DE1565998C3 - Electrical coaxial connector - Google Patents

Description

The invention relates to an electrical coaxial connector with an electrically conductive Housing, an insulating body mounted in the housing and having a coaxial through-hole, one arranged in the through hole and by radial shoulders in the axial direction in the Insulating body secured contact part which can be connected to the inner conductor of a coaxial cable.

From GB-PS 9 00 393 a connector is known in which the insulating body with a smooth, coaxial through hole is provided, in which the to be connected to the inner conductor of a coaxial cable Can insert contact part. Around the contact part in the inserted state against axial displacement to secure towards the front end of the connector is on the contact part the cable-side end of which a radial locking flange is formed. This locking flange is in the assembled State of the connector between the cable-side face of the insulating body and the dielectric of the Pinched in the cable. A disadvantage of this known connector is that at the transition point Significantly different wave resistances occur between the insulating body and the cable, which result in reflections express the electrical signal to be transmitted via the connector. The axial attachment of the Contact part by means of the clamped between the insulating body and the dielectric of the cable to be connected The locking flange is also disadvantageous in that the contact part is usually relatively soft formed dielectric can be pressed in, which can lead to breakage of the inner conductor and an uneven electrical field distribution can arise in the dielectric, which can lead to arcing. From the FR-PS 9 50 440 a connector emerges as known, in which an insulating body is used, which is formed in the rear section with a smaller outer diameter than in the front Section. This insulating body is provided with a coaxial through hole into which the contact part is used. On the side facing the cable there is a counterbore with a in the insulating body Diameter provided which is equal to the diameter of the dielectric of the coaxial cable to be connected is. In the assembled state of this connector, the coaxial cable with its dielectric is so far in the insulator pushed in so that it completely fills the counterbore. It is stated there that the impedance of the connector to the characteristic impedance of the coaxial cable to be connected can be adapted that the lengths of the insulating body sections and the counterbore and their individual diameters can be matched to one another. In this known connector, however, is not ensures that no undesirable and non-definable air inclusions arise that would cause the desired Wipe out impedance equalization again. In particular, such air inclusions between the end of the dielectric of the coaxial cable and the contact part arise because the contact part in the insulator is not secured at least in an axial direction Plug connectors adjust the impedance by matching the lengths and diameters mentioned of the connector to the coaxial cable to be connected during the manufacture of the connector be made. A subsequent adaptation to one coaxial cable with another Characteristic impedance is practically impossible.

From US-PS 31 24 406 another connector goes

binder as known, in which the contact part in the insulating body thereby against axial displacement it is ensured that an annular recess in the coaxial through hole of the insulating body is provided, in which an annular locking flange engages on the contact part

For axially securing a contact part in an insulating body, it is known from DT-AS 10 32814, to provide the contact part in the course of its length with a cross-sectional constriction, in the one corresponding cross-sectional constriction engages in the insulating body

The present invention is based on the object of providing a connector of the type mentioned at the beginning Specify the type in which an impedance equalization is created in a simple manner

This object is achieved according to the present invention in that the radial shoulders the contact part adapted radial shoulders in the insulating body in the area between its axial End faces are provided which, when the contact part is inserted, form-fit on its radial shoulders rest that the housing at the cable-side end has a coaxial bore for receiving the up to the inner conductor and dielectric has the cut back end of a cable that on the cable-side end face of the insulating body is provided a counterbore with a diameter serving to compensate for impedance which is larger than the diameter of the bore provided at the cable-side end in the housing and a depth which is selected in accordance with the desired impedance compensation, and that the length of the over the shoulders on the cable side protruding end of the contact part is chosen so that it is in the Insulating body inserted state with the end face formed by the counterbore in the insulating body concludes.

In the specified coaxial connector is in a simple manner by means of a between the end of the Coaxial cable to be connected and the adjacent section of the connector provided Annular gap an adaptation of the impedance of the connector to the wave resistance of the coaxial cable achieved. The radial and axial dimensions of this annular gap are chosen so that the Connector causes as few reflections as possible in a certain frequency band. The publication "Handbook of Design and Performance of Cable Connectors for Micro-Wave Use" Bu-Ships, Index No. N.E-110718, May 1956 by J.W.E. Griemsmann are instructions for calculating the axial and radial dimensions of this annular gap refer to. It is important with the present connector that the contact part in the insulator in axial direction is secured against displacements, since otherwise indefinable air gaps between the Contact part and the adjacent dielectric of the coaxial cable could arise.

Based on a preferred embodiment shown in the drawing, the invention ^ o explained in more detail below it show:

Fig.l is a cross-sectional view of a connector (Socket contact part) of the connector,

F i g. 2 is a cross-sectional view of a connector (Pin contact part) of the connector,

F i g. 3 shows a cross-sectional view of the interconnected plug connectors according to FIGS. 1 and 2, and F i g. 4 is a partial view of the contact part engaged with the insulating body.

The connector 10 according to FIG. 1 contains a metallic housing 12, one facing the cable side Has end extending socket 13 which is provided with gripping grooves 14 around the outer conductor of a coaxial cable after complete assembly. A cylindrical bore 17 extends through the socket 13 to a countersunk hole 18, the diameter of which at the shoulders 19, an inclined Wall 20 and at a beveled end 21 is enlarged for easy connection with the To create mating connectors. A cylindrical insulating body 22 is dimensioned so that this firmly in the Counterbore 18 fits It is secured by a locking ring 23 which fits into the shoulder 19 under pressure. the Insulating body 22 is provided with a through hole 25 which is formed by a cavity Counterbore 24 extends through a forwardly extending fitting 26 and which has a locking shoulder 27 has the counterbore 24 is not completely with the in the fully assembled state Dielectric of a coaxial cable is filled, as will be explained below, which results in an impedance equalization The locking shoulder 27 is clearer from the enlarged view in FIG Fig.4 can be seen in which part of an annular Shoulder 28a with angled edge 28 can be seen, while the other edge 29 lies radially to the through hole 25

According to Fig.l, the socket contact 30 is firmly secured in the insulating body 22, the socket contact for the sake of better illustration not together with the inner conductor of the coaxial cable is shown. The socket contact 30 is provided with a bore 31 into which a soldering opening 32 opens, through which Solder can be introduced to the inner conductor of the coaxial cable prior to final assembly to attach the connector. In engagement with the locking shoulder 27 of the insulating body 22 is a annular locking groove 33 in the socket contact 30. F i g. 4 shows in detail how the radial edges 34 and 35 are of the socket contact 30 lie tightly against the corresponding locking shoulders 27. The contact part 36 of the Socket contact 30 is designed so that it can accommodate a pin contact. The insulator 22 usually consists of a deformable plastic, e.g. B. polytetrafluoroethylene, or one Polypropylene connection, whereby the rigid socket contact 30 the locking shoulder 27 during the insertion can deform. The socket contact 30 is pushed through the through hole 25 until the front radial edge 35 of the annular locking groove 33 into position over the radial edges 29 of the locking shoulder 27 snaps. The rear edge 34 of the socket contact 30 fits snugly on the base of the beveled end 28 on, whereby the socket contact 30 is firmly attached in this position in the insulating body 22 during Known devices usually only block the contact in one direction, here there is a blocking effect in both Directions, namely in the forward and backward direction. The shoulder 29 of the insulating body 22 is achieved used to prevent contact from the connector due to forces acting on the cable is pulled out. However, it is also essential that a retention of the socket contact 30 in the forward direction is created by the shoulder 28 as a forward movement of the socket contact 30 can occur when the center conductor of the cable

ζ. B. expands as a result of an increase in the ambient temperature This position setting in the longitudinal direction of the Socket contact 30 through mating radial shoulders is very important for reducing an relative movement between the various parts of the connector and therefore significantly reduced Changes in the V.S.W.R.properties (standing wave ratio).

2 shows the connector 11 in cross section with the pin contact connected to the no cable for the sake of simplicity of the description A rotatable housing 37 contains a metallic main connector body 38 which is in the Housing 37 is rotatably mounted and held by means of a clamping sleeve 39 which is inserted into a groove 40 in the housing 37 is pressed. The clamping sleeve 39 sits loosely on the main connector body 38 and enables thus that the housing 37 can be easily rotated during final assembly. the Main connector body 38 is also held by a flexible seal 41 that slides with the Housing 37 mates. A spring washer 42 provides a biasing force to compress the seal 41, which defines the main connector body 38 when the connector is fully assembled. the Main plug body 38 contains an intermediate coupling part 43 which has a flexible outer contact element 44 a rearwardly extending sleeve 45 connects and thus leads to a uniform structure. the Socket 45 may be provided with grooves or notches 46 that exert a strong gripping force on the outer conductor of the Exercise coaxial cable when the connector is fully assembled. The housing 38 has a cylindrical bore 47 through which the sleeve 45 extends to a counterbore 48, which extends over the length of the flexible outer contact element 44. The contact element 44 is with provided an outwardly widening annular contact part 49, which has a good electrical Contact with the housing 12 is ensured when the two connectors 10 and 11 are plugged together are. The contact element 44 can be preformed and inserted into the intermediate coupling part 43 by machine or soldered in, it being possible for it to be plated with a coating. An insulating body 51 can then in his position will be pressed. To connect the insulating body 51 to the contact element 44 is in the Contact element 44 a radially inwardly projecting notch 50 is provided, the inner edge of which the Reference numeral 62 bears.

The insulating body 51 has various features in order to achieve satisfactory properties of the connector to surrender. The air gap 52 compensating for the impedance differences is through a countersunk hole formed, the depth and diameter of which are determined by a calculation made by the sizes of the desired impedance differences assumes a voltage curve that is as flat as possible over the length of the To get plug connection.

It should also be noted that the front end 53 of the insulating body 51 axially over the end of the widening annular contact part 49 extends. This extension results in much improved Standing wave ratios of the assembled plug-in connection, as it is capable of the insulating body 51 firmly under the biasing action of the spring washer 42 on the insulating body 22 after assembly to let abut, whereby variable air gaps in the assembled connector avoided will. The front end 53 of the insulating body 51 delimits a counterbore with a depth that of the Length of the forwardly extending fitting part 26 of the insulating body 22 of the connector 10 is the same. During the final assembly of the connectors, the insulating body 22 sits in the through the front end 53 of the insulating body 51 formed countersunk hole until the insulating body 22 and 51 in the axial Direction tightly against each other.

Just as in the insulating body 22 of the plug connector 10, there is also in the insulating body 51 of the plug connector 11 a locking shoulder 55 is provided which protrudes radially inward from the through hole 54 and a Has beveled edge 56. When the pin contact 57 with the contact element extending forward 58, the annular shoulder 59 and the contact-receiving bore 60 for the inner conductor of the cable is inserted through the cylindrical bore 47 into the through bore 54 of the insulating body 51 is, the pin contact meets the beveled edge 56. The front part 58 of the pin contact 57 is with a bevel 61 is provided which runs onto the bevel 56, whereby the flexible insulating material of the Insulating body 51 is briefly deformed. Finally, the locking shoulder 55 snaps into the annular one Locking groove of the pin contact 58 and holds it firmly within the insulating body 51, as shown in FIG is shown. A forward or backward movement of the pin contact 58 is prevented when the Connector 11 is fully assembled, causing changes in electrical properties of the connector due to mechanical forces or expansion as a result of changes in the Ambient temperature are practically switched off. In the wall of the cable receiving the inner conductor Bore 60, an opening 63 is provided through which a solder can be introduced to to fasten the inner conductor of the cable before the pin contact 57 is inserted into the connector 11 will.

F i g. 3 shows the fully assembled connector. The cable 64 is in a known manner prepared by the outer insulating cover 65, the metallic braid of the outer conductor 66 and the Dielectric 67 are cut back in stages in order to expose the inner conductor 68. Before the final Assembling both ends 64 and 69 of the cable are prepared in this way and attached to the pin and Socket contact 30 or 57 soldered on. These soldered-on contacts 30, 57 are then inserted into the sleeves 13 and 45, respectively the plug connector 11 or 10 is used, the outer conductor 66 being widened somewhat so that the after rear-extending sockets 13 and 45 can be pushed under the braid.

When inserting the insulating body 22 or 51 into the housing 12 or 37, the locking shoulders 27 or 55 briefly deformed In the final state, the locking shoulders 27 and 55 are in the ring-shaped Locking grooves of the contact parts snapped into place. The specified structure of the connector enables a mutual connection of the same by a turning process, with an accurate in both directions Storage of contacts is created.

When the socket or pin contact soldered to the inner conductor of the cable into the respective insulating body are snapped into place, cable ends 64 and 69 are securely attached to sockets 13 and 45, respectively. The outer conductor

66 cover substantially all of the outwardly extending sockets. Compression sleeves 70, the have previously been attached to the coaxial lines 64 and 69 are over the outside of the Outer conductor pushed and firmly pressed together in this position. The outer conductors 66 are in the Grooves or grooves 14 and 46 of the sockets 13, 45 pressed in, which results in a very good retention effect Outer tubes 72 resulting for the cable are then pushed over the compression sleeves and at this point shrunk by heat. The completed plug-in connectors can now become a complete plug-in connection be joined together.

When joining the two connectors 10 and 11, the locking projection 16 occurs in a helical shape formed groove 76. The housing 37 is rotated until the projection 16 is firmly seated in the opening 77. During the Inserting the connector 11 into the connector

the 10, the beveled end 21 of the connector 10 via the externally flanged contact part 49 of the Connector 11 out until the end of the connector 12 touches the resilient seal 41. the Seal 41 is compressed by the end 21 until the fitting part 26 of the insulator 22 to the Insulating body 51 abuts the end face 74 of the countersunk bore 24. The axial force on the flexible seal 41 and the insulating body 51 presses the entire main plug body 38 against the spring washer 42, wherein the locking lug 16 is held within the opening 77 and thereby the to be connected Connectors 10 and 11 are held against one another by biasing. Since the front The fitting part 53 of the insulating body 51 extends before the contact part 49, the insulating body 22 fits exactly into the Insulating body 51 until it abuts at 74.

1 sheet of drawings

609 529/4

Claims (6)

Patent claims: 1. Electrical coaxial connector, having an electrically conductive housing, one in the housing mounted, a coaxial through hole having insulating body, one arranged in the through hole and by radial shoulders in the axial direction in the insulator secured contact part, which is connected to the inner conductor of a coaxial cable is connectable, characterized in that that the radial shoulders (34,35; 59) on the contact part (30; 57) adapted radial shoulders (28, 29; 56) is provided in the insulating body (22; 51) in the area between its axial end faces are which, when the contact part (30; 57) is inserted, form-fit on its radial shoulders (34, 35; 59) rest that the housing (12; 43) at the cable-side end has a coaxial bore for The end of a cable cut back except for the inner conductor (68) and dielectric (67) (64) has that on the cable-side end face of the insulating body (22; 51) an impedance equalization serving counterbore (24; 52) is provided with a diameter which is larger than that Diameter of the bore provided at the cable-side end in the housing (12; 43) and with a depth which is chosen according to the desired impedance compensation, and that the length of the Shoulders (34, 35; 59) end of the contact part 30 protruding on the cable side; 57) is chosen in such a way that that in the state inserted into the insulating body (22; 51) with the counterbore (24; 52) formed end face in the insulating body (22; 51) closes. 2. Coaxial connector according to claim 1, characterized in that the contact part (30; 57) is essentially cylindrical and in its between the front, contact-making Part (36; 58) and the rear connection part lying area a cross-sectional constriction (33; 59), and that in the through hole (25; 54) of the insulating body (22; 51) a corresponding cross-sectional constriction (27; 55) is provided. 3. Coaxial connector according to claim 2, characterized in that the cable side lying Shoulders (34,28) of the cross-sectional constrictions (27; 55) of the contact part (30; 57) and the insulating body (22; 51) are beveled. 4. Coaxial connector according to one of claims I to 3, characterized in that the Insulating body (22; 51) made of polytetrafluoroethylene. 5. Coaxial connector according to one of claims 1 to 3, characterized in that the Insulating body (22; 51) consists of polypropylene. 6. Coaxial connector according to at least one of claims 1 to 5, characterized in that the contact part (30; 57) at the cable-side end an axial bore for inserting the inner conductor (68) a coaxial cable (64) and a radial soldering opening (32) opening into the coaxial bore.