WO2005050778A1 - Accessible area and method for creating an antenna or a screen - Google Patents

Abstract

The aim of the invention is to create an antenna (8) or a screen (16) for electromagnetically irradiating a wall (2, 14) of an area (4), especially a building. To this end, an electroconductive structure (8, 16) consisting of conductive material is sprayed onto the wall (2, 14), especially according to the flame-spraying method. Said measures enable large-surface antennae or screens to be provided for accessible areas (4) in a simple and cost-effective manner.

Description

 Description Walk-in space and method for forming an antenna or shield

The invention relates to a walk-in room, in particular a building or part of a building, with an antenna or a shield and a method for forming an antenna or a shield.

An antenna is used both for sending and receiving electromagnetic waves. For example, antennas are used to receive radio and TV stations. There are a variety of differently designed antennas, from simple rod antennas to parabolic antennas. The electrical component of the electromagnetic radiation is usually used. However, there are also antennas that use the magnetic field of electromagnetic radiation.

The antennas, for example for receiving radio and TV stations, are usually set up outside of a building and appropriately aligned. There, however, they are subject to adverse weather conditions. Indoor antennas that are arranged in the interior of the building generally have a lower reception quality than outdoor antennas.

The electromagnetic waves, which on the one hand are deliberately used to transmit information, are perceived by many people as increasingly disruptive with negative effects on health. The strong increase in transmitters and the resulting increase in the number of electromagnetic waves can also lead to technical impairments, which can lead to malfunctions and the failure of complex technical systems. For these reasons, it is often desirable that at least certain rooms are free or largely free of electromagnetic radiation.

A walk-in room is generally understood to be a lounge for people surrounded by walls, in particular a part of a building or the building. building itself. The space can also be a motor vehicle, in particular the passenger compartment, and the interior of a ship, aircraft or the like. his.

The invention has for its object to enable a simple and inexpensive design of an antenna or a shield for such a room.

The object is achieved according to the invention with the features according to claim 1. It is provided that a structure made of conductive material is sprayed onto a wall by at least one wall to form the antenna or the shield for electromagnetic radiation by a thermal spraying method.

A thermal spraying process is understood here as a thermal-kinetic application process, in particular the so-called flame spraying. Thermal spraying is generally listed, for example, in DIN 32530. In flame spraying, the conductive material to be applied, for example copper or a copper alloy, is first heated in a spray head or spray gun, so that it melts or at least softens and then sprayed onto a corresponding carrier with kinetic energy. Flame spraying is a very simple, inexpensive technique that allows individual conductor tracks to be produced in a targeted manner along any course by appropriate guiding of the spray head. To generate the discrete conductor tracks, for example, the particle beam or the like through diaphragms. bundled and focused. Manually operable spray guns can be used to apply the conductive structures. As a result, any discrete conductor pattern as well as flat, in particular full-surface patterns and structures can be produced easily and as desired.

Due to the high flexibility of the process and its robustness, this process can also be used to easily create any conductive structure on an outer wall of a room. These conductive structures are designed as an antenna or as a shield. The type of structure, for example the geometry and the course of the conductor tracks to be applied, depends on the respective according to requirements and the desired purpose. Here, wall is generally understood to mean a physical limitation of a room. This is, for example, the side wall or the ceiling of a room, or a roof area. Since a wall is used as a support for the conductive structures, there is the possibility of designing the antenna over a very large area, so that good reception quality can be achieved even if the alignment is not optimal.

According to an expedient embodiment, the conductive structure therefore also extends over a large area and in particular completely over the wall. Large area is understood here to mean that the area predetermined by the wall is used as completely as possible. If the antenna is designed, for example, as a simple loop, it essentially runs along the side edges of the wall.

To form an effective shield for the room, it is surrounded on all sides by the structure, i.e. the structure made of conductive material acting as a shield extends over all walls of the room and can also cover the floor of the room if necessary. For this purpose, the structure is expediently designed in the manner of a lattice with, in particular, a small lattice spacing, that is to say in close mesh. Alternatively, the structure completely covers the walls. In this preferred embodiment variant, the structure therefore forms a continuous, surface-applied layer. Such a coating of the walls can be applied in a simple manner by means of the flame spraying process.

According to an expedient development, the wall is constructed from individual components, these being provided with conductive sections of the structure before they are joined together to form the wall. As a result of this measure, the individual components can be provided with the conductive substructures with little effort already during production. It is not necessary to subsequently create the conductive structures on the created wall. However, there is definitely the possibility of connecting or repairing the parts of the structure by means of a subsequent spraying process if the part structures were damaged, for example during the assembly of the components. Damage is, however To be expected only in the case of very high mechanical effects, since on the one hand the selected technology, in particular flame spraying, creates a very firm and intimate connection with the surface of the component and on the other hand the structure is very flat, so that there are no protruding elements.

In an expedient development, the components are automatically contacted with one another during assembly. The components are in particular designed such that an automatic connection takes place. For this purpose, the components expediently have connecting elements. These connecting elements are preferably formed, for example, according to the tongue and groove principle by suitable shaping of the components. The mutually corresponding grooves and tongues are preferably also covered by the thermal spraying with an electrical contact surface, which in turn is part of the conductive structure.

The components are expediently roof tiles, so that, for example, an antenna structure is automatically formed when a roof is covered. The components are alternatively prefabricated wall elements.

According to a preferred development, the structure is applied to an elastic compensation layer. As a result of this measure, the occurrence of cracks in the wall, for example, does not lead to an interruption in a conductor track of the conductive structure. In this case, the elastic compensation layer serves to bridge any cracks that may occur.

The structure is preferably applied to the particularly visible outside of the wall. As a result, in addition to the technical function for forming the antenna or shielding, decorative surfaces can also be created as design elements of a building facade.

The object is further achieved according to the invention by a method with the features according to claim 12. The advantages given in terms of space and preferred configurations are also to be applied analogously to the method.

Exemplary embodiments of the invention are explained in more detail below with reference to the figures. Each shows in schematic and roughly simplified representations:

1 shows a roof with an antenna arranged in a loop on a roof surface with an associated evaluation unit,

2 is a greatly simplified representation of a cuboid room, the outer walls of which are covered with different lattice structures and with a continuous layer for shielding,

Fig. 3 is a fragmentary cross-sectional view of a wall piece, in which the conductive structure is applied to a compensating layer and

4 shows a component, in particular a roof tile, with molded-on electrical connecting elements for automatically connecting the conductive substructure formed on the roof tiles during assembly.

Parts with the same effect are provided with the same reference symbols in the figures.

1, a structure made of conductive material is sprayed onto a roof surface 2 of a roof 6 covering a space 4 to form an antenna 8. The antenna 8 is embodied here as a sprayed-on conductor track which runs in the manner of an approximately rectangular loop, the two end points 10 of which are connected to an evaluation unit 12 in a manner not shown here. The roof surface 3 at the rear in the figure is likewise provided with a conductive structure 5, which has a large or full surface area and which acts as a mirror. The received signals are processed or evaluated in the evaluation unit 12 and, if necessary, forwarded to subsequent devices.

The roof 6 is, for example, the roof of a conventional residential building. The antenna 8 extends almost completely over the entire roof surface 2, ie the loop is laid along the edge sides of the roof surface 2. By this measure A comparatively very large-area antenna 8 is formed, so that good reception quality is still achieved even with a less favorable orientation. In addition to the loop-like course of the antenna 8, this can also have any other suitable structures.

3, a structure made of conductive material is sprayed onto a side wall 14 surrounding a cuboid space 4 to form a shield 16. Two different structures are shown by way of example in FIG. 2. The upper side wall 14 is provided or coated over the entire area with a conductive material. In contrast to this, the two further illustrated side walls 14 have grids 18 or lattice patterns of different design as structures, which differ in their grating width. The grid 18 is formed here by crossing conductor tracks. The grid width, that is the distance between the individual sprayed-on webs, is to be selected appropriately depending on the radiation to be shielded. Due to the applied, in particular, close-meshed conductive structures, electromagnetic rays cannot or hardly penetrate into the interior of the room 4 or emerge from the room 4. Such shielding is suitable both for lounges or meeting rooms or for rooms in conventional residential buildings. Such a shield 16 can also be used for rooms in which highly sensitive technical devices are arranged which are to be protected against interference radiation.

A thermal spraying method, in particular flame spraying, is used in each case to apply the conductive structure, that is to say either the antenna 8 and the full-area structure 5 according to FIG. 1 or the shielding 16 according to FIG. 2. In flame spraying, the material to be applied, in particular copper or a copper alloy, is fed to a spray head or an injection mold and heated there until the material to be applied melts or at least softens. The material then leaves the spray head with high kinetic energy, so that the material to be applied hits the roof surface 2 or the side walls 14 in a particle beam. The spray parameters can be set in a wide range, so that both discrete individual conductor tracks with a defined conductor track width or flat structures can be generated. A full-surface coating takes place here, for example, by repeatedly sweeping the side wall 14 in a web-like manner. A major advantage of flame spraying can be seen in particular in its ease of use and in its robustness. The individual conductor tracks can also be applied using a manually operated device, in particular a hand-held device. The application process is based on purely physical effects and takes place without the use of chemicals. In particular, it is possible, depending on the materials and the surface on which the conductive structure is sprayed on, to spray it on without pretreating the corresponding surface. In the case of conventional building materials with a rough surface, such as stones, bricks, etc., the surface roughness generally results in very good adhesion. If appropriate, a pretreatment of the surfaces can also be provided, for example by applying a mediator or germ layer, by means of which good adhesion is established between the material to be applied and the surface. Such a mediating layer is, for example, a sprayed-on lacquer.

According to FIG. 3, the conductive structure 8, 16 is applied to a compensation layer 20, which in turn is applied to the actual wall, for example the roof surface 2 or the side wall 14. The compensating layer 20 has a certain elasticity, so that cracks 22 occurring in the wall 2, 14, for example, can be bridged without problems. The conductive structure 8, 16 therefore remains uninfluenced and undamaged by the crack 20. In particular, when an antenna 8 is formed, a crack 22 could otherwise lead to an interruption of the conductor track and thus possibly to the failure of the functionality of the antenna 8.

In the exemplary embodiment in FIG. 4, conductive material is sprayed onto a component designed as a roof tile 24. The conductive material here forms a section 25 of a conductive structure 8, 16, which is blended out by joining a plurality of roof tiles 24. The roof tiles 24 here have on their underside a bulge 26 designed in the manner of a knob or web and on their top side a receptacle 28 designed to complement them. Both the bulge 26 and the receptacle 28 are overmolded with the conductive material and thereby form complementary electrical connection elements. The bulge 26 and the receptacle 28 are on the opposite end sides of the Roof tiles 24 arranged. When the roof tiles are installed, the bulge 26 of the one roof tile 24 engages in the receptacle 28 of the roof tile 24 arranged underneath, whereby an electrical connection between the conductive structures 8, 16 of the roof tiles 24 is automatically established.

LIST OF REFERENCE NUMBERS

roof

Rear roof area

room

structure

top, roof

antenna

endpoint

evaluation

Side wall

shielding

grid

leveling layer

Crack

tile

Teilsück

bulge

admission

Claims

Expectations

1. Walk-in space (4), in particular a building, in which a structure (8, 16) made of conductive material is used to form an antenna (8) or a shield (16) for electromagnetic radiation on at least one wall (2, 14) a thermal spraying process is sprayed on.

2. Room (4) according to claim 1, wherein the structure (8, 16) extends over a large area, in particular completely, over the wall (2, 14).

3. Room (4) according to claim 1 or 2, which is surrounded on all sides for shielding from the structure (16).

4. space (4) according to any one of the preceding claims, wherein the structure (16) is designed in the manner of a grid (18).

5. Room (4) according to one of claims 1 to 3, in which the structure (16) covers the walls (14) over the entire surface.

6. Room (4) according to one of the preceding claims, in which the wall (2, 14) is constructed from individual components (24) which, before being joined together, to form the wall (2, 14) with conductive sections (25). the structure (8,16) are provided.

7. space (4) according to claim 6, wherein the components (24) are designed such that their respective sections (25) are automatically contacted during assembly.

8. space (4) according to claim 6 or 7, wherein the components (24) have electrical connecting elements (26,28)

9. space (4) according to one of claims 6 to 8, in which the components (24) are roof tiles.

10. space (4) according to any one of the preceding claims, wherein the structure (8, 16) is applied to an elastic compensation layer (20).

11. Room (4) according to one of the preceding claims, in which the structure (8, 16) is applied to the outside of the wall (2, 14).

12. Room (4) according to one of the preceding claims, in which the structure forming an antenna (8) is connected to an evaluation unit (12).

13. A method for forming an antenna (8) or a shield (16), in which a structure (8, 16) made of conductive material is sprayed onto a wall (2, 14) of a walk-in room (4) by a thermal spraying process.