DE1490840B2 - ELECTRIC PLUG-IN COUPLING FOR CONNECTING COAXIAL CABLES - Google Patents

Description

The invention relates to an electrical plug-in coupling for connecting coaxial lines with resilient ones Shield and inner conductor contacts on one of the two coupling halves.

The need to create electrical plug-in couplings that are absolutely reliable in operation is particular it has become more and more apparent that the demands on such components have risen considerably in missiles and rockets are. Absolutely reliable plug-in couplings are also required wherever there are operational difficulties want to avoid during an installation. Experience teaches that users like this Devices expect operational safety and reliability from installation parts that the high level, the properties of components for missiles come close.

In electrical plug-in couplings, it is known to use plug pins and sockets in which an electrical terminal engages another terminal. Do not use the contact socket with great care pulled out of the contact pin, then the contact part of the socket can be a permanent impairment experienced or completely changed with regard to its original geometric shape will.

In order to avoid this, it is also known to use flexible connecting elements in electrical plug-in couplings to use. The individual elements are in a preferred contact position resiliently or resiliently biased, from which they are a little bit during use be bent out. Such constructions are expensive to manufacture and assemble and uneconomical in maintenance and consequently for general use, although they are on and are safe to operate in and of themselves.

The invention has for its object to provide an electrical plug-in coupling which the has desired properties of the spring preload of the connecting elements against each other and is at the same time economical in terms of manufacture, assembly and service life.

This object is inventively achieved in that, in the one coupling half, the outer conductor is extended beyond the designed as a contact pin inner conductor also in an 'electric plug coupling of the type described and ^r indoor respectively and provided "· outer conductor against spring force against the plug displaceable sleeves are whose ends pointing in the plug-in direction are tapered conically inward, and that socket-like contact parts are provided in the other coupling half: -are which are tapered outwardly at their ends to match the ends and are longitudinally slotted to form resilient fingers In a special embodiment of the plug-in coupling according to the invention, the umbrella-like extension of the outer conductor of one coupling half has a shoulder, and a helical spring is housed between the shoulder and the one sliding sleeve, which serves to hold the tapered end of the H To press the oil against the spring force of the resilient fingers of the other half of the coupling and to establish electrical contact with the outer conductor. The contact pressure on the inner conductor can be generated in an analogous manner.

An embodiment of the invention is shown in the drawing and will be described in more detail below described. It shows

Fig. 1 is a plan view of an embodiment of the electrical plug-in coupling according to the invention,

F i g. 2 shows a view of a longitudinal section through an embodiment of the electrical plug-in coupling according to the invention, from which one can see the contact parts that are under spring pressure,

F i g. 3 is a view of a section through a plug-in coupling according to the invention, which is in a suitable insulating base plate is housed,

4 shows a view of a section through a contact element for the embodiment according to FIG. 3, which is built into a suitable insulating base plate is and

F i g. 5 is a view of a section through a complete electrical plug-in coupling according to the invention when the contact is completely closed in accordance with regulations.

Like F i g. 1 shows, the part 10 represents one coupling half of the electrical plug-in coupling according to the. * Invention. This part 10 has an outer conductor * 12, which interacts electrically with the shield part of the corresponding component of the plug-in coupling in order to be able to establish a continuous shield connection through the joined connection in a simple plug-in connection. A displaceable sleeve 14 engages over part of the length of the outer conductor 12, one end of the sleeve 14 resting against the one end of a helical spring 16 which is wrapped around the terminal. The other end of this helical spring abuts the shoulder 18 of the screen and is precisely axially aligned with this screen. The sleeve can therefore, as a result of its arrangement in the axial direction along the shield, execute movements towards and away from the shoulder 18.

As one can see from FIG. 2 of the drawing best seen in detail, the outer conductor 12 of the plug-in coupling according to the invention is a three-part construction element, namely the tubular outer conductor parts 12 a and 12 b with a conductive sleeve 12 c, which is in electrical connection with (parts 12 a and 12 b at the junction of these parts is. the ring 12 c provides a good electrical connection between the parts 12 a and 12 b. the outer conductors 12 consist of three individual Konstruktionselementenj because this distribution has in terms of manufacture and assembly, the greatest economic benefits.

The sleeve has a flange 40, a frustoconical clamping ring with clamping surface 22 and a circular recess 24. The helical spring 16 of the plug-in coupling pushes, as already said above, with one end against the shoulder 18. The other end of the helical spring 16 is in the Recess 24 of the sleeve 14 and presses against the Schuller 25 at the bottom of this recess. Will if no pressure is exerted on the displaceable sleeve 14, then the helical spring 16 moves into the completely relaxed position and presses the sleeve 14 into its static position, which is shown in FIG. 1 and 2 reproduced is.

The F i g. 3 and 5 show that the entire arrangement can be embedded in insulating material, the individual parts of the connector must be held in the correct operating position.

A flange 15 which extends inward in the radial direction is located in the tubular outer conductor part 126 in the vicinity of the connection point 13, as can best be seen from FIG. 2 sees. An insulating piece 26 is accommodated in the interior of the part 126 , which has a shoulder 27 which rests against the flange 15 of the part 126 in order to precisely align and mount the insulating piece 26 within the part 126 in the axial direction. A second insulating piece 30 is located inside the central bore 17 of the outer conductor part 126, one end 31 adjoining the insulating piece 26 and the insulating piece 30 resting from this end 31 on the free end 19 of the shielding part 126 . The insulator 30 has a shoulder 32 to form a joint between a first central bore 34 and a second (larger) the central bore 36. The tubular outer conductor part 126 is pressed at specific points, and in particular ¹ intervals on the periphery inward, as for example, the locations 38 in FIG. 2 show. A protective ring 40 is placed around the outer conductor part 12 6 at the deformed points.

An electrical connecting element 42 is located completely within the outer conductor 12 in the arrangement. The element 42 engages through the central bore 28 of the insulating piece 26 and through the bores 36 and 34 of the insulating piece 30.

Fi g. 2 shows that the connecting element 42 has the two contact pins 44 and 46. The contact pin 44 is hollow and has the shape of a tube. A collar 48 between the ends of the connecting element 42 rests against the insulating piece 26 in order to fix the connecting element 42 against movement in one direction.

A coil spring 50 is around the contact pin 46 of the connecting element 42 put around. One end of the helical spring 50 rests against the collar 48 ' to bring the helical spring 50 relative to the contact pin 46 in the correct axial position.

A sleeve 52 engages around the contact pin 46. The sleeve has a flange 54 and a main body 56. The flange> 54 prevents movement of the sleeve 52 beyond the shoulder 32, which is between the bores 34 and 36 is located. The diameter of the outer periphery 58 of the main part 56 of the sleeve is smaller than the diameter of the bore 36 so that the main body of the sleeve in the Inside this bore is axially displaceable.

As one can see from FIG. 3 of the drawing, the coupling half 10 is located in a split insulating block 62 with the two pieces 63 and 64, which allow easy assembly. The insulating piece 63 engages over the tubular outer conductor part 12 6 in the vicinity of the connection point 13 and has an inwardly projecting annular flange 66 which sits on the outer surface of the outer conductor part 12 6. The piece 63 is held in its axial alignment with the outer conductor part 126 by the shoulder 126 ' , and the flange 66 abuts this shoulder. The piece 64 of the insulating block is pressed against the block 63 during assembly and can be attached to it with clips, bolts, screws or other fasteners.

F i g. Figure 4 of the drawing shows a sectional view and a partial side view of the corresponding part the plug-in coupling according to the invention. The coupling is designated as a whole with 70 and has an outer conductor 72. This outer conductor consists of a first tubular piece 74 and a second tubular piece 76 which abut one another and have a joint 77 with one another. A ring 78 is applied to the inner wall of the tube so that it is the junction between overlaps sections 74 and 76 and a good electrical connection via this junction

ίο forms away. The outer conductor 72 of the coupling half 70 can be identical in shape to the coupling half 10 if necessary. A modified embodiment of an outer conductor is shown in FIG. 4 shown. However, it has a shorter rod length from the end 79 of the tube (which corresponds to the end 19 of the conductor 12 ) to the shoulder 75. Here there is a need for the installation of a spring or an axially displaceable shield on the coupling half 70 of the connector. The outer conductor part 76 of the coupling half 70 has a number of resilient fingers 80 .

A sleeve 82 made of insulating material is housed in the interior of the central bore 84 of the outer conductor part 76 and is axially aligned therein in that the inner end abuts the shoulder 86 associated with the central bore of the outer conductor part 76, the indentations 88 in the insulating material engage in order to bring about a rigid connection and fastening of the insulating sleeve 82 in the interior of the central bore 84 of the outer conductor part 76. A protective ring 90 is placed over the indentation points 88.

In the insulating sleeve 82 there is a central bore 92 in which an electrical connecting element 94 is accommodated. The electrical connector 94 is held within the central bore 92 by flanges 95 and 96 which extend radially inwardly on either side of the flange 98 on the insulating sleeve 82. One end 100 of the connecting element 94 forms a connection point for a line. The other end 102 of the connector carries a number of fingers 104 separated from one another by slots 105 which extend inwardly from the extreme end of the clip to allow the fingers 104 to flex and thus mate with the end 46, over which they are pushed when the two interlocking parts 10 and 70 are electrically connected to one another.

The coupling half 70 is housed in an insulating body 106 (FIG. 4). The part 106 has a bore 108 which extends inwardly from the end face 109. A second bore 110 with a smaller diameter than the bore 108 extends from the inner end 112 of the bore 108 to the opposite end face 114 of the insulating body 106. A shoulder 116 is located between the bore 108 and the bore 110 of the insulating body. The shoulder 75 of the shielding part 76 rests against the end face 114 of the insulating body 106 . Once the protective ring 90 has been inserted into the plug-in coupling, it abuts the shoulder 116 of the insulating body 106 .

The two parts 10 and 70 of the electrical connector are thus held together by a sliding connection or a latch connection. With the conventional connectors, there is no way to prevent the contact between the fingers.

like to manufacture one part and the corresponding elements of the other part; will the Therefore, fingers bent or damaged in the known devices, then at the same time the Effect of the electrical connector significantly impaired. Will the connector but used in an arrangement or device that requires the highest level of operational reliability such disadvantages are avoided at all costs. With the electrical plug-in coupling according to the In the invention, the arrangement is made so that inevitably a controllable electrical contact between the interlocking parts, even if the static positions of the fingers of their preferred orientations differ.

If the resilient fingers 104 have now moved over the end 46 of the front conical part 101 , then the front beveled surfaces 101 of the fingers come into engagement with the inclined surface 53 of the sleeve 52. The sleeve 52 is elastically biased so that it can act as a result the spring 50 reaches the extreme position along the end 46. The elastic response of the spring 50 to the sleeve 52 must be below the magnitude of the force of the frictional engagement of the fingers 104 with the end 46, because otherwise the spring would tend to go from its compressed position to the static position and thereby the fingers at least for the Part of the end 46 would loosen.

The inclined surface 103 of the fingers 80 comes into engagement with the inclined surface 22 of the displaceable sleeve 14 as soon as the coupling halves 10 and 70 are brought into engagement with one another. The sleeve 14 is under spring pressure and is pushed with the help of the helical spring 16 into the outermost position on the outer conductor part 12 b.

In an advantageous embodiment of the subject matter of the invention, a spring wire with the dimension 26 (ie 0.459 mm wire diameter) made of stainless steel with the trade name AISI302 is used, in which four turns and an effective free or static length of 5.963 mm and an outer diameter of 5.588 mm 8 ounces bring fingers 80 to bend 2.788 mm so that they are fully engaged with part 12b .

Claims (3)

Patent claims: 1. Electrical plug-in coupling for connecting coaxial lines with resilient shield and inner conductor contacts in one of the two coupling halves, characterized in that in one coupling half (10) the outer conductor (12) is extended beyond the inner conductor formed as a contact pin (46) and in each case on the inner and outer conductors (46, 12) are provided sleeves (14, 52) which can be displaced against spring force against the insertion direction, the ends (22, 53) of which are tapered inwardly in the insertion direction, and that in the case of the other coupling half (70) socket-like contact parts are provided which, in adaptation to the ends (22, 53) , are tapered conically outward at their ends and are longitudinally slotted to form resilient fingers (80, 105). 2. Plug-in coupling according to claim 1, characterized in that the umbrella-like extension of the outer conductor (12) of one coupling half (10) has a shoulder (18) and between the shoulder (18) and the displaceable sleeve (14) for generating the spring force one the Outer conductor (12) concentrically surrounding helical spring (16) is housed, which with the Outer conductor (12) and the sleeve (14) is in conductive connection. 3. Plug-in coupling according to claim 1 or 2, characterized in that the inner conductor (46) is housed in a body made of insulating material, one extending in the radial direction Has collar and for generating the spring force a concentrically surrounding the inner conductor Helical spring (50) which is conductively connected to the inner conductor (46) that one end of the Spring (50) strikes against the collar (48) and that the other end thereof on that of the insertion direction opposite end of the sleeve (52) rests. 1 sheet of drawings