FI118658B - Wiring mechanism of the electronic device, electronic device, housing structure of the electronic device and method for making the wire structure - Google Patents

Description

118658

Wire mechanism of the electronic device, electronic device, housing structure of the electronic device and method for manufacturing the conductor structure

FIELD OF THE INVENTION The present invention relates to an electronic device conductor mechanism, an electronic device, an electronic device housing structure, and a method for manufacturing an electronic device conductor mechanism.

Background

Electronic devices, such as mobile phones and laptops, include axially movable hardware components between which there are wires for transmitting, for example, user interface signals such as display signals and keyboard signals. Such wiring typically uses flexible cables that bend with each other in accordance with the movement of the movable components. In this case, the flexible cable is subjected to bending stress, which reduces the reliability of the flexible cable and thus the reliability of the entire electronic device.

Thus, it is useful to develop techniques for providing reliable wiring between axially movable components.

BRIEF DESCRIPTION OF THE INVENTION An object of the invention is to provide a reliable wiring of an electronic device. The first aspect of the invention is provided with an electronic device; ··· "a wiring mechanism for forming a wiring between a first device part and a second device part having Mechanical coupling to permit axial movement between the first device part and the second device part, the conductor mechanism comprising a flexible cable between the first device part and the second device part, the flexible cable comprising a bending part located between the first device part and the second device part! ···. between which the bending member is subjected to at least partial bending in the direction of axial movement between the first device portion and the second device portion during axial movement - *: **: 30; and that the conductor mechanism further comprises a winding member which: *: ** is attachable to another device part, the winding member being secured to at least. a portion of the flexible cable and adapted to rotate relative to the first piece of equipment during axial movement facilitated by mechanical coupling between the first piece of equipment and the second piece of piece 2 118658 and to roll at least partially the bending portion; and that the bending member is arranged at least partially to remain outside the rolled portion of the flexible cable during axial movement between the first device member and the second device member, the bending member being further adapted to have a bending radius of at least a predetermined bending radius during the axial movement

Another aspect of the invention is provided by an electronic device comprising: a first device part; a second piece of equipment; a mechanical coupling attached to the first device part and the second device part to enable axial movement between the first device part 10 and the second device part; and a conductor mechanism for wiring between the first device portion and the second device portion, the conductor mechanism comprising a flexible cable between the first device portion and the second device portion, the flexible cable comprising a bending portion disposed between the first device portion and the second device portion during axial movement between the first device part and the second device part; and that the conductor mechanism further comprises a winding member secured to the second device portion and at least a portion of the flexible cable adapted to rotate relative to the first device portion in the direction of axial movement enabled by mechanical coupling and to roll at least partially { ** .. only the bending part; and that the bending member is arranged to remain at least partially during the axial movement between the first device member and the second device member, or ··· a wooden cable roller, the bending member being further adapted ·· * «: 25 such that the bending member during axial movement between the second device • * «'• at least a predetermined bending radius.

A third aspect of the invention relates to a housing structure of an electronic device comprising: a first device housing; a second housing; a mechanical coupling of ϊ 30 to enable axial movement between the first housing and the second housing; and a conductor mechanism for wiring between the first device enclosure and the second device enclosure, the conductor mechanism comprising a flexible cable for the first device enclosure and the second device enclosure. between the roll, the flexible cable comprising a bending member disposed between the first device box and the second device box, the bending member being subjected to at least partial axial movement during axial movement between the first device box and the second device box; and that the guide mechanism further comprises a winding member secured to a second housing and at least a portion of a flexible cable adapted to rotate relative to the first housing in the direction of axial movement by mechanical engagement during the axial movement between the first housing and the second housing. at least partially a bending member; and that the bending member is arranged to remain at least partially out of the rolled portion of the flexible cable during axial movement between the first device member and the second device member, the bending member being further adapted to have at least a predetermined bending radius during the axial movement radius.

In another aspect of the invention there is provided a method of manufacturing a wiring mechanism of an electronic device which wires between a first device part and a second device part 15 of the electronic device having mechanical coupling between the first device part and the second device part to enable axial movement between the first device part and the second device part. at least partially a winding member comprising a bending member disposed between the first device part and the second device part, the bending member being subjected to at least partial axial movement during axial movement between the first device part and the second device part which is secured to the second device part is adapted to rotate ·; · * relative to the first device part axial movement of the mechanical coupling:. during the axial movement between the first device part and the second device part, and to roll at least partially the bending member, and that the bending member is at least partially retained during the axial movement between the first device part and the second device part. outside the section · · '··· *, the bending section being further arranged such that the bending section or bending radius during axial movement between the first piece of equipment and the second piece of equipment is at least a predetermined bending radius.

• * ·

Preferred embodiments of the invention are described in the dependent claims.

• ·

The invention is based on the fact that the winding member of the conductor mechanism rolls. around the bending portion of the flexible cable during the axial movement between the first and second · · · 35 device portions, whereby the bending radius of the: - / · portion of the flexible cable is always greater than or equal to the bending radius of the roller. The bending member is arranged to compensate for the 4 118658 portion of the flexible cable that rolls around the periphery of the winding member, so that the bending radius of the bending member remains at least a predetermined bending radius. Further, the bending member is arranged such that, as the roll is opened, the bending radius remains at least a predetermined bending radius.

Several advantages are achieved by the conductor mechanism, the electronic device, the housing of the electronic device and the method of manufacturing the conductor mechanism according to the invention. One advantage of the invention is to provide a mechanism for applying a bend to a flexible cable, which improves the reliability and service life of the flexible cable.

10 Pattern list

The invention will now be further described in connection with preferred embodiments, with reference to the accompanying drawings, in which Figure 1 illustrates an example of an electronic device to which the invention may be applied; Figure 2 shows an example of an electronic device enclosure in a first extreme position; in the extreme position, Fig. 4A shows an example of the housing structure of an electronic device in a second extreme position, ...: Fig. 4B shows an example of a conductor mechanism in a second extreme position, Fig. 5 shows a first example of a 25 embodiment of a conductor mechanism; from a direct * ·· .: form,

Figure 7 shows an example of a flexible cable, * * ·· Figure 8A shows a third example of a wiring mechanism: ***: 30 embodiments,

Figure 8B shows a fourth example of a conductor mechanism. embodiment,

Figure 9 shows a first example of a control structure,

Figure 10 shows another example of a control structure, and Figure 11 shows an example of embodiments of a method of manufacturing a conductor mechanism.

5, 118658

Description of Embodiments

Referring to FIG. 1, the electronic device 100 comprises device members 102, 104 between which are mechanical coupling means 106A, 106B, 106C for enabling axial movement between device members 102, 104. In axial movement 5, the device parts 102, 104 rotate relative to each other with respect to the actual or hypothetical axis of rotation common to the device parts 102, 104. Thus, an angle 108 is formed between the device parts 102,104. The actual axis of rotation may be, for example, a hinge pin or other hinge structure. The hypothetical axis of rotation can be achieved by a mutual support structure of the device parts 102, 104 which does not utilize the hinge structure but which nevertheless allows axial movement. In one embodiment, the real or hypothetical axis of rotation moves in a transverse direction relative to the direction of the axis of rotation during axial movement between the device parts 102, 104. In this case, the axial movement and the linear movement are simultaneously present between the device parts 102, 104.

The mechanical coupling means may be parts of a hinge structure, such as hinge pins 106C and / or hinge bushes 106A, 106B.

The device parts 102, 104 typically include electrical components, at least some of which require electrical or optical coupling between the device parts 102, 104. The electronic device 100 may be a laptop computer, a handheld computer 20, or a mobile phone, wherein the device parts 102, 104 may be a body 104 and a display 102. In some embodiments, the device parts 102, 104 may be a body and j *. keyboard. However, the solution presented is not limited to the exemplary ·: ·: applications shown, but can be applied to any electronic device.:. wherein there is a mechanical coupling between the device parts 102,104 to enable axial movement. There may be more than two device parts 102,104.

Fig. 2 shows an example of an electronic device enclosure structure 200 comprising a first device enclosure 202, a second device enclosure 204, and mechanical coupling means 210A, 212A, 214A, 210B, 212B. , 214B, allowing axial movement between the first device box 202 and the second device box 204 ··: * ·· 30. The first device enclosure 202 comprises a first device compartment 206 and the second device enclosure 204 comprises a second device compartment 208. The device compartments 206, 208 are typically reserved for circuit boards and electronic components of the electronic device and possibly other components of the electronic device.

. Thus, device enclosures 202, 204 constitute electronic device device parts 102, ··· 35 104, and enclosure structure 200 may be identified with electronic device 100, and device enclosures 202, 204 may be identified with device parts 102, 104 to facilitate handling of embodiments and features of the invention.

6 118658

In this example, the mechanical coupling means comprise a hinge body 210A, 21BB of a first device housing 202, a hinge body 212A, 212B of a second device housing 204, and hinge pins 214A, 214B axially connecting the hinge bodies 210A, 210B, 212A, 212B. Hereby, an axial movement 224 is provided between the first device housing 202 5 and the second device housing 204, whose movement axis is defined by the pivot pins 214A, 214B.

Figure 2 further illustrates a wiring mechanism for forming a wiring between the first device box 202 and the second device box 204. The conductor mechanism comprises a flexible cable 218 and a winding member 216.

The winding member 216 is secured to the second housing 204 so that the longitudinal direction 236 of the winding member is substantially parallel to the axial movement axis and the winding member 216 rotates relative to the first housing 202 in the direction of axial movement 224 provided by mechanical coupling during movement. In this case, the winding member 216 winds the flexible cable 218 relative to the first device housing 202 in the direction of the axial movement 224 provided by the mechanical coupling means 210A-214B during the axial movement between the first device case 202 and the second device case 204.

The winding member 216 may be a cylindrical structure having an outer periphery around which a flexible cable is wound. In one embodiment, the winding member 216 is a polygon having angular vertices formed by outer peripheral points, and having a number of angles sufficiently large relative to the flexible cable.

Iin 218 so that the flexible cable 218 forms a circular · "·. 25 structure through the corners of the corners without bending with the corners.

· · · ** Y The winding member 216 may be, for example, plastic, metal, and / or plastic. coated metal. However, the disclosed solution is not limited to the materials shown, but any material that allows the flexible cable 218 to be wound may be used as the material of the winding member.

·· *: *** 30 The flexible cable 218 is typically a flexible circuit board cable, or flexi cable, which provides wiring between the first device case 202 and the second device case 204 by combining the electrodes in the first device case 202. Electronic components located in the second device housing 204. The flexible cable 218 comprises a width direction 238 and a longitudinal direction »35 nan 240. The flexible cable 218 may include galvanic conductors for transmitting electrical data signals and / or power between the device cases 202, 204. In one embodiment of 7,118,658, the flexible cable 218 comprises at least one optical guide for optical signal transmission.

The flexible cable 218 may comprise terminals 220, 222 for connecting the flexible cable 218 to circuit boards 5 and / or electronic circuits, e.g., housed in device enclosures 202, 204. In this case, the conductor mechanism may be manufactured separately from other parts of the housing structure 200 of the electronic device and may be connected to the housing structure 200 or to the device parts 102, 104 of the electronic device 100 using various joining techniques such as screws, vulcanization, glue and / or compression.

The flexible cable 218 may be divided into a functionally rigid portion 232 and a bending portion 226. The rigid portion 232 is a portion of a flexible cable 218 substantially interposed between the black dots referred to by reference numeral 232. The flex portion 226 is a remains substantially static in bending 15 during axial movement 224 between device housings 202, 204. Instead, the bending member 226 is subjected to at least partial bending in the direction of axial movement during axial movement 224 between the first device box 202 and the second device box 204.

The bending portion 226 may abut the half-20 portion of the first device housing 202 to a support structure 234 which may be secured to the first device housing and support the flexible cable 218 such that the flexible cable 218 is wound and unrolled from the winding member 216 in a controlled manner. The support structure 234 may also serve as a strain relief.

In one embodiment, the flexible cable 218 further comprises a side-shift 228, by means of which the portion of the first device housing of the flexible cable 218 is positioned at a different position along the longitudinal direction of the winding member 216 ;;; 236 as the part facing the second housing 204. In one embodiment, the flexible cable 218 is secured, for example, by adhesive, mechanical fasteners, and / or other fastening structures at the lateral displacement 228 to the winding member 216, whereby the lateral displacement 228 divides the flexible cable 218 into a rigid thus, the bending section 226 is formed between the lateral displacement 228 and the first device housing 202, and the bending section 226 is received. takes a bend on the flexible cable 218. Instead, the rigid member 232 is fixedly engaged with the second device housing 204 and the winding member 216, with a bending force of 35 ° during axial movement thereof, or: **: it does not exist.

• f 8 118658

The bending member 226 is arranged to remain at least partially out of the rolled portion of the flexible cable 218 during axial movement between the first device member 202 and the second device member 204. In the example shown in Fig. 3A, the bending section 226 is arranged such that the portion outside the rolled portion of the flexible cable 218 forms a free loop 230 which compensates for the flexible cable section 218 wrapping around the winding member 216 such that the first bend During the axial movement between the 202 and the second device housing 204, is at least a predetermined bending radius. The rolled portion of the bending member 226 is substantially the portion of the bending member 226 which rotates about the winding member 216 in any of the axial positions between the first device box 202 and the second device box 204.

The bending radius of the bending member 226 may also be substantially affected by the location and the position of the support structure 234 in which the free link 230 is formed. In this context, it is assumed that space does not, in an uncontrolled sense, limit the magnitude of the bending radii formed in the free loop 230. However, the space may include control structures for controlling the formation of the free loop 230 and thus the magnitude of the bending radii present in the free loop 230.

The predetermined bending radius can be, for example, a radius of the end section of the winding member 216 20 or a minimum radius obtained from the stress measurements, which provides the desired stress resistance. For example, the bending radius may be defined as "... the radius of the hypothetical circle which is positioned within the sharpest bending area of the bending cable 218 such that the circumference of the hypothetical and other · · tangent tangent to the sharpest bending area 218 of the flexible cable" immediate environment. However, the solution disclosed is not limited to the above definition, but any of the bending lengths of the flexible cable 218 may be used.

Figures 3A and 4A illustrate examples of the solution shown in the axial positions of the first device box 302 and the second device box 304 of the housing structure 300. Figure 3A shows a first acoustic position with a minimum angle between the first device case 302 and a second device case 304. Figure 4A shows a second extreme position with a maximum angle between the first device case 302 and the second device case 304. The other first device case 302 and the positions between the second housing 304 are located: ** [: 35 between the extreme positions shown. In the example, the difference between the minimum and maximum angles is about 180 degrees, however, the example shown does not limit the solution shown to 180 degrees Figures 3A and 4A do not show mechanical fastening means.

In the extreme position shown in Figure 4A, the length of the free loop 230 is at its maximum and the free loop 230 is formed about the tangent of the winding member 216. In this case, a free angle 306 is formed in the free loop 230, the size of which depends on the angle between the first device housing 202 and the second device housing 204.

Fig. 3B is a perspective view of the conductor mechanism in the first extreme position. In the example of Figure 3B, the flexible cable comprises a sidewall 228.

Fig. 4B is a perspective view of the conductor mechanism in a second extreme position.

In the extreme position shown in Figure 4B, the length of the free link 230 is minimal and the free angle 306 is large. However, in this case, the abutment point 234 radiates 15 to the free loop 230 such that a limiting angle may be formed in the free loop 230 in the vicinity of the abutment point 234. In the example of Figure 4B, the flexible cable comprises a lateral displacement 228.

In one embodiment, the length of the bending member 226 is selected such that the free angle 306 at the first extreme position and the second extreme position 20 is at least a predetermined bending radius. In this case, the bending portion 226 is so short that the free link 230 does not fold in the first extreme position, and yet so long that the free link 230 is sufficiently curved *: · *: near the support point 234 in the second extreme position.

··· to the free angle 306 formed by the bending section 226 and the folding ····:. For example, the bending stiffness of the flexible cable 218 may be affected by bending stiffness 218. The bending stiffness may be determined by the choice of material and construction and possible bending of the flexible cable 218.

In the embodiment shown in Figure 5, the winding element 510 of the conductor mechanism 500 comprises a longitudinal lateral displacement groove 236 of the winding element 510 into which the lateral displacement 228 of the flexible cable 504 is at least partially embedded. The lateral displacement groove 502 may be dimensioned such that the flexible cable 504 • *: ··: the lateral displacement 228 is completely submerged in the lateral displacement groove 502. In addition, the flexible cable 504 may be provided with folds 506, 508 which fold the flexible cable

35 In the example shown in Fig. 6, the lateral displacement of the winding member 602 provides a passage for the flexible cable 604 through the winding member 602 10 118658. Figure 7 shows a flexible cable 604 having a bending section 704, a rigid section 706 and a lateral displacement 702 suitable for this purpose.

In the example shown in Fig. 6, the lateral displacement groove 502 is formed relative to the end profile of the winding member 602 such that the bend 608 on the bending portion 226 of the flexible cable 5604 is not subjected to bending during axial movement 224 between the first device housing 202 and the second device housing 204.

In one embodiment, the guide mechanism comprises guiding means 606, 610 for controlling the bending member 226 such that, when the bending member 226 is unrolled, the bending radius 226 has a bending radius of at least a predetermined bending radius between the first device housing 202 and

The guide means may be, for example, a partially sleeve-like structure 606 surrounding a winding member 602 having a cable opening 612 and pressing tails wooden cable 604 against the winding member 602. In the example shown, the sleeve-like structure 606 is secured to the first device portion 202 so that the edge 614 of the cable opening 612 serves as a guide structure for the bending portion 226. The location of the cable opening 612 may be selected such that, when the bending portion 226 is rolled out, the free portion 616 is formed at a desired location in the housing structure and the bending radius of the bending portion 226 remains at least a predetermined bending radius.

Fig. 8A shows an example of the conductor mechanism of Fig. 6 from above. The sleeve-like structure 606 may be shaped at the edges 802 so that the support is directed to the edge 608 of the flexible cable 604, which may be left:. 25 free from electrical or optical betting.

In one embodiment, the guide means 610 is adapted to curve at least a portion of the bending section 226 into the width direction **** **** pin 238 of the flexible cable 604, whereby the bending section 226 stiffens in the direction of axial movement.

The warping may be accomplished by the structure of Figure 9, comprising: *** a curved surface printing means 904 and a curved surface t · · anvil 906. A portion of the flexible cable bending portion 902 may be clamped between the curved surfaces of the printing means 904 and anvil 906 the drive portion 902 is curved in the width direction 238. In this case, the steering force • ·. Line 610 may be integrated as part of the support structure 234. In one embodiment, the curvature is performed such that the sleeve-like structure 606 and: * ·· winding member 602 comprises curved surfaces between which a portion of the bending member 902 remains.

11 118658

Curving the bending member 902 stiffens the bending member 226 in the longitudinal direction 240 such that the bending member 226 tends to spontaneously straighten. In this case, when unrolled, the free member 616 tends to unfold in a direction tangential to the circumference of the winding member 602, whereby the free member 616 5 is formed at a desired position in the housing structure and the bending radius of the bending member 226 remains at least a predetermined bending radius.

In the example of Figure 10, the guide means 10 include a tension roll 12, a tension spring 16 and a support 14 between a tension spring 16 and a tension roll 12, via a support 14 pushing the tension roll 12 against the free ring 616 10 so that the free ring 616 The radius of the tensioning roll 12 then defines a minimum radius of the bending member 226.

In one embodiment, the winding member 216 is integrated into the hinge pin 214A, 214B of the mechanical coupling between the first device housing 202 and the second device housing 204. In this case, the hinge pin 214A, 214B is useful for attaching to the second device housing 204 and the hinge body 212A, 212B of the second device housing 204 is not necessary.

The winding member 216 may be disposed between the hinge bodies 210A, 210B, wherein the winding member 216 may be implemented as a cylindrical protrusion at the hinge pin 214A, 214B. In one embodiment, the winding member 216 is disposed within the hinge body 210A, 210B such that at least a portion of the control means 610 is integrated into the hinge body 210A, 214B. Hereby, the hinge body 210A, 210B forms: ** .. a structure for protecting the winding member 216.

·: ··: Figure 8B shows an example of a hinge structure. The winding member ··· 602 may be secured, for example, by screws or integrated into another ····: 25 device housing 204. The first device housing 202 may comprise support members 804, • * with sliding surfaces supporting the winding member 602. Support members 804 support the winding member 602 such that the winding member 602 rotates axially between the support members 804. The support members 802 may be mounted or integrated in the first housing housing 202 and may be positioned at the ends and / or center portion of the winding member 602. However, the solution shown limited to the location of the gripping organs.

· · ·

Fig. 11 illustrates embodiments of a method for manufacturing a conductor mechanism.

The method starts at 910.

In the embodiment of 912, the winding member 216 is integrated into the mechanical coupling hinge pin 214A, 214B of the first device housing 202 and the second device housing 204.

In 118658 914, the flexible cable 218 is at least partially secured to the winding member 216, the flexible cable 218 comprising a bending portion 226 disposed between the first device portion 202 and the second device portion 204, at least partially axially deflected by the first enumeration device portion 226. During the axial movement between the 202 and the second device portion 204, the winding member 216 can be secured to the second device portion 204 adapted to rotate relative to the first device portion 202 during axial movement between the first device portion 202 and the second device portion 204 -10 at least partially slanting the bending portion 226, the flexible cable 218 further comprising a lateral displacement 228 for positioning a portion of the first hardware portion 202 of the flexible cable 218 and a portion of the second hardware portion 204 of the flexible cable 218; 216 in the longitudinal direction, and that the bending section 226 is arranged to remain at least partially outside the rolled portion of the flexible cable 218 during axial movement between the first assembly section 202 and 15, the bend section 226 being further arranged such that the bending section 226 during axial movement between the second device part 204, at least a predetermined bending radius.

At 20,916, the lateral displacement 228 of the flexible cable 218 is at least partially embedded in the lateral displacement groove 502 of the winding member 510, which is longitudinal 236 of the winding member 216.

In: 918, guide means 10, 606, ··· 610 are formed in the conductor mechanism, which controls the bending section 226 so that the bending section 226 is rolled open. At bending portion 226, the bending radius is at least a predetermined amount of bending "V radius" during axial movement between the first device part 202 and the second device part 204.

• · '** · In 1920 the method ends.

Although the invention has been described above with reference to the example of p. 30 of the accompanying drawings, it is clear that the invention is not limited thereto, but can be modified in many ways within the scope of the appended claims.

• · • · ··· • ♦ • · · · · · · · · · · · · ·

Claims (23)

13 118658 An electronic device conductor mechanism for forming a wiring between a first device part and a second device part having mechanical coupling between the first device part and the second device part to enable axial movement between the first device part and the second device part, comprising a first cable part and a second device part characterized in that the flexible cable (218) comprises a bending member (226) disposed between the first device member and the second device member, which bend member (226) is subjected to at least partial bending in axial movement during axial movement between the first device member and the second device member. ; and that the conductor mechanism further comprises a winding member (216) engageable with a second device portion, which winding member (216) is secured to at least a portion of the flexible cable (218) and rotated relative to the first device portion in axial movement by mechanical coupling 15 during movement and at least partially roll the bending member (226); and that the bending portion (226) is arranged to remain at least partially outside the rolled portion of the flexible ka-play (218) during axial movement between the first piece of equipment and the second piece of equipment, the bending portion (226) being further arranged so that the bending radius during the axial movement between the component part and: · · · .. at least a predetermined bending radius ····. The conductor mechanism according to claim 1, characterized in that the conductor mechanism further comprises a lateral displacement (228) of a flexible cable (218) and a flexible cable (218)]! for positioning a portion of the second device portion at different positions along the longitudinal direction of the winding member (216) *****. A conductor mechanism according to claim 2, characterized in that the winding member (510) further comprises a lateral displacement groove (502) which is longitudinal to the reeling member (510) and to which the lateral displacement groove (502) has a flexible cable (504). the lateral displacement (228) is at least partially embedded. A conductor mechanism according to claim 1, characterized. characterized in that the conductor mechanism further comprises guide means (10, 606, 610) for controlling the bending member (226) so that when the bending member (226) is rolled open or V ·! the bending radius of the drive member (226) being at least a predetermined bending radius 14 118658 during axial movement between the first device member and the second device member. A conductor mechanism according to claim 4, characterized in that the guide means (610) are adapted to curve at least a portion of the bending section (226) in the width direction of the flexible cable (604), whereby the bending section (226) stiffens in the axial movement direction. A conductor mechanism according to claim 1, characterized in that the winding member (216) is integrated in the hinge pin of the mechanical coupling between the first device part and the second device part. An electronic device comprising: a first device part (202); a second device part (204); a mechanical coupling (210A-214B) secured to the first device part (202) and the second device part (204) to enable axial movement between the first device part (202) 15 and the second device part (204); and a conductor mechanism for wiring between the first device part (202) and the second device part (204), the conductor mechanism comprising a flexible cable (218) between the first device part (202) and the second device part (204), characterized in that the flexible cable (218) comprises (226) disposed between the first device part (202) and the second device part (204), the bending part (226) being subjected to at least partial bending in the direction of axial movement of the first device part (202) and the second: during axial movement between the device part (204); and that wire mec- · :. It also includes:. A winding member (216) secured to the second device member (204) and a "V" of at least a portion of the flexible cable (218) rotated relative to the first device member (202) by mechanical coupling ***** ( 210A-214B) during axial movement between the first device part (202) and the second device part (204) and: *** to roll at least partially the bending part (226), and that the bending part (226) is arranged to remain at least partly during axial movement between the first device part (202) and the second device part (204), outside the rolled portion of the flexible cable (218), which is additionally arranged so that the bending radius of the bending part (226) is during axial movement between the component part (202) and the second component part (204) • ·% **: at least a predetermined bending radius. The electronic device according to claim 7, characterized in that the conductor mechanism further comprises a lateral displacement (228) for positioning the first device part of the flexible cable (218) and the second device part of the flexible cable (218) at different positions along the longitudinal direction of the winding member (216). An electronic device according to claim 8, characterized in that the winding member (510) further comprises a lateral displacement groove (502) which is longitudinally oriented and into which lateral displacement (228) of the flexible cable (504) is at least partially embedded in the lateral displacement groove (502). An electronic device according to claim 7, characterized in that the conductor mechanism further comprises guiding means (10, 606, 610) for guiding the bending member (226) such that the bending member (226) has at least a predetermined bending radius when the bending member (226) is rolled. during axial movement between the first device part (202) and the second device part (204) 15. An electronic device according to claim 10, characterized in that the guide means (606) is adapted to curve at least a portion of the bending section (226) in the width direction of the flexible cable (604), whereby the bending section (226) stiffens in the axial movement direction. An electronic device according to claim 7, characterized in that the winding member (216) is integrated into a hinge pin (214A, 214B) of a mechanical coupling (210A-214B) between the first device part (202) and the second device part (204). An electronic device housing structure comprising: 25 first device housing (202); A · · ** Y second device case (204); ::: to enable axial movement between the mechanical device (210A-214B) and the first device housing • · ***** (202) and the second device housing (204); and ·· * i *** 30 for conducting a wiring mechanism between the first device case (202) and the second device case (204), the wiring mechanism comprising the first device case (202) and the second device case of the flexible cable (218) (204), characterized in that the flexible cable (218) comprises φ ·. a bending member (226) disposed between the first device case (202) and the second device case (204), the bending member (226) being subjected to at least Y * j partial axial movement bending between the first device case 16 118658 (202) and the second device case (204); during axial movement; and that the conductor mechanism further comprises a winding member (216) secured to a second housing (204) and at least a portion of a flexible cable (216) disposed rotatably relative to the first housing (202) by mechanical coupling (210A-214B). ) to allow axial movement in the direction of axial movement between the first device housing (202) and the second device housing (204) and to roll at least partially the bending member (226); and that the bending section (226) is arranged at least partially to remain outside the rolled portion of the flexible cable (218) during axial movement between the first assembly portion (202) and the second assembly portion (204), the bending section (226) being further arranged such that ), during the axial movement between the first device part (202) and the second device part (204), is at least a predetermined bending radius. Enclosure structure according to claim 13, characterized in that the conductor mechanism further comprises a lateral displacement (228) for positioning the first device part of the flexible cable (218) and the second device side of the flexible cable (218) at different positions along the longitudinal direction of the winding member (216). Enclosure structure according to claim 14, characterized in that the winding member (510) further comprises a lateral displacement groove (502) which is longitudinal and has a lateral displacement of a ··· f cable (504) flexible to which lateral displacement groove (502). (228) is at least partially embedded. Enclosure structure according to claim 13, characterized in that the conductor mechanism further comprises guiding means (10, 606, 610) for guiding the bending member (226) so that when the bending member (226) is opened or * ::: the bending radius of the drive member (226) is at least a predetermined bending radius • · ** ·· * during axial movement between the first device box (202) and the second device box (204). The housing structure according to claim 13, characterized in that the control means (606) is adapted to curve at least a portion of the bending section (226) in the width direction of the flexible cable (604), wherein: the bending member ..... (226) stiffens in the direction of axial movement. • *. Enclosure structure according to claim 13, characterized in that the winding member (216) is integrated in the hinge pin (214A) of the mechanical coupling (210A-214B) between the first device enclosure (202) and the second device enclosure (204). , 214B). 17 118658 A method of manufacturing a wiring mechanism for an electronic device, the wiring mechanism providing a wiring between a first device part and a second device part having mechanical coupling between the first device part and the second device part to enable axial movement between the first device part and the second device part. 914) a flexible cable at least partially to the winding member, comprising a bending member disposed between the first device part and the second device part, the bending member being subjected to at least partial axial movement during axial movement between the first device part and the second device part, attachable to a second device part adapted to rotate relative to the first device part in the direction of axial movement of the mechanical coupling between the first device part and the second device part n during axial movement and at least partially winding the bending member, and that the bending member is arranged to remain at least partially outside the rolled portion of the flexible cable during axial movement between the first and second device members, the bending member being further adapted during axial movement between at least 20, a predetermined bending radius. A method according to claim 19, characterized in that the flexible cable further comprises a lateral displacement for positioning the first portion of the flexible portion of the flexible cable and the portion of the portion of the flexible portion of the flexible cable at different positions along the longitudinal direction of the winding member; 916) a lateral displacement of the flexible cable at least partially into a lateral displacement groove of the reel member * * · ** Y, which is longitudinal to the reel member. γ | A method according to claim 19, characterized by providing (918) guide means for guiding the bending member such that, when the bending member is rolled out, the bending radius of the bending member is at least predetermined. a defined bending radius during axial movement between the first device part and the second device part. A method according to claim 21, characterized in that the guiding means are adapted to curve at least a portion of the bending member. * in the width direction of the flexible cable, whereby the bending member stiffens in the direction of axial «··;„. 35 movement. »• · * • · ♦ • · 18 118658 A method according to claim 19, characterized in that (912) is integrated into the hinge pin of the mechanical coupling between the first device box and the second device box. • · • m • ·· • 1 • · · · · · · · · · · · · · · · · · · · · · · · · · · · · ··· ··· · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · • · · · · · · · terms to Aner • 118 · · · ···