DE102018108475B3 - Supportless coaxial air duct and vector network analyzer - Google Patents

Abstract

The invention relates to a columnless coaxial air line (10) having (a) a first plug connection (20), (b) wherein the first plug connection (20) has a threaded sleeve (26), and (c) a second plug connection (42) opposite the first plug connection (20). According to the invention, it is provided that (d) the second plug connection (42) has a connector sleeve (34).

Description

The invention relates to a columnless coaxial air line with (a) a first plug connection, wherein (b) the first plug connection has a, preferably displaceable, screw sleeve, and (c) a second plug connection, which lies opposite the first plug connection.

In the US 4,967,173 A a generic unsupported coaxial air duct is described by means of which a vectorial network analyzer can be calibrated traceable.

The unsupported coaxial air ducts are therefore used to calibrate vectorial network analyzers because their characteristic impedances can be supplied solely to the geometrical dimensions of the inner conductor and the outer conductor. If these geometrical dimensions are known with high accuracy, the characteristic impedance can be calculated from this. This allows feedback to the SI base units. In columnless coaxial air ducts there is no connection between the inner conductor and the outer conductor. The inner conductor is therefore held only by the plug or the base of those components to which the air duct is attached.

Because the vectorial network analyzers to be calibrated are typically precision encoders, it is necessary not to plastically deform the inner conductor and the outer conductor of the unsupported air line to ensure that the geometrical dimensions are always those of which, in the calculation of the characteristic impedance was assumed.

In order to connect a known columnless coaxial air line with a vectorial network analyzer to be calibrated, first the inner conductor of the air line is connected to the inner conductor of the device plug connection of a coaxial line of the network analyzer. In a second step, the second plug connection of the air line is connected to the inner conductor of a second device coaxial line. This step is prone to error, since the position of the inner conductor of the air line is not known exactly. In particular, it is possible that the inner conductor sags, so that it is not aligned with the inner conductor of the device plug-in connection. In order to avoid a plastic deformation, exercise and tact are necessary. Nevertheless, there is a risk of plastically deforming the air duct and rendering it useless.

In the EP 0 323 153 A1 describes a system that can solve this problem. According to the local solution, the air duct has an axially displaceable inner conductor, so that the coupling of the inner conductor of the air line is facilitated with the coaxial line of the network analyzer.

The invention has for its object to improve the assembly of an air line with simple means.

The invention solves the problem by a generic air line, in which the second plug connection has a connector sleeve.

According to a second aspect, the invention solves the problem by a vectorial network analyzer having (a) a first device coaxial line and (b) a second device coaxial line having a second device connector, wherein (c) at least one device connector Device connector sleeve has.

It is convenient, but not necessary, for both device plug-in connections to each have a device connector sleeve, in particular a displaceable device screw sleeve.

An advantage of the invention is that the connection of the air line with the vectorial network analyzer is particularly easy. Unlike in the case of known unsupported air ducts, an air duct according to the invention makes it possible to observe the process of connecting to the eye when establishing the second connection between the inner conductor of the air duct and the inner conductor of the device coaxial line of the network analyzer. If, for example, the inner conductor sags, this can be seen and reacted to. This prevents the two inner conductors from being plastically deformed in an attempt to connect them together so that the characteristic impedance changes in an uncontrolled manner and the unsupported coaxial air line is no longer suitable for calibration.

In the context of the present description, the vectorial network analyzer is understood in particular to mean a measuring device for measuring scattering parameters, that is to say the wave size of the reflection and transmission at electrical ports, as a function of the frequency. The network analyzer may include connection cables and / or adapters for connecting the air line. The network analyzer can have one goal, two goals or more goals.

According to a preferred embodiment, the second plug-in connection is female, is thus designed as a socket, and has a plug contact surface, in which a hole is recessed, wherein the screw sleeve has an end face and wherein the second displaceable threaded sleeve so far on the the first plug-in connection is displaceable, that the plug contact surface and the end face are aligned with each other. This is to be understood in particular that an angle between the male contact surface on the one hand and a straight line between the edge of the hole and the end face on the other hand is at most 30 °. In this case, the insertion of the male connector, so a plug into the hole can be monitored very well with the eye.

Preferably, the air line is a normal. A standard comprises a material measure and an associated calibration certificate, in which the relevant quantities, which are relevant for the representation of the embodied variable, are listed. An air duct in the form of a standard therefore differs from an air duct that is not normal, that the characteristic impedance is known with high accuracy. Preferably, the characteristic impedance is known to four significant digits or better.

It is advantageous if the device connector sleeve is rotatably supported by means of a rolling bearing. This facilitates the merging of the air line with a coaxial line of a network analyzer. If the network analyzer has two device coaxial lines, then it is advantageous if both are rotatably mounted by means of rolling bearings.

It is advantageous if the rolling bearing initially has rolling elements which are made of a different material than the body on which the surface is formed, on which the rolling elements roll. This can lead to less wear and tear. Low wear is therefore an advantage, since column-free coaxial air ducts, which are designed as normal, are high-priced products for which the service life has great relevance.

By rolling cold welds are also avoided as a rule. It is particularly favorable when the connector sleeve is mounted without play by means of the roller bearing.

According to a preferred embodiment of the air line, the second plug connection has a second gender opposite to a first gender of the first plug connection. Alternatively, both device plug-in connections are designed as sockets, that is to say as female plug connections. In this case, the invention requires a particularly good advantage, since the insertion of the corresponding connector, so the male connector, thereby better monitored can be as air lines according to the prior art.

It should be noted that the first device plug-in connection can be formed both male and female. In addition, the second plug-in connection can be formed both male and female. It is thus possible in particular that both device plug connections are either male or both device plug connections are female.

Preferably, the first plug-in connection is a plug, so a male plug-in connection, and has a non-displaceable screw. The second plug connection is a socket, that is a female plug connection, and has a displaceable screw sleeve

• 1 in den 1a und 1b eine herkömmliche stützenlose koaxiale Luftleitung beim Anschließen an einen herkömmlichen Netzwerkanalysator,
• 2 in den 2a und 2b eine erfindungsgemäße stützenlose koaxiale Luftleitung, wobei in 2a die Verbinderhülse in dem Zustand gezeigt ist, in dem sie mit einem Netzwerkanalysator verbunden ist, und wobei 2b die der Montagestellung zeigt.
• 3 zeigt in der 3a eine Teil-Querschnittsansicht eines erfindungsgemäßen vektoriellen Netzwerkanalysators im unverbundenen Zustand und in 3b in verbundenem Zustand.

In the following the invention will be explained in more detail with reference to the accompanying drawings. It shows

• 1 in the 1a and 1b a conventional columnless coaxial air duct when connected to a conventional network analyzer,
• 2 in the 2a and 2 B a columnless coaxial air duct according to the invention, wherein in 2a the connector sleeve is shown in the state in which it is connected to a network analyzer, and wherein 2 B which shows the mounting position.
• 3 shows in the 3a a partial cross-sectional view of a vector network analyzer according to the invention in the unconnected state and in 3b in connected condition.

1a shows a columnless coaxial air duct 10 according to the prior art, with a network analyzer 12 is to be connected, from the sake of clarity, only a first device coaxial line 14 and a second, schematically drawn device coaxial line 16 are drawn.

To calibrate the network analyzer 12 first becomes an inner conductor 18 a first plug connection 20 the air pipes 10 with a first device inner conductor 22 a first device plug connection 24 the first coaxial line 14 connected. Thereafter, a sliding screw 26 a first plug connection 28 the air line 10 with an external thread of the first device plug connection 24 bolted, so that also a first outer conductor of the device 30 with an outer conductor 32 the air line 10 electrically connected. The order of connection can also be reversed.

The following is a connector sleeve 34 in the form of a device screw of a second device connector 36 and the second coaxial line 16 pushed back. This is a second device inner conductor 38 the second device coaxial line16 freely accessible. During the first device inner conductor 22 is formed as a socket, the second device inner conductor 38 designed as a plug.

The second device inner conductor 38 must be in a hole 40 in the inner conductor 18 the air line 10 be introduced. It must be ensured that there are no mechanical deformations on the inner conductor 18 comes. That requires a high concentration and experience.

1b shows the air line 10 that with the partially drawn network analyzer 12 connected is.

2 shows a coaxial air duct according to the invention 10 with the first plug connection 28 , which is the immovable screw 26 having.

The air line 10 has a second plug connection 42 , the one connector sleeve in the form of a second sliding screw 44 having.

The second plug connection 42 is female, that is designed as a socket, and has a plug contact surface A into the hole 40 is admitted. The screw sleeve has an end face 46 and is, as in 2 B shown so far on the first connector 20 too displaceable, that a straight line G between the edge hole 40 and the face 46 with the face a small angle, which in the present case is 0 °.

It can be seen that the device connector sleeve in the form of the second sliding device screw 44 by means of a rolling bearing 48 rotatable relative to the outer conductor 32 is stored. The rolling bearing has several rolling elements 50.1 . 50.2 , ..., which are preferably made of a different material than their rolling surface R , It is also beneficial if the material comes from the rolling element 50 exist, other than the sliding screw sleeve 44 ,

2 B shows the second sliding device screw 44 in the pushed back state. The hole 40 is well visible, so the inner conductor 38 (see. 1a) can be safely introduced without causing plastic deformation. After insertion, the second sliding screw sleeve 44 moved axially outward and a thread 52 bolted to a corresponding mating thread of the network analyzer.

3 schematically shows a part of a network analyzer according to the invention 12 in which only the first device coaxial line 14 is drawn. The first device plug-in connection 24 has the connector sleeve in the form of the sliding screw 44 on.

LIST OF REFERENCE NUMBERS

10

air line

12

network analyzer

14

first device coaxial line

16

second device coaxial line

18

inner conductor

20

first plug connection

22

second plug connection

24

first device plug connection

26

threaded

28

first plug connection

30

first device outer conductor

32

outer conductor

34

connector sleeve

35

Device threaded

36

second device plug connection

38

second device inner conductor

40

hole

42

second plug connection

44

second sliding screw sleeve

46

face

48

roller bearing

50

roller bearing

52

thread

A

Plug-contact surface

G

Just

R

rolling surface

Claims (10)

A columnless coaxial air line (10) having (a) a first plug connection (20), (b) the first plug connection (20) having a threaded sleeve (26), and (c) a second plug connection (42) being connected to the first plug connection ( 20), characterized in that (d) the second plug connection (42) has a connector sleeve (34). Supportless coaxial air line (10) to Claim 1 characterized in that (a) the second plug connection (42) is female and has a plug abutment surface (A) into which a hole (40) is embedded, (B) the connector sleeve (34) as a second displaceable threaded sleeve (44) is formed and has an end face (46), and that (c) the second displaceable threaded sleeve (44) so far on the first plug connection (20) is displaceable in that the plug contact surface (A) and the end face (46) are aligned with one another. Air duct to Claim 2 , characterized in that it is a normal. Air line (10) according to any one of the preceding claims, characterized in that the connector sleeve (34) by means of a rolling bearing (48) is rotatably mounted. Air line (10) according to any one of the preceding claims, characterized in that the second plug connection (42) has a second gender opposite to a first gender of the first plug connection (20). A vector network analyzer (12) comprising (a) a first device coaxial line (14) having a first device connector (24), (b) at least a second device coaxial line (16) having a second device connector (36 ), characterized in that (c) at least one device plug connection has a displaceable device screw sleeve (44). Vector network analyzer (12) after Claim 6 , characterized in that the second device-plug connection (36) also has a second displaceable device-screw sleeve (44). Vector network analyzer (12) after Claim 6 or 7 , characterized in that (a) the first device coaxial line (14) to the first plug connection (20) of the unsupported coaxial air line (10) according to one of Claims 1 to 5 is connected and (b) the second device coaxial line (16) with the second plug connection (42) of the unsupported coaxial air line (10) according to one of Claims 1 to 5 connected is. Vector network analyzer (12) according to one of the Claims 6 to 8th , characterized in that the second device connector (36) has a gender opposite to the first gender of the first device connector (24). Use of an air line (10) according to one of Claims 1 to 5 for calibrating a vectorial network analyzer (12).

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