NO317436B1 - Laser fiber optic switching mechanism - Google Patents

Description

The present invention relates to a mechanism for locking an optical fiber connector, and in particular a locking mechanism for a connector that forms an optical connection between a panel or motherboard and a circuit board.

It is relatively common within the electronic industry to transmit signals by means of an optical fiber due to a number of advantages of light transmission in relation to the transmission of electrical signals, namely the very high transmission speed of the signals and the light signals' insensitivity to electrical and magnetic netic cousin. A common example of high-speed data transfer is between substrate cards with printed electrical circuits, where it is often desirable to have both an electrical and optical connection between the cards, as this connection often occurs between a mother board and daughter board.

An optical fiber cable is usually made up of an inner core surrounded by a sheath and around this fiber for reinforcement and further a protective plastic insulation. The core transmits all or most of the light and is usually made of glass or plastic so that the diameter of this core can be as small as 2 to 8 micrometers. The sheath surrounding the core is usually made of plastic or flake and serves to keep the light inside the inner core due to the specially selected and different refractive indices of the core and sheath, whereby the outer diameter of this sheath can be about 20 to 125 micrometers . The very small diameter of the inner light-transmitting core means that great accuracy is required when connecting two optical fibers. This is achieved by feeding the core and shell through the bore in a precisely manufactured sleeve and holding it in this by anchoring or bonding, the optical fiber protruding through the tip of the sleeve, and the tip of the sleeve being so finely polished that the optical the fiber is flush with the tip of the sleeve. The sleeve is then inserted into a precisely manufactured sleeve which precisely centers and aligns the sleeve so that the sleeve of another optical cable can be inserted through the other end of the sleeve until both sleeve tips butt against each other in exact alignment. It is also important to ensure that the gap between the tips of coupled optical fibers is as small as possible and remains constant, which requires the sleeves to be pressed against each other. This is achieved by means of springs mounted in the optical fiber connector and which push against the sleeve. The spring also absorbs the varying axial positions of the sleeve tips. In order to enable the accurate centering of the sleeves in the bushing, it is necessary to allow the sleeves to "float" in relation to the contact, this being for example achieved by providing a certain clearance between the sleeve and the housing.

One of the difficulties in forming an optical connection from card to card is due to the inaccurate spacing of the cards which can for example be caused by using a hybrid connector where a number of adjacent optical and/or electrical contacts are placed on a card and plugged in at the same time in corresponding contacts on the motherboard. Electrical contacts can easily be engineered to absorb 2 or 3 mm of axial misalignment by simply making the receptacle space and corresponding pin or tongue terminal sufficiently long. The problem with optical contacts, however, is that the axial misalignment has been absorbed by the spring device as mentioned above, which can produce either a very high compression force or insufficient compression force. This varying spring force is undesirable due to the potentially high loads on the motherboard and the uncontrolled butting forces on the sleeves. In addition, it is desirable to avoid absorption of spring forces through the cards as this causes it to twist and also requires stronger and more expensive structural support.

Some of the above problems have been partially solved by the prior art described in "Compact and Self-Retentive Multi-Ferrule Optical Back Panel Connector" published in "Journal of Light Wave Technology", Volume 10, No. 10, October 1992. This reference describes a jack or contact spring assembly mounted to a back panel and a plug mounted on a printed circuit board for optical connection therebetween, the plug having a locking mechanism for locking to an inner housing in the jack. The plug also has a lock release that disconnects the plug and the jack from the jack's outer housing, as this outer housing is connected to the rear panel. This solution provides a method of releasing the connecting spring forces from the boards and also allows axial movement of the plug and jack relative to the back panel to thereby absorb axial tolerances. One of the problems with this solution, however, is that the back panel jack can have a significant number of optical connections so that the optical cables that lead into the rear part of the back panel jack are relatively heavy and stiff, thereby putting a strain on the jack.

However, the plug must be able to slide inside an outer housing, which means that the fixation between the jack and the outer housing must also allow a small amount of play. Not only is the fastening of the jack to the rear panel thus weakened by the need for sliding, but the sliding of the jack inside the outer housing is made difficult due to the increased frictional force and tilting of the jack inside the outer housing due to the load from the optical the cables.

An optical fiber connector which can be connected or disconnected by simple insertion and removal operations, without imposing any sleeve-coupling force on other elements, is described in EP-A-430107. The optical connector, which corresponds to that defined in the preamble of claim 1, comprises a first housing, a second housing, a third housing slidably held in the second housing, a first engagement mechanism provided between the second and third housings for to provide engagement between these two housings when the first and third housings are not coupled, a second engagement mechanism provided between the first and third housings, to provide engagement between these two housings when the first housing is coupled to the second and third the house. The contact further comprises a first release means for the first housing, to release the first engagement mechanism when the third housing is engaged with the first housing, and a second release means for the second housing, to release the second engagement mechanism when the second housing is connected to the third house or the first house is disconnected from the second and third houses. In order to allow the optical connector to preferably be used in a plug-in connector with as small dimensions as possible and with as high a packing density as possible, a new floating structure for the connector, a new sliding sleeve support structure, a strong coupling mechanism are also shown for the optical plug, a reliable insertion structure for the optical plug or jack, a contact jack that can be cleaned and replaced, etc.

One of the purposes of the present invention is to provide an optical connector that can absorb axial misalignment and still have a strong and firm connection between the plug and the jack.

Another object of the invention is to provide an optical contact device which does not exert any significant forces through the objects on which they are mounted.

Yet another object of the present invention is to provide an optical contact device which can absorb axial misalignment without affecting the spring forces inside the contact device.

Yet another object of the invention is to provide a reliable locking mechanism for an optical connector which can be very easily locked and released without the use of tools.

It is also an object of the present invention to provide an optical contact which is particularly suitable for use in a hybrid connection system composed of both optical and electrical contacts, where the optical contacts have the ability to absorb axial tolerance which is necessary for the electrical contact.

The present invention consists of a fiber optic contact device as defined in patent claim 1.

A preferred embodiment of the invention will now be described in more detail with reference to the attached drawings, where: Fig. 1 is an isometric sketch of a commercially available plug and jack device; Fig. 2 is an expanded sketch of the plug arrangement in Fig. 1; Fig. 3 is an expanded sketch of the plug body in Fig. 2; Fig. 4 shows an expanded sketch of the recording device in Fig. 1; Fig. Shows a cross-section through the axial center line of the recording device on Figures 1 and 4; Fig. 6 is a cross-section through a jack according to the invention, which is in the process of being inserted into a plug, whereby the receiving jack housing is shown in dotted lines; Fig. 7 shows an exploded, isometric sketch of a single position plug connector in accordance with the present invention; Fig. 8 is a detailed isometric sketch of the locking profile on the front for the housing which is shown in Figure 7; Fig. 9 -13 shows the complete locking sequence for the jack and the plug, with Fig. 11 being a snapshot of the release of the thrusters; Fig. 14 -17 show the release sequence of the plug and jack; Fig. 18 shows a cross-section of a slightly different embodiment of an optical connector with the plug and jack housings in solid lines; Fig. 19 is a plan view from the front of an integrated housing for a hybrid connector which

carries both optical and electrical contacts;

Fig. 20 shows a view in a lower plane of the house in Fig. 19; and

Fig. 21 shows a side view of the house in figure 19.

Reference is first made to Figure 1, where reference numeral 2 shows a commercially available fiber optic plug device which can be inserted into and lockably connected to a receiving jack device shown at 4. This known fiber optic contact plug 2 is composed of an inner plug body shown generally as 6, and an outer plug housing 8.

It is now shown in Figures 2 and 3 where the plug device 2 will be described in more detail. The inner plug body 6 in figure 2 is shown in figure 3 expanded to include an insulating housing body 10, a sleeve device 12, a spiral spring 14, insulating tube 16 and an inner body part 18. The body part 10 comprises an inner cavity 20 to receive the sleeve 12 and a rear part of the housing space 20 is profiled to receive the front end 22 of the inner body part 18 so that the ceramic sleeve 12 is flowable inside the insulating housing body 10 and spring-secured between a stem part 24 of the sleeve device and an outer flange 26 of the inner body part 18. A fiber 28 can thus be received slidably through the inner body part 18, the insulating tube 16, the spiral spring 14 and into the sending position inside the sleeve 12, whereby the sleeve and the inner body part 18 are engaged in the housing body 10 for spring- charged withholding in this.

The housing body 10 comprises upper and lower surfaces 30 and side surfaces 32. The housing body 10 has chamfered surfaces such as 34, which provide a polarizing feature for the body 10 as described in more detail below. The body 10 has sunken surfaces at 36 which extend rearwards to a transverse rib 38, behind which there is a further sunken surface at 40. Further back there is an inclined surface at 42 which leads up to a raised abutment surface 44. It will be understood that the underside of the body 10 as shown in Figure 3 is identical to the upper surface, but that only such a surface is visible in Figure 3.

Reference is now made to figure 2, where the outer plug housing is shown in more detail and comprises an inner cavity at 30 for sliding reception of the housing body 10, from the rear edge, into a locked state. The cavity 50 is provided with surfaces 52 that correspond to the chamfered surfaces 34 for correct polarization of the plug body 10 in the outer housing 8. The outer housing 8 is provided with a locking opening 54 that extends towards the front contact surface 56. The openings 54 delimit two side walls 58 which flank the openings 54 and which are connected to the upper and lower bridge portions 60. The side walls 58 extend rearwardly from the front surface 56 and include cam surfaces 62 which extend obliquely rearwardly to a top surface 64 of the outer housing 8. On the inner surface of the side walls 58, a recess is formed which includes a slanted edge 66 and a horizontal edge 68. At the rear edge of the opening 54, a notch is formed at 70 which forms a stop member for the housing 8 as described in more detail below. Finally, the housing 8 includes a polarization knob 72 on only one side of the housing for correct polarization in the recording device 4.

The inner device 6 can now be slidably received in the rear part of the housing 8 to a fully locked position as shown in Figure 1, where the raised abutment surface 44 is received in the notch 70, which prevents withdrawal of the plug body 6. The plug body 6 is also movable forward inside the plug housing 8, to a position where the transverse rib abuts a rear edge of the bridge part 60.

Reference is now made to figures 1, 4 and 5 where the receiving device 4 will be described in more detail. The receiving device 4 is composed of two identical halves 80 with flanges 82 which can collide with each other and be fixed in place by means of gluing or ultrasonic welding. The receiving device further comprises two identical locking devices 84 which between them receive a fiber aligning sleeve 85. The sleeve 85 is engaged in openings 86 in the rear part of the locking members 84, and is retained in cylindrical bushing parts 88 of the locking members 84 by means of a shoulder 90 at the leading edge of the cylindrical bushings 88, which is most clearly shown in Figures 4 and 5. The locking members 84 further comprise locking protrusions 91 which comprise individual locking protrusions 92, which are flanked by side wing parts at 94. A clamping member 95 in the form of a metal spring can is clamped on one of the receiving halves 80 so that the receiving device 4 can be clamped on a panel such as a motherboard 100 as partially shown in Figure 5, where the receiving device 4 is held to the motherboard 100 between the flanges 82 and a locking spear 96 on the clamping device 95. Finally, the identical the halves 80 a polarization slot 98 for receiving the polarization knob 72 on the plug device 2.

Connection and release of the plug device 2 to the receiving device 4 will now be described in detail. The plug device 2 can be accommodated in a receiving cavity 99 (Figure 5) in the receiving device 4 so that the sleeve 12 is positioned inside the alignment sleeve 85 in the receiving device 4. It should be understood that the wing members 94 (Figure 4) on the locking protrusions 91 are as wide as the cam surfaces 62 (Figure 2), but narrower than the inner surfaces 71 (Figure 1) of the side walls 58 (Figure 2). Movement of the plug member 2 into the receiving device 4 therefore causes the outer wing members 94 to move up along the cam surfaces 62 to a position where the wing members are on the top surfaces 64, whereby continued insertion of the plug member 2 causes the wing members 94 to move down along the surfaces 66 to a resting position on the surface 68 (Figure 2). This positions the eye projection 92 in the receiving device 4 behind the transverse rib 38 of the housing body 10. Due to the spring load on the front surface of the sleeve member 12, the inner plug body 6, when inserted, is always placed in such a position that the locking engagement of the projection 92 abuts the transverse rib 38. A pulling force against the inner body 18 or on the fiber cable 7 will not remove the plug member 2 from the receiving member 4 due to the locking engagement of the projection 92 behind the cross rib 38.

In order to extract the plug member 2 from the receiving member 4, the outer housing 8 can be moved backwards to the position where the front edge of the transverse rib 38 abuts the rear edge of the bridge part 60 (figure 2) and causes the outer wing parts 94 (figure 4) to move up along the surface 66 and be placed on the upper surface 64

(figure 2). This causes lifting of the locking member 92 so that further rearward movement of the outer plug housing 2 causes removal of the entire plug device 2.

A significant improvement has been made with the above contact system for use, for example, on daughterboard connectors, and preferably in combination with electrical connectors having pins and corresponding receiving devices or plug connectors. More particularly, the inventors have proposed that a fiber optic connector similar to that described in Figures 1 to 3 be mounted on a daughter card next to a receiving connector similar to that described in EP publication no. 422785. Furthermore, a receiving device will make to the one described in figures 4 to 5 above, be connected to the motherboard along the edge which is also described in the above-mentioned European patent application. Although the combination of fiber contacts and a contact system as described in the above-mentioned European patent application is highly desirable, new complications are added due to the combination.

A need for such a system described in the above-mentioned European patent application must have an axial tolerance between corresponding contacts of, for example, 2.5 mm. A fiber optic system as described above with reference to Figures 1-5 is therefore not usable as this fiber optic system would significantly burden the mother board and the daughter board. If, for example, a connector plug similar to that in Figure 2 was mounted directly on a daughter board, and the electrical plug and fiber plug were received inside their respective corresponding plug connectors and fiber receiving devices and brought into engagement with each other to the position where the fiber plug is completely locked, i.e. where the locking projection 92 is located behind the transverse rib 38 as described above, due to the tolerance factors as described, it may still be necessary to move the daughter card further forward by 2.5 mm. Although forward movement of the daughterboard would be possible due to the coil spring 14, additional force added to the sleeve by further compression of the coil spring would be intolerable to the daughterboard and motherboard as the full axial load is taken up.

Reference is now made to figure 6 where a fiber optic system which is usable in connection with electrical contacts, so-called hybrid contacts, is shown. It should be noted that the plug mounted from the left side of the motherboard can be and in fact is shown to be identical to the previously known plug connector of Figure 1. As shown by X-ray in Figure 6, the receiving arrangement is somewhat different from that shown in figure 1, and is therefore marked with the reference number 204. However, the receiver 80 and the internal locking member 84 are essentially the same as described above with reference to figures 1-5.

Reference is now made to Figures 6 and 7 where a plug with similar features to plug 2 is generally shown at 102 with an outer housing 104 mounted to a printed daughter circuit board 101 and an inner plug body 106 slidably received within a cavity 111 in the housing 104. The plug body 106 has a housing 109 (figure 7) which comprises an inner cavity 110 in which is mounted a spiral spring 112 that pushes on a piston 114, and to the piston 114 a sleeve 116 is mounted which has a thin central bore for receiving an optical fiber.

Reference is now made to figure 7 where the housing 109 is shown with a cover 118 which surrounds the sleeve 116. In a similar way to the previous plug body 6, the plug body 106 also has a transverse rib 128 with a recess 126 behind this. Instead of having a raised surface such as 44 shown in the embodiment of figure 1, the plug body 106 has a springy locking tongue 150 which can for example be attached around the insertion housing 109 or can be in one piece with the body 106.

With reference to Figure 8, the outer housing 104 comprises cam members 120 with a chamfered front cam surface 124, an upper surface 125, a chamfered rear release surface 122 and a lower surface 121. There are two chambers 120 separated by an opening 127. A front end of the outer housing body 104 is a bridge part 131 which connects the cam members 120. The bridge 131 also serves to prevent forward extraction of the plug body 106, whereby forward extraction of the plug body 106 caused the transverse rigging 128 on the plug body 106 to collide with the bridge 131.

It is again shown back to figure 6 where the plug housing 109 has an outer circumferential surface 151 which is mainly profiled as an inner surface 153 of the cavity 111, so that the plug body 106 is slidably held inside the cavity 111. The springy sliding tongues 150 which project at an angle backwards can be brought into engagement with a front shoulder surface 152 in the receiving housing 104. The plug body 106 is held in the opposite direction by means of the transverse rib 128 against the bridge part 131. The sliding tongues 150 enable the introduction of the jack insert 106 into the plug 2 because the locks or latches 150 is in engagement with the shoulder 152 of the insert while spring forces on the butted sleeves 12, 116 produce a backward thrust force on the plug body 106. It should be pointed out here that the sleeve 116 extends outwards past the cover 118, longer than the corresponding sleeve 12 past its associated cover 35 for reasons that will become clear.

As shown in Figure 6, a jack housing 204 is shown which is similar in nature to the jack housing 4 described above. As mentioned above, the motherboard side may have a jack-receiving member similar to that described above, as well as a locking insert 84 which is identical to that described above. On the daughterboard side, however, a special jack housing part 280 with centrally placed trigger ribs 248 arranged at the insertion surface in the jack housing 280 is required, so that the width of the ribs 248 is profiled to be received between the two cam members 120 (figure 8). Another locking means 284 is also required, having locking arms 291 which are significantly longer than the corresponding locking arms 91 on the opposite side, for reasons which will be described in more detail below.

The locking sequence is best shown in Figures 9 to 13, where the plug 102 is shown partially inserted into a cavity 213 in the jack 204 with the sleeve 116 partially inserted into the bushing 85 and the locking devices 291 spring biased outwards due to the engagement of the wings 294 with the insertion cam surface 124 , 125. The locking projection 291 passes over the bridge portion 131 between the cam members 120. Figure 10 shows the locking projection 292 inside a cavity 126 in the jack insert housing 109 and behind the transverse rib 128 which prevents it from extending backwards. The protrusions 292 protrude through the openings 127 between the cam members 120 (see also Figure 8), and the wings 294 rest on the lower cam surface 121. In the position shown in Figure 10, the jack insert cover 118 is over the center part 288 and the sleeves 12,116 butt against each other with a spring force. In the position of Figure 10, optical connection has been achieved between the two plugs 2, 102 and the plugs are releasably locked to the jack 204. It is important to note that the cover 118, unlike its counterpart 35, is spaced from the end face 289 in the position shown in Figure 10.

However, this is an unfavorable situation because very little tolerance is allowed in the axial distance D between the edge of the daughter board and the mother board. If the distance between the daughter board 101 and the mother board 100 is to be less than D, a force must be applied to the plug housing 104 which pushes the sliding tongues 150 forward and thus compresses the spring 112 so that the cross rib 128 will move forward and away from the locking projection 292.

If the push devices 150, 152 are engaged and the distance separating the daughter board 101 and the mother board 1 is less than D, the force loop will be as follows: plug sleeve 116 piston 114 spring 112 plug body 109 sliding tongues 150 jack housing 104 daughter board 101- iord or structural motherboard 100-jack housing 204-locking devices 92-jack insert housing 6-spring 14-piston 24-sleeve 12. As can be seen from the above, the spring forces are absorbed by the boards 100, 101, which is an undesirable situation as these the forces can be quite large depending on the number of optical terminals in the connector, which can cause deformation of the cards 100,101 and require a stronger and thus more expensive mounting structure.

In order to avoid the above-mentioned undesirable situation, the jack housing 204 is provided with release ribs 248 which slide between the cam members 120 on the plug 102 as shown in figures 9, 10 and 11, so that the ribs 248 have an inner surface 249 (figure 6) very close to the outer surface 151 of the housing 106. Figure 11 illustrates the daughter board 101 and the plug 102 inserted even further into the jack 204 until the ribs 248 are guided past the shoulder 152 into the rib slots 151 in the plug housing 104, where the springy push tongues 150 are bent inwards so that they are out of contact with the shoulder 151.

Figure 11 actually represents a snapshot as the plug insert 106 in this position is no longer pushed forward by the tongues 150 and will therefore spring back until the locking projection 292 abuts the transverse rib 128, as shown in Figure 12.

The power loop of the connection shown in figures 12 and 13 is located inside the connector and is therefore plug sleeve 116-piston 114-spring 112-insert-housing 10-jack latch 291-jack insert 6-jack spring 14-jack piston 24-jack sleeve 12.

As mentioned above, the loop does not load the cards as mentioned above when the sliding devices 150,152 are engaged. The plug housing 104 and thus the daughter board 101 can then slide forward practically without resistance to the position shown in figure 13 and back again to the position in figure 12, thereby allowing a tolerance T in the axial distance between the daughter board 101 and the mother board 100 which shown in figure 13. This can be allowed since the plug housing 104 as shown in figures 12 and 13 is completely freed from the plug body 106, the plug body being held to the mother board 100 exclusively by the projections 292 on the transverse ribs 128.

To release the plug from the jack, it is sufficient to withdraw the plug housing 104, as shown in figure 14, i.e. by withdrawing the daughter card 101 so that the wings 294 come into contact with the releasing cam surface 122 which forces the locking arms 291 to pre-tension the springs outwards as shown in figure 15, until the wings 294 pass over the upper cam surface 125 (figure 16), thereby enabling the locking projection 292 to pass over the transverse rib 128. The plug 102 can then be withdrawn completely from the jack as shown in figure 17 , whereby the sliding tongues 150 are again in contact with the jack insert shoulder 152 for a new connection between the plug and the jack by repeating the steps adjusted in figures 9 to 12.

Reference is now made to Figure 18 where an alternative embodiment of the plug connector is shown at 102' where the locking arms or pushers 150' are molded in one piece with the housing 109 and comprise cam surfaces 149 which cooperate with the ribs 248 of the jack housing to release the insert body 109 from the outer the housing 104. Figure 18 further shows an alternative locking arm 91' which is shaped in reverse and comprises wing members 94' in one piece.

Although the invention has been described with reference to a single plug housing as shown in Figure 7 at 104, a further contact device is shown in Figure 19 at 300 comprising an electrical contact housing part 301 and a fiber plug part 302 with an outer housing 304. Any number of a a plurality of cavities may be provided at 311, which will receive the insert members 106 (Figure 7) in an identical manner. Cam members 320 are arranged close to each cavity 311 for locking connection with the insert 106 as described earlier. As shown in figure 19, the housing 304 has a lower surface 330 for abutment against the daughter card, and a number of alignment pins 332 which extend from this for correct positioning of the housing 304 on the daughter card. As shown in figure 19, the contact part 301 also comprises a number of terminal insertions 340 which are similar to the above-mentioned European patent application no. 422785.

The invention as described above relates to the preferred embodiment. One can, however, imagine many different shapes, dimensions and attachment points for the plug housing, plug locks, jack housing, jack inserts, push devices and the number and shape of the cam members, as well as the number of optical fibers mounted inside the connector, without deviating from the scope of the invention.

Claims (10)

1. Fiber optic contact device comprising a jack device to receive, on one side, at least one jack sleeve (12), and a plug device (.102,132) which can be inserted into the jack device from its opposite side and has at least one plug sleeve (116} which can positioned coaxially with the jack sleeve to provide optical interconnection between optical fibers supported by the sleeves (12,116); the plug assembly comprising an outer housing (104), an inner plug body (106) on which the plug sleeve(s) is slidably mounted, and which is axially slidable in a through cavity (111) in the outer housing, and a spring device (112) to force the plug sleeve(s) softly against the cooperating jack sleeve(s), the inner plug body (106) having a radially bendable, outer push device (150) to abut a forward facing striker (152) on the outer housing (104) to enable insertion of the plug device into the jack device by movement of the outer housing forward into the jack device, the outer housing (104) having a opening (12 7) at its front end and the inner plug body (106) has an outer plug locking device (128) facing the opening (127) for cooperation with the jack device (204); and the jack device (204) comprises a jack locking device (284) which cooperates, via the opening (127), with the plug locking device, in response to the plug device reaching a predetermined axial position in the jack device, to hold the inner plug body in the jack device to provide optical connection between the optical fibers, and an axial release device (248) for bending the pusher device radially inwardly to a position clear of the shoulder (152) when the plug device is moved further forward and past the predetermined axial position, whereby the outer housing (104) alone can is moved axially further over a tolerance absorption distance (T) in relation to the jack unit (204) and the inner plug body (106) which is optically and mechanically coupled, further axial movement not affecting the force exerted by the spring device (112), characterized in that the opening (127) has the forward-facing shoulder (152) at a rear end, and a bridge portion (131) which projects into the outer housing (104) cavity (111) at a front end of the opening to cooperate with the plug locking device (128), so that the plug body (106) is restrained from forward extraction from the cavity (111), and in that the pushing device comprises a rearwardly extended, soft tongue (150) which projects obliquely outwards and into the opening (127) in the plug housing, and the jack locking device (284) and the axial release device (248) are positioned so that, after passing over the bridge portion (130) upon insertion of the plug device into the jack device, they can respectively engage with the plug locking device and the sliding tongue (150) through the opening (127) . 2. Contact device according to claim 1, characterized in that the plug device (102,132) comprises several sleeves (116), each of which is for supporting a fiber, and each sleeve (216) is mounted in a separate plug body (106). 3. Contact device according to claim 1 or 2, characterized in that the plug body (106) or each plug body (106) has an outer surface (151) close to an inner surface (153) of the outer housing (209) so that, when the push device (150, 352) is released, the plug body (106) is guided ) sliding axially in the cavity (111). 4. Contact device according to one of claims 1-3, characterized in that the sliding tongue (150) is one with an insertion housing (109) for the plug body (106). 5. Contact device according to one of claims 1 -4, characterized in that the axial release device (248) is located adjacent to the front surface of the jack device (204). 6. Contact device according to one of claims 1-5, characterized in that the jack locking device (284) comprises at least one soft locking arm (291) attached to the jack device (204) and extending forwards from this to a free end which has a locking projection (292) which cooperates with the plug locking device in the form of a rib (128) on the plug body (106) to retain this. 7. Contact device according to claim 6, characterized by at least one pair of locking arms (291) per plug sleeve (116). 8. Contact device according to one of claims 1-7, characterized in that the plug housing (104) has cam members (120) for cooperation with wings (294) attached to the jack locking device (284) of the jack device (204), the cam members (120) having cam surfaces (122, 125) whereby the wings (294) overlap these surfaces (122,125) so that, during withdrawal of the plug (102) from the jack assembly (204), the wings (294) contact the cam surfaces (122,125), to cause the jack locking device (284) to be gently forced outward, thus releasing the jack device (204) from the plug body (106). 9. Contact device according to claim 8, characterized in that the plug (102) has at least one pair of cam members (120) which extend from the top or bottom of the plug housing (104) and are separated by the opening (127), the opening enabling the jack locking device (284) to engage with the plug locking device, which is in the form of a rib (128) on the plug body (106), to hold the plug (102) to the jack device (204). 10. Contact device according to claim 9, characterized by pairs of cam members (120) respectively on the upper side and the opposite lower side of the plug housing (104).