EP1476956B1 - Device for transmitting signals between mobile units - Google Patents

Abstract

A device for signal transmission between units that are movable along given tracks comprises at least one transmitter for generating electrical signals, at least one conductor arrangement for conducting the electrical signals along a track of movement, and at least one receiver for coupling out electrical signals from a conductor arrangement. At least one conductor arrangement comprises at least one conductor structure for conducting electrical signals, an electric reference surface assigned thereto, and at least one dielectric between the conductor structure and the reference surface. A dielectric of the kind used has a high homogeneity, or a high symmetry with respect to the electrical center of the longitudinal axis of the conductor structure, or both.

Description

Technical area

The invention relates to a device for transmitting electrical signals or energy between a plurality of mutually movable units.

For the sake of clarity, no distinction is made in this document between the transmission between mutually movable units and a stationary and movable unit, since this is only a question of location reference and has no influence on the operation of the invention. Likewise, no distinction is made between the transmission of signals and energy, since the mechanisms of action are the same here.

State of the art

In the case of linearly movable units such as crane and conveyor systems and also with rotatable units such as radar systems or computer tomographs, it is necessary to transmit electrical signals or energy between mutually movable units. A device suitable for this purpose is disclosed in German Offenlegungsschrift DE 44 12 958 A1. The signal to be transmitted is fed here into a strip line of the first unit, which is arranged along the path of movement of the mutually movable units. By means of capacitive or inductive coupling, the signal is tapped from the second unit. An improved device for transmission, as described, for example, in WO 98/29919, is based on a special conductor structure which simultaneously has filter properties. With such structures, it is possible to realize extremely broadband transmission systems in the range of a few MHz to GHz. In the following embodiments, the term ladder structures refers to all conceivable forms of conductor structures which are suitable for carrying electrical signals. The signals are decoupled in the near field of the conductor structure. The signal extraction should ideally take place only in the area of the second unit. A further signal transmission in other areas of the conductor structure is usually undesirable in contrast to the known leakage lines, since the broadband signals can lead to disturbances in other equipment parts or devices.
The design and sizing principles of leakage lines, such as described in US 5,936,203, are not applicable to this type of conductor structures. Leakage lines are currently designed to radiate a certain portion of the guided RF energy over the entire length to the outside. But this is exactly what should be avoided here.

Technically similar to the contactless signal decoupling is also the contacting signal decoupling. A However, contactless decoupling is usually preferred because it is more reliable and maintenance free.
The conductor structures described here can be made either contact or contactless. Of course, adjustments according to the transfer task are possible. Thus, a conductor structure for contacting transmission have a particularly good conductive surface, for example with silver coating. In contrast, a conductor structure for contactless transmission can be provided with a lacquer layer on the surface as corrosion protection. However, the basic principles for designing the ladder structures are identical in these cases. A particular embodiment of a contacting transfer device is described in U.S. Patent No. 5,208,581. Here also an unbalanced conductor system is described. Although the geometry is symmetrical here, the conductor system is fed with an unbalanced signal. The signal flow takes place via the middle conductor from the transmitter to the receiver and partly via one or both outer conductors or else the computed tomography system itself. The reference surface here is the device itself. The geometry of the reference surface is not clearly symmetrical here.
Due to the asymmetrical signals with an ambiguously defined signal path and the undefined reference surface, this system radiates high RF power. Even with data rates of 50 MBaud, the current EMC standards can no longer be met without additional, expensive shielding.

The conductor arrangements used here for the transmission are usually constructed as strip lines or conductor structures by means of double-sided printed circuit boards. As a carrier and dielectric is usually a glass fiber reinforced plastic. This support is provided on one side with a continuous conductor surface as electrical reference surface or ground and on the other side with a strip-shaped conductor or the conductor structure.

Among the most difficult technical problems with such transmission systems is the achievement of high immunity to interference and low radiation.
In order to achieve a particularly interference-free signal transmission, for example, two parallel lines or conductor structures are fed symmetrically with a differential signal. As a result, the distance field is at least approximately zero at conductor distances which are smaller than the wavelength. Thus, only a very low energy is emitted. In the opposite case, the unwanted coupling of electromagnetic waves from the outside in both conductors generates the same signal. This can now be filtered out by a receiving circuit with high common-mode rejection. Essential for a high immunity to interference is the symmetry of the entire arrangement.

In order to increase the immunity to interference, the signal level of the transmitter can not normally be increased arbitrarily. Despite high symmetry always a low radiation takes place. With higher symmetry, the radiation is reduced and the signal levels can be further increased.

At high bandwidths or data rates in the range of a few 100 MHz to several GHz, no longer negligible attenuation or distortion of the signals occur. For example, with standard conductor materials and a frequency of 1 GHz, attenuations of the order of 10 dB per meter were measured. This leads to unacceptable attenuation for long lengths. There is also an increased risk of asymmetries. Often, the lines or conductor structures are manufactured in widths of several millimeters to centimeters, so that the mechanical tolerances in the web between the moving parts can be quite a few millimeters, without affecting the signal transmission. Such wide conductor structures are particularly sensitive to changes in the properties of the dielectric. Thus, particularly high demands are placed on the homogeneity of the dielectric, since changes in the thickness, the dielectric constant and also the loss factor affect the propagation of the signal, the symmetry and also the emission properties. Thus, the dielectric must be very homogeneous over the length and especially over the width of the array. Standard circuit board materials do not meet these requirements by far. Even special printed circuit board materials, such as those used for high-frequency engineering printed circuit boards, are often unsuitable here. For common use in small geometry circuit boards such as 50 mm * 50 mm and strip lines with widths in the range of 1 mm, the variations in material properties are of little importance. Suitable, prior art materials such as special, particularly homogeneous Teflon or ceramic materials are problematic in processing and very expensive. The main problem with such materials, however, is that they are not available in the required long lengths of a few meters. These are available in typical plate sizes of 50 cm * 50 cm. So it would have to be developed new manufacturing processes for the production of conductor assemblies with the above-described high quality materials in long lengths. Alternatively, short segments of the conductor assembly could be interconnected lengthwise. The necessary connection points or solder joints cause a high production cost, usually have reflections and asymmetries at the site of the connection result and reduce the reliability of the entire conductor arrangement significantly.

One solution that avoids these problems from the outset is disclosed in U.S. Patent No. 5,287,117. Herein, the conductor assembly is replaced by a plurality of small antenna segments. These can be manufactured on PCBs of small area with high quality materials. The power supply over long distances can be achieved with high-quality coaxial cables of high shielding and low attenuation. However, here too, the high number of antenna segments results in a high use of material and in particular a high assembly outlay, which leads to high production costs.

US 2002/000936 A1 discloses a broadband microstrip line antenna having a structure of a coated dielectric, one of these layers comprising air.

In DAIGLE, B. "Printed circuit board material and design considerations for wireless applications" ELECTRONIC COMPONENTS AND TECHNOLOGY CONFERENCE; May 28, 1996 (1996.05-28), - May 31, 1996 (1996-05-31) pages 354-357, XP010167266, tolerance ranges of the dielectric constants of known microwave materials of ± 0.02 to ± 0.05 are given.

US 5,463,404 discloses a microstrip antenna having materials having a dielectric constant tolerance of about 5%.

Presentation of the invention

It has as its object to represent a broadband and cost-effective device for signal transmission, which has a conductor arrangement with conductors or conductor structures, which achieves high signal symmetry and low attenuation values even at high frequencies.

The object is achieved according to the invention with the means specified in the independent claims. Advantageous development in the invention are the subject of the dependent claims.

An inventive device for signal transmission comprises at least one transmitter which generates the electrical signals to be transmitted and feeds them into a conductor arrangement. At least one such conductor arrangement is arranged along the path of the movement and carries the signals fed by the transmitter. At least one receiver, which is movable relative to the transmitter and the conductor arrangement, serves to decouple the signals from the conductor arrangement. Depending on the application, a transmitter can also feed several conductor arrangements. Likewise, a conductor arrangement can be fed by several transmitters. Furthermore, it is possible to use any number of receivers for coupling signals to a conductor arrangement.
A conductor arrangement comprises at least one conductor structure in which electrical signals can be guided. Such a conductor structure includes one or more conductors of a preferably highly conductive material.

Furthermore, a conductor arrangement comprises at least one electrically conductive reference surface assigned to each conductor structure. Between the conductor structure and the reference surface there is at least one dielectric for insulating the conductor structure and the reference surface. Such a dielectric optionally has a high homogeneity or a high symmetry with respect to the electrical center of the longitudinal axis of the conductor structure. The symmetry term here refers to a symmetry of the electric field. Starting from the electrical center of the conductor structure, the electric field lines should be symmetrical. This can be realized, for example, with a mirror-symmetrical arrangement. Likewise, however, other implementations are conceivable, such as in the case of a layered dielectric for conductors parallel to the reference surface. Here, in principle, the layer sequence of the dielectric in the conductors may be different if the total dielectric constants are the same on both sides and the areas are the same size.
The symmetry of the electric field is related to an equipotential surface with a potential which corresponds to the mean potential between the active conductors, ie conductors used for signal routing.
A high homogeneity here means that the electrical properties, in particular the dielectric constants and the dielectric losses are subject to only slight fluctuations. Typical values of tolerances of these values are <5% and preferably <1%. If particularly high demands are made, tolerances of 0.1% are also appropriate. Are the production different homogeneities of the dielectric in different directions, perpendicular to the direction of the longitudinal axis of the conductor structure, the highest homogeneity is provided. In the direction of the longitudinal axis lower homogeneities can be tolerated. It is essential here that, in accordance with the preceding considerations on the symmetry, there is symmetry at each point along the longitudinal axis of the conductor structure and accordingly the properties of the dielectric are symmetrical.
This relatively complex symmetry concept will be explained by means of a simple example. It is assumed that a ladder structure of two parallel, equal width and equal thickness conductors. The electrical center of the longitudinal axis of the conductor structure lies exactly in the middle between the conductors. Now, for each infinitesimally short distance of this ladder structure, the electrical parameters of the dielectric should be the same for both conductors. When considering such a short conductor piece, it does not matter from which layering or composition of the dielectric a certain dielectric constant or a certain dissipation factor results. It is essential that these values are the same for both conductor pieces. In the further course of the conductor still changes of the values to previous sections can be tolerated, provided they are the same for both conductors. Thus, a high symmetry can be achieved with the desired electrical properties
A high symmetry with respect to the electrical center of the longitudinal axis of the conductor structure prevents the signals in symmetric conductors or in asymmetrical conductor system with multiple conductors due to different Running times or attenuations become unbalanced.
Ideally, a dielectric of high homogeneity and high symmetry is used. Experience has shown that the best results can be produced at a reasonable cost. If a symmetrical arrangement of the dielectric can not be achieved, the use of a high-homogeneity dielectric also brings about a significant improvement. Likewise, a symmetrical arrangement brings about an improvement, even if sufficient homogeneity of the dielectric can not be achieved.

The ladder structure is usually open to one side to the free space. From this side the coupling of receivers takes place. The opposite side and optionally also its boundary are closed off by symmetrical surfaces with a conductive surface. On the one hand, this makes it possible to achieve a defined impedance of the conductor system and, on the other hand, to realize a defined symmetrical limitation. If no defined reference surface were present here, then at least a part of the device in which the device is mounted would serve as an electrical reference. Certainly, the required symmetry would not be achieved here along the entire length of the conductor structure since different components or assemblies of the device would not be arranged arbitrarily symmetrical.

In a further advantageous embodiment of the invention, at least one dielectric comprises an air or gas layer.

Most of the known engineered gases, especially the air, which is a varying combination of various gases with a high nitrogen content, have similar dielectric properties with a relative dielectric constant close to 1 and a nearly negligible loss factor. In this document, reference is therefore made only to air as a dielectric or an air layer. Also included herein are mixtures of several different gases having electrical properties similar to air. Instead of air, liquids with very low loss factors can be used.

Essential for the function is the low dielectric loss factor of the gases. Thus, fluctuations in the loss factor have little effect.

If the attenuation is low, with the same tolerance of the attenuation this has a much smaller influence on the tolerance of the signal level as with high attenuation values. An example will explain this. If a given material with given geometry has a signal attenuation of 10% with a tolerance of ± 10% of the attenuation, the actual attenuation value may vary between 9% and 11%. The level of the attenuated signal is thus 9% to 11% lower than the original signal. Depending on the current attenuation value, the signal level can now vary by 2%. If, on the other hand, the attenuation of the material is only 1% with the same tolerance of ± 10% of the attenuation, the signal level between 0.9% and 1.1% may be attenuated from the original signal level.

Thus, in this case, depending on the current attenuation value, the signal level can only vary by 0.2%. Furthermore, the amplitude of the signal is only slightly attenuated by the low attenuation value, even with long conductor structures. By a uniformly high signal level only a low dynamics of the receiver is required. At the same time, immunity to interference can be maximized since the maximum possible input level is always available to receivers.

In a further advantageous embodiment of the invention, at least one dielectric comprises a honeycomb or lattice-shaped structure of an insulating material. The spaces or cavities are filled with air. Basically, other hollow structures, which are suitable for receiving air, can be used.
In the case of such hollow structures, the dielectric consists of a combination of the insulating material, usually with a higher dielectric constant than air and a higher loss factor than air. The electric field is now preferably by webs of insulating material, which bridge the gap between the conductors or the conductors and the reference surface run. Therefore, these bars should be designed with the smallest possible cross section. In the majority of the total area, the electric field will pass through a series circuit of insulating material and air. Here then dominate the excellent electrical properties of the air, as applied to the air paths inversely proportional to the dielectric constant higher field strength.

In a further, improved embodiment of the invention, at least one dielectric comprises a foam of an insulating material. The cavities of the foam are filled with air. In the case of a foam, it is naturally possible to realize extremely thin wall thicknesses of the insulating material and thus extremely small bridge cross sections. Thus, the bridged by the insulating material without the interposition of air surface is substantially lower than in honeycomb or lattice structures. In addition, foams can be produced inexpensively and processed. As an alternative to foaming, it is also possible to use granules or air-filled hollow spheres.

A further embodiment of the invention consists in that at least one dielectric comprises a polyethylene foam. Polyethylene is a plastic with excellent electrical properties. It is one of the insulating materials with the lowest loss factor. At the same time, inexpensive foams can be produced with this material. Processing is particularly simple and inexpensive, especially in the form of thin films with thicknesses of a few millimeters.

Another advantageous embodiment comprises a multilayer structure of a dielectric. By means of such a multi-layered structure, for example, different dielectrics with different electrical and mechanical properties can be combined. Thus, particularly advantageous thin webs of mechanically stable insulating material combined with large-area arrays of dielectrics with the inclusion of air.

In a further advantageous embodiment of the invention, at least one dielectric has a construction of a plurality of layers arranged parallel to the conductor structure. With such a parallel layer structure, insulation materials with poor electrical properties can also be combined over a large area with insulation materials having good electrical properties, in particular if they have a lower dielectric constant. Thus, the combination still relatively good electrical properties can be achieved.

A particularly advantageous embodiment of the invention is that a dielectric, which includes air and consequently has only a low mechanical stability is combined with at least one second insulating material in solid construction and corresponding high mechanical stability. Thus, this second insulating material can be used to stabilize the combination of different dielectrics. Thus, irrespective of the poorer mechanical properties of the first layer, there is a precise fixation of the dielectrics which is absolutely necessary for a high degree of symmetry.

In a further advantageous embodiment of the invention, the second layer is formed as a mechanically rigid layer for fixing or stabilizing the first layer and connected thereto. Such a connection can be done for example by positive engagement or by gluing. With such a configuration results not only a high stability, but also a precisely defined geometry. In addition, the manufacturing process can now be simplified if all layers of a dielectric can be prefabricated together and finally assembled as a unit.

A further advantageous embodiment of the invention is that the second layer is additionally designed as a carrier of the conductor structure. As a result, all components of the electrical system of the conductor arrangement are connected in one unit and can be mounted extremely inexpensively with the lowest tolerances.

A further advantageous embodiment of the invention is that at least one additional layer of conductive material or material with high conductivity and incomplete surface coverage, such as a grid structure is provided. Such layers act as equipotential surfaces and help to compensate for asymmetries in the dielectric. Depending on the design or arrangement of the surfaces, these are arranged electrically isolated or even at the ends of the conductor structure reflection-free.

In a further advantageous embodiment, at least one dielectric comprises a structure comprising a plurality of layers arranged perpendicular to the conductor structure. Such layers can be used, for example, as a support of the conductor structure.

Also advantageous is an embodiment of these layers symmetrical to the electrical center of the longitudinal axis of the Conductor structure. This maintains the symmetry.

Another advantageous embodiment of the invention consists in that layers of a second, mechanically rigid insulating material are provided in a dielectric made of a first material comprising air perpendicular to the conductor structure. Thus, the electrical properties of the device are dominated by the large area first material. The second material is provided as a support for fixing the conductor structure and for stabilizing the first material, if this is a foam or hollow body, for example. Of course, the cross-sectional area of the supports of the second material should be as low as possible in order to influence the field as little as possible. Furthermore, the supports can be arranged at irregular intervals to prevent resonances on the conductor system.

In a further advantageous embodiment, the part carrying the conductor structure has a groove for receiving at least one dielectric. With the help of such a groove, the dielectric can be fixed easily and inexpensively in production.

Another embodiment provides that the groove for receiving at least one dielectric is simultaneously provided for fixing the conductor structure.

In a particularly advantageous embodiment of the invention, the conductor structure comprises a symmetrical conductor system. Such symmetrical conductor systems can especially low emission can be realized. Particularly in a symmetrical design of the conductor system and in operation with symmetrical electrical signals, the electric fields and the magnetic fields of the conductors cancel each other out in the distance. Such ladder systems are preferably used with two conductors. For further illustration, reference is made to the disclosure of US Pat. No. 5,530,422 and international publication WO 98/29919.

In a further embodiment of the invention, the conductor structure comprises an asymmetrical conductor system. There are special cases of unbalanced conductor systems in which the radiation can be kept low. An example of this is the system shown in US Patent 5,208,581. In this case, current flows through different conductor systems in accordance with the signal polarity. However, unbalanced conductor systems usually require significantly more technical effort for suppressing interference than with symmetrical conductor systems.

Description of the drawings

• Fig. 1 zeigt in allgemeiner Form schematisch eine erfindungsgemäße Vorrichtung.
• Fig. 2 zeigt beispielhaft eine Ausführungsform einer Leiteranordnung.
• Fig. 3 zeigt beispielhaft eine Ausführungsform einer Leiteranordnung mit einem Dielektrikum, welches zumindest Feststoffe enthält.
• Fig. 4 zeigt eine Anordnung mit einem Träger aus Isoliermaterial.
• Fig. 5 zeigt eine Anordnung mit einem leitfähigen Träger.
• Fig. 6 zeigt eine Anordnung in einem leitfähigen Träger mit abgeschrägter Bezugsfläche.
• Fig. 7 zeigt eine Ausführungsform mit einem parallel zu Leiterstruktur und Bezugsfläche geschichteten Dielektrikum.
• Fig. 8 zeigt eine vorteilhaften Ausführung mit senkrecht zu Leiterstruktur und Bezugsfläche geschichteten Dielektrikum in einem Schnitt längs zur Bewegungsrichtung.
• Fig. 9 zeigt eine vorteilhaften Ausführung mit senkrecht zu Leiterstruktur und Bezugsfläche geschichtetem Dielektrikum in einem Schnitt quer zur Bewegungsrichtung.
• Fig. 10 zeigt eine Anordnung mit senkrecht zu Leiterstruktur und Bezugsfläche geschichtetem in Dielektrikum, wobei die Schichten als Stützen in Längsrichtung der Leiterstruktur ausgebildet sind.
• Fig. 11 zeigt eine Anordnung mit einer besonders Kapazitätsarm ausgebildeten Stütze aus massivem Dielektrikum.

The invention will now be described by way of example without limitation of the general inventive idea by means of embodiments with reference to the drawings.

• Fig. 1 shows in a general form schematically a device according to the invention.
• Fig. 2 shows an example of an embodiment of a conductor arrangement.
• FIG. 3 shows by way of example an embodiment of a conductor arrangement with a dielectric which contains at least solids.
• Fig. 4 shows an arrangement with a carrier made of insulating material.
• Fig. 5 shows an arrangement with a conductive carrier.
• Fig. 6 shows an arrangement in a conductive support with a beveled reference surface.
• FIG. 7 shows an embodiment with a dielectric layered parallel to the conductor structure and the reference surface.
• FIG. 8 shows an advantageous embodiment with dielectric layered perpendicular to the conductor structure and the reference surface in a section along the direction of movement.
• Fig. 9 shows an advantageous embodiment with layered perpendicular to the conductor structure and reference surface dielectric in a section transverse to the direction of movement.
• FIG. 10 shows an arrangement with dielectric layers stacked perpendicular to the conductor structure and the reference surface, wherein the layers are formed as supports in the longitudinal direction of the conductor structure.
• FIG. 11 shows an arrangement with a support of solid dielectric formed with a particularly low capacity.

In Fig. 1, a device according to the invention is shown by way of example. A transmitter (10) feeds electrical signals into the conductor arrangement (11). Opposite the conductor arrangement (11) and the associated transmitter (10), the receiver (12) is arranged to be movable. The relative movement takes place on predetermined paths. Such webs may for example be linear or circular. The conductor arrangement (11) is arranged along at least one of these tracks of the movement, so that there is only a short distance between the conductor arrangement (11) and the receiver (12) at each point of the movement at which signals are to be transmitted. Typically, the distances are in a range of 0.1 mm to about 10 mm. Direct contact with a distance of 0 is possible. This is the case of a galvanic transmission. In order to obtain a long service life of the contact system here, it is necessary to design surfaces as special. Normally, however, a contactless and thus low-wear transmission he wishes. Greater distances than about 10 mm are not excluded, but in most cases undesirable because the radiation of the entire conductor assembly (11) should be so low that no interference or interference of other equipment or devices takes place. Therefore, the transmission system is deliberately designed so that the electromagnetic far field of the conductor arrangement (11) is as low as possible and ideally equal to zero.

2 shows by way of example a particularly simple embodiment of a conductor arrangement (11). The conductor arrangement comprises at least one conductor structure (1) and a reference surface (2) associated therewith and a dielectric (3). For better illustration, two conductors (1a, 1b) are shown on the conductor structure (1). These conductors may have any of the prior art gradients. The reference surface (2) itself is electrically conductive at least on its surface. In this example, located between the conductor structure (1) and the reference surface (2) is a cavity, which is guided with air or a similar gas. Thus, in this case, the air is the dielectric.

In Fig. 3 is an example of an embodiment of a conductor arrangement (11) corresponding to Fig. 2, wherein the cavity between the conductor structure (1) and the reference surface (2) with a dielectric (3) is filled, which consists at least partially of solids. Such dielectrics may be, for example, lattice structures or foams of an insulating material.

Fig. 4 shows an arrangement in which the conductor structure (1) is mounted in a carrier (6) made of insulating material. For receiving the dielectric (3) and the reference surface (2), a groove is provided in the carrier. In this case, the reference surface (2) is designed as an electrically conductive surface in the bottom of the groove. Such an electrically conductive surface can be realized for example by means of a conductive paint or a thin film strip. Such a film strip can be attached by adhesion, but also by adhesive such as double-sided adhesive tape. Due to the comparatively robust attachment in a solid support, the geometry and thus also the symmetry of the arrangement is precisely defined and fixed with long-term stability.

FIG. 5 shows an arrangement with a conductive carrier. This conductive support has a groove for receiving the dielectric and fulfills with its surface the function of the reference surface (2). Optionally, the surface is refined inside the groove to obtain a long-term stable, highly conductive surface. Furthermore, the groove can be designed such that it is designed for precisely defined recording of the conductor structure (1). In this embodiment, the geometry can usually be defined even more precisely than with a conductive support and an additional reference surface, since tolerances due to sticking or due to the thickness tolerances of the additional reference surface are omitted here. Furthermore, in this embodiment, a greater degree of freedom for the design of the groove itself. This can now be optimized with regard to cost-effective production be, because here no additional conductor must be introduced as a reference surface.

FIG. 6 shows an embodiment in which the dielectric (3) and the conductor structure (1) are accommodated in a conductive carrier. Here, the groove for receiving a symmetrical, both sides beveled bottom.

FIG. 7 shows an embodiment with a dielectric layered parallel to the conductor structure and reference surface. For receiving serves a carrier (6), in which a groove is introduced, the inside of which serves as a reference surface (2) at the same time. By way of example, the dielectric has a first layer (5) consisting of a solid insulating material. Parallel to this is a second layer consisting of a dielectric comprising air or gas. The primary purpose of the first dielectric is to support the conductor structure (1) and fix it in a defined position. A precise fixation of the conductor structure at the predetermined position symmetrical to the environment and in particular to the reference surface (2) is essential for a high symmetry of the signals and thus a high immunity to interference or a low interference emission. In order to achieve sufficient mechanical stability, a large layer thickness of the first layer was chosen in this example. The second layer (4) consists of a dielectric with low dielectric constant and low losses. By the electrical series connection with the first layer with high dielectric constant is the vast majority of the total electric field strength and thus also the stored energy in the second layer (5) with low dielectric constant. Because this also has a much lower loss factor, the total loss factor of the arrangement is much lower.

FIG. 8 shows an advantageous embodiment of the invention with a dielectric layered perpendicular to the conductor structure or reference surface in a section along the propagation direction. At certain intervals supports made of a solid insulating material (5) are arranged perpendicularly between the conductor structure and the reference surface in order to ensure a defined alignment of the conductor structure to the reference surface. The spaces are filled with an insulating material comprising air or gas. The supports themselves can be mounted in constant or variable intervals. Variable distances help to prevent resonances in the line system. Ideally, the supports are made narrow, so that the capacity at the location of the supports is relatively low. This minimizes reflections at the location of these columns.

FIG. 9 shows an arrangement corresponding to FIG. 8 in a section perpendicular to the direction of movement. Here, the supports of solid insulating material are designed such that they do not extend over the entire width of the groove in the carrier. This leads to a further reduction of the losses in the supports. Of course, these supports can also be extended for reasons of stability over the entire width of the groove.

Fig. 10 shows an arrangement with vertical layering of the dielectric. In this case, the layers are formed in such a way that narrow webs of the first dielectric (5), made of solid insulating material, result along the conductor structure. Thus, no reflections are present in the propagation direction along the conductor structure. However, attention must be paid to a very symmetrical arrangement and stable fixation of the longitudinal strips in order to achieve a high degree of symmetry.

Fig. 11 shows an arrangement with a particularly low-capacity solid dielectric support to minimize the reflections at the location of the supports. Of course, other types and configurations of supports can be used. Essential here is the mechanically supporting function of the support. Ie. it should be stiffer than the dielectric, which essentially retains its properties of air or gas.

LIST OF REFERENCE NUMBERS

1

conductor structure

1a

first leader

1b

second conductor

2

reference surface

3

Dielectric (general)

4

Dielectric comprising air or gas

5

Dielectric made of solid insulating material

6

carrier

10

transmitter

11

conductor arrangement

12

receiver

Claims (16)

1. Device for broadband signal transmission between units that are movable along predetermined tracks, comprising:

   - at least one transmitter (10) for generating electrical signals;

   - at least one conductor arrangement (11) for conducting at least one of the electrical signals of at least one transmitter along the track of movement with low outward emission of radiation;

   - at least one receiver (12) for coupling-out electrical signals from at least one conductor arrangement in the near field of the conductor arrangement;

   in which at least one conductor arrangement comprises:

   - at least one conductor structure (1) for conducting electrical signals, the conductor structure comprising a symmetrical conductor system; and

   - at least one electrically conducting reference surface (2) assigned to each conductor structure; and also

   - at least one dielectric (3) of high homogeneity between the conductor structure and the reference surface;

   characterized in that
   at least one dielectric of high homogeneity and of high symmetry with respect to the electrical centre of the longitudinal axis of the conductor structure is provided, the tolerances of the dielectric constants and the dielectric losses with reference to an equipotential surface through the longitudinal axis of the conductor structure are less than 5 %, and the dielectric comprises hollow structures that are filled with air and/or industrially usable gases, and/or a gas layer.
2. Device according to claim 1,
   characterized in that at least one dielectric comprises a honeycomb-shaped or grid-shaped structure of an insulating material, the hollow spaces or intermediate spaces being filled with air or a gas.
3. Device according to any one of the preceding claims,
   characterized in that at least one dielectric comprises a foam or granules of an insulating material, the hollow spaces being filled with air or a gas.
4. Device according to any one of the preceding claims,
   characterized in that at least one dielectric comprises a polyethylene foam.
5. Device according to any one of the preceding claims,
   characterized in that at least one dielectric is built-up of a plurality of layers.
6. Device according to any one of the preceding claims,
   characterized in that at least one dielectric is built-up of a plurality of layers disposed in parallel to the conductor structure.
7. Device according to any one of the preceding claims,
   characterized in that at least one dielectric comprises at least one first layer of a first material comprising, or enclosing in hollow spaces, air or a gas, and at least one layer of at least one massive second insulating material.
8. Device according to claim 7,
   characterized in that the second layer is designed to be a mechanically rigid layer for stabilizing or fixing the first layer.
9. Device according to any one of claims 7 to 8,
   characterized in that the second layer is designed to be a support for the conductor structure.
10. Device according to any one of the preceding claims,
    characterized in that at least one additional layer of a conductive material, or a conductive material having incomplete surface coverage such as a grid structure, for example, is provided.
11. Device according to any one of the preceding claims,
    characterized in that the dielectric is built-up of a plurality of layers disposed perpendicularly to the conductor structure.
12. Device according to claim 12,
    characterized in that the layers are disposed to be symmetrical to the electrical centre of the longitudinal axis of the conductor structure.
13. Device according to any one of the preceding claims,
    characterized in that a dielectric of a first material comprising air or gas is provided, and that layers of a mechanically stiff insulating material disposed perpendicularly to the conductor structure are provided at a predetermined spacing to stabilize or fix the conductor structure.
14. Device according to at least one of the preceding claims,
    characterized in that a groove for accommodating the dielectric (3) is provided in the part supporting the conductor assembly (11).
15. Device according to claim 14,
    characterized in that the groove for accommodating the dielectric is also provided for fixing the conductor structure.
16. Device according to any one of the preceding claims,
    characterized in that a groove for fixing the conductor structure is provided in the part supporting the conductor assembly (11).

Images