DE10057670C1 - Antenna element for transmission and/or reception of electromagnetic waves uses mesh embedded in flexible material of automobile tyre - Google Patents

Abstract

The antenna element is at least partially formed as a flexible mesh of conductive fibres which is enclosed by a flexible material (3) forming part of an automobile tyre (1), the antenna element positioned outside the steel girdle of the tyre, or incorporated in one of the tyre flanks and coupled to a sensor (6), e.g. a passive acoustic wave sensor.

Description

The invention relates to an antenna element according to the Preamble of claim 1.

For the determination of certain tire parameters and Driving conditions of motor vehicles such as adhesion potential, Driving and / or braking forces, slip angle and others It is necessary to set the parameters in the tires integrate and read out on the radio path. For this are Antennas necessary with the sensors in the tires can be integrated.

The desired tire measurement systems can be, for example with surface wave sensors. A corresponding one Sensor is disclosed in EP 0 937 615 A2. alternative Embodiments of radio-questionable or self-transmitting Prior art sensors are described, for example, in DE 198 60 058 C1, EP 0 746 775 B1, EP 0 655 701 B1, EP 0 651 344 B1, EP 0 619 906 B1, US 5 691 698, US S 841 214, US 5 966 008, US 5 691 698, US 5 910 779, US 6 029 324 and US 6 084 503 specified. In addition, it is also possible others, not with surface waves and / or bulk waves working sensor elements and / or sensor circuits in Bring in tires.

The arrangement of the for is problematic The radio antenna required in the tire can be queried. By the in Steel belts available in practically all modern tires different antenna types due to their Beam characteristics already out. So you can Example for truck tires with three sides on one Steel belts are provided, practically no dipole antenna integrate. With car tires, integration is one Dipole antenna in the steel belt-free flanks of the tire  possible in principle, due to the occurring there Walk movements are always undesirable Separation phenomena. Antenna types other than Dipole antennas often differ due to their voluminous structure from the small amount available in the tire Space cannot be realized.

From DE 195 29 623 A1 it is known to use the steel belt Tire to be used indirectly as an antenna. According to others in Arrangements described in this document is a coil trained antenna in the tire sidewall or the Tire treads integrated.

The object of the present invention is therefore a Antenna element for sending and / or receiving specify electromagnetic waves, especially for the Accommodation in a tire is suitable.

This task is accomplished with an antenna element Features of claim 1 solved.

By designing the antenna element as a network this is particularly easy in one on the accommodation bring the shape into the flexible material. The flexible Material is part of a tire.

The antenna element is also a flexible network trained, so it can the movements of the flexible Follow material without detaching from it tear.

The antenna element is advantageously in the flexible Embedded material, that means in particular that the flexible material around and between the stitches of the as Network trained antenna element is arranged. So there is a particularly intimate connection of the flexible Material with the antenna element, so that detachment of the  Antenna element further prevented from the flexible material becomes.

The advantages of designing the antenna element as a network come into their own in particular because they are flexible Material is arranged so that it often moves becomes. These movements are, in particular, flexing movements.

The flexible material can be a natural and / or synthetic plastic or rubber.

The mesh size of the network is preferably chosen so that it for those to be received and / or sent electromagnetic waves are essentially seamless Represents structure. Gaps in the network serve only the greater flexibility and a better connection with the flexible material. Alternatively, the mesh can also be used in this way be arranged that parts of the antenna element in a predetermined distance to act as a filter for to work at certain wavelengths.

The antenna element can be flat, in particular as a surface a patch antenna. It can go beyond that also be arched, for example, in order to get one through the to adapt flexible material to given structure.

Alternatively, the component contains a dipole antenna, which especially in the form of a slit in a flat structure a conductive network is formed.

The network of the antenna element can be conductive Build up fibers. This can be metal fibers and / or Be textile fibers, in particular in a fabric and / or Knitted fabrics are arranged. This makes one special Achieve high flexibility with robustness. Furthermore, in this training on known Manufacturing processes can be used.  

The antenna element is preferably passive Sensor, especially one with surface waves working sensor, connected. This configuration will explained in detail below.

Further essential advantages and features of the invention result from the description of exemplary embodiments based on the drawings. Show

Fig. 1 shows the arrangement of an antenna element in a tire,

Figures 2 and 3 the schematic design of a connected to the antenna element and the sensor.

FIGS. 4 and 5 the construction of an antenna that includes the antenna element.

In Fig. 1 it can be seen a tire 1 having a belt containing a steel casing 2, one is supported radially outwardly adjoining the carcass 2 protector 3, and the protector 3 profile elements 4, 5. A sensor 6 is arranged inside the rubber of the protector 3 near the carcass 2 of the tire. The sensor 6 is arranged in the region of a radially inward extension of a profile groove 7 , here a transverse groove. With this position of the sensor 6 , the force flow that occurs within the protector 3 between the two profile elements 4 , 5 resting on a roadway 8 can be measured via the pressure.

If the sensor 6 is designed as a surface wave component, it is usually of a small size in the millimeter range up to about 1 cm in length as the largest dimension. With such a size of the sensor 6, it can be easily positioned at the desired location in the tire. With such a sensor, forces, strains, compression, shear and bending movements can be measured in the smallest space. The sensor can also be positioned in a direction that is essentially orthogonal to the tangential direction. Forces in the protector 3 or in the carcass 2 can then be measured as bending movements on the sensor.

A more or less large number of sensors 6 can also be arranged distributed over the circumference of the tire, that is to say in particular over the circumferential protector, over several profile elements or over the carcass. By appropriate choice or configuration of the sensors with regard to the electromagnetic waves to be emitted with an associated coding for the respective special sensor, the electromagnetic waves emitted by this sensor and containing measured value signals can be clearly assigned to a specific sensor.

The structure of a sensor 6 is described with reference to FIG. 2. There one recognizes the sensor 6 with an interdigital transducer 9 which is supplied with an electromagnetic high frequency signal received by an antenna shown in FIGS. 1 and 3 via a feed line 10 . Via the interdigital transducer 9 , the electromagnetic high-frequency signal in a piezoelectric substrate 11 is converted into mechanical vibrations in the form of surface waves 12 and 13 . The surface wave 12 serves as a reference wave and is reflected back by a reflector 14 to the interdigital transducer. From this, the surface wave is converted back into an electromagnetic wave and transmitted to the antenna 16 via the feed line 10 . Temperature and pressure fluctuations, which act on the sensor 6 as a whole, are found both in the surface wave 12 serving as a reference and in the surface wave 13 serving for the measurement. They can therefore be eliminated by comparing the measurement results obtained for the surface waves.

The mechanical vibration used for measurement runs as surface wave 13 also through the piezoelectric substrate 11 , interacts with a reflector 15 and is reflected back by the reflector 15 to the interdigital transducer 9 . There, the mechanical vibration of the surface wave 13 is converted into an electrical signal in the form of an electromagnetic high-frequency wave and transmitted from the feed line 10 to the antenna 16 . The sensor 6 is deformed when the area of the tire in which it is used comes into frictional contact with a roadway. This changes the propagation properties for surface waves on the sensor 6 , and this change can be detected by means of a corresponding change in a signal reflected as described above.

Fig. 3 shows an alternative embodiment of the sensor 6. A capacitor 21 is connected to the reflector 15 , the value of which influences the amplitude and phase of the reflection of the surface wave 13 . This in turn has an influence on the electrical signal passed from the feed line 10 to the antenna and can thus be evaluated by a receiver arranged in the vehicle. The capacitance 21 is in turn a function of a quantity to be measured, for example a pressure, for sensor purposes.

In Fig. 1, it can be seen that the antenna 16 is connected to the one shown in Fig. 2 supply line 10 to the sensor 6. The antenna 16 is arranged outside the steel belt located in the carcass 2 in the protector 3 of the tire. In the illustrated embodiment, it is located below the tread in the tread of the tire. Alternatively, it is possible to arrange the antenna in one of the sides of the tire.

The antenna 16 will now be explained in more detail with reference to FIG. 4. There you can see the feed line 10 , via which the antenna 16 is connected to the sensor 6 . The antenna 16 itself is constructed as a patch antenna. For this purpose, it contains a first antenna element 17 , which forms a first surface of the patch antenna, and a second antenna element 18 , which forms a second surface of the patch antenna. A dielectric 19 is arranged between the two antenna elements 17 , 18 of the antenna 16 .

Furthermore, the steel belt 20 of the tire 1 is shown schematically in FIG. 4. This is located on the side of the first antenna element 17 opposite the second antenna element 18 . The first antenna element 17 forms a significantly larger area than the second antenna element 18 . This arrangement and configuration result in a radiation characteristic of the antenna 16 away from the steel belt.

The first antenna element 17 is designed as a flexible network. In its flat design, it runs with a slight curvature approximately parallel to the adjacent surface of the steel belt 20 .

The first antenna element 17 is completely cast into the rubber of the tire 1 ( not shown in FIG. 4 ) . The rubber of the tire 1 encloses the mesh of the network of the first antenna element 17 and is located between them.

The first antenna element 17 is preferably formed as a network from materials customary in the area of electromagnetic compatibility. These are fine metal grids or highly flexible conductors made of conductive textile fibers. Such conductive textile fibers can be, for example, metal fibers coated with aromatic polyamides. The coating results in high tensile strength, chemical resistance and thermal stability.

The mesh size of the antenna element 17 is so small that the antenna element represents a homogeneous surface for the electromagnetic waves to be transmitted and received.

If the sensor 6 is to be arranged below the profile in a flank of the tire 1 , the antenna 16 is preferably also arranged below the profile of the tire 1 . This avoids the effort involved in the manufacture of the tire 1 , which would be necessary if the antenna were to be arranged in a flank of the tire 1 - under certain circumstances, special support and holding measures would be required in order to provide the sensor 6 , the antenna 16 and the necessary connecting line to ensure the necessary dimensional accuracy in the tire 1 .

The feed line 10 may have to have a special design in order to be suitable for the transmission of high-frequency electromagnetic waves. It can therefore also consist of a highly flexible conductor instead of the copper wires or other metallic wires that are otherwise generally used. Compared to purely metallic wires, metallized textile fibers are characterized by their low rigidity, higher resilience, lower weight and easier processing. The feed line ( 10 ) can advantageously also be implemented in the form of a network. In all of these embodiments, the feed line 10 is in particular designed as a microstrip line, coaxial line or triplate line in accordance with common practice in electromagnetic high-frequency technology.

Fig 5, finally, shows an embodiment of the antenna 16 as a dipole antenna, which is designed in the form of a slot 22 in a planar conductive structure, which is in turn designed as a network. A network provided in this way with a slot 22 can easily be integrated into a side of the tire 1 .

All embodiments of the invention have in common that they high flexibility with a good connection at the same time ensure with the surrounding flexible material.

Claims (11)

1. Antenna element for transmitting and / or receiving electromagnetic waves, which is at least partially surrounded by a flexible material ( 3 ), the antenna element ( 17 ) being at least partially designed as a network and the flexible material ( 3 ) being part of a tire ( 1 ), characterized in that the antenna element ( 17 ) is arranged outside the steel belt ( 20 ) of the tire ( 1 ) or in one of the flanks of the tire ( 1 ). 2. Antenna element according to claim 1, characterized in that the antenna element ( 17 ) is designed as a flexible network. 3. Antenna element according to one of the preceding claims, characterized in that the antenna element ( 17 ) is embedded in the flexible material ( 3 ). 4. Antenna element according to one of the preceding Expectations, characterized, that the mesh size of the network is selected so that it is suitable for the electromagnetic to be received and / or transmitted Waves represents an essentially seamless structure. 5. Antenna element according to one of the preceding claims, characterized in that the antenna element ( 17 ) is flat, in particular as a surface of a patch antenna. 6. Antenna element according to one of claims 1 to 4, characterized in that the antenna element ( 17 ) is designed as a dipole antenna. 7. Antenna element according to one of the preceding claims, characterized in that the antenna element ( 17 ) is curved. 8. Antenna element according to one of the preceding claims, characterized in that the antenna element ( 17 ) contains conductive fibers. 9. antenna element according to claim 8, characterized, that the fibers are metal fibers and / or textile fibers. 10. Antenna element according to one of the preceding claims, characterized in that the antenna element ( 17 ) is a woven and / or knitted fabric. 11. Antenna element according to one of the preceding claims, characterized in that the antenna element ( 17 ) is connected to a passive sensor ( 6 ), in particular a sensor ( 6 ) working with surface acoustic waves.