WO2000046882A1 - Hf right-angle coaxial connector element - Google Patents

Abstract

The invention relates to an HF right-angle coaxial connector element in the form of a printed board component. Said connector element comprises an electroconductive housing (2) with connections at the printed board end. A right-angle coaxial connection line (3) is integrated into said housing. The central carrier wire of the coaxial connection line (3) consists of two straight central carrier wire elements (7, 8), namely a central carrier wire element (7) at the plug end and a central carrier wire element (8) at the printed board end. Said central carrier wire elements are interconnected via a clamping joint inside the single-piece housing (2). A cross-sectional contraction (10) is configured at the central carrier wire element (7) at the plug end and a clamping slot (12) which is open towards the top is configured at the printed board end of the central carrier wire element. The clamping connection is established by sliding the clamping slot (12) at the printed board end of the central carrier wire element (8) onto the cross-sectional contraction (10) at the plug part of the central carrier wire element (7).

Description

description

RF coaxial ink connector part

The invention relates to an RF coaxial plug connector part in printed circuit board component, consisting of an electrically conductive housing with printed circuit board side / connections, in which a right-angled coaxial connecting line is integrated, in which the coaxial plug part of the coaxial connecting line is on the front side of the housing is attached and its connections serve at the same time for its attachment to the printed circuit board and in which the inner conductor of the coaxial connecting line, which is held in insulating sleeves, is inserted into the outer conductor parts integrated into the housing.

Muscle connector parts of this type are known, for example, from US Pat. No. 5,088,937. The insertion of the right-angled inner conductor held in insulating sleeves of the coaxial connecting line m of the outer conductor parts integrated into the housing is only possible here in that the housing is provided on its rear wall with an assembly opening which, after inserting the inner conductor held in insulating sleeves, has an opening on this assembly adapted housing cover is closed.

The elbow plug connector parts are required in large numbers, for example for signal ultiplexer. A simple automatic production with as few consecutive simple steps as possible is therefore necessary for an economical production. The cumbersome insertion of the right-angled inner conductor into the housing, as well as the subsequent closing of the housing, contradicts this objective.

From the as yet unpublished German patent application with the official file number 197 56 890.4 is also a Generic HF-coaxial connector part known, in which the inner conductor of the coaxial connecting line is formed in two parts to simplify assembly. The inner conductor consists of two straight inner conductor parts, a connector-side and a circuit board-side inner conductor part, which enter into a clamp connection within the housing. For the clamp connection, a plug pin is formed on the inner conductor part on the plug side and a pin clamp on the inner conductor part on the printed circuit board, into which the plug pin is inserted.

During assembly, the inner conductor part on the circuit board side is first inserted into the housing with the pin clamp and then the inner conductor part on the plug side with the plug pin.

In certain applications, however, it would be advantageous if the inner conductor part on the pin side and then the inner conductor part on the printed circuit board side could be inserted into the housing for the assembly.

Starting from US Pat. No. 5,088,937, the invention is based on the object of specifying an angled plug connector part which can be produced inexpensively and can be assembled automatically in a few simple steps.

This object is achieved according to the invention in that the inner conductor of the coaxial connecting line consists of two straight inner conductor parts, namely a plug-side inner conductor part and a printed circuit board-side inner conductor part, which form a clamp connection within the housing, which is made in one piece, at their close ends and for this clamp connection at the relevant end of the connector part-side inner conductor part, namely its rear end, a diameter constriction and relevant end of the inner side part of the printed circuit board, namely its upper end, a clamping slot is provided and in this the diameter of the inner part side of the plug part is received.

The two-part design of the inner conductor makes it possible to manufacture the housing in one piece. Assembly is also easy to automate due to the design of the angle plug connector part according to the invention and is limited to a few steps, since only the inner conductor parts m and their respective insulating sleeves have to be inserted into the housing afterwards.

Compared to the unpublished patent application with the official file number 19756890.4, the invention has the advantage that the part of the inner conductor on the plug side and only then the part of the inner conductor on the circuit board side is used first in the assembly process. The circuit board-side inner conductor part is preferably a flat molded part such as. B. executed as a sheet metal part and therefore only strong in the longitudinal direction. By plugging the inner conductor part on the printed circuit board side over the diameter cord on the inner conductor part on the plug side, it is only loaded in the longitudinal direction and there is no danger that it will bend during assembly.

Another advantage of the design according to the invention is that the connector-side inner conductor part is axially positively fixed via the clamping slot of the inner part on the circuit board side. Thus, even with a large number of plug-in operations, there is no risk that the inner conductor on the part of the connector will become loose in the clamp connection.

Further advantageous embodiments of the invention are disclosed in the subclaims. The invention is explained in more detail below with reference to ^exemplary embodiments illustrated in the drawings. Show in the drawings

FIG. 1 shows a first exemplary embodiment of an angled plug connector part in an exploded view,

FIG. 2 shows the angular plug connector part connected to a printed circuit board according to FIG.

FIG. 3 shows a second exemplary embodiment of an angled plug connector part with an inner conductor part that is pulled out downwards,

FIG. 4 shows a third exemplary embodiment of an angled plug connector part with the inner conductor part pulled out downward on the circuit board side,

FIG. 5 shows a first embodiment for the upper end of the inner conductor part on the printed circuit board in an enlarged manner

Presentation,

FIG. 6 shows a second embodiment for the upper end of the inner conductor on the printed circuit board in an enlarged view,

Figure 7 shows a third embodiment of the upper end of the inner side part of the printed circuit board in an enlarged view.

The angled connector part 1 shown in FIG. 1 in an exploded view and in longitudinal section in FIG. 2 in the form of a printed circuit board component consists of a one-piece metallic housing 2 into which a right-angled coaxial connecting line 3 is integrated. The coaxial connecting line 3 has a coaxial plug part 4, the outer conductor part 5 of which protrudes from the front side 6 of the housing 2 and is an integral part of the housing 2. The rectangular in ^¬ nenleiter of the coaxial connection line 3 is composed of two straight inner conductor parts, namely a plug part side inner conductor part 7 and a board-side inner conductor part 8. The male part side inner conductor part 7 is a round bar and has at its front end a tip 9 and at its rear end a constriction in diameter 10.

Within the coaxial angled connector part, the inner conductor part 7 on the plug side is received in an insulating sleeve 11, the area of the inner conductor part 7 on the plug side with the constricted diameter 10 protruding beyond the insulating sleeve 11 at the rear end.

According to the first exemplary embodiment shown in FIGS. 1 and 2, the inner conductor part 8 on the printed circuit board side is designed as a flat molded part, preferably as a stamped sheet metal part with a clamping slot 12 at its upper end. Below the clamping slot 12, a stop 13 is formed on the inner conductor part 8 on the circuit board side via a width reduction, against which an insulating sleeve 14 is pushed from below when the parts are assembled. On the circuit board side, the outer conductor part 36 is formed by the wall of the housing 2.

The housing 2 has a connection at its bottom 15 at the four corner areas. In the first exemplary embodiment shown in FIGS. 1 and 2, these connections are designed as pin-shaped solder connections 16. Furthermore, the underside 15 of the housing 2 has an attachment 17, which represents an offset, adjacent to a four pin-shaped solder connections 16.

As FIG. 2 shows, the housing 2 of the angular plug-in connector part 1 with its projections 17 is placed on a printed circuit board 18. The printed circuit board-side inner conductor part 8 is also formed as a solder connection 19 below the receiving area for the insulating sleeve 14. Both this solder connection 19 and the solder connections 16 of the housing are inserted into metallized connection holes 20 on the printed circuit board 18 and soldered to the printed circuit board 20 at these connection holes.

In the case of partial assembly, the inner conductor part 7 on the plug side is first inserted into the associated insulating sleeve 11 and inserted into the housing 2 via the opening 21 on the plug side. The positioning of the connector-side inner conductor part 7 in the insulating sleeve 11 takes place in such a way that the constriction in diameter 10 is no longer surrounded by the insulating sleeve. The inner conductor part 7 on the plug side, including the insulating sleeve 11, is inserted into the housing to such an extent that the constriction in diameter 10 lies exactly above the center of the housing opening 22 on the circuit board side. In order to simplify the positioning of the insulating sleeve 11 with the inserted inner conductor part 7 on the plug side, a shoulder 21a is worked into the inner wall of the outer conductor part 5, against which the insertion tool strikes.

For further assembly, the insulating sleeve 14 is pushed onto the inner side of the printed circuit board 8 from below and the inner side of the printed circuit board 8 together with the insulating sleeve 14 is inserted into the housing 2 via the opening 22 on the side of the printed circuit board. Here, the clamping slot 12 is pushed over the constriction 10 until the underside of the clamping slot 12 strikes the inner conductor 7 on the part of the connector.

The clamping connection between the constricted diameter 10 and the clamping slot 12 results in a good coaxial fixation of the inner conductor part 7 on the plug side and also a good low-resistance electrical connection between the two inner conductor parts 7 and 8. The second ^exemplary embodiment shown in FIG. 3 differs from the first exemplary embodiment shown in FIGS. 1 and 2 in that the connections on the housing side are pin-shaped press-in contacts 23 and the connection of the inner conductor 8 on the printed circuit board side is designed as a pin-shaped press-in contact 24. FIG. 3 shows the inner conductor part 8 including its insulating sleeve 14 pulled downward out of the housing 2 for better understanding.

The third exemplary embodiment shown in FIG. 4 also differs from the exemplary embodiments shown in FIGS. 1 to 3 with regard to the connections, which are embodied here as SMD connections 25. In FIG. 4, the inner conductor part 8 on the circuit board side and its insulating sleeve 14 are again shown pulled out of the housing 2 for better understanding. Four SMD connections 25 are provided on the housing 2, each of which protrude slightly above the underside of the housing 2.

The printed circuit board-side inner conductor part 8 also has an SMD connection 26 at its lower end. For this purpose, it has a foot part 35 bent at a right angle, at the end of which the SMD connection 26 is arranged. In this embodiment, the insulating sleeve 14 is pushed over the inner side part 8 of the printed circuit board. For this purpose, it is provided with a longitudinal slot 27, which is dimensioned such that the insulating sleeve 14 can be pushed over the somewhat wider area with the clamping slot 12 of the inner conductor part 8 on the circuit board side.

On the underside of the housing 2, a groove channel 34 is formed toward the rear 28 of the housing 2, in which the angled foot part 35 of the inner conductor part 8 on the printed circuit board side is inserted during assembly. The SMD connection 26 of the inner conductor part 8 on the printed circuit board side projects in the assembled was about the back 28 of the housing 2 before, so that soldering is easily possible.

FIGS. 5 to 7 show different embodiments of the inner conductor part 8 on the circuit board side, only the upper clamping area being shown in FIGS. 5 and 6.

FIG. 5 shows the clamping region of the inner conductor part 8 on the circuit board side, as has already been shown in the embodiments according to FIGS. 1 to 4. According to this embodiment, the inner conductor part on the circuit board side is designed as a flat molded part, such as a sheet metal part. The clamping slot 12 begins on its open upper side with a first V-shaped section 29, which merges into a clamping section 30 with parallel sides. Following the clamping section 30, a second V-shaped section 31 is formed, which does not close completely, but merges into a narrow, vertical slot 32 in the center.

When the inner conductor part 8 on the circuit board side is pushed onto the constricted diameter 10 on the inner conductor part 7 on the plug side, the inner conductor part 8 is centered on the constricted portion 11 via the first V-shaped section 29 and then pushed onto the constricted section 10 along the clamping area 30 up to the second V-shaped section 31 . The second V-shaped section 31 thus serves as a stop.

The narrow vertical slot 32 in the extension of the second V-shaped section 31 facilitates the elastic widening of the clamping slot 12.

The upper area of the inner conductor part 8 shown in FIG. 6 is identical in geometry to the embodiment in accordance with FIG. 5. Rich 30 are formed on the parallel sides inwardly tapering cutting edges 33 and the material ^¬ thickness of the inner conductor part 8 is chosen slightly stronger.

This embodiment has the advantage that the inner conductor part 8 with the clamping slot 12 is pushed onto the diameter constriction 11 on the inner conductor 7 on the plug part side, as in a insulation displacement device, and thus the cutting edges 33 cut into the material of the inner conductor part 7 on the plug side. This creates a much firmer and better mechanical and electrical connection.

FIG. 7 shows a third embodiment variant of the inner conductor part 8 on the circuit board side, wherein according to this embodiment it is designed as a tube in the upper region. Two clamping slots 12 are thus formed in the tube, the geometry of which is identical to the clamping slots according to FIGS. 5 and 6. The individual areas are therefore also provided with the same reference symbols.

The design of the upper part of the inner conductor on the circuit board side as a tube has the advantage that four contact points are created when it is pushed onto the inner conductor part 7 on the plug side, thus ensuring a very good mechanical and electrical connection. Furthermore, a tube has a much higher stability than a flat molded part, as a result of which the spring force of the clamping slot can also be selected to be significantly higher, without the risk that material failure will occur on the inner conductor part 8 on the circuit board side.

According to this embodiment, the lower region is designed as a pin-shaped solder connection 19, as was already shown in the embodiment according to FIGS. 1 and 2. It is also possible to design the lower area of the inner conductor part 8 on the circuit board side as a press-in contact or as an SMD contact. When designing as an SMD contact, the insulating sleeve is either made in two parts or the through hole is large enough that it can be pushed over the angled area (cf. version according to FIG. 4).

Claims

claims 1. RF coaxial angle connector part in the form of a printed circuit board component, consisting of an electrically conductive housing (2) with printed circuit board-side connections, into which a right-angled coaxial connecting line (3) is integrated, in which the coaxial connector part (4) of the coaxial Connecting line (3) is attached to the front (6) of the housing (2) and its connections serve at the same time to fasten it to a printed circuit board (18) and with the inner conductor of the coaxial connecting line (3.) Held in insulating sleeves (11, 14) ) integrated in the housing (2) outer conductor parts (5, 36), characterized in that the inner conductor of the coaxial connecting line (3) consists of two straight inner conductor parts (7, 8), namely an inner conductor part (7) and There is a printed circuit board-side inner conductor part (8) which, within the one-piece housing (2), clamps together at its ends which are close to each other enter into a bond and for this clamping connection a constriction in diameter (10) is provided at the relevant end of the inner conductor part (7) on the plug part side, namely its rear end, and a clamping slot (12) is provided on the relevant end of the inner conductor part (8) on the printed circuit board side, namely its upper end and the diameter constriction (10) of the inner conductor (7) on the connector part side is accommodated therein. 2. RF coaxial angle connector part according to claim 1, characterized in that the circuit board-side inner conductor part (8) is a flat molded part, for example a sheet metal part. 3. RF coaxial angle connector part according to claim 1, characterized in that the upper region of the board-side inner conductor part ^¬ (8) is formed in which the clamping slot (12) is a tube or a rod. 4. RF coaxial angle connector part according to one of the preceding claims, characterized in that the clamping slot (12) on its upper open side with a V-shaped section (29) begins, then merges into a parallel clamping section (30), following the clamping section (30) narrowed in a second V-shaped section (31) and ending in a narrow vertical slot (32 ^" ). 5. RF coaxial angle connector part according to one of the preceding claims, characterized in that in the clamping slot (12) on the inside cutting edges (33) are formed. 6. RF coaxial angle connector part according to one of claims 1 to 5, characterized in that the circuit board-side inner conductor part (8) in the region of the clamping slot (12) has the width of the diameter constriction (10) in the plug-side inner conductor (7). 7. RF coaxial angle connector part according to one of the preceding claims, characterized in that the circuit board-side inner conductor part (8) at its lower end has a stop (13) in the form of a width or cross-section reduction, which is the position of the bottom attachable insulating sleeve (14). 8. RF coaxial angle connector part according to one of claims 1 to 7, characterized in that four connections are provided on the housing (2) in the four corner regions on the underside (15) and on the underside (15) there are also four lugs (17) which represent an offset and adjoin the four connections and with which the housing (2 ) sits on the circuit board (18). 9. RF coaxial Wmkel plug connector derteil according to claim 8, characterized in that the four connections are the four corner areas on the underside (15) of the housing (2) pin-shaped solder connections (16) and the connection of the circuit board-side inner conductor part (8) is also a pin-shaped solder connection (19). 10. RF coaxial Wmkel-Steckverb derteil according to claim 8, characterized in that the v_ι he connections in the four corner areas on the underside (15) of the Geh uses (2) are pin-shaped press-in contacts (23) and the connection of the circuit board-side inner conductor part (8) is also a pin-shaped press-in contact (24). 11. RF coaxial Wmkel-Steckverb derteil according to claim 8, characterized in that the connections both of the housing (2) including the outer conductor parts integrated therein (5, 36) and the connection of the circuit board-side inner conductor part (8) SMD connections (25th , 26) are. 12. RF coaxial Wmkel connector part according to claim 10, characterized in that the SMD connections (25) for the housing (2) including the integrated outer conductor parts (5,36) are flat from contact stands, from which four or more on the circumference of the housing (2), namely on its underside (15), are arranged and protrude slightly beyond the underside (15) of the housing (2), the printed circuit board-side inner conductor part (8) has an angled foot part (35), at the free end of which the SMD connection (26) is provided, this angled foot part (35) is arranged below an outwardly directed groove channel (34) which is open towards the underside (15) and to an outside (28) of the housing (2), and this angled foot part (35) with its SMD connection (26 ) protrudes beyond the opening of the groove channel (34) on the outside (28) of the housing (2). 13. A method for mounting an RF coaxial angle connector part in the form of a printed circuit board component according to one of claims 1 to II, characterized in that the plug-side and the printed circuit board-side inner conductor part (7, 8) are each inserted into the associated insulating sleeve (11, 14), - The plug-side inner conductor (7) together with the associated insulating sleeve (11) is inserted into the housing (2) - Then the inner conductor (8) on the PCB side together with the corresponding insulating sleeve (14) is pushed into the housing (2) from the connection area on the PCB side - And in this case the clamping slot (12) on the printed circuit board-side inner conductor (8) is pushed as far as it will go onto the diameter reduction (10) on the plug-side inner conductor (7).