DE102023004088B4 - Coaxial connectors - Google Patents

Abstract

The invention relates to a coaxial connector (10) for connection to a mating connector and for connecting a coaxial cable (11), which has a cable dielectric (12) through which a coaxial cable inner conductor (13) extends and is surrounded by a coaxial cable outer conductor (14) and a coaxial cable sheath (15), wherein the coaxial connector (10) has a connector unit (20) and a cable receiving unit (90), wherein the connector unit (20) has a compression element (80) for receiving and/or contacting the front end region of the coaxial cable outer conductor (14) and a connector insulating housing (60) through which a connector inner conductor (70) extends and is surrounded by a connector outer conductor housing (40), wherein the cable receiving unit (90) has a cable receiving unit (100) and a slotted sleeve element (130) with a radially outwardly projecting Deformation element (139), and wherein a cable receiving region (120) and a sleeve element receiving region (110) with a radially inwardly projecting deformation block (115) are arranged in the cable receptacle (100). For PIM-stable contact of the coaxial cable outer conductor (14) to the coaxial connector outer conductor housing (40), it is proposed that an annular free space (E) be formed between the second end-face boundary (132) of the sleeve element (130) and the second cover surface (82) of the compression element (80) facing it in the axial direction.

Description

The invention relates to a coaxial connector for connection to a mating connector and for connecting a coaxial cable with a connector unit and a cable receiving unit according to the preamble of claim 1.

Generic coaxial connectors are used, for example, in mobile radio base stations for transmitting high-frequency electrical signals and can be detachably connected to a complementarily designed mating connector as part of an electrical transmission path in order to establish an electrical connection between a first and a second coaxial cable or between a coaxial cable and an electrical assembly arranged on a printed circuit board.

Coaxial cables of this type to be connected to the aforementioned coaxial connector have an insulating cable dielectric through which a coaxial cable inner conductor extends concentrically and is surrounded by a coaxial cable outer conductor. This arrangement is circumferentially encased by a coaxial cable jacket.

Various designs for coaxial cable outer conductors are known to those skilled in the art. To increase the mechanical stability of the coaxial cable, for example, so-called corrugated tube outer conductors are used, in which a wave-shaped profile surface is formed along a helical line or helix as a guide curve. For lower stability requirements, coaxial cable outer conductors in the form of a shielded braid are known.

For optimal transmission of high-frequency AC signals, particularly in the gigahertz range, it is essential that passive intermodulation (PIM) is avoided as much as possible. This requires targeted avoidance of mutual interference caused by electrical signals transmitted at different frequencies. A suitable design of the coaxial connector plays a key role in meeting this requirement, avoiding undefined and/or changing contact points between the coaxial connector outer conductor housing and the coaxial cable outer conductor in order to achieve a mechanically and electrically stable connection, particularly under external mechanical loads. Connecting the coaxial cable to the coaxial connector should be simple and require little effort, avoiding the use of special tools.

In order to improve the PIM stability of generic coaxial connectors, it is also necessary to effectively prevent the formation of abrasion and the associated chips when establishing contact between the coaxial cable outer conductor and the coaxial connector outer conductor housing.

In the EP 1 170 833 A1 A generic coaxial connector for connecting to a mating connector and for connecting a coaxial cable is proposed, comprising a connector unit 1-9 and a cable receiving unit 10-14. The connector unit has a connector insulating housing 6, through which a connector inner conductor 1 extends concentrically and is circumferentially surrounded by a connector outer conductor housing 2, 3. The cable receiving unit has a cable receiving unit 12 and a sleeve element 11 with a plurality of longitudinal slots and an internal thread 22. A radially outwardly projecting deformation element 18 is arranged on the sleeve element 11. A cable receiving area for receiving the coaxial cable to be connected and a sleeve element receiving area are provided in the cable receiving unit 12. A radially inwardly projecting deformation block is arranged in the sleeve element receiving area. When the sleeve element 18 moves into the sleeve element receiving area of the cable receptacle 12, this deformation block causes a radially inward deformation of the sleeve element 11 from a position exposing the coaxial cable outer conductor to a position contacting the coaxial connector outer conductor. The design of the sleeve element 11 with a plurality of longitudinal slots connected at the end leads to the formation of a plurality of clamping wings that are connected to the ring 30. This limits the clamping of the coaxial cable to the geometry furthest away in the axial direction from the connection of the clamping tabs. Depending on the tolerances of the coaxial cable outer conductor and the sleeve element 11, this results in different contact points and thus different signal paths from the coaxial cable outer conductor to the connector outer conductor.

The EP 0 975 051 A1 discloses another generic coaxial connector for connecting a coaxial cable, comprising a connector unit 1 and a cable receiving unit 2. The connector unit 1 has an insulating housing through which a connector inner conductor extends concentrically and is surrounded by an outer conductor housing. A radially inwardly projecting deformation block on the sleeve part 6 causes a radially inwardly acting deformation of the slotted sleeve element 4 arranged in the cable receiving unit 2 upon axial displacement of the cable receiving unit 2 relative to the connector unit 1. and thus contact between the sleeve element 4 and the coaxial cable outer conductor. At the same time, the cable sheath is clamped by the radially inwardly projecting end portion facing the coaxial cable to be connected. The proposed dual function of the sleeve part 6 limits the use of the proposed coaxial connector to a narrow range of connectable coaxial cables in terms of external dimensions. Furthermore, the clamping of the coaxial cable is limited to a small area in the axial direction, as in the first example.

The EP 3 329 554 B1 discloses a generic coaxial connector 20 for a coaxial cable 10, wherein the coaxial cable comprises a spirally corrugated coaxial cable outer conductor 11 and an insulating medium 13 through which a coaxial cable inner conductor 12 concentrically extends. The coaxial connector has a connector unit 21 and a cable receiving unit 22, which are detachably connectable to one another. The connector unit 21 consists according to 3 from a connector insulating housing 35, through which a connector inner conductor 34 passes concentrically and is surrounded circumferentially by a connector outer conductor housing 30. The cable receiving unit 22 has a cable receptacle in the form of a lock nut 70 and a sleeve element 60, the end region of which facing the coaxial cable 10 to be connected has a plurality of slots 68, as well as an expansion ring 50 engaging in the sleeve element 60 in the axial direction and a spiral spring 56 arranged between the expansion ring 50 and the sleeve element 60. To assemble the coaxial connector 20 with the coaxial cable 10, the prepared coaxial cable 10 is first screwed through the lock nut 70 into the sleeve element 60 of the cable receiving unit 22 until it rests against the expansion ring 50. This is particularly shown in the 1 The subsequent screwing of the cable receiving unit 22 with the coaxial cable received therein into the connector unit 21 initially causes an expansion of the coaxial cable outer conductor 11 and then a clamping and squeezing of the coaxial cable outer conductor 11 between the bevels 54, 67 of the expansion ring 50 and the sleeve element 60. In this way, a load-resistant electrical connection is established between the cable receiving unit 22 and the spirally corrugated coaxial cable outer conductor 11. The high number of individual parts in this proposal has a disadvantageous effect with regard to the expected costs. To assemble the coaxial cable 10 to the coaxial connector 20, the user is disadvantageously provided with two separate assemblies in the form of a cable receiving unit 22 and a connector unit 21, which the user must assemble in a further assembly step after connecting the coaxial cable 10 to the cable receiving unit 22. Another disadvantage of this proposal is the limitation to coaxial cables with a spirally corrugated coaxial cable outer conductor.

From the DE 10 2004 004 567 B3 Another generic coaxial connector is known, which has a connector unit consisting of a connector insulating housing through which a connector inner conductor 2 passes concentrically and is circumferentially surrounded by an outer conductor housing 1. The cable receiving unit, which is detachably connected to the connector unit, consists of a threaded sleeve 4 in which a clamping ring 6 and a profile seal 7 are arranged at an axial distance from one another. The clamping ring 6, arranged in the annular free space 4.1, has a continuous slot 6.1 in the axial direction, which allows deformation of the clamping ring 6 in the radial direction. For the assembly of the coaxial cable, which has a cable dielectric 51, a tubular coaxial cable inner conductor 50 passes concentrically through it, and a corrugated coaxial cable outer conductor 52, the user advantageously has only one assembly available, in which the aforementioned connector unit and the cable receiving unit are detachably connected to one another in a pre-assembled position. However, due to the disclosed design of the clamping ring 6, the proposal is limited to coaxial cables with a ring-corrugated outer conductor. Coaxial cable outer conductors whose corrugated profile follows a helical line cannot be used.

The object of the present invention is therefore to further develop a generic coaxial connector in such a way that it enables a secure, PIM-stable and defined contacting of differently shaped coaxial cable outer conductors to the coaxial connector outer conductor housing as well as a simple, cost-effective assembly of the coaxial cable to the coaxial connector.

This object is achieved according to the invention in a generic coaxial connector with the characterizing features of claim 1.

The arrangement of an annular clearance between the compression element of the connector unit and the end face of the sleeve element facing the connector unit ensures that the end face of the connected coaxial cable outer conductor always rests against the compression element, deforms it, or partially penetrates the compression element. This proves to be particularly advantageous with regard to undesired electrical connections from the coaxial cable outer conductor to the outer conductor housing of the connector unit. advantageous. For example, burrs caused by shortening the coaxial cable outer conductor may prevent a connection to the outer conductor housing of the connector unit.

In a preferred embodiment of the invention, the compression element in the connector unit comprises an elastic, electrically insulating material.

In a further advantageous embodiment of the invention, the outer diameter of the radially outwardly projecting deformation element on the sleeve element and the inner diameter of the radially inwardly projecting deformation block in the sleeve element receiving area of the cable receptacle have an identical value. This enables uniform deformation of the sleeve element over its entire length.

In a particularly advantageous embodiment of the invention, the radially outwardly projecting deformation element is arranged at the front end region of the sleeve element facing the connector unit. This allows for maximum axial spacing from the radially inwardly projecting deformation block in the sleeve element receiving area of the cable receiving unit. The stability of the contact between the sleeve element and the coaxial connector outer conductor increases with the distance between the deformation element and the deformation block in the axial direction.

In an advantageous embodiment of the invention, the sleeve element receiving area of the cable receptacle has a sleeve element stop surface for engaging the complementary end face of the sleeve element of the cable receiving unit. This enables defined and repeatable connections of the coaxial cable to the coaxial connector.

The design of the coaxial connector in a particularly advantageous embodiment as a pre-assembled assembly comprising the connector unit and the cable receiving unit, which can be detachably connected, proves to be advantageous with regard to user-friendly assembly.

In a preferred use of a coaxial connector according to the invention with a connected coaxial cable, which has a cable dielectric penetrated by a coaxial cable inner conductor and is surrounded in the circumferential direction by a coaxial cable outer conductor and a coaxial cable sheath, the front end region of the coaxial cable outer conductor engages at least partially in the compression element or deforms it.

• - Vorbereitung des anzuschließenden Koaxialkabels durch ein gestuftes Freilegen des Koaxialkabel-Innenleiters und des Koaxialverbinder-Außenleiters am stirnseitigen Endbereich des Koaxialkabels sowie das Entfernen des Koaxialkabel-Mantels auf einer definierten Länge
• - Bereitstellen des vormontierten Koaxialverbinders, wobei das Hülsenelement eine den Koaxialkabel-Außenleiter freigebende Stellung einnimmt
• - Einbringen des vorbereiteten stirnseitigen Endbereichs des Koaxialkabels in die Kabelaufnahmeeinheit hinein und hindurch bis zur Anlage des stirnseitigen Endbereichs des Koaxialkabel-Außenleiters am Kompressionselement der Verbindereinheit
• - Eine axiale Verschiebung der Kabelaufnahme relativ zum Verbinder-Außenleitergehäuse hin bis zur Anlage der dem anzuschließenden Koaxialkabel zugewandten stirnseitigen Begrenzung des Hülsenelements an der komplementären Hülsenelement-Anlagefläche der Kabelaufnahme der Kabelaufnahmeeinheit bewirkt eine radiale Verformung des Hülsenelements von einer den Koaxialkabel-Außenleiter freigebenden Stellung in eine den Koaxialkabel-Außenleiter kontaktierende Stellung

In an advantageous embodiment, the method for connecting the coaxial cable to a coaxial connector according to the invention comprises the following assembly steps:

• - Preparation of the coaxial cable to be connected by a stepped exposure of the coaxial cable inner conductor and the coaxial connector outer conductor at the front end of the coaxial cable and the removal of the coaxial cable sheath over a defined length
• - Providing the pre-assembled coaxial connector, wherein the sleeve element assumes a position releasing the coaxial cable outer conductor
• - Insert the prepared front end section of the coaxial cable into the cable receiving unit and through it until the front end section of the coaxial cable outer conductor rests on the compression element of the connector unit
• - An axial displacement of the cable receptacle relative to the connector outer conductor housing until the end limit of the sleeve element facing the coaxial cable to be connected rests against the complementary sleeve element contact surface of the cable receptacle of the cable receptacle unit causes a radial deformation of the sleeve element from a position releasing the coaxial cable outer conductor to a position contacting the coaxial cable outer conductor

The following description of advantageous embodiments of the invention serves to explain it in more detail in conjunction with the drawing.

• 1: eine perspektivische Ansicht des Koaxialverbinders in einer ersten vorteilhaften Ausführung mit angeschlossenem Koaxialkabel;
• 2: eine perspektivische Ansicht des Koaxialverbinders aus 1 nach der Art einer Explosionszeichnung;
• 3: eine perspektivische Schnittansicht der Verbindereinheit des Koaxialverbinders aus 1;
• 4: eine perspektivische Ansicht der Verbindereinheit aus 3;
• 5: eine Schnittansicht der Verbindereinheit aus 3;
• 6: eine vergrößerte Ansicht von Detail X aus 5;
• 7: eine perspektivische Ansicht des Verbinder-Innenleiters der Verbindereinheit aus 4;
• 8: eine Schnittansicht des Verbinder-Innenleiters der Verbindereinheit aus 7;
• 9: eine perspektivische Ansicht der Kabelaufnahmeeinheit aus 1 nach der Art einer Explosionszeichnung;
• 10: eine Schnittansicht der Kabelaufnahmeeinheit aus 9;
• 11: eine perspektivische Ansicht der Kabelaufnahmeeinheit aus 2;
• 12: eine Schnittansicht der Kabelaufnahmeeinheit aus 11;
• 13: eine vergrößerte Ansicht von Detail Y aus 12;
• 14: eine Schnittansicht des Koaxialverbinders aus 1 mit teilweise eingeschobenem Koaxialkabel;
• 15: eine vergrößerte Ansicht von Detail Z aus 14;
• 16: eine Schnittansicht des Koaxialverbinders aus 14 mit vollständig eingeschobenem Koaxialkabel;
• 17: eine vergrößerte Ansicht von Detail R aus 16;
• 18: eine Schnittansicht des Koaxialverbinders aus 16 mit vollständig eingeschobenem Koaxialkabel und vollständig montierter Kabelaufnahmeeinheit;
• 19: eine vergrößerte Ansicht von Detail T aus 18;

They show:

• 1 : a perspective view of the coaxial connector in a first advantageous embodiment with a connected coaxial cable;
• 2 : a perspective view of the coaxial connector from 1 in the manner of an exploded view;
• 3 : a perspective sectional view of the connector unit of the coaxial connector of 1 ;
• 4 : a perspective view of the connector unit from 3 ;
• 5 : a sectional view of the connector unit from 3 ;
• 6 : an enlarged view of detail X from 5 ;
• 7 : a perspective view of the connector inner conductor of the connector unit from 4 ;
• 8 : a sectional view of the connector inner conductor of the connector unit from 7 ;
• 9 : a perspective view of the cable holding unit from 1 in the manner of an exploded view;
• 10 : a sectional view of the cable holding unit from 9 ;
• 11 : a perspective view of the cable holding unit from 2 ;
• 12 : a sectional view of the cable holding unit from 11 ;
• 13 : an enlarged view of detail Y from 12 ;
• 14 : a sectional view of the coaxial connector from 1 with partially inserted coaxial cable;
• 15 : an enlarged view of detail Z from 14 ;
• 16 : a sectional view of the coaxial connector from 14 with coaxial cable fully inserted;
• 17 : an enlarged view of detail R from 16 ;
• 18 : a sectional view of the coaxial connector from 16 with coaxial cable fully inserted and cable holding unit fully assembled;
• 19 : an enlarged view of detail T from 18 ;

In the 1 to 19 A first advantageous embodiment of a coaxial connector according to the invention is shown schematically and is designated overall by the reference numeral 10. According to the 1 and 2 The coaxial connector 10 to be connected to a coaxial cable 11 includes a connector unit 20 and a cable receiving unit 90.

According to the 2 The coaxial cable 11 has a cable dielectric 12, which is concentrically penetrated by a coaxial cable inner conductor 13 and concentrically surrounded by a coaxial cable outer conductor 14. A coaxial cable sheath 15 surrounds the coaxial cable outer conductor 14 in the circumferential direction. Generic coaxial cables are known to those skilled in the art.

The 3 to 8 disclose the connector unit 20 with a connector insulating housing 60, through which a connector inner conductor 70 extends concentrically and is circumferentially surrounded by a connector outer conductor housing 40. At the end region of the connector unit 20 facing the mating connector, a union nut 30 is arranged which circumferentially surrounds the connector outer conductor housing 40 and is rotatably mounted relative to the connector outer conductor housing 40.

In the interior of the connector outer conductor housing 40, a compression element 80 is positioned concentrically to the coaxial connector 10 at its end region facing the coaxial cable 11 to be connected.

According to the 5 The union nut 30 extends between the end faces 31 and 32 as a rotationally symmetrical sleeve with an external hexagon 33. An internal thread 34 is provided in the interior for connecting the union nut 30 to a mating connector. To secure the union nut 30 to the connector outer conductor housing 40 in the axial direction, a securing element 37 with a rectangular cross-section 38 and a slot 39 extending in the axial direction is provided, which engages in complementary recesses 35, 44 in a manner familiar to those skilled in the art.

The union nut 30 can be designed as a turned part and made of an electrically conductive material, such as brass. Alternatively, a plastic material is also possible.

The securing element can, for example, be made of a spring steel wire.

The connector outer conductor housing 40 extends as a rotationally symmetrical, sleeve-shaped component between the end-face boundary surfaces 41, 42. The outer geometry of the connector outer conductor housing is essentially cylindrical and has a total of six circumferentially arranged flattened portions 43 at its end region facing the coaxial cable 11 to be connected, which can, for example, encompass the opening of an open-end wrench. The outer cylindrical surface 45 at its end region facing the mating connector is dimensioned such that an annular free space is created in the radial outward direction up to the internal thread 34 of the union nut 30, into which the outer conductor housing of a mating connector can engage.

The inner cavity of the connector outer conductor housing 40, which extends over the entire length of the connector outer conductor housing 40, starts from the end face 41 as a cylindrical recess 46 for receiving a complementary mating connector up to a stop surface 47 and has a circumferential and radially inward projecting fastening projection 48 for securing the connector insulating housing 60 in the cylindrical recess 46 of the connector outer conductor housing 40, which engages in the enveloping surface 63 of the connector insulating housing 60 in a manner known to those skilled in the art. This is particularly evident from the 6 clearly. An opening delimited in the circumferential direction by the cylindrical surface 49 adjoins the aforementioned cylindrical recess 46 with a smaller diameter via a chamfer in the direction of the coaxial cable 11 to be connected. This opening then transitions into a cone 50 to form the support surface 51 for the compression element 80 and to which the cylindrical receiving opening 52 for receiving the compression element 80 adjoins in the axial direction. The cylindrical receiving opening 52 opens via a sleeve element stop surface 53 into a connector opening 54 of larger diameter with an internal thread 56 for receiving the cable receptacle 100 of the cable receptacle unit 90, which is provided with a complementary external thread 106, and ends via an insertion chamfer 55 on the end face 42 of the connector outer conductor housing 40.

The connector outer conductor housing 40 can be designed as a turned part and made of an electrically conductive material, for example brass.

The connector insulating housing 60 arranged in the connector outer conductor housing 40 extends between the end-face boundaries 61, 62 in the form of a hollow cylinder with the enveloping surface 63, which is provided with a continuous slot 64 in the axial direction. The slot 64 enables assembly into the groove 75 of the connector inner conductor 70 provided for this purpose by temporarily widening the connector insulating housing 60, so that the continuous concentrically arranged opening 65 forms the aforementioned groove 75 as shown in 5 in the circumferential direction.

The connector insulating housing 60 can be provided as a turned part and made of an insulating plastic, for example POM.

The compression element 80 arranged in the receiving opening 52 of the connector outer conductor housing 40 extends as a hollow cylinder with the enveloping surface 83 in the axial direction between a first cover surface 81 and a second cover surface 82, which is penetrated over its entire length by the through opening 84, which opens at the end face via chamfers 85, 86 into the first and second cover surfaces 81, 82.

The compression element 80 can be designed as a turned part and made of an insulating plastic, for example POM.

The 7 and 8 disclose the connector inner conductor 70, which extends as a substantially rotationally symmetrical component between the end-face boundaries 71, 72. Arranged at its end region facing the mating connector is a contact region 73 of fully cylindrical shape, which opens into the boundary 71 via a tapered cone 74 and serves to contact a complementarily formed contact element of the mating connector. Adjacent to the coaxial cable 11 to be connected is a groove 75 for positively receiving the connector insulating housing 60. At its end region facing the coaxial cable 11 to be connected, the connector inner conductor 70 has a total of four identical contact spring arms 77 spaced apart from one another in the circumferential direction, which circumferentially surround a receiving opening 78, which serves to receive the coaxial cable inner conductor 13 to be connected. Each contact spring arm 77 extending from the cylindrical element 76 in the direction of the coaxial cable 11 to be connected has a contact zone 79 for electrical contact with the coaxial cable inner conductor 13, wherein the contact is made in a manner known to those skilled in the art by widening the contact spring arms 77 by inserting the coaxial cable inner conductor 13 into the receiving opening 78. This is shown in the 16 once again clearly shown.

The connector's inner conductor 70 can be provided as a turned part and made of a conductive material, such as spring bronze. For optimal signal transmission, a galvanic surface, such as gold plating, can also be provided.

The 9 to 13 show the cable receiving unit 90, which consists of the cable receiving unit 100 and the sleeve element 130.

According to the 9 and 10 The cable receptacle 100 extends in sleeve form between the end-face boundaries 101, 102. At its end region facing the coaxial cable 11 to be connected, a cylindrical element 104 is arranged, which is equipped with two opposing flattened areas 103 that can be gripped by the complementary opening of an open-end wrench. At its end region facing the connector unit 20, an external thread 106 is arranged on the cylindrical outer geometry 105, which enables a connection of the cable receptacle unit 90 to the complementary internal thread 56 of the connector outer conductor housing 40 of the connector unit 20.

The interior of the cable receptacle 100 has a sleeve element receiving area 110 extending in the axial direction between the end boundary 101 and the sleeve element contact surface 111 and a cable receiving area 120 extending between the end boundary 102 and the cable system 122, which is surrounded in the circumferential direction by the cable receiving sleeve 121.

Between the sleeve element receiving area 110 and the cable receiving area 120 there is a passage area 108 which is circumferentially delimited by the cylindrical enveloping surface 109 and establishes a connection between the sleeve element receiving area 110 and the cable receiving area 120.

To ensure the deformation function of the sleeve element 130 to be inserted into the cable receptacle 100, the sleeve element receiving area 110 has a stepped design. The sleeve element receiving area 110 starts from the end boundary 101 with a conical deformation opening 112 tapering in the direction of the coaxial cable 11 to be connected, which transitions into a cylindrical contact area 113 and, via a further conical transition opening 114 tapering in the direction of the coaxial cable 11 to be connected, opens into a radially inwardly projecting deformation block 115.

The cable holder 100 can be provided as a turned part and made of a conductive material, for example brass.

According to the 9 and 10 The sleeve element 130 extends between the first end-face boundary 131 and the second end-face boundary 132 as a rotationally symmetrical, sleeve-shaped component with a continuous coaxial cable outer conductor opening 140 and with a slot 141 extending in the axial direction. At its end region facing the connector unit 20, a radially outwardly projecting deformation element 139 is arranged, which is delimited in the axial direction by the second end-face boundary 132 and the end face 137. The rounded portion 138 between the end face 137 and the deformation element 139 prevents an otherwise sharp edge from digging into the complementary deformation opening 112 of the cable receptacle 100 during the deformation of the sleeve element 130 in the radial direction for contacting the coaxial cable outer conductor 14.

Adjoining the radially outwardly projecting deformation element 139 in the direction of the coaxial cable 11 to be connected is a sleeve element deformation region 136, which has a smaller diameter than the deformation element 139 and, after a shoulder 134, opens into a sleeve element insertion region 133, which has the smallest outer diameter of the sleeve element 130. The shoulder 134 is rounded with the sleeve element deformation region 136 over a radius 135.

The sleeve element 130 can be provided as a turned part and made of a conductive material, for example brass.

The 11 to 13 show the cable receiving unit 90 in the pre-assembled state as an assembly with the cable receptacle 100, into which the sleeve element 130 is concentrically inserted, so that the cylindrical contact area 113 of the cable receptacle 100 surrounds the sleeve element deformation area 136 in the circumferential direction and the first end boundary 131 of the sleeve element 130 is at a distance A from the sleeve element contact surface 111. In this position, the radii 135, 138 engage under the deformation opening 112 and the conical deformation opening 114 at least partially, but without causing a deformation of the sleeve element 130 in the radial direction. This is shown in the 13 shown particularly clearly. In this position, the coaxial cable outer conductor opening 140 of the sleeve element 130 assumes a position K1 that exposes the coaxial cable outer conductor 14.

In the 14 to 19 The method for connecting the coaxial cable 11 to a coaxial connector 10 according to the invention is described. 14 In the first assembly step, the prepared coaxial cable 11 is inserted into the coaxial connector 10 in the axial direction through the cable receiving unit 90 and into the connector unit 20. The preparation of the coaxial cable 11 includes the gradual exposure of the coaxial cable inner conductor 13 and the coaxial cable outer conductor 14 as well as the partial removal of the coaxial cable sheath 15 up to the cut surface 16. In this position, the coaxial cable outer conductor opening 140 of the sleeve element 130 of the cable receiving unit 90 pre-assembled in the connector unit 20 assumes a position K1 which releases the coaxial cable outer conductor 14 and enables the insertion of the coaxial cable outer conductor 14 into the coaxial cable outer conductor opening 140 of the sleeve element 130. Likewise, the through-opening 84 of the compression element 80 allows the exposed coaxial cable inner conductor 13 to be inserted and passed through. The appropriate dimensioning of the cable receiving sleeve 121 allows the coaxial cable sheath 15 to be received in the circumferential direction.

In the pre-assembled position of the cable receiving unit 90 relative to the connector unit 20, the second end-face boundary 132 rests against the sleeve element stop surface 53 of the connector outer conductor housing 40, forming an annular clearance E between the second end-face boundary 132 of the sleeve element 130 and the first cover surface 82 of the compression element 80. The formation of the annular clearance E guarantees defined contact between the coaxial cable outer conductor opening 140 of the sleeve element 130 and the coaxial cable outer conductor 14 by receiving the end region of the coaxial cable outer conductor 14, which protrudes from the second end-face boundary 132 and is shortened at the end and may contain burrs, in the compression element 80.

In the further course of the connection process, the coaxial cable 11 reaches its final position in the pre-assembled coaxial connector 10 according to the 16 and 17 by placing the exposed front end region of the coaxial cable outer conductor 14 against the cover surface 82 of the compression element 80 while maintaining the distance A. This means that the coaxial cable outer conductor opening 140 of the sleeve element 130 of the cable receiving unit 90 pre-assembled in the connector unit 20 continues to assume a position K1 exposing the coaxial cable outer conductor 14, wherein the cutting surface 16 of the exposed coaxial cable sheath 15 to the cable system 122 of the cable receiving unit 100 has a value B1 greater than or equal to zero. The coaxial cable inner conductor 13 extends concentrically through the through-opening 84 of the compression element 80 and engages the receiving opening 78 of the connector inner conductor 70, contacting the contact zones 79 to the coaxial cable inner conductor 13 in a manner known to those skilled in the art.

To contact the coaxial cable outer conductor opening 140 of the sleeve element 130 to the coaxial cable outer conductor 14, the next 18 and 19 The step shown involves completely screwing the cable receptacle 100 with the external thread 106 into the complementary internal thread 56 of the connector opening 54 of the connector outer conductor housing 40 from the pre-assembly position 16 into the final connection position after 18 . While maintaining the contact of the second end-face limit 132 with the sleeve element stop surface 53 of the connector outer conductor housing 40, the first end-face limit 131 comes to rest against the sleeve element contact surface 111 and in this way limits the axial movement of the cable receptacle 100 into the connector opening 54. The 16 The distance A shown in the figure assumes the value zero in the final connection position. However, a relative movement takes place between the cable holder 100 and the coaxial cable 11, whereby the 16 described distance B1 to the distance B2 in 18 changed.

As already mentioned, screwing the cable receiving unit 90 into the cable receiving opening 54 causes a relative movement between the cable receiving unit 100 and the sleeve element 130 in the axial direction. This axial movement causes the radially outwardly projecting deformation element 139 to engage below the cylindrical contact area 113 and the radially inwardly projecting deformation block 115 to engage over the sleeve element deformation area 136, resulting in a deformation of the sleeve element 130 in the radially inward direction toward the coaxial cable outer conductor 14. The deformation opening 112 provided in the cable receiving unit 100 and the conical transition opening 114, in conjunction with the rounded portions 135, 138, enable a uniform deformation of the sleeve element 130 radially inward in the sense of a wedge-shaped thrust mechanism.

In summary, screwing the cable receptacle 100 into the connector opening 54 causes the sleeve element 130 to deform radially inward from a position K1 exposing the coaxial cable outer conductor 14 to a position K2 contacting the coaxial cable outer conductor 14. The dimensions of the outer diameter of the radially outwardly projecting deformation element 139 and the inner diameter of the radially inwardly projecting deformation block 115, as well as the axial distance between the deformation element 139 and the deformation block 115, ensure, in the exemplary embodiment, a uniform radially inward deformation of the sleeve element 130 and thus a secure contacting of the coaxial cable outer conductor 14 by the sleeve element 130 of the cable receptacle unit 90.

Depending on the requirements of the coaxial connector 10 and with the aid of suitable dimensioning, it is also possible to use the described contacting of the sleeve element 130 to the coaxial cable outer conductor 14 as cable strain relief. This functional integration has a positive effect on the length of the coaxial connector 10.

Claims (7)

Coaxial connector (10) for connection to a mating connector and for connecting a coaxial cable (11), which has a cable dielectric (12) penetrated by a coaxial cable inner conductor (13) and is surrounded in the circumferential direction by a coaxial cable outer conductor (14) and a coaxial cable sheath (15), wherein the coaxial connector binder (10) has a connector unit (20) and a cable receiving unit (90), wherein the connector unit (20) is constructed from a connector insulating housing (60) through which a connector inner conductor (70) extends concentrically and is surrounded in the circumferential direction by a connector outer conductor housing (40), wherein the connector unit (20) has a compression element (80) for at least partially receiving and/or contacting the front end region of the coaxial cable outer conductor (14), wherein the compression element (80) is delimited in the axial direction by a first cover surface (81) and a second cover surface (82), wherein the cable receiving unit (90) has a cable receiving unit (100) and a slotted sleeve element (130), and wherein a cable receiving region (120) and a sleeve element receiving region (110) are arranged in the cable receiving unit (100), wherein the Sleeve element (130) has a first and a second end-face boundary (131, 132) and a radially outwardly projecting deformation element (139), wherein the second end-face boundary (132) of the sleeve element (130) and the second cover surface (82) of the compression element (80) face each other in the axial direction, wherein a radially inwardly projecting deformation block (115) is arranged in the sleeve element receiving area (110), which deformation block is spaced apart from the deformation element (139) in the axial direction when assembled with the sleeve element (130), wherein the deformation element (139) and the deformation block (115) cause a radially inwardly directed deformation of the sleeve element (130) from a Coaxial cable outer conductor (14) releasing position (K1) into a position (K2) contacting the coaxial cable outer conductor (14), characterized in that an annular free space (E) is formed between the second end-face boundary (132) of the sleeve element (130) and the second cover surface (82) of the compression element (80). Coaxial connector (10) according to Claim 1 , characterized in that the compression element (80) is made of an elastic, electrically insulating material. Coaxial connector (10) according to one of the preceding claims, characterized in that the outer diameter of the radially outwardly projecting deformation element (139) on the sleeve element (130) has the same value as the inner diameter of the radially inwardly projecting deformation block (115) in the cable receiving area (120). Coaxial connector (10) according to one of the preceding claims, characterized in that the radially outwardly projecting deformation element (139) is arranged on the end region facing the connector unit (20) with the second end-face boundary (132) of the sleeve element (130). Coaxial connector (10) according to one of the preceding claims, characterized in that the sleeve element receiving area (110) of the cable receptacle (100) has a sleeve element contact surface (111) for contacting the first end-side boundary (131) of the sleeve element (130). Coaxial connector (10) according to one of the preceding claims, characterized in that the coaxial connector (10) consists of a maximum of one pre-assembled assembly comprising the connector unit (20) and the cable receiving unit (90), wherein the cable receiving unit (90) is detachably connectable to the connector unit (20). Coaxial connector (10) according to Claim 1 with a connected coaxial cable (11) which has a cable dielectric (12) through which a coaxial cable inner conductor (13) passes and is surrounded in the circumferential direction by a coaxial cable outer conductor (14) and a coaxial cable sheath (15), characterized in that the front end region of the coaxial outer conductor (14) at least partially penetrates into the compression element (80) or deforms it.

Images