DE102014214023A1 - Conduit system with closed-cell rigid foam - Google Patents

Abstract

The invention relates to a conduit system for microwave transmissions consisting of an inner conductor (2) and an outer conductor (1), wherein the inner conductor (2) is held by a dielectric (3) in the outer conductor (1). According to the invention, the dielectric (3) is a closed-cell rigid foam, in particular of polymethacrylimide. The invention further relates to a method for producing a conduit system. The invention further relates to a microwave transition (12).

Description

The invention relates to a line system consisting of an inner conductor and an outer conductor. The invention further relates to a method for producing such a conduit system, a microwave transmission and a use in a power measuring element.

Line systems for transmitting signals in the high-frequency range are, for example, coaxial line systems or coplanar line systems. It is provided, for example, to separate an inner conductor of an outer conductor by means of a dielectric and to hold. The transmission properties are determined by the dielectric. By using a high air dielectric, these transmission characteristics can be improved. The problem with such coaxial conductors is to make the structure mechanically stable.

From the DE 10 2008 012 591 A1 a coaxial cable system is known in which the inner conductor is held at so-called support points in the outer conductor. Thus, the inner conductor is spaced from the outer conductor and firmly fixed in the outer conductor due to the support points. The problem with such a structure is that the nodes have effects on the transmission behavior of the line system. In particular, in the vicinity of the upper limit frequency of this coaxial line system exists in the support point, a resonant higher mode of the transmission frequency. Due to this higher mode, in such constructed coaxial line systems, a cross-section reduction of the inner conductor between the pad of the inner conductor to another assembly and the location of the first support of this coaxial line system is provided. This cross section reduction causes the resonant frequency of this mode to be increased and is above the cutoff frequency of the coaxial line system.

However, this cross-cut reduction disadvantageously causes the first post to have a relatively large distance from the mating face of the coaxial line system, thereby creating a large lever on the inner conductor of the coaxial line system with respect to the first node when the coaxial line system is connected to another Components and assemblies is connected. Due to this large lever, both the support point and the inner conductor must be made of a mechanically stable and mechanically strong material.

Furthermore, the inner conductor is further tapered by the Querschnittreduzierung the already small transverse dimensions of the inner conductor of sometimes less than one millimeter. This taper further reduces the mechanical strength of the inner conductor and prevents a force-transmitting connection possibility. In order for the inner conductor to withstand mechanical force in the area of the support points when subjected to a radial force and to counteract the great leverage effect, only very solid materials can be used as the inner conductor material. This severely restricts the material selection for the inner conductor and prevents the selection of materials with properties required for a specific application, for example low thermal conductivity, low material costs, etc.

For example, copper-beryllium alloys are used as the material of the inner conductor, which although a high mechanical strength by high tensile strength, hardness and elongation at break, but are disadvantageously produced very expensive and very good heat conductors, which is for special applications, such as in the Power measuring range is disadvantageous.

Furthermore, in such a Koaxialleitungssystem relevant support points and their associated cross-sectional changes within the useful frequency range as perfectly as possible to compensate to allow ideal transmission conditions. Due to manufacturing tolerances even theoretically perfectly compensated impurities lead to reflections. The compensation at the support points is critical because the geometry of the inner conductor must be made very precisely. Tolerances of a few micrometers must be observed in order to keep the reflection small.

The object of the present invention is to provide a conduit system which overcomes the above-mentioned problems. In particular, a line system is to be created which has an ideal transmission behavior and can be implemented cost-effectively.

The stated object is achieved with a line system according to claim 1 and a method for producing a line system according to claim 7. The object is further achieved by a transition according to claim 12.

According to the invention, a conduit system with an inner conductor and an outer conductor is proposed, wherein the inner conductor is separated by a dielectric in the outer conductor. The dielectric is or consists of a closed-cell rigid foam.

A closed-cell rigid foam is a hard foam whose inner cells are completely or fully closed. Only the cells of the hard foam arranged on the surface of the dielectric can be open in order to ensure a good bonding of the hard foam to the inner conductor or the outer conductor.

Hard foam is understood to mean a material which has a volume which is difficult to change as a result of pressure, and which has, in particular, a modulus of elasticity which is much greater than that of flexible foam, a greater shear modulus, greater tensile strength, greater flexural strength and / or greater shear strength. In particular, the strength of the inner cell walls causes a high strength and hardness of the rigid foam according to the invention.

Preferably, the modulus of elasticity of the dielectric is greater than 30 megapascals, preferably greater than 70 megapascals, more preferably greater than 90 megapascals, and most preferably greater than 150 megapascals. This causes a high stiffness of the dielectric, whereby mechanical support points in the outer conductor can be omitted.

The dielectric preferably contains or consists of polymethacrylimide, polystyrene or polyetheretherketone, PEEK for short.

Polymethacrylimide, PMI for short, is a polymer that is commonly used in aircraft, automotive and medical because of its low density. PMI is heat resistant up to 180 ° C, creep resistant and durable. In comparison to other polymers, PMI has, in particular, a very high rigidity and homogeneous structure, which, in addition to high stability, also enables simple processing. Due to the high strength, the PMI as a dielectric in line systems enables a stable holding of the inner conductor in the outer conductor. In conclusion, the support points according to conventional piping systems can be dispensed with. Due to the higher mechanical stability of the PMI thus the aforementioned leverage is reduced.

The use according to the invention of this material in the piping system gives a large number of advantages.

On the one hand, the use of a closed-cell rigid foam such as PMI from assembly view is advantageous because in particular the high strength, rigidity and high stability makes the individual parts of the line system insensitive during assembly, cleaning and overall handling.

On the other hand, a closed-cell rigid foam from the manufacturing point of view is advantageous because the high strength and high rigidity insensitivity of the items is also obtained during manufacture. In particular, high compression strength, tensile strength, flexural strength and shear strength - measured in megapascals -, a high compression hardness - measured in kilopascals - and a high indentation hardness - measured in grams per square centimeter - compared to alternative dielectric materials for machining, the Clamping in a collet and sawing the material easier.

In this way, the line system is very easy to manufacture and has a very homogeneous structure, which can be omitted to be provided for the compensation of the support points Querschnittreduzierungen the inner conductor. As a result, the inner conductor is mechanically stronger and has an ideal transmission behavior. The choice of materials for the inner conductor is now less limited, whereby application-specific materials for the inner conductor can be used. A cost-reduced manufacturing and an ideal transmission behavior of the pipe system is the result. Preferably, the outer conductor is a mechanically rigid shell of the conduit system. In this way, the already high stability of the conduit system due to the dielectric material is further strengthened. Furthermore, a closed-cell rigid foam as a dielectric can be integrated into the line system in a simplified manner.

The dielectric is foamed. For foaming in particular air, oxygen or nitrogen is used. The resulting foamed PMI is also referred to as PMI-E, the PMI-E also being referred to below as PMI. By foaming, the PMI has a high gas content of air, or of Oxygen or nitrogen, up. This proportion preferably has a value greater than 90 percent, preferably greater than 94 percent, more preferably greater than 97 percent.

The dielectric preferably has a very low relative dielectric constant ε _r . The relative dielectric constant of the dielectric in this case has a value of less than 1.15, preferably less than 1.10, more preferably less than 1.05, so that the dielectric in the form of the closed-cell rigid foam PMI is highly frequency-transparent and has hardly any dielectric losses.

Furthermore, foaming introduces a multiplicity of small closed cells into the dielectric. This high number of closed cells provides a high insensitivity to moisture.

In comparison to line systems of the conventional type, the line system according to the invention has a nearly homogeneous cross-section. Due to the stability of the rigid foam as a dielectric, the inner conductor can likewise be made homogeneous, it is not possible to produce complex compensations due to supporting points, and it is not necessary to reduce the cross section. In conclusion, significantly fewer reflections occur on the line system.

By using hard foam, in particular PMI as a dielectric, the dielectric can have a comparatively small distance from the contact surfaces of further assemblies, so that an improved mechanical strength is obtained.

Preferably, the inner conductor with the dielectric by means of a first adhesive, which may be in particular cyanoacrylate or consists of this, glued. The cyanoacrylate forms a good network with the inner conductor and the PMI and allows an increase in the stability of the line system.

Preferably, the outer conductor with the dielectric by means of a second adhesive, which may be in particular epoxy resin or consists of glued. The epoxy resin forms a good network with the outer conductor and the dielectric and allows a further increase in the stability of the conduit system.

Instead of using different adhesives, it is also possible to use a single adhesive both for the connection of the inner conductor and the dielectric as well as of the outer conductor and the dielectric, as a result of which, in particular, manufacturing and material costs can be saved.

The use of a closed-cell rigid foam prevents too deep penetration of the adhesive into the dielectric. On the other hand, the foaming causes a roughening and thus increasing the surface of the dielectric, whereby an ideal bonding is obtained. The high mechanical strength is guaranteed.

Preferably, the inner conductor core is made of a non-metallic core and is connected to a metal e.g. coated by electroplating, vapor deposition or sputtering. Due to the high mechanical stability of the dielectric as PMI can be dispensed with a highly stable full-volume metallic inner conductor, for example, a copper-beryllium alloy. In particular, plastic inner conductors can now be used. The manufacture of the inner conductor made of plastic means, in particular, that the core of the inner conductor is a plastic and has a metal coating. Due to the alternative materials for the core of the inner conductor, the thermal conductivity of the inner conductor is greatly reduced. Due to the skin effect, high frequency waves propagate almost completely on the surface of the inner conductor, whereby a full-volume metallic design of the inner conductor for high-frequency applications is unnecessary. Due to the high stability of the conduit system by means of a closed-cell foam as a dielectric can be dispensed with a full-volume design of the inner conductor for reasons of stability.

By using an inner conductor with significantly lower coefficients of thermal conductivity than metal, the external heat influence for thermal, sensitive components that are connected to the line system drops enormously. In particular for heat-sensitive applications, for example the measurement of heat by means of power, the line systems according to the invention can preferably be used and increase the measuring accuracy.

Due to this novel cable system with significantly reduced mechanical complexity, it is possible to work with signal frequencies of more than 110 GHz for even smaller cross-sections, for example 0.8 mm or 0.5 mm.

According to the invention, a method for producing a line system is furthermore provided. The method comprises the method steps: providing the dielectric in the form of half-shells; Inserting a recess in each of the half-shells of the dielectric; Placing the inner conductor in at least one recess of one of the half-shells; Connecting the half shells of the dielectric; and placing the dielectric with inner conductor in an outer conductor.

Due to the use of a closed-cell rigid foam, in particular of PMI or PEEK or polystyrene, as a dielectric, a machining method can be used. This is made possible by the high compression and indentation hardness of the PMI. The production is thus less sensitive and cheaper possible. In particular, a milling of a recess and the subsequent placement of the inner conductor can be made possible without technical difficulties.

Preferably, after the step of placing the inner conductor, bonding of the inner conductor to the dielectric takes place. For example, an adhesive bore in the closed-cell rigid foam is provided as a dielectric for this purpose. For example, the adhesive for bonding the inner conductor to the dielectric contains or consists of cyanoacrylate.

Alternatively, prior to placing the inner conductor, the adhesive is introduced into the recess. This variant of the bonding allows a more cost-effective placement.

Preferably, the dielectric is bonded to the outer conductor before the step of placing the dielectric with inner conductor in the outer conductor. For this purpose, the dielectric has adhesive grooves into which the first adhesive or a second adhesive different from the first adhesive is introduced into the adhesive grooves. For a cost-effective bonding of the outer conductor is achieved with the dielectric. For example, the adhesive for bonding the outer conductor to the dielectric contains or consists of epoxy resin.

In an alternative embodiment, the method comprises the method steps:
Providing a tool in the form of half-shells, wherein the tool has a receptacle; Introducing the dielectric into the receptacle of one of the half-shells of the tool, wherein the cross-section of the dielectric in at least one orientation has a larger dimension than the receptacle; Heating the two half-shells; and compressing the half-shells of the tool.

A deformation of the dielectric, for example of the PMI, takes place at temperatures from 180 ° C. In order to obtain a positive and homogeneous line system, the dielectric is made with a slightly larger volume than can be accommodated in the recesses of the half-shells of the tool without compression. When compressing the half-shells of the tool after they have been heated, dimensionally accurate half shells or rigid foam parts can be produced. The compression of the dielectric by heat or temperature represents an enhancement of the mechanical stability of the hard foam part.

Preferably, the inner conductor is inserted into a recess of the dielectric prior to the step of introducing the dielectric into the tool. Alternatively, the inner conductor is inserted into the recess of the dielectric after the crimping step and the heat molded part.

In particular, the depression in the dielectric is carried out by a chip removal process. These very simple production methods reduce the manufacturing costs for the production of the piping system enormously.

In particular, the dielectric is placed in the outer conductor after the crimping step.

According to the invention, a transition from a coaxial line system to a coplanar line system is furthermore provided, in which a particular round inner conductor of the coaxial line system continues in a longitudinal bore of an outer conductor housing into a planar inner conductor, the coaxial line system corresponding to a line system of the preceding type ,

Such a microwave transition is provided in particular when adapting different types of line systems. Since high dielectric losses are to be expected in particular when moving from coaxial line systems to coplanar line systems, it is desirable to produce the coaxial line system by means of the previously described type in order to achieve an ideal transmission behavior of To obtain microwave signals. Due to the use of a closed-cell rigid foam, for example PMI as a dielectric, an inner conductor of highly stable material can be dispensed with. In conclusion, the core of the inner conductor can be made of less stable material, such as plastic, whereby a cost reduction in manufacturing and a reduction of the external heat influence are obtained.

In a preferred embodiment, the microwave transition is used in a high-frequency power measuring element. In particular, a low heat conduction of the inner conductor is desired, which is obtained by means of a plastic as inner conductor core with metal coating. This mechanically less stable inner conductor can be used because the dielectric is a closed-cell rigid foam, which has a high basic stability.

Hereinafter, embodiments of the invention will be explained in more detail by way of example with reference to figures of the drawing. In this case, the same components in the figures have the same reference numerals. For clarity, individual components in the figures are exaggeratedly large or exaggerated simplified. Show it:

1 A first embodiment of a conduit system according to the invention,

2 a further education of in 1 illustrated piping system according to the invention,

3 an inventive dielectric material for a conduit system according to the 1 or 2 .

4 one too 3 alternative hard foam part according to the invention for a line system according to the 1 or 2 .

5 a power measuring element for high-frequency signals with a line system according to the invention according to the 1 or 2 .

6 this in 5 shown power measuring element in perspective view,

7a B shows a second embodiment of a conduit system according to the invention,

8th A third embodiment of a conduit system according to the invention,

9a Fig. 5 shows schematic diagrams of a manufacturing method for obtaining a line system according to the invention.

1 shows a central longitudinal section through a conduit system according to the invention. This in 1 shown piping system is a coaxial line system, wherein alternative piping systems, such as coplanar piping systems can also be made according to this structure. According to 1 is an inner conductor 2 from a dielectric 3 jacketed. The dielectric 3 is from an outer conductor 1 jacketed.

As a dielectric 3 is provided a closed-cell foam or the dielectric 3 consists of it. In particular, this hard foam has a relative dielectric constant ε _{r of} less than 1.2, which is achieved in particular by a very high proportion of air of greater than 90 percent. The modulus of elasticity is preferably greater than 30 megapascals, the tensile strength greater than 1 megapascal, the compressive strength greater than 0.4 megapascals, the flexural strength greater than 0.8 megapascals and the shear modulus greater than 13 megapascals.

The conduit system according to the invention consists of a dielectric 3 in that the polymer preferably contains or consists of polymethacrylimide, PMI for short.

The PMI is designed as a closed-cell rigid foam PMI-E, being used as a foaming agent air, oxygen or nitrogen. This PMI is characterized in particular by a comparatively high air content of more than 90 percent, as a result of which it has almost the dielectric properties of air and hardly any dielectric and ohmic losses in the line system due to the PMI as a dielectric 3 come to fruition. Moreover, PMI is extremely stable, which is characterized by a - compared to alternative foams - very high compressive strength, tensile strength, flexural strength, shear strength, indentation hardness and compressive strength, so PMI easily by means Spanabhebe method, eg by turning or Milling, machinable and causes a high stability in the piping system. Due to the heat resistance up to 180 degrees Celsius, it can be easily thermoplastically deformed for the production.

The material properties of PMI as an exemplary dielectric according to the invention 3 with different specific weights are listed in the table below. property Type 31 Type 51 Type 71 Type-110 Specific weight (kg / m ³ ) 32 52 75 110 Dielectric εr (2-20GHz) 1.04 1.07 1.10 1.12 Loss factor tan δ (2-20GHz) 0.0006 0.0008 0.0010 > 0.001 Surface resistance (Ω) 2 × 1013 9 × 1012 5.5 × 1012 - Compressive strength (MPa) 0.4 0.9 1.5 3 Tensile strength (MPa) 1.0 1.9 2.8 3.5 Bending strength (MPa) 0.8 1.6 2.5 4.5 Shear strength (MPa) 0.4 0.8 1.3 2,4 Modulus of elasticity (MPa) 36 70 92 160 Shear modulus (MPa) 13 19 29 50 Elongation at break (%) 3.5 4.0 4.5 > 4.5 Heat resistance (° C) 180 180 180 180 Wärmeausdehnungskoeff. (K - 1) 0.000037 0.000033 0.000035 - Thermal conductivity (W / mK) 0.031 0,029 0,030 0.032 Air content (%) 98% 95.5% 94% 91%

In 2 is a further education of in 1 illustrated conduit system according to the invention shown. In difference to 1 are a first adhesive 4 and a second adhesive 5 provided to further increase the stability of the piping system. It is between the inner conductor 2 and the dielectric 3 the first adhesive 4 brought in. The first adhesive 4 contains in particular cyanoacrylate or consists of this. Moreover, between the outer conductor 1 and the dielectric 3 a second adhesive 5 intended. The second adhesive 5 consists in particular of epoxy resin or contains this.

The bonding is particularly possible because the penetration and withdrawal of the adhesive due to the large number of small closed cells of the dielectric material 3 not possible. The dielectric 3 , especially from PMI, has due to the high air content of up to 98 percent on such a large number of closed cells, that a high roughness of the surfaces and a demensprechend good bonding of the adhesive 4 and 5 be enabled. Alternatively, it is provided to reduce manufacturing costs, only provide an adhesive for both bonds.

The adhesives 4 . 5 are according to 2 full surface between inner conductor 2 and dielectric 3 or outer conductor 1 and dielectric 3 brought in. Alternatively, punctual placements of the adhesives 4 . 5 conceivable. Alternatively, placements of the adhesives 4 . 5 conceivable along an adhesive line.

In 3 is a longitudinal section of a dielectric according to the invention shown. The dielectric 3 has a recess 9 for introducing an inner conductor 2 on. This depression 9 is for example by means of machining production methods in the dielectric 3 brought in. Furthermore, the dielectric has 3 two adhesive holes 8th on to one in the dielectric 3 introduced inner conductor 1 with the dielectric 3 to stick together. Alternative to the adhesive holes 8th can be a coating of the inner conductor 1 or the incorporation of adhesive 4 . 5 into the depression 9 of the dielectric 3 respectively.

Moreover, there are glue grooves 7 provided, which are schematically indicated here in the form of triangles. These preferably circumferential adhesive grooves 7 serve to receive the second adhesive 5 and allow a mechanical fixation of the dielectric 3 with the outer conductor 1 ,

This in 3 represented dielectric 3 is made in one piece from closed-cell rigid foam, especially PMI. In contrast, as in 4 represented, the dielectric 3 also be made in several pieces of closed-cell rigid foam, in particular PMI. Due to the multi-piece a simplified installation of the piping system is made possible. In particular, the middle part of the dielectric 3 has no glue grooves 7 on, since already the outer parts of the multi-piece dielectric 3 the glue grooves 7 and the middle part can not perform any longitudinal movement.

The dielectric 3 For example, it is machined from PMI-based closed-cell rigid foam. Alternatively, the dielectric becomes 3 foamed within the conduit system. The introduced adhesive holes 8th allow the gluing of the dielectric 3 with the inner conductor 1 , As an alternative to bonding, shrinking of the dielectric on the inner conductor is also possible 1 Under heat possible, since the closed-cell rigid foam, in particular the PMI has a low heat resistance of about 180 ° C.

In the 1 to 4 In particular, piping systems shown are coaxial piping systems. Alternative piping systems are also possible. In particular, internal conductors with a quadrangular cross-section or strip conductor line systems are not excluded from the basic idea of the invention. The manufacture of such a conduit system is especially simplified in quadrangular configurations.

In 5 is a power measurement element 10 shown. The power measurement element 10 has a coaxial connection 15 and a measuring cell 16 on. To high-frequency or microwave signals from the coaxial connector 15 to the measuring cell 16 to be able to transmit, becomes the coaxial connection 15 to a coaxial line system 13 connected. Am from the coaxial connection 15 remote end of the coaxial line system 13 is a microwave transition 12 intended. Furthermore, a coplanar line system 20 from the transition 12 to the measuring cell 16 intended. For contacting the measuring cell 16 is a coplanar connection 21 intended.

The transition 12 is in particular very broadband design and must have low reflections and low high frequency losses. The coaxial line system 13 is according to the invention according to a conduit system of 1 to 4 designed to obtain the best possible transmission behavior.

The microwave transition 12 is realized in the embodiment by a one or both sides metallized film piece of elastic insulating material. The foil piece is at the end of the coaxial line system 13 on a step-like support 11 arranged. On the transition 12 becomes the round inner conductor 2 of the coaxial line system 13 connected to a planar inner conductor of the coplanar line system, which through a funnel-shaped transition section 12 on the coplanar pipe system 20 is transferred.

In this way, a continuous transition of the coaxial field is achieved in a coplanar field and a reflection-free connection of the coplanar line system 12 to the coaxial line system 13 it acts. In particular, the embodiment as a power measuring element 10 requires that a low-loss transmission over the coaxial line system 13 follows. Since so far to achieve low-reflection and low-loss coaxial cable systems support points were provided, which finally by elaborate designs of the inner conductor 2 of the coaxial line system 13 had to be compensated was a per se stable mechanical inner conductor 2 in the coaxial line system 13 inevitable. Because a stable inner conductor 2 could be obtained only by means of a copper-beryllium alloy, there was a high external heat influence of the coaxial line system 13 , This external heat influence due to the very good thermal properties of the copper-beryllium alloy caused a deterioration of the measuring accuracy of the power meter 10 ,

According to the invention can now by means of the closed-cell rigid foam as a dielectric 3 , preferably PMI, an inner conductor 2 can be used, which has a lower mechanical stability. In particular, therefore, a vapor-deposited or sputtered on a plastic core metal as the inner conductor 2 intended. The very good high-frequency properties of the plastic-based inner conductor 2 are not affected due to the skin effect in microwave transmission, whereas the plastic as a very poor conductor of heat little external heat in the thermal measuring cell 16 brings. The result is the power measurement element 10 much more accurate. Moreover, due to the homogeneous design of the coaxial cable system 13 be dispensed with a complex compensation of support points, whereupon the power measuring element 10 is much cheaper to produce.

The outer conductor 1 of the power meter 10 is a one-piece, rigid and metallic hollow cylinder. The inner conductor is preferred 2 before insertion into the outer conductor 1 with the dielectric 3 jacketed.

In a first production variant, the dielectric 3 as a half shell 6a . 6b provided and the introduction of the inner conductor 2 takes place by means of in 3 described way. Alternatively, the dielectric becomes 3 provided as a hollow cylinder and the inner conductor 2 in the dielectric 3 guided. Subsequently, the dielectric 3 with inner conductor 2 into the outer conductor 1 from the side of the coaxial connector 15 guided. In this production variant, the inner conductor 2 spared.

In a second production variant, the dielectric 3 provided as a hollow cylinder and in the outer conductor 1 from the side of the coaxial connector 15 guided. Subsequently, the introduction of the inner conductor takes place 2 in the form of a closed-cell rigid foam dielectric.

In 6 is a perspective view of the in 5 shown and described Leistungsmesselements 10 shown. It can be seen that the power measurement element 10 a one-piece outer conductor 1 so that the dielectric 3 and the inner conductor 2 from the coaxial connector 15 into the outer conductor 1 be introduced. This one-piece design of the outer conductor 1 allows a rigid shell of the outer conductor 1 and good high frequency shielding of the power meter 10 , Alternatively, the outer conductor 1 also be formed by half-shells.

In 7a and 7b show alternative embodiments of a conduit system according to the invention. It is clear that the invention is not based on round inner conductors 2 or outer conductor 1 is limited.

In 7a is the dielectric 3 also configured cuboid and has a recess 9 for picking up the inner conductor 2 on. By so designing the dielectric 3 the dielectric acts 3 as a support holder for the inner conductor and enables a stable construction of the pipe system.

In 7b is the dielectric 3 as two half-cuboid 6a . 6b shown. Not shown, but not excluded from the idea of the invention is a U-shaped configuration of the dielectric 3 as a first half shell 6a in whose recess the inner conductor 2 is placed. A lid-like half-shell 6b then serves to completely sheathing the inner conductor 2 ,

In 8th is one to the 1 . 2 and 7 illustrated alternative conduit system according to the invention. It can be seen that the outer conductor 1 has a rectangular cross-section and both inner conductor 2 as well as dielectric 3 are cuboidal. The dielectric 3 acts similarly to 7 as a support holder for the inner conductor 2 in the outer conductor 1 and has two half-shells 6a . 6b on. The outer conductor 1 is integrally formed.

According to the invention, the cross sections of the inner conductor 2 and the outside manager 1 a same shape, so that both inner conductor 2 and outer conductor 1 have rectangular, round, triangular, oval and / or otherwise configured cross sections.

Alternatively and not excluded from the idea of the invention are the cross sections of inner conductor 2 and outer conductor 1 different. In particular, a recess needs 19 of the supervisor 1 not with the cross-section of the dielectric 3 be positive. To achieve the positive engagement, the dielectric 3 heated by thermoplastic processing and adapted to the respective contour, resulting in matching contours that justify an increase in stability. Advantageously, outside and inside pores of the dielectric formed as a PMI foam are closed.

In 9a to 9f are shown in an overview of representations for manufacturing a line system according to the invention. According to 9a is first the dielectric 3 shown. This dielectric is, for example, PMI and is provided as rigid foam in a plate form and can be processed in the chip removal process due to the good material properties according to the above table. The result of editing the PMI material 3 is in 9b shown. 9b shows a first half shell 6a of the dielectric 3 , The training in half shells 6a . 6b is advantageous because on the one hand a good mechanical processing of the PMI as a dielectric is possible and on the other hand, the inner conductor 2 just inside the half-shells 9a . 9b can be placed. The cross section 18 of the dielectric 3 is preferably configured slightly larger than a recording 191 in one of the half-shells 192 . 193 one for the final shaping of the dielectric 3 provided tool 19 , Furthermore, a depression 9 by milling or alternative Spanabhebe method in the dielectric 3 brought in. Radially encircling two adhesive grooves 7 , shown here in the form of triangles, in the dielectric 3 brought in. The glue grooves are preferred 7 introduced into the dielectric before the dielectric 3 in half shells 6a . 6b is split.

According to 9c is now in the depression 9 the first adhesive 4 brought in. The introduction takes place selectively or along an adhesive line or alternatively by full-surface coating of the recess 9 , Alternatively, the bonding is done by means of adhesive holes, as in 3 or 4 are shown.

According to 9d now becomes the inner conductor 2 into the depression 9 the first half shell 6a placed. Subsequently, the placement of the second half-shell takes place 6b of the dielectric 3 , Suggestion is the inner conductor 2 in 9d shown.

In 9e is a first half shell 192 of the tool 19 shown. This first half shell 192 has a recording 191 on, in which the dielectric 3 with inner conductor 2 is to bring. Alternatively and not shown here, the introduction of the dielectric takes place 3 as part of a foaming process.

In order to enable a positive and therefore homogeneous configuration of the conduit system, the cross section 18 of the dielectric 3 preferably dimensioned slightly larger than the recess 191 of the tool 19 , When placing the inner conductor 2 with the dielectric 3 in the first half shell 192 of the tool 19 will - as in 9f indicated - the first half shell 192 and the second half shell 193 of the tool 19 under heat 17 heated.

Due to the heat resistance of 180 ° C of the formed as a closed-cell rigid foam dielectric 3 is a thermoplastic deformation of the dielectric 3 possible. Now the one with dielectric 3 sheathed inner conductor 2 in the heated tool shells 192 . 193 placed. Subsequently, the tool shells 192 . 193 compressed. Subsequently, the compressed dielectric 3 in the outer conductor 1 placed. This is the compressed dielectric 3 with the inner conductor 2 into the outer conductor 1 pushed. In this production variant, the inner conductor 2 mechanically not stressed, so that comparatively unstable inner conductor 2 can be used. By the compression is a positive engagement of outer conductor 1 and dielectric 3 receive. The strength of such a conduit system produced is also improved.

Contrary to the embodiment according to 9d is alternatively provided, the dielectric 3 directly in the tool 19 to form, taking on the formation of half-shells 6a . 6b as well as the introduction of the depression 9 is waived. Only after the crimping step does the indentation become 9 introduced by means of a longitudinal bore, in which the inner conductor 2 is placed. Alternatively, the inner conductor 2 only after the placement of the dielectric 3 in the outer conductor 1 brought in.

All shown, claimed and described features can be combined with each other. The invention is not limited to the embodiments shown, in particular, are various cross-sections of inner conductor 2 or outer conductor 1 providable, the dielectric 3 as a form adapter allows a form-fitting design of the conduit system. Other suitable plastics are z. As polystyrene or PEEK.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 102008012591 A1 [0003]

Claims (16)

Line system consisting of an inner conductor ( 2 ) and an outsider ( 1 ), wherein the inner conductor ( 2 ) through a dielectric ( 3 ) from the external manager ( 1 ), characterized in that the dielectric ( 3 ) is a closed-cell rigid foam. A conduit system according to claim 1, wherein the outer conductor ( 1 ) is a mechanically rigid shell of the conduit system. Lead system according to one of the preceding claims, wherein the modulus of elasticity of the dielectric ( 3 ) has a value greater than 30 megapascals, preferably greater than 70 megapascals, more preferably greater than 90 megapascals, and most preferably greater than 150 megapascals. Lead system according to one of the preceding claims, wherein the relative dielectric constant of the dielectric ( 3 ) has a value less than 1.15, preferably less than 1.10, more preferably less than 1.05. Line system according to one of the preceding claims, wherein the gas portion of the dielectric ( 3 ) has a value greater than 90 percent, preferably greater than 94 percent, more preferably greater than 97 percent. A conduit system according to any one of the preceding claims, wherein the dielectric ( 3 ) Contains or consists of polymethacrylimide, polystyrene or PEEK.  Line system according to one of the preceding claims, wherein the inner conductor core consists of a non-metallic material and is coated with a metal. Method for producing a line system, in particular according to one of the preceding claims, comprising the steps of: - providing a dielectric ( 3 ) in the form of half shells ( 6a . 6b ); - introducing a depression ( 9 ) in at least one of the half-shells ( 6a . 6b ) of the dielectric ( 3 ); - placing an inner conductor ( 2 ) in the depression ( 9 ) at least one of the half shells ( 6a ); - connecting the half-shells ( 6a . 6b ) of the dielectric ( 3 ); and - placing the dielectric ( 3 ) with inner conductor ( 2 ) in an outer conductor ( 1 ). Method according to claim 8, wherein prior to the step of placing the inner conductor ( 2 ) introducing a first adhesive ( 4 ) into the depression ( 9 ) of the inner conductor ( 2 ) he follows. Method according to claim 8 or 9, wherein after the step of connecting the half shells ( 6a . 6b ) of the dielectric ( 3 ) gluing the dielectric ( 3 ) with the outer conductor ( 1 ) by means of the first adhesive ( 4 ) or by means of a second adhesive ( 5 ) he follows. Method for producing a line system, in particular according to one of claims 1 to 7, with the method steps: - providing a tool ( 19 ) in the form of half shells ( 192 . 193 ), the tool ( 19 ) a recording ( 191 ) having; - introduction of the dielectric ( 3 ) into the recording ( 191 ) one of the half shells ( 192 ) of the tool ( 19 ), where the cross-section ( 18 ) of the dielectric ( 3 ) in at least one orientation has a larger dimension than the receptacle ( 191 ) having; - heating ( 17 ) of the two half shells ( 192 . 193 ); and - compressing the half-shells ( 192 . 193 ) of the tool ( 1 ). Method according to claim 11, wherein the inner conductor ( 2 ) into a depression ( 9 ) of the dielectric ( 3 ) before the step of introducing the dielectric into the tool ( 19 ) is introduced. Method according to claim 11, wherein the inner conductor ( 2 ) into a depression ( 9 ) of the dielectric ( 3 ) is introduced after the step of compressing. Method according to one of claims 10 to 13, wherein the dielectric ( 3 ) after the step of compressing in the outer conductor ( 1 ) is placed. Crossing ( 12 ) from a coaxial line system ( 13 ) to a coplanar piping system ( 20 ), in which in a longitudinal bore of an outer conductor housing an inner conductor ( 2 ) of the coaxial line system ( 13 ) continues into a planar inner conductor, the coaxial line system ( 13 ) is a conduit system according to one of claims 1 to 7. Use of a microwave transition ( 12 ) according to claim 15 in a high-frequency power measuring element ( 10 ).

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