EP0360957A2 - Connecting box for electrical lines - Google Patents

Abstract

A junction box 10 for flat cables 15 of telecommunications technology can be made more space-saving if the circuit board 20, which runs parallel to the box bottom 11 in the box interior 13, is provided directly with penetration contacts 40 which interact with receptacle bodies 30 in the case of assembly. These can be pressed against the printed circuit board 20 by at least one set screw 25 and have a channel 36 for receiving the cable end 15. The set screws 25 reach through an opening 23 in the printed circuit board 20 and can be screwed into threaded receptacles 29 in the can base 11, which are located on the opposite side of the circuit board 20 are located. By screwing the receptacle 30, the circuit board 20 is additionally held on the can base 11.

Description

The invention relates to a junction box for electrical lines, in particular for flat cables in telecommunications, which have a plurality of parallel stranded conductors.

In the known connection terminal (DE-35 45 305-A1), assemblies were prefabricated and subsequently contacted with the circuit board, which were then arranged between a circuit board and a can lid. Each assembly consisted of a frame-shaped housing, of which the lower frame spar was the support for the penetration contacts and from which the connecting tongues protruded for later connection on the circuit board. The opposite frame spar was used to hold a nut, which formed the thread mount for a set screw rotatably mounted centrally in the mount body. The lower end of the set screw was axially fixed to the receiving body and formed in the longitudinal center to its channel, which was used to insert the cable to be contacted. The set screw was arranged in the longitudinal center of the field of the penetration contacts arranged in the other frame spar, which had to penetrate through the vertical slots into the channel of the receiving body when the set screw was turned. When loosened, the screw with its screw head protruded disturbingly over the upper frame web.

The cumbersome and time-consuming production of the individual assemblies and their later assembly was disadvantageous. These assemblies required a disturbingly large height, for which a correspondingly large-sized receiving space in a junction box was necessary. Above all, however, the mechanical and electrical connection between the modules and the printed circuit board was susceptible to faults, which is why additional fastening means, such as pins or the like, were required on the housing frame. However, even these could not sufficiently secure the strength of the connection and, above all, had no influence on a good electrical connection of the connecting tongues.

The invention has for its object to develop an inexpensive junction box with moveable receptacles for cables, which is more space-saving is characterized by great mechanical strength and good electrical contacting and yet is quick to assemble and easy to use. For this purpose, the junction box is designed according to claim 1, resulting in the following special measures and effects.

In the invention, the circuit board itself is a carrier for the penetration contacts and has openings for the set screw because the thread holder is arranged in the bottom of the can. In the invention, the engaged shaft end of the set screw is on the one hand and the screw head to be handled with a turning tool is on opposite sides of the circuit board. The receiving body itself has a vertical bore for the shaft of the set screw and is pressed directly against the circuit board by its actuation by means of the screw head. In the tightened state, the receptacle body can be pressed onto the printed circuit board over the entire surface. Thereby the end position of the contact is not only fixed, but also particularly stabilized. The receiving body presses the connecting tongues in a mechanically and electrically reliable manner into the circuit board. The adjusting screw therefore not only takes on the function of contacting the contact blades, but also, via the receiving body, the mechanical and electrical securing of the penetration contacts. A low overall height is achieved because only the receptacle body with the screw head is located above the circuit board. The thread receptacle in the bottom of the can can also accommodate a longer shaft length of the set screw and therefore ensure that the receptacle body is pressed particularly well with the properly contacted cable on the circuit board.

If desired, the movements of the receiving body can be guided via guide webs and prevent a horizontal adjustment when the adjusting screw is tightened, which can be achieved in various ways with the aid of claims 2 to 8. This does not significantly increase the overall height because the guide bars are also stuck to the bottom of the can under the circuit board. You can also take over the function of end stops according to claim 3, 6 and 7 and also contribute to simplifying assembly, according to claim 4 and 8.

For easier handling of a screw tool, the screw head should be designed according to claim 9 or 10. Such a recess encompassing the head also limits the effective width of the screwdriver, which prevents damage to the screw head by incorrect screwdrivers and at the same time prevents the screwdriver from sliding off.

In order to rule out unscrewing too much, one should design the shaft length of the set screw in relation to the lifting movement of the receiving body in accordance with claim 12. Its thread intake is easiest to implement according to claim 13. A clear material according to claim 14 ensures visibility, in order to be able to visually determine the correct position of the inserted cable in the channel of the receiving body. Parallel ribs according to claim 15 also ensure a pin-free insertion of the cable if it should have an adhesive application on one side for laying the cable on the wall or the like.

In some cases, a lateral offset of the field of the penetration contacts with respect to the set screw is advantageous. One can in particular, according to claim 17, bring about a lateral play of the adjusting screw in the receptacle, a smooth, successive penetration of the contact knife. Such a construction is also conceivable, according to claim 18, which also permits an angled arrangement of the wings according to claim 19 and thus allows two cables lying on the corner to be contacted simultaneously with a single adjusting screw.

An easier handling results from the design of the receiving body in the form of a bridge according to claim 20, where the channels sit on both sides between a pair of adjusting screws.

A further alternative to the configuration of the receiving body results from claims 21 to 24, where, because of the two-part nature of the receiving body, continuous cables and not only cable ends are contacted in a junction box can be. The latter is particularly interesting if one or more branches of cables are to be derived from a line that has already been laid.

The aforementioned axially fixed connection of the set screw in the receiving body according to the invention can be designed according to claim 25 or 26. Further measures and advantages of the invention result from the following description and the drawings. The invention is directed to all the new features and combinations of features that can be derived therefrom, even if these should not be expressly stated in the claims.

• Fig. 1 eine Schnittansicht, teilweise im Ausbruch, durch eine erste Ausführungsform einer erfindungsgemäßen Anschlußdose,
• Fig. 2 eine Draufsicht auf die Anschlußdose von Fig .1 bei entferntem Dosendeckel mit Blick auf die am Dosenboden angeordneten Bauteile,
• Fig. 3 und 4 im Quer- bzw. im Längsschnitt ein Detail der Anschlußklemme von Fig. 1, die auch dort be­reits im Ausbruch dargestellten Bauteile, wobei diese aber sich in einer Ausgangsstellung be­finden,
• Fig. 4 und 5 eine der Fig. 3 und 4 entsprechende Dar­stellung der gleichen Bestandteile, allerdings in der die Kontaktierung eines nicht näher gezeigten Kabels verdeutlichenden Endstellung,
• Fig. 7 einen Horizontalschnitt durch die Bauteile von Fig. 4 längs der dortigen Schnittlinie VII-VII,
• Fig. 8 in einer der Fig. 2 entsprechenden Darstellung eine alternative Ausbildung der erfindungsge­gemäßen Anschlußdose,
• Fig. 9 eine dritte Ausführungsform der erfindungsge­mäßen Anschlußdose in einer zur Fig. 3 analogen Darstellung der Bauteile,
• Fig. 10 eine vierte Ausführungsform der erfindungsge­mäßen Anschlußdose in einer der Fig. 2 ent­sprechenden Darstellung,
• Fig. 11 in Vergrößerung eine Schnittansicht durch Fig. 10 längs der dortigen Schnittlinie XI-XI und
• Fig. 12 eine zwar zu Fig. 11 analoge Darstellung der maßgeblichen Bestandteile, allerdings in einer anderen Schnittlinie, nämlich gemäß XII-XII von Fig. 10 sowie in einer anderen Position der dabei beteiligten Bestandteile.

The invention is shown in several exemplary embodiments in the drawings. Show it:

• 1 is a sectional view, partly in breakout, through a first embodiment of a junction box according to the invention,
• 2 is a plan view of the junction box of Fig. 1 with the can lid removed with a view of the components arranged on the can bottom,
• 3 and 4 in cross-section or in longitudinal section a detail of the terminal of Fig. 1, the components already shown there in the outbreak, but these are in a starting position,
• 4 and 5 a representation of the same components corresponding to FIGS. 3 and 4, however in the end position, which illustrates the contacting of a cable, not shown in more detail,
• 7 is a horizontal section through the components of FIG. 4 along the section line VII-VII,
• 8 shows an alternative embodiment of the junction box according to the invention in a representation corresponding to FIG. 2,
• 9 shows a third embodiment of the junction box according to the invention in a representation of the components analogous to FIG. 3,
• 10 shows a fourth embodiment of the junction box according to the invention in a representation corresponding to FIG. 2,
• Fig. 11 is an enlarged sectional view through Fig. 10 along the section line XI-XI and
• FIG. 12 shows a representation of the relevant components that is analogous to FIG. 11, but in a different section line, namely according to XII-XII of FIG. 10 and in a different position of the components involved.

1 to 7 show a first exemplary embodiment of a junction box 10 according to the invention, which consists of a can base 11 which can be attached to the wall or the like for mounting and a can lid 12 placed thereover. Through lateral openings 14 or openings in the side walls of the can lid 12, electrical cables 15 are inserted into the resulting can interior 13, the appearance of which can best be seen from the cross-sectional view of FIG. 1.

These are flat cables 15 for telecommunications. This flat cable 15 consists of a ribbon-shaped web 16, on which a plurality of parallel stranded conductors 17 are arranged with a piece of insulation. (Fig. 8) The flat cable has a rib profile on this side. The opposite side of the flat cable, which is formed by the band-shaped web 16, is largely flat and has an adhesive layer 18 which, when laying the flat cable 15, is useful for holding it on the wall or the like. This saves additional fasteners for such a cable 15. The junction box 10 has the task of electrically connecting the various stranded conductors 17 of such cables 15 to one another and in particular to contact sockets 19. Such contact sockets 19 can carry contact tongues 64 in the inside of the socket on one side or on both sides, as shown in FIG. 10, which can be connected to associated plugs. The openings of the contact sockets 19, which are not shown in more detail, are generally directed upward and in alignment with recesses on the top of the socket cover 12, which are likewise not shown in detail. The recesses are used to couple the plugs into the junction box 10.

The contact sockets 19 are seated on a printed circuit board 20, which is provided in the usual way with conductor tracks which effect the electrical connection between the individual cables 15 to be contacted on the one hand and the sockets 19 on the other hand. The circuit board 20 runs in the interior of the can 13 parallel to the can base 11 and lies there on a bracket 21 formed on the can base 11. On the upper side, the circuit boards 20 can be overlapped at the edges by latching hooks 22, which are also integrally formed on the can base 11 with their hook shank. The locking hooks 22 are intended to secure the position of the printed circuit board 20, they are supported by adjusting screws 25, which also perform other functions.

The circuit board 20 is provided with an opening 23 in order, as can best be seen from FIG. 4, to let the threaded shaft 24 of the adjusting screw 25 pass through. This engages when screwing into the threaded receptacle of a threaded sleeve 29 which is integrally formed in the support bracket 21 of the can base 11. The set screw 25 has the task of making a special receiving body 30 for a cable 15 in the sense of the double arrow 31 of FIG. 4 movable in relation to the printed circuit board 20, on which a group of penetration contacts 40 are seated. The following structure is available for this.

The receiving body 30 initially comprises the vertical bore 32 best shown in FIG. 4 for the shaft 24 of the adjusting screw 25, which rests with its screw head 27 lowered in a recess 33 at the upper end of the receiving body 30 in each screwing position. This recess 33 is created by a partially annular bead 34 on the receiving body 30. This annular bead 34 circumferentially surrounds the screw head 27 and excludes that screwdrivers with a too wide blade can be used as a screwing tool. Because the screw head 27, as best shown in FIG. 4, is always lowered in the recess 33, the blade of the screwdriver is always guided when it is turned. The set screw 25 is also provided with a stepped neck 28 in order to produce an annular groove there which, in the case of assembly, is aligned with a slot 35 which intersects the vertical bore 32. The slot 35 is open at the side and serves to receive a snap ring 49 which, with its resilient legs, engages around the neck 28 and thereby ensures a rotatable but axially fixed connection between the adjusting screw 25 and the receiving body 30.

Above all, the receiving body 30 has a channel 36, which runs perpendicular to the vertical bore 32 and serves to receive the flat cable 15. According to the cable profile described in connection with FIG. 9, the upper duct wall is provided with the longitudinal grooves 37 best seen in FIG. 3, into which the individual stranded conductors 17 are received with their insulation in the case of assembly, and thereby assume a defined position in channel 36. The opposite lower channel wall is initially provided with parallel ribs 38 running in the channel direction, which produce a tooth profile and only touch the adhesive layer 18 on the flat cable 15, which was already mentioned in connection with FIG. 9. As a result, the end of the cable can easily be pushed into the channel 36 of the receiving body 30 without the adhesive layer 18 having to be removed, as can be seen in FIG. 1. The receiving body 30 should preferably consist of transparent material so that the correct position of the cable end can be recognized therefrom.

3 and 4, the receiving body 36 finally also has vertical slots 39, which open into the channel 36 through the lower channel wall, in alignment with the grooves 37 on the top of the channel, which is also an alignment with the 9 stranded conductors 17 of the inserted cable 15 justified. These vertical slots 39 serve, as can be seen from FIGS. 3 and 4, for the engagement of contact knives 41, which are preferably made several times, by structuring the penetration contacts 40 and are laterally offset with respect to one another with their knife tips, in order to be described in more detail below Penetration process to spear the stranded conductors 17 at different cross-sectional locations. For this purpose, the vertical slot 39 is provided with converging, inclined slot walls, which serve to guide the contact blades 41 during the lifting movement 31 of the receiving body 30.

The penetration contacts 40 have diametrically downwardly directed to the upstanding contact blades 41, preferably integrally formed with them contact tongues 42, which are inserted into the circuit board 20 and are there electrically connected by soldering or the like to the conductor tracks already mentioned. The receiving body 30 is namely arranged according to the invention immediately above the top 48 shown in FIG. 4 of the printed circuit board 20 and interacts with it over the full area when the receiving body moves from the starting position of FIG. 4 to the end position of FIG. 6 in the sense of the already mentioned Arrow 31 stroke is moved. This is done using the adjusting screw 25.

This lifting movement is supported by a pair of guide webs 50, which, according to FIG. 7, are arranged on the two side surfaces 44 of the receiving body 30, and specifically engage in grooves 43 of complementary design there. As can best be seen from FIG. 3, these guide webs 50 are also integrally formed on the can base 11 and here consist of hooks that are mirror images of one another. 52. The hook legs 50 take over the function of the guide webs mentioned, while the hook ends 51 produce stops for the upper stroke position of the receiving body 30 according to FIGS. 3 and 4. The counter shoulder 45 to this hook end 51 is formed here by the upper front end of the receiving body 30 itself. In this upper stroke position, as can best be seen from FIG. 4, the shaft end 26 of the adjusting screw 25 is out of engagement with its threaded sleeve 29, which is why the receiving body 30 is further raised by unscrewing the adjusting screw 25 is not possible. As can be seen from FIG. 3, the hook legs 50 reach through corresponding openings 46 in the printed circuit board 20, but the hook legs 50 could also grip around the printed circuit board 20 in this area on the edge. About this hook 52, the receiving body 30 is held in spite of the loosened screw 25 in the position shown in FIGS. 3 and 4. At the same time, the printed circuit board 20 is also held in position via the penetration contacts 40 mentioned.

The hooks 52 allow the receptacle body 30 to be snap-fitted over the finished printed circuit board 20 that holds the penetration contacts 40. For this purpose, the hook ends 51 are provided with inlet slopes 53 that run in mirror image to one another, against which the receptacle body 30 moves during its vertical push-in movement and for a short time spreads apart elastically. Then the hook ends 51 snap over the upper front end 45 of the receiving body 30 that is to lie in the end position between the hook legs 50. The contact knives 41 also travel over the slots 39 in the receiving body. The junction box prepared in this way is suitable for contacting the various flat cables 15.

As can be seen from FIG. 2, such receptacle bodies 30 are provided at different, desired locations in the box for a single cable end in each case and can also be operated independently via their own set screws 25. Is a flat cable 15 properly in the channel 36 of the relevant receiving body 30 introduced, the screw 25 is screwed. As a result, the receiving body 30 moves downward in the direction of the lifting movement arrow 31 from FIG. 4, the contact knives 41 increasingly penetrate into the channel 36 and thereby hit the cable, where they finally meet the stranded conductor 17. This naturally creates resistance. In the present case, as can be seen from FIG. 4, the field 47 is in a lateral offset 57 to the location of the adjusting screw 25 in the receiving body 30. The adjusting screw 25 is namely in one end region 54 of the receiving body, while the channel opening 55 is on the opposite side End of the receiving body 30 opens out. The vertical bore 32 surrounds the screw shaft 24 with play, as can be seen from FIG. 4. The offset 57 mentioned between the effective area 47 of the penetration contacts and the point of attack of the screw 25 establishes a lever arm which leads to a slight inclination of the receiving body when the adjusting screw 25 is tightened in the sense of the tilting movement arrow 56 indicated in FIG. 4. This has the consequence that the channel 36 is also inclined accordingly and therefore the adjacent individual tips of the contact blades 41 penetrate into the cable one after the other in time when the receiving body 30 is moved against the printed circuit board 20 when the screws are actuated. Then, however, there is a flat contact between the top 48 of the circuit board 20 and the receiving body 30, where the penetration contacts 40 are pressed into the circuit board 20 by the receiving body 30, as can be seen from FIGS. 5 and 6. The adjusting screw 25 has, through the circuit board 20, screwed into the threaded sleeve 29 and brought the receiving body 30 into its lower stroke position. The penetration contacts 40, with their contact blades 41, have passed through the channel 36 to the opposite channel wall and thus have had good electrical contact with the stranded conductors of the flat cable 15, which are located there but are not shown in FIGS. 5 and 6 for reasons of clarity. By means of the tightened set screw 25, the printed circuit board 20 is finally also pressed onto the support stands 21 of the can base 11 via the receiving body 30. The receiving body 30 thus fulfills the further function of holding the printed circuit board 20 firmly on the can base 11. At the same time, the penetration contacts are secured in mechanical and electrical terms via the receiving body 30 on the printed circuit board 20.

Fig. 8 shows another embodiment 10 'compared to the junction box of Fig. 2, which, like that, is intended for contacting four flat cables 15. The same reference numerals as in the first exemplary embodiment are used to designate corresponding components. In this respect, the previous description applies. It is only sufficient to deal with the differences. The receiving body 30 'there comprise two wings 58, 59, each of which is equipped with a previously described channel 36 for receiving a flat cable end. Accordingly, the circuit board 20 also has a field aligned therewith with penetration contacts which are effective in the manner described above. The two wings 58, 59 are angled to one another, in the present case at right angles to one another. In the apex between the wings there is a single set screw 25 for both wings 58.59. Here, the cables 15 can be inserted "in a corner" to each other in the junction box 10 '. The can base 11 can be mounted via a screw fastening or the like, for which openings 63 are provided in the bottom corner region. The can base 11 could, however, similarly to the cables 15 described above, be attached to the wall to be equipped with a rear adhesive layer, which can also be carried out additionally.

In Fig. 9, a third alternative 10˝ a junction box is shown, and only a fragment in a representation similar to Fig. 3. Corresponding components are also provided with the same reference numerals here and reference is made to the preceding description in this respect. It is sufficient to describe the additional measures.

The receiving body here consists of a bridge 60, which is provided at both bridge ends 61, each with a vertical bore 62 for the passage of an adjusting screw 25. In the section in between, the bridge 60 is provided with a plurality of channels 36 for receiving cable ends 15, to which fields 47 with the penetration contacts 40, which have already been described several times, are assigned in each case in the circuit board 20 directly below it. The set screws 25 find below the circuit board 20 a thread receptacle in the form of a nut 65, which is received in a correspondingly non-circular recess 66 in the can base 11 and is covered there by a latched circuit board 20.

Here, too, the can base 11 has molded hooks 52 which engage with their hook ends in an end groove 67, where a heel surface 68 interacts as an end stop with the hook end 51 when the bridge 60 is in its upper stroke position according to FIG. 9. The set screws 25 are on their neck 28 with the vertical bore 62 narrowing projections 69 in engagement, which is why the screw heads 27 are always flush with recesses 33 on the top of the bridge 60. The length of the threaded shafts 24 is also dimensioned here in such a way that there is still no engagement relationship with the nut 65 in the upper stroke position of FIG. 9.

The bridge 60 is assembled with the two hooks 52 in the manner already described in the first exemplary embodiment. To facilitate the snap-in movement of the hooks 52, there is a wedge surface 79 opposite the mentioned entry slopes 53 of the hooks below the shoulder surface 68, which is provided in the lower region of the two-sided grooves 67 in the bridge 60. To contact the inserted cable ends 15, the two adjusting screws 25 are screwed in in a manner coordinated with one another. The lowering movement of the bridge 60 is controlled by the hook ends 51, which slide in the grooves 67.

FIGS. 10 to 12 show a fourth exemplary embodiment of a junction box 70 according to the invention in plan view and in individual parts, of which likewise only the designs different from the previous exemplary embodiments need to be described. In all other respects, the previous description applies.

A special feature in this case is that the box base 11 has a continuous cable channel 71, which allows the junction box 70 to be subsequently connected to an already laid cable without having to cut the cable at this point. For this purpose, this receptacle 70 has two parts 72, 73 lying one above the other in the case of assembly, the structure and mode of operation of which can be seen in particular from FIGS. This receiving body is also designed as a bridge with two set screws 25 provided in the two end regions 74 of the lower part 73. These are mounted in a manner similar to that in the exemplary embodiment of the connection box 10 ′ from FIG. 9 and act with corresponding nuts located below the printed circuit board 20 65 together. Here, too, hooks 51 are provided for limiting the upper stroke position and for guiding the receiving body when contacting the cable, which is not shown in detail here.

The upper part 72 of the receiving body is connected to the lower part 73 via a joint 75 in the direction of arrow 76 such that it can be folded. In the present case, a pin 77 formed on the lower part 73 in an end region 74 and an articulated eyelet 78 formed here on the upper part 72 are used for this purpose. The upper part 72 thus acts like a pivotable lever. If it is in the unfolded position in FIG. 12, the receiving channel 36 is open at the top for a continuous cable. The can 70 can therefore be pushed with the edge area 80 of the bottom 11 shown in FIGS. 10 and 12 under the cable, which is then inserted into the lower half of the channel in the lower part 73 can be, which includes the channel bottom 81 and the channel side walls 82. The upper part 72, on the other hand, has only the corresponding duct cover wall 83. Alternatively, height regions of the duct side walls 82 could also be provided on the upper part 72. In this case too, the channel cover wall 83 produces, due to its profiling, the already mentioned receiving grooves 37 for the insulated conductors 17 formed on one side on the flat cable. If the cable has therefore been inserted into the lower half of the channel 36 from the lower part 73, the cable will be closed when it is closed of the upper part 72 exactly aligned with the individual penetration contacts 40 also arranged here in the printed circuit board. This collapsed position, which is shown in FIGS. 10 and 11, is secured by a snap lock 84, 85. This consists of a latching hook 84 which is formed on that end 74 of the lower part 73 which is opposite the joint 75. Its hook shank is bendable and also has an inlet slope 86 which, when the upper part 72 is closed, interacts with the free end 85 of the upper part 72 there, which has a counter bevel 87. After this elastic deformation, the end 85 snaps under the locking hooks 84, as can be seen from FIG. 11. As a result, the receiving channel 36 for the cable is closed. Now, by coordinated movement of the two set screws 25, the contacting of the cable with the penetration contacts 40 takes place in the manner already described several times. For this purpose, the upper part 72 has in the closed position with the screw heads 27 in the lower part 73 aligned openings 33 which arrange them recessed as recesses. The upper part 72 acts like “glasses” for the screw heads 27.

Reference symbol list:

• 10 junction box, Fig. 1 to 7
• 10 'junction box, Fig. 8
• 10˝ junction box Fig. 9
• 11 can base
• 12 can lids
• 13 can interior
• 14 breakthrough
• 15 cables, flat cables
• 16 ribbon-shaped bridge from 15
• 17 stranded conductors from 15
• 18 adhesive layer on 15
• 19 contact socket
• 20 circuit board
• 21 trestle for 20
• 22 locking hooks on 11
• 23 breakthrough in 20
• 24 threaded shaft
• 25 set screw
• 26 shaft end
• 27 screw head
• 28 neck, ring gutter of 24
• 29 threaded sleeve
• 30 receiving bodies
• 30 'receiving body, Fig. 8
• 31 stroke movement arrow
• 32 vertical hole for 25
• 33 recess
• 34 ring bead
• 35 slot
• 36 channel
• 37 groove in 36
• 38 rib in 36
• 39 vertical slot in 30
• 40 penetration contact
• 41 contact blades of 40
• 42 contact tongue of 40
• 43 groove in 30
• 44 side surface of 30
• 45 counter shoulder, upper forehead of 30
• 46 breakthrough for 50 in 20
• 47 arrangement field for 40
• 48 top of 20
• 49 snap ring for 25
• 50 guide bar, hook legs
• 51 hook end
• 52 hooks
• 53 Entry slope
• 54 end range of 30
• 55 channel opening of 36
• 56 Tilting Arrow of 30
• 57 lateral offset between 25, 47
• 58 wings of 30 ′
• 59 wings of 30 ′
• 60 bridge of 10˝
• 61 end of bridge
• 62 vertical drilling at 61
• 63 breakthrough in 11
• 64 contact tongue in 19, FIG. 10
• 65 mother, Fig. 9, 11
• 66 recess for 65
• 67 groove in 60
• 68 sales area in 67
• 69 lead in 62
• 70 junction box in Fig. 12
• 71 cable duct
• 72 upper part of the receiving body, FIGS. 9 to 12
• 73 lower part of the receiving body, FIGS. 9 to 12
• 74 end range of 73
• 75 joint
• 76 Folding movement arrow
• 77 hinge pin
• 78 hinge eye
• 79 wedge surface
• 80 edge area of 11, Fig. 10, 12
• 81 channel floor of 70
• 82 channel sidewall of 70
• 83 duct cover wall in 72
• 84 snap lock, snap hook
• 85 snap lock, free end of 72
• 86 entry slope at 84
• 87 counter-slopes to 85

Claims (26)

1.) Junction box (10) for electrical lines, in particular for several flat cables (15) of the telecommunications technology, which have parallel stranded wire conductors, with a can base (11) which can be attached to a wall or the like and with a recess for coupling plugs with can lids ( 12), with a printed circuit board (20) intercepted on the socket base (11), which has conductor tracks and carries contact sockets (16) for the plugs, and with directly on the printed circuit board (20) and electrically connected to the conductor tracks via connecting tongues (42) Penetration contacts (40) which have contact blades (41) which protrude into the non-stripped stranded conductors (17) of the flat cable (15) to be connected, the housing base (11) itself having at least one thread receptacle (29) for the shaft end (26) of an adjusting screw ( 25), which penetrates both an opening (23) in the printed circuit board (20) and a vertical bore (32) of a receiving body (30), whose screw shaft (24) is axially fixed, but freely rotatable, connected (28,49) to the receptacle body (30) and whose screw head (27) always rests at the upper end of the receptacle body (30), the receptacle body (30) directly above the circuit board ( 20) and can be moved by actuating the adjusting screw (25) with respect to the printed circuit board (31) and can be pressed against the area (47) of the printed circuit board (20) equipped with the contact blades (41) while securing the support (21) of the printed circuit board ( 20) on the can base (11) and the receiving body (30) both a channel (36) running transversely to its vertical bore for inserting the cable (15) to be contacted and the circuit board (20) facing vertical slots (39) opening into the channel, which are aligned with the individual stranded conductors (17) of the flat cable (15) inserted in the channel (36) and in which the contact blades (41) of the individual penetration contacts (40) engage and are guided during the lifting movement (31) of the receiving body (30). 2.) Junction box according to claim 1, characterized in that the socket bottom (11) has at least a pair of upstanding guide webs (50) which pass through the printed circuit board (20), optionally on the edge side, and opposite side surfaces (44) of the receiving body (30 ) slide during its stroke movement (31). 3.) Junction box according to claim 2, characterized in that the guide webs are the legs (50) of mutually mirror images on the can bottom (11) molded hooks (52), the hook end (51) overlap lateral stop shoulders (45) of the receiving body (30) and limit the upper stroke position of the receiving body (30). 4.) Junction box according to one or more of claims 1 to 3, characterized in that the two guide webs (50) and the hook ends (51) are provided with mutually mirror-inverted inlet bevels (53) to in when pressing in the receiving body (30) spread the webs (50) or hooks (52) apart elastically between them. 5.) Junction box according to one or more of claims 1 to 4, characterized in that the side surfaces (44) of the receiving body (30) have grooves (43) for the guide webs (50) or the hook ends (51). 6.) Junction box according to one or more of claims 1 to 5, characterized in that the stop shoulders for the hook ends (51) from the upper end (45) of the receiving body (30) are generated. 7.) Junction box according to one or more of claims 1 to 6, characterized in that the stop shoulders are generated by a shoulder (68) in the groove (67) (Fig. 9). 8.) Junction box according to one or more of claims 1 to 7, characterized in that a complementary mating wedge surface (79) on the receiving body (60) are arranged for the inlet slope (53), preferably in the region of its lateral grooves (67), (Fig. 9). 9.) Junction box according to one or more of claims 1 to 8, characterized in that the receiving body (30) at its upper end has a circumference of the screw head (27) adapted recess (33) in which the head (27) in each The screwing position of the set screw (25) is lowered. 10.) Junction box according to claim 9, characterized in that the recess (33) is formed by a ring or partial ring bead (34) at the upper end of the receiving body. 11.) Junction box according to one or more of claims 1 to 10, characterized in that the receiving body (30) in its lower stroke position is pressed over the entire surface (48) on the printed circuit board (20). 12.) Junction box according to one or more of claims 1 to 11, characterized in that in the upper stroke position of the receiving body (30) the shaft end (26) of the adjusting screw (25) out of engagement with the threaded receptacle (29) in the socket bottom (11) is. 13.) Junction box according to one or more of claims 1 to 12, characterized in that the thread receptacle is formed by a nut (65) which is received in a non-circular recess (66) of the can bottom (11) and there from the circuit board (20 ) is covered (Fig. 9, 11). 14.) Junction box according to one or more of claims 1 to 13, characterized in that the receiving body (30) consists of a clear material which allows a view of the end of the cable (15) inserted in the channel (36). 15.) Junction box according to one or more of claims 1 to 14, characterized in that the channel (36) has on its one channel wall in the channel direction facing parallel ribs (38) which produce a tooth profile (Fig. 3). 16.) Junction box according to one or more of claims 1 to 15, characterized in that a single set screw (25) in the lateral offset (57) to the penetration contacts (40) receiving field (47) preferably at one end (44) of the Receiving body (30) is arranged (Fig. 4). 17.) Junction box according to claim 16, characterized in that the set screw (25) with lateral play penetrates the vertical bore (32) of the receiving body (30) and the receiving body (30) when tightening the screw (25) due to the resistance of the cable (15) tilted relative to the penetration (56) and the penetration contacts (40) can penetrate the cable (15) one after the other. 18.) Junction box according to one or more of claims 16 or 17, characterized in that. the receiving body (30 ') on both sides of its vertical bore receiving the adjusting screw (25) has two wings (58, 59) with at least one continuous channel (36) in each wing for inserting a cable (15), (Fig. 8). 19.) Junction box according to claim 18, characterized in that the two wings (58, 59) run at an angle to one another and are used for contacting angularly positioned in the junction box (10 ') cables (15). 20.) Junction box according to one or more of claims 1 to 15, characterized in that the receiving body consists of a bridge (60) with at both bridge ends (61) vertical bores (62) for a pair of adjusting screws (25) and with at least a channel (36) in the intermediate bridge section for inserting the cable (15), (Fig. 9). 21.) Junction box according to one or more of claims 1 to 20, characterized in that the receiving body (72,73) is composed of two superimposed parts in the assembly case (upper part 72, lower part 73), which after dismantling the channel (36) Open at the top to insert a continuous, uncut cable (Fig. 9 to 12). 22.) Junction box according to claim 20, characterized in that the lower part (73) has the vertical slots (39) for the contact blades (41), the channel bottom (81) with both channel side walls (82) and the vertical bores (62) for the set screws ( 25), while the upper part (72) essentially only has the duct cover wall (83) and the cutouts (33) for the screw heads (27), (Fig. 11). 23.) Junction box according to claim 20 or 21, characterized in that the upper part (72) to the lower part (73) of the receiving body is foldable (76) (Fig. 12). 24.) Junction box according to one or more of claims 20 to 22, characterized in that the upper and lower part (72, 73) are connected at one end via a joint (75) and at the other end via a snap lock (84, 85). 25.) Junction box according to one or more of claims 1 to 23, characterized in that the axially fixed but rotatable connection between the adjusting screw (25) and the bridge (60) from an annular groove (28) in the screw shaft (24) and an elastic resilient constriction (69) in the material of the bridge (60) surrounding the vertical bore (62), (Fig. 9). 26.) Junction box according to one or more of claims 1 to 23, characterized in that the axially fixed but rotatable connection between the adjusting screw (25) and the receiving body (30) from an annular groove (28) in the screw shaft (24) and from one Snap ring (49), which can be inserted into a laterally open slot (35) in the receiving body (30) that penetrates the vertical bore (32) (FIG. 4).

Images