4) of the middle portion (2c) g is slotted.

Description

The present invention relates to a slot waveguide, having a longitudinally extending cavity for guiding electromagnetic waves, which is bounded by lateral, electrically conductive walls, wherein at least one lateral wall in the longitudinal direction of the slot waveguide for coupling the electromagnetic waves along the slot waveguide is slotted

A generic slot waveguide is used for information transmission along a route, in particular track-guided vehicles. The known slot waveguide has at least one slot in the longitudinal direction and is inter alia from the DE 2555909 C3 known.

Slotted coaxial conductors are used in various forms. Out DE 10 2009 061 067 A1 . DE 10 2009 052 871 B1 and DE 10 2011 119 351 A1 It is known to fasten slot waveguide laterally to a mounting rail, wherein the supported and guided by the support rail vehicle engages with an antenna mounted on the vehicle in the slot waveguide and thus on the slot waveguide, z. B. with a localized data processing, can communicate. These slot waveguides, which are additionally mounted in parallel on the carrier rail or carrier, disadvantageously require additional space, as a result of which the cross section of the carrier rail is adversely increased by the transmission line. Installation in the area of switches and turntables is problematic if not impossible due to lack of space. On such mounting rails and lateral busbars or inductive systems for power transmission to the vehicle can be arranged. Also, additional displacement measuring systems can be arranged on the mounting rail. The out DE 10 2009 061 067 A1 known slot waveguide 10 is in 1 shown in cross section. The slot waveguide 10 is by a profile body with the Längsseitenwandungen 13 - 17 formed and includes a cavity 11 as well as the longitudinal slot 12 which is often referred to as a fireplace. In the slot 12 the z. B. mounted on a vehicle antenna and couples out in the slot waveguide longitudinally propagating electromagnetic wave or feeds an electromagnetic wave in the slot waveguide.

The cross-sectional dimensions of a slot waveguide are basically inversely proportional to its transmission frequency. In order to build a slot low enough so that it does not protrude beyond the available space of a support profile, the transmission frequency can be increased. This is economically only up to a certain limit, which is currently under 6 GHz, makes sense.

The in the DE 10 2011 119 351 A1 described solution is solved for a monorail (EHB profile) of size 80 mm × 240 mm. In the case of the very popular EHB profile of the size 60 mm × 180 mm [VDI 3643], the slot-type waveguide used there would protrude beyond the available free space, thereby obstructing the movement of the vehicle.

Also is off DE 10 2004 008 571 B4 . WO 2012062435 A1 and DE 10 2010 048 586 A1 known to integrate the inner contour of the slot conductor directly into the support profile. The disadvantage here is that special support profiles must be made. It is also not possible to retrofit an existing system with a slot-type conductor integrated in a supporting profile.

In addition, Doppelsteghohlleiter are known which have been derived from the rectangular waveguides. A corresponding Doppelsteghohlleiter is in 2 shown. By constricting the central region of the originally rectangular cavity of a rectangular waveguide, two outer regions are formed 22a and 22b passing through a middle section 22c with each other over the entire longitudinal extent of the waveguide 20 are connected, wherein the height D of the central portion is smaller than the height B of the two outer sections 22a and 22b , The middle area 22c is through the two bars 25a and 26a limited, by the length A, which has not been changed relative to the original rectangular waveguide, virtually extended, resulting in an extension of the unique transmission range. If the cut-off wavelength of the H10 wave of the rectangular waveguide is assumed for λ _c , this results from the web or the constriction in the middle section 22c , In the cavity, a reduction in the lower limit frequency of the rectangular waveguide. The constriction is made by the fact that the upper and lower walls 25 . 26 in the middle area 25a and 26a be formed thicker. Of course, it is also possible to form the wall thickness of the formed as a profile double ridge waveguide constant, which then looks from the outside approximately as a double-T-beam. By reducing the lower limit frequency can be transmitted from the Doppelsteghohlleiter with the same outer dimensions relative to the rectangular waveguide electromagnetic waves with lower frequency. At the same frequency, the space required for the waveguide is thus reduced [ Cheese, Günter; Pauli, Peter: Microwave Technology: Fundamentals, Application, Measurement - Franzis 1991, Chap. 2.4.2 ].

The object of the present invention is to further develop a slot waveguide such that it is smaller in size than conventional slot waveguides, wherein the frequency of the transmission signal is smaller than the signal frequency with correspondingly small slot waveguides of known design.

This object is achieved with a slot waveguide with the features of claim 1. Further advantageous embodiments of the slot waveguide according to claim 1 result from the features of the subclaims.

The inventive idea is to provide a Doppelsteghohlleiter with a longitudinal slot, similar to known slot waveguides. By using the principle of Doppelsteghohlleiters instead of the rectangular waveguide advantageously the space required for the slot waveguide is reduced at the same frequency. Through the longitudinal slot now also a signal pick along the Doppelsteghohlleiters is advantageously possible.

It has been shown that the two outer sections do not necessarily have to be rectangular. Rather, a round in cross-section, in particular circular or elliptical, embodiment of the two outer sections is possible. Also, the walls bounding the middle portion need not necessarily be flat. It is also possible that the height of the middle section over the length of the middle section, d. H. from the one outer portion toward the middle and the other outer portion. This can be done continuously or in jumps. It is thus possible for the upper and / or lower walls delimiting the middle section, if the slot is arranged at the top or bottom, to be round, curved or triangular in cross-section.

The two outer sections do not have to be identical. Thus, the cross-sectional area of one outer portion may be greater than the cross-sectional area of the other outer portion. It is only necessary that the height of at least one outer portion is greater than the height of the central portion.

By means of the principle according to the invention, it is possible to realize a slot waveguide with dimensions of 21 mm × 40 mm, wherein the frequency of the signals may be less than 6 GHz. This is z. B. advantageously possible to arrange the slot waveguide for information transmission along the support rail of a small electric monorail in the space for contact rails, without the slot waveguide engages in the travel of the monorail systems. Due to the advantageously small dimensions of 21 mm × 40 mm, the slot waveguide can be easily bent. The slot waveguide can thus advantageously also be arranged along the horizontal and vertical curves customary in small-suspension overhead conveyors.

Various possible embodiments of the slot waveguide according to the invention will be explained in more detail with reference to drawings.

Show it:

1 : Slot waveguide according to the prior art;

2 Double ridge waveguide according to the prior art;

3 : Cross section through a first possible embodiment of a slotted waveguide according to the invention;

4 : Perspective view on the front side of a waveguide according to 3 with an antenna arrangement engaging in the slot;

5 : Cross section through a second possible embodiment of a slotted waveguide according to the invention;

6 : Perspective view on the front side of a waveguide according to 5 with an antenna arrangement engaging in the slot;

7 : Cross section through a third possible embodiment of a slotted waveguide according to the invention with curved boundary walls of the middle section;

8th : Cross section through a fourth possible embodiment of a slotted waveguide according to the invention, whose cavity corresponds in cross section to a round dumbbell;

9 : Cross-section through a modified embodiment of a slotted waveguide according to the invention compared to the second embodiment;

10 : Cross section through a fifth possible embodiment with outlet channels;

11 : Cross-section through a sixth possible embodiment, wherein the cavity of the conductor is partially foamed in the longitudinal direction or filled with a dielectric material;

12 : Cross section through a seventh possible embodiment, wherein the height of the slot is extended by externally molded or fixed fireplace walls.

The 3 shows a cross section through a first possible embodiment of a slotted waveguide according to the invention 1 , The cutoff frequency of the waveguide according to the invention is determined by the dimensions of the waveguide sections 2a . 2 B and 2c , The two outer sections 2a and 2 B have a height B and the middle portion of the height D. Because the two outer sections 2a and 2 B are substantially rectangular in shape, with only slightly rounded corners, the width C of the upper projection V _{3 is} equal to the sum of the widths of the projections V ₁ and V ₂ and the slot width S. The slot height S _H is given by the height of the projections V ₁ and V ₂ . The larger the slot height S _H , the lower the radiation from the slot 6 , The slot itself has only a minor effect on the cutoff frequency of the waveguide 1 , So that in principle for the dimensioning of the waveguide the same formulas as for the well-known from the literature and sufficiently described and explored Doppelstegrechteckhohlleiter apply, since the walls W ₁ -W ₇ are flat.

The 4 shows a perspective view of the front side of the waveguide 1 according to 3 with one in the slot 6 engaging antenna assembly A, which is arranged at the free end of the supply line Z. The antenna order A may be in the slot 6 be freely moved in the longitudinal direction L of the waveguide and coupling signals and decouple.

The 5 shows a cross section through a second possible embodiment of a slotted waveguide according to the invention 1 in which the length C of the upper web V _{3 is} smaller than the sum of the lengths or widths E and S of the projections V ₁ and V ₂ and of the slot 6 , By this measure, the two outer sections 2a and 2 B no longer purely rectangular in cross-section, whereby the mode training given the embodiment according to 3 changed. By choosing the ratio C / D, the cutoff frequency and the broadband of the waveguide according to the invention 1 to be influenced. 6 shows the perspective view of the front side of a waveguide 1 according to 5 with an antenna arrangement A. engaging in the slot

The 7 shows a cross section through a third possible embodiment of a slotted waveguide according to the invention 1 in which the boundary walls W ₁ , W ₂ and W ₃ , which are formed by the projections V ₁ , V ₂ and V ₃ , are curved. Due to the nature of the curvature and the choice of the radii of curvature of the curved boundary walls W ₁ , W ₂ and W ₃ , the mode formation can be influenced since the height D changes continuously over the web width C.

The 8th shows the cross section through a fourth possible embodiment of a slotted waveguide according to the invention 1 whose cavity 2 in cross section corresponds to a round dumbbell. The cross sections of the two outer sections 2a and 2 B can also be circular.

If the waveguide is mounted in the orientation shown, it may be in the two outer sections 2a and 2 B Collect moisture. So that the moisture does not disturb the signal transmission, several drainage channels AK at the lowest points of the lower walls 11 , In particular in the form of holes, be incorporated.

As in 9 shown, it is also possible, the boundary wall W ₃ curved and the opposite walls W ₁ and W _{2 form} flat. It should be noted, however, that the ratio between the height H _V3 and the slot height S _H significantly the radiation from the slot 6 determined out. In this case, the smaller the height H _V3 in relation to the slot height S _H , the lower the radiation.

The 10 shows a fifth possible embodiment, this according to the first embodiment according to 3 corresponds, which is provided with outlet channels AK. If the waveguide is arranged rotated by 90 °, the outlet channels can also be in the walls 8th or 9 be provided.

The in 11 illustrated waveguide 1 has a at least partially longitudinally foamed cavity 2 , wherein the foam is preferably a dielectric with ε _{r is} approximately equal to 1. Filling at least the two outer sections 2a and 2 B causes them to not pollute or to fill with moisture, especially condensation.

The 12 shows a cross section through a seventh possible embodiment, wherein the height S _{H of} the slot 6 is extended by externally molded or fixed fireplace walls W _S and thereby the radiation through the slot 6 can be reduced compared to the embodiments described above. Through the chimney walls W _S builds the waveguide 1 but higher, which may be undesirable, which is why should be dispensed with the fireplace walls W _S in the rule.

It goes without saying that other cross-sectional shapes for the cavity 2 possible are. For the purposes of the invention, all the slotted waveguide, which is a constricted middle range 2c have to achieve a lower lower limit frequency with respect to one of the outer dimensions of the same rectangular waveguide, so that the waveguide advantageously having a smaller dimensions.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 2555909 C3 [0002]
• DE 102009061067 A1 [0003, 0003]
• DE 102009052871 B1 [0003]
• DE 102011119351 A1 [0003, 0005]
• DE 102004008571 B4 [0006]
• WO 2012062435 A1 [0006]
• DE 102010048586 A1 [0006]

Cited non-patent literature

• Cheese, Günter; Pauli, Peter: Microwave Technology: Fundamentals, Application, Measurement - Franzis 1991, Chap. 2.4.2 [0007]

Claims (14)

Slot waveguide ( 1 ), with a longitudinally extending (L) cavity ( 2 ) for guiding electromagnetic waves, which of lateral, electrically conductive walls ( 3 ) is limited, wherein at least one lateral wall ( 4 ) in the longitudinal direction (L) of the slot waveguide ( 1 ) for coupling the electromagnetic waves along the slot waveguide ( 1 ) is slit, characterized in that the slot waveguide ( 1 ) in cross-section at least two outer sections ( 2a . 2 B ) and a middle section connecting them ( 2c ), wherein the middle section ( 2c ) at least in sections or over its entire width (C) one, in particular constant, height (D) and the outer portions ( 2a . 2 B ) have a height or radius (B), the height (H) of the middle section (B) being 2c ) is smaller than the height or the radius (B) of at least one outer portion ( 2a . 2 B ), and that a boundary wall ( 4 ) of the middle section ( 2c ) is slotted. Slotted top conductor ( 1 ) according to claim 1, characterized in that the cross-sectional shape and the dimensions of the sections ( 2a . 2 B . 2c ) in the longitudinal direction (L) of the slot waveguide ( 1 ) are constant. Slotted top conductor ( 1 ) according to claim 1 or 2, characterized in that the slot conductor ( 1 ) is a profile body. Slotted top conductor ( 1 ) according to one of the preceding claims, characterized in that the outer sections ( 2a . 2 B ) have a rectangular, circular or elliptical cross-sectional shape. Slotted top conductor ( 1 ) according to one of the preceding claims, characterized in that the cavity of the slot waveguide ( 1 ) in cross-section dumbbell-shaped or I-shaped or is formed corresponding to a double-T-carrier, wherein the connecting web the middle section ( 2c ). Slotted top conductor ( 1 ) according to one of the preceding claims, characterized in that the middle section ( 2c ) is formed by means of inwardly projecting projections (V ₁ , V ₂ , V ₃ ), which are rectangular in cross-section, wherein the projections (V ₁ , V ₂ , V ₃ ) at the same time with their sides (V _1s , V _2s , V _3s ) side walls of the outer sections ( 2a . 2 B ) form. Slotted top conductor ( 1 ) according to claim 6, characterized in that the two material projections (V ₁ , V ₂ ) the slotted wall ( 4 ), wherein the two material projections (V ₁ , V ₂ ) each have a width (E) and the slot ( 6 ) have a width (S). Slotted top conductor ( 1 ) according to claim 6 or 7, characterized in that the sum of the widths (E, S) of the two material projections (V ₁ , V ₂ ) and the slot ( 6 ) is greater than or equal to the width (C) of the upper material projection (V ₃ ). Slotted top conductor ( 1 ) according to one of claims 6 to 8, characterized in that the edges (K) of at least one material projection (V ₁ , V ₂ , V ₃ ) are rounded. Slotted top conductor ( 1 ) according to one of the preceding claims, characterized in that the slot waveguide ( 1 ) is a slotted double bridge rectangular waveguide, wherein the connecting web ( 7 ) of the double-bar rectangular waveguide is formed slotted. Slotted top conductor ( 1 ) according to one of the preceding claims, characterized in that in the walls ( 8th . 9 . 10 . 11 ) Drainage channels (AK), in particular at non-equidistant intervals and / or formed by holes, are arranged. Slotted top conductor ( 1 ) according to one of the preceding claims, characterized in that at least the outer sections ( 2a . 2 B ) and / or the middle section at least partially or completely with a dielectric material (FÜ), in particular foam, are filled. Slotted top conductor ( 1 ) according to one of the preceding claims, characterized in that the slot ( 6 ) by both the projections (V ₁ , V ₂ ) and / or by outer on the outer wall ( 11 ) formed or fixed wall sections (W _S ) is formed. Slotted top conductor ( 1 ) according to one of the preceding claims, characterized in that the height (D) in the region of the central portion ( 2c ) over the length (C = 2 * E + S) of the middle section ( 2c ), ie starting from the one outer section ( 2a . 2 B ) towards the middle and the other outer section ( 2 B . 2a ), changes.

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