KR20200009018A - High pressure resistant spiral / sine / log-per antenna with conical profile cavity structure. - Google Patents

Abstract

The present invention relates to a cavity (2), a hollow structure for arranging a balloon (5) therein, and a conical structure (7) having a hole therein; An electromagnetic absorber 8 disposed on the wall of the cavity 2 facing the conical structure 7 and a dielectric 9 filling the space between the absorber 8 and the conical structure 7. As a result of modifying the antenna cavity structures as proposed, a uniform foam / elastomer absorber (without high voltage resistance) was used in the cavity of these antennas instead of the high pressure resistant absorbent material 8 (ie, the honeycomb structure). This allowed the antenna 1 to still resist high pressure levels.

Description

High pressure resistant spiral / sine / log-per antenna with conical profile cavity structure.

The present invention relates to a high hydrostatic withstand spiral / sine / log-per antenna.

Spiral / sine / log-per antennas provide constant input impedance and radiation characteristics (e.g. gain, axial radio (helical), beam symmetry, beam width) over a very wide band range (bandwidth ratio of 18: 1 or higher). to provide. Simple spiral / sine / log-per antennas radiate in both directions. Conical versions of these antennas are alternatives for providing directional radiation, but are not preferred because the projections created on the surface of the shell in which they will be placed will prevent movement inside the air or liquid in some applications. Therefore, for applications requiring unidirectional radiation, spiral / sine / log-per antennas are typically placed in a cavity structure filled with electromagnetic absorbers. With a typical l _max / 3 (helical and sinusoidal) or l _max / 2 (log-per) diameter at the highest wavelength (at the lowest frequency) at which the antenna operates, this antenna can be "flush mounted" on a platform or vehicle. have. With this feature, this type of antenna is commonly used in electronic warfare practices.

In the case of a planar antenna, the absorber cavity is generally filled with a bubble absorber. The foam absorbent of this antenna does not provide sufficient mechanical resistance at high pressures. Placing the entire antenna on a separate breakproof, leak-proof radome can solve the breakdown voltage problem. However, this may not be an effective solution in terms of size, cost and electrical properties (eg ensuring that the radome has good electromagnetic transmission over a very wide operating band). Instead, an antenna that is itself voltage resistant may be desirable.

Honeycomb absorbers that can withstand high pressures can be used in the cavities of these antennas to create voltage resistance. However, the use of honeycomb absorbers in antennas has certain challenges with respect to their application. That is, the use of a voltage absorber as a honeycomb absorber for developing a pressure resistant cavity supporting antenna may cause problems in terms of cost, production and supply. Such honeycomb structural modeling is not easy even during antenna simulation.

The most significant disadvantage of the pressure resistant honeycomb absorber is that the honeycomb structure is due to damage to the material in other layers in the cavity (antenna card, spacer material, etc.) in the high pressure environment due to the thin wall structure. Test results at high pressure levels showed that the honeycomb structure cuts other elements in the cavity.

In addition, since these honeycomb absorbers have a heterogeneous structure, it is difficult to identify electrical coefficients such as dielectric constants and use them in antenna design. In addition, the computational simulation modeling of these honeycomb absorbers requires a lot of detail, and very high computational resources (memory and CPU power) are required to perform electromagnetic simulations of models created in this way. Since these honeycomb structures are not uniform materials, it is difficult to model them in detail and design the antenna accordingly. Failure to model this non-uniform structure creates ambiguity in antenna design, resulting in increased prototyping iterations during antenna realization / validation activities, thus increasing costs and time.

Placing the antenna supply structure in the honeycomb cell structure of such an antenna may cause mechanical problems. In general, the feeding structure of such antennas does not fit into a single honeycomb cell and requires the use of multiple cells (by cutting the wall between cells) or cutting the honeycomb structure in any direction. Such cleavage negatively affects the pressure resistance of the honeycomb structure. Also, sometimes the honeycomb cells are flat (FIG. 4B) instead of the usual hexagon (or rectangle) (FIG. 4A). This may cause anisotropy in the material properties, which may cause defects in the polarization characteristics of the antenna. For example, the axial ratio of an antenna expected to have circular polarization may be high, or other ports of a dual linearly polarized (such as sine) antenna may exhibit a different pattern (regardless of the port's 90 degree angular rotation).

Prior art US patent document US3686674 describes a microwave spiral antenna structure. The present invention includes a conical structure inserted into another metal structure. Simple cones are used to separate the balun from the antenna card, but this conical structure does not have the ability to reflect radiation to the side walls. In addition, the bottom of the cavity is also coated with an absorbent material, and the absorbent is disposed in the area between the sidewall and the cone, which is affected by high pressure levels. Therefore, in the present invention, there is no doubt about the high voltage resistance, and a new absorber layout has been proposed to correct the antenna pattern.

Reference Documents

1) Frequency Independent Backup Cavity US3192531 for Spiral Antenna

2) Broadband Spiral Antenna with Reflective Cavities of Various Sizes US3358288

3) Cavity Backup Spiral Antenna US3441937

4) Cavity Based Spiral Antenna with Mode Suppression US3555554

5) microwave spiral antenna structure US3686674

6) Multipurpose Antenna System for Submarine US3911441

7) Submarine Certified Antenna Aperture US7580003B1

8) In addition to C.Fumeaux, Finite Volume Time Domain Analysis of Cavity-based Archimedes Spiral Antennas, IEEE Transactions on Antennas and Propagation, Vol. 54, No 3, March 2006

Included in the text.

The highest pressure in the cavity backup antenna occurs in the compression direction and there is no lateral force. All vertical forces due to the pressure effect on the antenna surface are transmitted to the bottom of the antenna cavity by the sub components. With this in mind, the cavity structure has been changed to avoid the use of absorbers with high voltage resistance (eg honeycomb) in new high voltage resistant antennas. By modifying the antenna cavity as proposed, a uniform foam / elastomer absorber was used instead of the high voltage resistive (honeycomb) absorber itself, resulting in an antenna that can still withstand high voltage levels.

By using the proposed conical structure, the absorber material can be placed on the side of the cavity in an efficient manner. This new cavity structure allows the use of foam or elastic absorbers to obtain high voltage resistive spiral / sinusoidal / log antennas without using high pressure resistive absorbers.

Included in the text.

Antennas developed to achieve this purpose are shown in the accompanying drawings, which are as follows;
1 is an exploded cross-sectional view of the antenna of the present invention.
Figure 2 is a cross-sectional view of the antenna of the present invention.
3. Shapes of conical structures with different cone angles.
4. The shape of regular hexagonal and flat honeycomb structures.
Each part of the figure is numbered and the number indicates the following items.
1. Antenna
2. Cavity
3. Antenna card
4. Radom
5. Balun
6. Connector
7. Conical structure
8. Absorber
9. Dielectric
10. Support material
11. Home
12. Valve

The simplest form of the high hydrostatic withstand voltage antenna 1 is;

- Cavity 2 surrounded by base and sidewalls,

- An antenna card 3 arranged on top of the cavity 2,

- A radome 4 covering the top of the cavity 2 and the antenna card 3,

- Connector (6) connected to the balun (5) at one end,

- A conical structure (7) arranged at the bottom of the cavity, a hollow structure for placing the balun inside and a hole at the top,

- An electromagnetic absorber material disposed only on the sidewalls of the cavity 2 facing the conical structure 7 as a result of the deformation of the cavity 2 structure within the scope of the invention,

- Dielectric 9 filling the space between absorber 8 and conical structure 7

It includes.

In the preferred embodiment of the invention shown in FIGS. 1 and 2, the antenna 1 comprises a cavity 2 having a base and a side wall. The side walls shown in the figures mentioned belong to a cylindrical shape, but the invention is not limited to this shape; The walls may also belong to other shapes (eg, rectangular, pentagonal, hexagonal prisms, etc.).

In the base of the cavity 2 there is provided a hole for the connector 6 to pass through (but the invention is not so limited and the connector 6 can also be arranged on the side wall of the antenna 1). One end of the connector 6 is connected to the balloon 5 and the other end passes through a hole in the bottom (or sidewall) of the cavity 2.

The hollow conical structure 7 of the cavity 2 is arranged on the base. The conical structure 7 can be of any geometric shape (eg regular conical or triangular, rectangular, pentagonal, hexagonal pyramid, etc.).

The balloon 5 extends from the base center of the conical structure 7 towards the top and the other end of the balloon 5 (the end not soldered to the connector) passes through an opening in the top of the conical structure 7. After it is soldered to the antenna card.

The walls of the cavity 2 are coated with an electromagnetic absorber 8 which is not resistant to pressure (eg foam or elastomeric material). In addition, the homogeneous dielectric material 9 is disposed in the space between the conical structure 7 and the absorber 8. The antenna card 3 is at the top of the cavity 2. When the top of the conical structure 7 is filled with one of the pressure resistant homogeneous dielectric material 9 and the antenna card 3 rests on this conical structure 7, the pressure is indirectly through the conical structure 7 to the base of the cavity 2. Is passed to. Thus, with this conical structure 7, an absorbent body 8 which is not resistant to pressure can be arranged on the side wall (low pressure force) instead of the base (high pressure force).

The upper part of the cavity 2 is covered with a radome 4 with an inner space and an outer wall. The radome 4 has a flange surrounding the outer wall and connected to the metal cavity 2. Similarly, there is a flange on the outer wall of the cavity 2 for installing the radome 4. When the radome 4 is placed above the cavity 2, the flanges of the cavity 2 and the radome 4 come into contact with each other, and the radome 4 is inserted into the cavity 2 using screws through the holes of the flange. Is mounted. In another embodiment of the invention, the radome 4 may be mounted on an external threaded cavity 2 instead of the plan topography. In another embodiment of the invention, the radome 4 may be directly bonded onto the cavity 2.

In one embodiment of the invention, the radome 4 may be disposed directly on the antenna 1 structure, and may press the antenna card 3 without placing the pressure resistant dielectric material 9 therebetween, If necessary, in another embodiment of the present invention, the radome 4 may be disposed after placing the pressure resistant support material 10 on the antenna card 3.

The conical structure 7 with the balloon 5 therein separates the balloon 5 and the cavity 2 from each other and, as a result, interference from the inside of the cavity 2 to the balloon 5 is prevented. The actual function of the conical structure 7 is to change the radiation direction from the antenna card 3 towards the base (into the cavity 2) to the absorber 8 arranged on the inner wall of the cavity 2. This is indicated by several different cone angles in FIGS. 3A-3C. For a cone with a cone angle of 2α it can be indicated by a simple geometric beam trace, the beam reflecting the absorption (90-α) / α time from the vertical sidewall, which is the wall of the cavity to be covered by the absorber 8 (but seen Although the invention is not limited to this, the side walls may extend toward the base of the cavity 2 without being perpendicular to the base). The angle α may be reduced or increased depending on the absorption characteristics of the absorbent body 8. For example, the α = 18 ^o value is reflected four times on the absorber surface before the beam leaves the cavity (FIG. 3A). This number is 2 for α = 30 ^o (FIG. 3B) and 1 for α = 45 ^o (FIG. 3C). This control is another advantage of the proposed method. If the absorber performance is insufficient, the α angle can be reduced, so that electromagnetic waves emitted into the cavity 2 can repeatedly pass through the absorber material 8 and the performance of the antenna 1 can be improved. As a result, effective electromagnetic absorption is possible even on thin absorber surfaces.

Specific measures have been taken to ensure the waterproofness of the mentioned antennas. The first is to select hermetic connectors (6). As a result, undesirable leaks which may occur due to physical deformation (collision) of the radome 4 are limited only to the antenna 1 and leaks to other parts are prevented. Another measurement is that the gasket groove 11 is arranged on the outer wall of the cavity 2 and the flange of the cavity 2. The first is to ensure the waterproofness between the device on which the antenna 1 is to be placed and the antenna 1. The second is to ensure the watertightness between the cavity 2 and the radome 4. The need and number of these grooves 11 should be determined in accordance with the reliability requirements for airtightness.

In one embodiment of the invention, there is a valve 12 disposed on the base of the cavity 2. The valve 12 allows the air / gas flow of the antenna 1 to be controlled. Thus, the air of the antenna 1 can be replaced by dry air to prevent the humidity limitation of the antenna 1 caused by the relative humidity of the air during assembly of the components of the antenna 1.

Claims (14)

A cavity 2 having an interior space with a base and a wall, an antenna card 3 disposed above the cavity 2, a radome 4 and an antenna card 4 covering the top of the cavity 2, and one end balun A connector (6) connected to the
A hollow structure 7 arranged at the base of the cavity 2 and having a hollow structure for arranging the balloon 5 therein and a hole thereon;
An electromagnetic absorber 8 arranged on the wall of the cavity 2 facing the conical structure 7;
A dielectric 9 filling the space between the absorbent body 8 and the conical structure 7
Characterized in that it comprises a,
Antenna (1) The method of claim 1,
Antenna (1), characterized in that the absorbent body (8) is made of foam. The method of claim 1,
Antenna (1), characterized in that the absorber (8) is made of elastomeric material. The method of claim 1,
Antenna (1), characterized in that the radome (4) has an internal space. The method of claim 4, wherein
Antenna (1), characterized in that the support (10) resists pressure and fills the space of the radome (4). The method of claim 5,
Antenna (1), characterized in that the support (10) is made of a dielectric material. The method of claim 1,
Antenna (1), characterized in that the connector (6) has waterproof properties. The method of claim 1,
The antenna (1), characterized in that at least one gasket groove (11) is opened at the interface of the outer body of the cavity (2) and the unit to which the cavity (2) is to be connected. The method of claim 1,
Antenna (1), characterized in that at least one groove (11) is open at the flange of the cavity (2). The method of claim 1,
Antenna (1), characterized in that the flange is on the radome (4) and the cavity (2). The method of claim 1,
Antenna (1), characterized in that the valve (12) is arranged at the base or sidewall of the cavity (2). 12. Antenna (1) according to any one of the preceding claims, in the form of a spiral antenna. 12. Antenna (1) according to any one of the preceding claims, in the form of a sinusoidal antenna. 12. Antenna (1) according to any one of the preceding claims, in the form of a planar log-per antenna.

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