TW201225756A - Fine-diameter coaxial electronic wire harness connected to boards - Google Patents

Abstract

A fine-diameter coaxial cable harness 20 which is formed by bundling a plurality of fine-diameter coaxial cables is connected to respective boards 11 and 12 within two casings 13 and 14 which are slid, an accommodation portion 30 includes a broad part 31 whose width in a direction orthogonal to the direction of the slide is large; and a narrow part 32 whose width is smaller than the width of the broad part 31, one end part 21a of the fine-diameter coaxial cable harness 20 is fixed to the board 11 within the casing 13 in which the broad part 31 is provided; while the other end part 21b of the fine-diameter coaxial cable harness 20 is fixed to the board 12 within the other casing 14, and the fine-diameter coaxial cable harness 20 is wired in a wave shape so as to make, at least, two round trips in a widthwise direction of the casing and is accommodatable in the wave shape within the broad part 31.

Description

201225756 VI. Description of the Invention: TECHNICAL FIELD The present invention relates to a small-diameter coaxial electric wire harness that connects both end portions to a substrate. [Prior Art] Conventionally, a small-diameter coaxial wire having a plurality of small-diameter coaxial wires is connected between the frames which are relatively moved. The case of the relatively moving frame is composed of two frames that are slidably overlapped with each other, and the two frames are slid so that the length is stretched. In this type of mobile phone, it is conventional to have a wire harness that is connected to each board. In the state in which the whole is bent in the shape of a U, the patent document 1) is attached, or the state in which it is bent in the shape of an S is referred to Patent Document 2). [PRIOR ART DOCUMENT] [Patent Document 1] Japanese Laid-Open Patent Publication No. 2007-54 No. 569 (Patent Document 2) JP-A-2009-177377 In addition, the accommodating portion of the wire harness is formed in any of the frames and is housed in a U-shape or an S-shape, and is expanded in the width direction of the casing to form an accommodating portion. Therefore, the assembly space of the electronic component on the side of the frame body is limited, so that the wire harness of the shaft with the substrate can be made into a base of the frame according to the use condition (for example, when it is used, it needs to be formed. It is difficult to miniaturize the steps of the apparatus of the accommodating section. The object of the present invention is to provide a small-diameter coaxial electric wire harness with a substrate which can increase the degree of freedom in assembling the parts and further reduce the size of the machine. According to the present invention, the small-diameter coaxial wire harness with a substrate of the present invention, which is a small-diameter coaxial wire harness bundled with a plurality of small-diameter coaxial wires, is connected to two frames that are vertically overlapped and slid. In each of the substrates, the small-diameter coaxial electric wire harness is housed in an accommodating portion provided in at least one of the frames, and the accommodating portion has a wide portion having a wide width in a direction orthogonal to the sliding direction, And a narrow portion narrower than the width of the wide portion before being fixed on the substrate in the frame in which the wide portion is provided One end of the small-diameter coaxial wire harness, the other end of the small-diameter coaxial wire harness is fixed to the other substrate in the frame, and the small-diameter coaxial wire harness is wave-wound at least twice in the width direction. In the wide-width portion, the small-diameter coaxial wire harness can be accommodated in a shape of a wave. Further, in the small-diameter coaxial wire harness with a substrate according to the present invention, the accommodating portion is preferably provided in one of the frames. In the wire harness of the small-diameter coaxial wire with the substrate, the accommodating portion is preferably constituted by a narrow portion provided in a frame body and a wide portion of 201225756 provided in the other frame body. Further, the substrate with the substrate is thin. In the coaxial cable harness, it is preferable that the entire length of the small-diameter coaxial wire harness is accommodated in the wide portion of the housing portion in a state where the overlapping portion of each of the frames is the smallest. In the thin-diameter coaxial wire harness of the substrate, it is preferable that the overlapping portion of the aforementioned frame bodies is the largest, and the narrow-length coaxial wire harness is slightly longer than the full length. Further, in the wide-width coaxial wire harness with a substrate of the present invention, a plurality of the small-diameter coaxial wires are preferably bundled by a flexible sleeve and bundled. In the wire harness of the small-diameter coaxial wire with a substrate according to the invention, a plurality of the small-diameter coaxial wires are preferably wound by a tape to remove a portion at a predetermined position, and are bent into a wave shape at a portion where the tape is not wound. (Effect of the invention) When the narrow-diameter coaxial wire harness with a substrate of the present invention is used, the wire harness can be accommodated in a wavy portion having a wide portion that can accommodate a small-diameter coaxial wire in a wave shape and a narrow portion narrower than the wide portion. In order to reduce the width of the narrow portion, the frame housing the small-diameter coaxial wire harness can ensure a large assembly space for assembling electronic components on the side of the narrow portion of the accommodating portion. The degree of freedom in circuit design, in turn, further miniaturization of the frame. In addition, the small-diameter coaxial wire harness can be smoothly stretched and contracted in the receiving portion, and the mechanical reliability of the small-diameter coaxial wire is also high. [Embodiment] Hereinafter, an embodiment of a thin-diameter coaxial electric 201225756 wire harness with a substrate according to the present invention will be described with reference to the drawings. (First embodiment) First, the small-diameter coaxial wire harness of the first embodiment is shown in Fig. 1 and Fig. 2, and in the present embodiment, it is placed up and down (front view, second figure). The left and right direction of the figure is horizontally moved between the substrates 1 and 12, and is passed through a small-diameter coaxial cable wire diameter coaxial wire harness including a plurality of (20 to 60) rear-diameter coaxial cables (small-diameter coaxial wires) 24. ) 20 and connected. The substrates 1 1 and 1 2 are respectively incorporated into the frames 13 and 14 that slide relative to each other, such as the action 10 shown in Fig. 3 . The mobile phone 10 is provided with a display in a box body 13 and a key portion in the other frame body 14. Fig. 1 shows the state in which both end portions 2 1 a and 2 1 b of the small-diameter coaxial cable 20 are in the closest state when the frame body 1 3 and 14 are linearly slid, and the second figure is the two ends: 21b is the most alienated status. The horizontal movement distance of the substrates 11 and 12, and the sliding stroke L between the frames 13 and 14 are, for example, 30 mm to 80 mm left. Further, the sliding stroke L in the present embodiment is 60 mm. As shown in Fig. 4, both ends of the small-diameter coaxial cable harness 20 are terminally processed by the mounting connector 25, and are easily connected to the substrate 1 1. Then, the narrow coaxial cable harness 20 has a plurality of narrow coaxial cables 24 by a braided sleeve (which must be a flexible sleeve) 23 in addition to the both end portions 21a. In addition, in the fourth diagram and the first diagram, the longitudinal direction of the connector 25 is disposed in the same manner as the sliding overlap of the frames 13 and 14 (in the thin telephone, the operation harness 21a, that is, the right is used. 12 21b Binding direction of the driver's 201225756 direction, but it may be in other directions. For example, the length direction of the connector 25 may be arranged in a direction orthogonal to the sliding direction of the frames 13 and 14. The narrow coaxial cable In the cross section perpendicular to the central axis, the central conductor, the inner insulator, the outer conductor, and the outer cladding are sequentially arranged from the center to the outer side, and are implemented at the respective end portions 2 1 a, 2 1 b . In the terminal processing, the outer conductor, the inner insulator, and the center conductor system are exposed to a specified length in steps, and the small-diameter coaxial cable harness 20 may include no outer conductor in addition to the plurality of small-diameter coaxial cables. Thin-diameter insulated cable. In addition, a small number of small-diameter coaxial cables 24 are shown in a simplified manner in the drawings. The narrow-diameter coaxial cable 24 should preferably have a specification such as AWG (American Wire Gauge). AWG42 is finer The thin coaxial cable is used, whereby the narrow coaxial cable harness 20 is easily bent, and the resistance when the two substrates 1 1 and 12 are slid can be reduced. Further, the plurality of narrow coaxial cables 24 are bundled to form a small diameter coaxial cable. In the case of the wire harness 20, the diameter of the small-diameter coaxial cable harness 20 can be reduced, and the height of the housing portion can be reduced, and the thickness of the device can be reduced. The narrow-coaxial cable harness 20 includes a diameter of about 20 to 60. In the case of the coaxial cable 24, the narrow coaxial cable 24 is a fineness of the A WG 46, and when the 40 small-diameter coaxial cable harnesses 20 are bundled in a shape close to a circle, the braided sleeve 23 is included. The outer diameter (thickness) including the thickness is 1.7 mm or less, and can be wired in a housing portion having a height (thickness) of 1.7 mm. The narrow coaxial cable harness 20 is a plurality of narrow coaxial cables 24 that pass through the braided sleeve. The tube 23 is formed by bundling, and the plurality of 201225756 narrow coaxial cables 24' are covered by the braided sleeve 23 to improve the durability of the friction of the thin coaxial cable harness 20 against the wall surfaces of the substrates 1, 1 and 12. In addition, the thin coaxial cable harness 20 is such that the braided sleeve 23 The sectional area of the side space is larger than the sectional area of the small-diameter coaxial cable 24, so as to loosely bundle the small-diameter coaxial cable 24. Therefore, the frame 13 and 14 slide and the narrow coaxial cable harness 2 In the case of 0 deformation, the small-diameter coaxial cable 24 is easily changed in the braided sleeve 23. The braided sleeve 2 of the present embodiment is formed by weaving polymer fibers to form a tubular shape. The polymer fiber is preferably made of molten liquid crystal. A monofilament hybrid fiber composed of a polymer and a bendable polymer. The monofilament hybrid fiber is composed of a core component containing a molten liquid crystalline polymer and a sheath component containing a bendable polymer. The sleeve is flexible. Therefore, it has wear resistance. A housing portion 30 that can accommodate the small-diameter coaxial cable harness 20 is formed in one of the housings 13. The accommodating portion 30 has a wide portion 31 having a wide width in a direction orthogonal to the sliding direction of the frames 13 and 14, and a narrow portion 32 having a width narrower than the wide portion 31, and the wide portion 3 A shape is formed between the narrow portion 32 and the narrow portion 32 so as to gradually change in width in the sliding direction. From the wide portion 31 to the narrow portion 32, one side surface has curved surfaces 31a and 33a, and the curved surface 31a of the wide portion 31 is convexly curved outward, and the curved surface 33a is convexly curved toward the inner side. Then, the side portion of the narrow portion _ 3 2 in the frame 13 can secure a large assembly space S in which electronic components can be assembled. The accommodating portion 30 is provided by forming a groove on the surface of the casing 13 opposite to the casing 14. Further, the accommodating portion 30 may be provided by forming a guide wall on the surface opposite to the frame 14 in the frame 13 201225756. One end portion 2 U of the small-diameter coaxial cable harness 20 is fixed to the substrate 11 in the casing 13 in which the accommodating portion 30 is provided, and the other end portion 21b of the small-diameter coaxial cable harness 20 is fixed to the other frame body 14. On the substrate 12 inside. The thin coaxial cable harness 20 has a hole portion (not shown) formed on the opposite side of the other frame body 14 and the frame body 13 on the other end portion 2 1 b side. Further, on the side of the back surface (opposing surface of the frame body 14) of the casing 13, at least in the state where the frames 13 and 14 are opened, the portions overlapping with each other except the frames 13 and 14 are clogged. The cover 34 of the accommodating portion 30. Thereby, the accommodating portion 30 is prevented from being exposed in a state in which the casing 1 3 '14 is opened. Further, in the cover 34, a slit 35 is formed along the sliding direction of the frames 13, 14, and the narrow coaxial cable harness 20 drawn from the side of the frame 14 is inserted. The accommodating portion 30 may be exposed without the cover 34. In the small-diameter coaxial cable harness 20, the both end portions 2 1 a and 2 1 b are disposed on the side of the linear side portion 30a of the accommodating portion 30, and are reciprocated twice in the width direction (formed in a U shape or a W shape). In the state in which the frames 13 and 14 are slid and opened, the narrow coaxial cable 20 is curved in the first and second forms (a). The curved portion 4 1 and 43 are formed on the side 31a, and the wave shape in which the curved portion 42 is formed on the side of the side portion 30a between the curved portions 41 and 43 is accommodated in the wide portion 31.

The total length G of the accommodating portion 30 is the closest to the both end portions 2 1 a and 2 1 b of the small-diameter coaxial cable harness 20 by opening the frames 13 and 14 (the state of Fig. 1). The interval L 1 of the two end portions 2 1 a, 2 1 b and the total of the sliding strokes L -10- 201225756 are a little longer. Further, the width dimension W of the narrow portion 32 of the accommodating portion 30 is set to a state in which the frames 13 and 14 are closed (the state of Fig. 2), and even if it is the smallest, the diameter of the wire harness 20 is smaller than that of the small-diameter coaxial cable. A slightly wider width dimension. Therefore, in the narrow portion 32, the small-diameter coaxial cable harness 20 is wired in a substantially straight line shape. When the width of the narrow width portion 32 is several times the diameter of the small-diameter coaxial cable harness 20, the waveform shape of the small-diameter coaxial cable harness 20 is maintained gentle. Further, the wide portion 31 of the accommodating portion 30 is provided such that the both end portions 2 1 a, 2 1 b of the small-diameter coaxial cable harness 20 are closest to each other by opening the frame 1 3 ' 14 . In the state of Fig. 1, the width dimension of the small-diameter coaxial cable harness 20 having a waveform shape can be sufficiently incorporated. The length of the small-diameter coaxial cable harness 20 is set to be closest to both ends 2 1 a and 2 1 b of the small-diameter coaxial cable harness 20 (see Fig. 1). The interval L 1 of 2 1 a and 2 1 b is longer than the total of the sliding stroke L, and a slight waveform shape is maintained even in the state in which the frames 13 and 14 are closed (the state of Fig. 2). The small-diameter coaxial cable harness 20 has a height in which the curved portions 4丨 to 43 are peaks of the apex in a state in which the frames 13 and 14 are opened and stored in a corrugated shape (in the state of Fig. 1). The part 2 1 a side is longer. In addition, the small-diameter coaxial cable harness 20 is creased in advance so as to easily form a wave shape in a state in which the frames 13 and 14 are opened (the state in the first drawing). Further, one end portion 2 1 a of the small-diameter coaxial cable harness 20 may be disposed on the side opposite to the other end portion 2 1 b, that is, on the curved surface 31a side. At this time, the curved portion of the thin -11 - 201225756 coaxial cable harness 20 is an even number. Next, the movement of the small-diameter coaxial cable harness 20 with the expansion of the frames 13 and 14 will be described. When the frames 13 and 14 are gradually opened from the state in which the respective frames 13 and 14 are closed (the state of Fig. 2), as shown in Fig. 5(a), the two of the small-diameter coaxial cable harnesses 20 are used. The end portions 21a and 21b are close to each other, and the curvature radius of each of the curved portions 41 to 43 is reduced, and the respective curved portions 41 to 43 are slid on the side surface of the accommodating portion 30. In the state in which the respective frames are closed as shown in Fig. 2, the overlapping portions of the respective frames are in a maximum state. Further, by opening the frames 13 and 14, as shown in Fig. 5(b), when the curved portion 41 enters the wide portion 31, the curved portions 42, 43 receive the reaction force from the side surface of the accommodating portion 30, The curved portion 41 is deformed such that the height of the peak of the apex (the distance between the curved portion 41 and the width direction of the adjacent curved portion 42) is gradually increased. Further, when the frames 13 and 14 are opened, the curved portion 43 also enters the wide portion 31, and is accommodated in the wide portion 31 in a state in which the small-diameter coaxial cable harness 20 is bent into a wave shape (refer to 1 picture). At this time, as shown in FIG. 1 , the small-diameter coaxial cable harness 20 that is bent into a wave shape is disposed on the overlapping portion with the casings 13 and 14. Therefore, for example, the cover 34 is not provided on the back surface of the casing 13 . In order to expose the structure of the accommodating portion 30, the small-diameter coaxial cable harness 20 is not exposed to the accommodating portion 30 on the back side of the exposed frame body 13. When the state of each of the frames 1 3 and 14 is opened (the state of Fig. 1) is slowly closed -12-201225756 when the frames 13 and 14 are closed, as shown in Fig. 5(c), the curved portion 43 is made of a small diameter Both end portions 2 1 a and 2 1 b of the coaxial cable harness 20 are moved away, and are slid against the curved surface 3 3 a of the side surface of the housing portion 30. Thereby, since the small-diameter coaxial cable harness 20 receives the reaction force toward the wide portion 31, the curved portion 41 remains in its original state. The state in which the respective frames are opened as shown in the figure is the state in which the overlapping portions of the respective frames are the smallest. Further, when the frames 13 and 14 are closed, as shown in Fig. 5(d), the curved portion 43 enters the narrow portion 32, and the curved portion 42 is moved, and the radius of curvature of each of the curved portions 41 to 43 is increased. Further, when the frames 13 and 14 are closed, as shown in Fig. 5(e), the curved portions 42, 43 enter the narrow portion 32, and the curved portion 41 also moves, and the curved portion 41 is the height of the peak of the apex. reduce. Then, when the frames 13 and 14 are completely closed, the small-diameter coaxial cable harness 20 is stretched along the narrow portion 3 2 into a gentle waveform shape (state of Fig. 2). When the frames 13 and 14 are thus switched, the narrow coaxial cable harness 20 smoothly expands and contracts in the sliding direction in the housing portion 30. Therefore, in the case of the small-diameter coaxial cable harness with a substrate according to the first embodiment, the wide portion 31 having the waveform coaxial shape of the narrow coaxial cable harness 20 and the width portion 3 are provided. Since the accommodating portion 30 of the narrow narrow portion 32 is narrow, the width dimension W of the narrow portion 32 can be reduced. In the case where the frame bodies 13 and 14 that accommodate the small-diameter coaxial cable harness 20 in the accommodating portion 30 are compared with the structure in which the small-diameter coaxial cable harness 20 is housed in a U shape, In the case of a U-shaped shape, a width larger than the size of the diameter of the two portions of the total length of the coaxial cable 13 - 201225756 bundle 20 and the size of the labyrinth is required, and the width dimension W of the web portion 32 can be suppressed to only the specific diameter. The width of one portion of the coaxial cable harness is slightly wider than the width. Thereby, the large assembly space S of the electronic component can be ensured at the side of the narrow portion 32 of the accommodating portion 30, and the degree of freedom of the circuit design of the substrate is used in the mobile phone 10 using the thin-wire cable harness with the substrate.増 Further miniaturization of the frames 13 and 14 can be achieved. Further, the small-diameter coaxial wire harness 20 can be smoothly stretched and contracted in the accommodating portion 30, and the reliability of the small-diameter coaxial electric wire is also high. In addition, the thin-diameter coaxial cable harness with the above-mentioned structure has a durability test for rotating the frame 13 and 14 at a moving speed of 1 second to 5 times, and still does not cause electrical disconnection. . The above-mentioned thin-diameter coaxial cable harness with a substrate is connected to the connector 25 for performing terminal processing on the two 21a ' 21b. However, as shown in FIG. 6 , the thin-diameter coaxial cable harness 20 can also be used. The thin shaft cable 24 is directly coupled to the substrates 11 and 12 to perform terminal processing. When the coaxial cable 24 is directly connected to the substrates 11 and 12, only the terminals of the thin coaxial cable 24 are fixed to the substrate 1 1 and 1 2 by a film or the like, and then the thin coaxial cable 24 is The center conductor of the terminal may be soldered to the connection terminals of 1 1 and 1 2 and connected. Further, even if the ground rod 26 is connected to the outer conductor, and another ground rod 27 or the pressing member 27 is disposed from the side thereof, the pitch can be fixed next to each of the small diameter cables 24'. It can also be directly connected to the substrate I and 12, and the narrow coaxial cable can be assembled. If the moving end is clear, the diameter of the cable will be the same as the one on the opposite side of the temporary substrate -14-201225756 (refer to In Fig. 6(a)), the end portions directly attached to the substrates 1 1 and 12 may be directly bonded to both surfaces (see Fig. 6(b)). The 11 o'clock connected to the upper side is attached to the lower surface thereof, and is attached to the lower substrate 12 when it is attached. It is not limited to direct mating, and when it is connected to the substrate 11 by a connector or the like, it may be connected to both surfaces of the substrates 11 and 12. In addition, the end of the small-diameter coaxial cable harness 20 may be connected to a flexible substrate (FPC: Flexible Pr CircuUs (flexographic circuit)) having a wiring pattern such as a metal foil, or a relay substrate such as a rigid substrate, and may be connected. The device 25' is connected to the substrate 11 and 12 with a socket. Further, the thin-diameter coaxial cable harness with a substrate of the present invention can be suitably mixed with an insulated wire having no external conductor as described above. Use the wire as a ground wire or use an insulated wire as a feeder. Further, the thin-diameter coaxial cable harness with a substrate according to the present invention may be appropriately changed, improved, or the like as defined above. The shape of the wide portion 3'' shown in Fig. 7 is a curved surface whose width is widened from the end portion toward the narrow portion 32 along the sliding direction width, and the width thereof is narrowed thereafter. In this case, the curved portion 4 1 to 43 of the small-diameter coaxial cable harness 20 in the state in which the casing 1 is opened is the peak height of the apex (distance in the width direction of the curved portion), and the other end portion 21b is Big. As shown in Fig. 8, the shape of the small-diameter coaxial cable harness 20 is formed into a waveform shape of five curved portions 41 to 45. In this case, the peak heights of the curved portions 4 1 to 45 as the apexes can be reduced, so that the width dimension in the accommodated wide portion 31 can be reduced. When the substrate is connected to 12, if it is inted, the insulation is not limited. Observe i 3 1a 3 '14. The parts shown in Figure 9 are tied to the small diameter coaxial cable. The straight portions 21c along the sliding direction are provided on both end portions 21a and 21b of the wire harness 20. In this case, the small-diameter coaxial cable harness 20 is easily attached to the substrate. In addition, in the above example, the narrow coaxial cable harness 20 in which the entire length of the plurality of small-diameter coaxial cables 24 is bundled by the braiding sleeve 23 is used, but as shown in FIG. 10, the tape can also be wound. 28 and bundle a plurality of narrow coaxial cables 24. In this case, the portions of the curved portions 41 to 43 that are bent by the switches of the frames 13 and 14 and the portions at both ends are bundled by the tape 28. That is, in addition to the designated position, the thin coaxial cable 24 can be bundled by the tape 28 to specify the bending position. In this manner, the small-diameter coaxial cable harness 20 is smoothly bent by the curved portions 41 to 43 formed by the portions of the tape 28 along with the switches of the frames 13 and 14. Thereby, in the state in which the respective frames 13 and 14 are opened (the state in the tenth (a)th view), the small-diameter coaxial cable harness 20 is bent into a wave shape and accommodated in the wide portion 3 1 , and each of them is closed. In the state of the frames 13 and 14 (the state in the tenth (b)th view), the small-diameter coaxial cable harness 20 extends in the accommodating portion 30. (Second Embodiment) Next, a small-diameter coaxial electric wire harness according to a second embodiment will be described. The same components as those in the first embodiment are denoted by the same reference numerals and will not be described. As shown in Fig. 11, in the case of the second embodiment, the small-diameter coaxial cable harness 20 including a plurality of (20 to 60) small-diameter coaxial cables 24 is connected to the upper and lower overlapping positions (the 11 in the left and right direction) Water-16 - 201225756 The two substrates 13 and 14 of the two frames 13 and 14 that move in a flat position. Both end portions 21a and 21b of the small-diameter coaxial cable harness 20 are connected in the vicinity of the center in the sliding direction of each of the substrates 11 and 12. Further, the accommodating portion 30 is formed in the casing 13 (the upper casing). The wide portion 31 is disposed on the right side in Fig. 1, and one end portion 2 1 a of the narrow coaxial cable harness 20 connected to the substrate 1 1 is disposed on the side of the wide portion 31. Fig. 1(a) shows a state in which both end portions 21a and 21b of the small-diameter coaxial cable harness 20 are the farthest. The first 1(b) diagram shows the state in which the both end portions 21a and 21b are the closest. The narrow coaxial cable harness 20 of the second embodiment is extended in the accommodating portion 30 by opening the frames 13 and 14, and is bent at the wide portion 31 of the accommodating portion 30' by closing the frames 13 and 14. In a wave shape. Therefore, in the case of the small-diameter coaxial cable harness with a substrate according to the second embodiment, when the switch frames 13 and 14 are also formed, the small-diameter coaxial cable harness 20 smoothly expands and contracts in the sliding direction in the accommodating portion 30. . In the mobile phone 10 to which the small-diameter coaxial cable harness having the substrate is applied, the large assembly space S of the electronic component can be secured on the side of the narrow portion 32 of the housing portion 30, so that the substrate circuit design is The degree of freedom is increased, and further miniaturization of the frames 13 and 14 can be achieved. Further, the small-diameter coaxial cable harness 20 is smoothly stretchable in the accommodating portion 30, and the mechanical reliability of the small-diameter coaxial wire is also high. In the second embodiment, when the casings 13 and 14 are opened, a part of the wide portion 17-201225756 31 of the accommodating portion 30 on the side of the end portion 21a of the small-diameter coaxial cable harness 20 is disposed from the casings 13 and 14 The overlapping part is exposed. Therefore, by providing the cover 34 that blocks the wide portion 31 of the accommodating portion 30 on the back side of the casing 13, it is possible to prevent the small-diameter coaxial cable harness 20 from being exposed in the state in which the frames 13 and 14 are opened. Next, it is explained that the narrow coaxial cable harness 20 is extended in the accommodating portion 30 by opening the frames 13, 14. By closing the frames 13, 14, the narrow coaxial cable harness 20 is in the wide portion of the accommodating portion 30. A modification of the structure of the second embodiment in which the bending is performed in 31. As shown in Fig. 12, both end portions 2 1 a and 21b of the small-diameter coaxial cable harness 20 are connected in the vicinity of the center in the sliding direction of each of the substrates 11 and 12. Further, the accommodating portion 30 is formed on the side of the casing 14 (the lower casing), and the wide portion 31 is disposed on the left side in the first drawing, and is connected to one end of the small-diameter coaxial cable harness 20 of the substrate 11. 2 1 a is disposed on the side of the wide portion 3 1 . Fig. 12(a) shows a state in which both end portions 21a and 21b of the small-diameter coaxial cable harness 20 are the most distant, and Fig. 12(b) shows a state in which both end portions 21a and 21b are closest to each other. In other words, the modified example of the small-diameter coaxial cable harness 20 is extended in the housing portion 30 in the housing 14 by opening the frames 13 and 14 to accommodate the housing 14 in the housing 14 by closing the housings 13 and 14. The wide portion 31 of the portion 30 is bent into a wave shape. Therefore, when the thin-diameter coaxial cable harness with the substrate is also the switch frame body 13 and 14 , the small-diameter coaxial cable harness 20 is smoothly slid in the housing portion 30 of the frame body 14 side. Telescopic in the sliding direction. In the mobile phone 1 〇 -18-201225756 to which the thin-wire coaxial cable harness with a substrate is applied, the large assembly space S for assembling electronic components can be ensured at the side of the narrow portion 32 of the accommodating portion 30. Therefore, the degree of freedom in the design of the substrate circuit is increased, and further miniaturization of the frames 13 and 14 can be achieved. Further, the small-diameter coaxial cable harness 20 can smoothly expand and contract in the accommodating portion 30, and the mechanical reliability of the small-diameter coaxial wire is also high. In particular, in the case of the modification, even when the frames 13 and 14 are opened, the entire accommodating portion 30 is disposed in the overlapping portion of the frames 13 and 14, so that the accommodating portion 30 can be prevented from being exposed. (Third Embodiment) Next, a small-diameter coaxial electric wire harness according to a third embodiment will be described. The same components as those in the first embodiment are denoted by the same reference numerals and will not be described. As shown in Figs. 13 and 14, in the third embodiment, the narrow coaxial cable harnesses 20 including a plurality of (20 to 60) small-diameter coaxial cables are connected to each other in an up-and-down arrangement. Between the front and rear (the left and right directions of Figs. 13 and 14), between the respective substrates 1 1 and 1 2 of the two frames 13 and 14 which are horizontally moved. As shown in Fig. 15, a groove portion 51 along the sliding direction is formed on the surface of the frame body 13 opposite to the frame body 14, and a part of the groove portion 51 (one part of the left side in the 15th (a) figure) is formed. The narrow portion 3 2 of the accommodating portion 30. As shown in Fig. 16 (a) and (b), a guide member 52 slidably inserted into the groove portion 51 of the frame body 13 is provided on the opposite side of the frame body 14 from the frame body 13. Further, as shown in Fig. 16(c), the wide portion 31 constituting the accommodating portion 30 is formed on the opposite surface of the frame 14 from the frame 13 to 201225756. Further, the frame 14 is formed with a guide 53 that is connected to the end of the intermediate portion 33 of the accommodating portion 30 and is inclined. A slope surface 54 that is parallel to the inclined surface 53 is formed in the guiding member 52 covering the intermediate portion 33. Then, in the third embodiment, the accommodating portion 30 is constituted by the narrow portion 32 formed by the groove portion 51 of the frame body 13 and the wide portion 31 of the frame body 14, and the small diameter portion coaxially accommodates the accommodating portion 30. Cable harness 20. Further, the small-diameter coaxial cable harness 20 accommodated in the accommodating portion 30 is disposed on the end portion 21b side of the narrow portion 32 at the end portion 21b side to form a straight portion 2 1 c ° along the sliding direction. In the third embodiment of the structure, when the frame bodies 13 and 14 are opened, the narrow-diameter coaxial cable extending along the narrow portion 32 in the housing portion 30 including the frame body 13 and the frame body 14 is opened. The wire harness 20 is guided to the guide surface 53 and the slope surface 54 and fed into the wide portion 31 provided on the side of the frame 14. Therefore, the small-diameter coaxial cable harness 20 is bent into a wave shape and housed in the wide portion 31 of the casing 14. Further, when the frames 13 and 14 are closed, the narrow coaxial cable harness 20 housed in the wide portion 31 of the frame 14 is guided to the guide surface 53 and the slope surface 54 and pulled out to the frame 13 A part of the groove portion 51 constitutes a narrow portion 32 of the accommodating portion 30. Therefore, the narrow coaxial cable harness 20 is housed in the housing portion 30 formed by the frame 13 and the frame 14. In the case of the small-diameter coaxial cable harness with a substrate according to the third embodiment, when the switch frames 13 and 14 are switched, the small-diameter coaxial cable harness 20 smoothly expands and contracts in the sliding direction in the housing portion 30. . -20- 201225756 Further, in the mobile phone 10 to which the small-diameter coaxial cable harness with a substrate is applied, a large assembly space S in which electronic components can be assembled can be secured on the side of the narrow portion 32 of the housing portion 30, Therefore, the degree of freedom in the design of the substrate circuit is increased, and further miniaturization of the frames 13 and 14 can be achieved. Further, the small-diameter coaxial cable harness 20 can smoothly expand and contract in the accommodating portion 30, and the mechanical reliability of the small-diameter coaxial wire is also high. In particular, by dividing the accommodating portion 30 into the two frames 13 and 14, it is possible to reduce the exposure of the accommodating portion 30 when the frames 13 and 14 are opened to each other, and for example, the key operating portion can be easily secured. Further, when the frames 13 and 14 are opened to each other, the guide member 52 may be provided so that the narrow coaxial cable harness 20 is guided to the wide portion 31 of the frame 13, but the guide member 52 may not be provided. . [Embodiment] The structure (see FIG. 17) of the first embodiment of the first embodiment in which the small-diameter coaxial cable harness 20 is bent into a corrugated shape and is accommodated in the wide portion 31 is compared with a small-diameter coaxial cable. The conventional structure (refer to FIG. 18) in which the wire harness 20 is bent into a U shape is known. The housing portions of the small-diameter coaxial cable harness are located on the upper frame 13 . As a result, in the accommodating portion 30 of the present invention, the wide portion 31' is required, but the width dimension W 2 of the rectangular accommodating portion 6 先前 which is previously configured can be reduced, and the narrow portion which occupies a large portion along the sliding direction is narrowed. 3 2 width dimension W1. Specifically, the width dimension W2 of the accommodating portion 60 of the conventional structure is -21 - 201225756 10 mm, and the width dimension W 1 of the narrow portion 32 of the accommodating portion 30 of the present invention is 5 m m. This is because, in the case of the conventional structure, the small-diameter coaxial cable harness 20 is always bent in the accommodating portion 60, so the width dimension W2 of the accommodating portion 60 needs to be larger than the diameter of the two portions of the total small-diameter coaxial cable harness 20. The size after the size of the curved diameter. On the other hand, in the configuration of the present invention, in the state where the both end portions 2 1 a, 2 1 b of the small-diameter coaxial cable harness 20 are the most distant, the narrow-diameter coaxial cable harness 20 is extended in the sliding direction, so The width dimension W 1 of the narrow portion 32 is suppressed to a width dimension slightly larger than the diameter of one portion of the thin coaxial cable harness 20. From this, it is understood that, in the configuration of the present invention, a large assembly space S can be secured to the side portion of the narrow portion 32 of the accommodating portion 30, so that electronic components can be assembled to the assembly space S. In the case where the sliding stroke is set to 60 mm, the accommodating portion of the present invention can be made into the following dimensions. The total length of the 7 5mm narrow portion 32 is 5 mm wide. The maximum width of the wide portion 31 is 20 mm. The length of the narrow portion 32 is 37 mm. The length of the narrow portion 32 is about 1/2 of the total length, and the width of the wide portion 31 is from the narrow portion 3. 2 slowly widens. In the case of forming a U-shaped wiring, the length of the accommodating portion is 6 5 m m and the width is 1 〇 m m. -22- 201225756 When the area of the accommodating portion is compared with the above example, the case of the present invention is 670 mm 2 , which is substantially equal to the case where the U-shape is 650 mm 2 . When the stroke is shorter than 60 mm, the wiring of the present invention can reduce the area of the housing portion. Further, in a state in which the frames 13 and 14 are opened to each other, in the conventional structure, the small-diameter coaxial cable harness 20 is exposed in the accommodating portion 60 that is separated from the overlapping portions of the frames 13 and 14, so that When the cover closes the accommodating portion 60, the small-diameter coaxial cable harness 20 is exposed (see Fig. 18(a)). In contrast, in the configuration of the present invention, since the narrow-diameter coaxial cable harness 20 bent into a wave shape is disposed on the overlapping portion of the frames 13 and 14, the thin coaxial cable is not blocked even by the cover. The wire harness 20 is still not exposed (refer to Fig. 17(a) h] [Simplified description of the drawings] Fig. 1(a) shows an example of the first embodiment of the small-diameter coaxial cable harness with a substrate of the present invention. (b) is a plan view showing a state in which each of the frames is opened, and (b) is a side view. Fig. 2(a) is a view showing a closed frame of the first embodiment of the small-diameter coaxial cable harness with a substrate according to the present invention. The plan view of the state, (b) is a side view thereof. Fig. 3(a) is a perspective view showing the state of each of the frames of the mobile phone to which the thin-diameter coaxial cable harness with a substrate of the present invention is applied. b) is a perspective view showing the state of each frame in which the mobile phone is turned off. Fig. 4 is a plan view showing a state in which the connector is attached to the end of the small-diameter coaxial cable harness. -23- 201225756 Fig. 5 (a) ~(e) shows the storage state of the small-diameter coaxial cable harness in the housing portion Fig. 6(a) is a side view showing an example of a state in which a small-diameter coaxial cable harness is directly attached to one surface of a substrate, and (b) a small-diameter coaxial cable harness is directly attached to a substrate. A side view showing an example of a state of both sides. Fig. 7 is a plan view showing a state in which each of the frames of the modification of the small-diameter coaxial cable harness having the substrate is opened. Fig. 8 is a view showing a thin coaxial path with a substrate. Fig. 9 is a plan view showing a state in which each of the casings of the modified example of the small-diameter coaxial cable harness having the substrate is opened. Fig. 10(U) shows the state of the frame of the modification of the cable harness. A plan view showing a state in which each of the frames of the modified example of the small-diameter coaxial cable harness having the substrate is displayed, and (b) is a plan view showing a state in which the respective frames are closed. Fig. 11(a) is a plan view showing a state in which each of the frames of the second embodiment of the small-diameter coaxial cable harness with a substrate of the present invention is opened, and (b) is a plan view showing a state in which the respective frames are closed. . Fig. 2(a) is a plan view showing a state in which each of the frames of the modification of the small-diameter coaxial cable harness with a substrate of the second embodiment is opened, and (b) is a plan view showing a state in which the respective frames are closed. Fig. 13(a) is a plan view showing a state in which each of the casings of the third embodiment of the small-diameter coaxial cable harness with a substrate of the present invention is opened, and (b) is a side view thereof. -24- 201225756 Fig. 14 (a) is a plan view showing a state in which each of the casings of the third embodiment of the small-diameter coaxial cable harness with a substrate of the present invention is closed, and (b) is a side view thereof. . Fig. 15 (a) is a plan view showing a block body used in a third embodiment, and (b) is a cross-sectional view. Fig. 16 is a plan view showing another block body used in the third embodiment, (b) is a cross-sectional view, and (c) is a plan view of a frame in which the guide member is removed. Fig. 17 (a) A plan view showing a state in which each of the frames of the small-diameter coaxial cable harness with a substrate of the structure of the present invention is displayed, and (b) is a plan view showing a state in which the respective frames are closed. Fig. 18(a) is a plan view showing a state in which the respective frames of the previously constructed small-diameter coaxial cable harness with the substrate are opened, and (b) is a plan view showing the state in which the respective frames are closed. [Description of main components] 10 Mobile phones 1 1 and 1 2 Substrate 13, 14 Frame 20 Thin coaxial cable harness (small diameter coaxial wire harness) 21a ' 21b End 21c Straight portion 23 Braided sleeve (flexible Casing) 24 Small-diameter coaxial cable (small-diameter coaxial wire) 25 Connector 26 Grounding bar-25- 201225756 27 Grounding bar (extrusion member) 28 Tape 30 accommodating portion 30a. Side portion 3 1 Wide portion 31a, 33a Curve 32 Narrow 33 Medium 34 Cover 35 Slit 4 1 ～ 45 Bend 5 1 Ditch 52 Citation 53 Citation 54 Oblique 60 G G Receiver H Tip L Slip LI S Group W, W1, W2 Wide Width Intersection Guide member guide surface (inclined surface) Slope surface capacity portion of the full-length peak height dynamic stroke masculine space size -26-

Claims (1)

201225756 VII. Patent application scope: 1 · A small-diameter coaxial wire harness with a substrate, which is a small-diameter coaxial wire harness bundled with a plurality of small-diameter coaxial wires and connected to two frames which are arranged to overlap and slide In each of the substrates, the small-diameter coaxial electric wire harness is housed in an accommodating portion provided in at least one of the frames, and the accommodating portion has a wide portion having a wide width in a direction orthogonal to the sliding direction, And a narrow portion narrower than the width of the wide portion, wherein one end of the small-diameter coaxial wire harness is fixed to a substrate in the frame in which the wide portion is provided, and the other end of the small-diameter coaxial wire harness is fixed The small-diameter coaxial electric wire harness is formed in a wave shape so as to reciprocate at least twice in the width direction on the other substrate in the frame, and the small-diameter coaxial electric wire harness can be accommodated in the wide portion in a wave shape. 2. The small-diameter coaxial wire harness with a substrate according to the first aspect of the patent application y, wherein the housing portion is provided in one of the frames. 3. The small-diameter coaxial wire harness with a substrate according to the first aspect of the patent application, wherein the housing portion is formed by a narrow portion provided in a frame body and a wide portion provided in the other frame body. 4. In the state in which the narrow-coaxial coaxial wire harness with the substrate of the second application of the patent application is in a state in which the overlapping portions of the frames are the smallest, the substantially full length of the small-diameter coaxial wire harness of the former -27-201225756 is accommodated. In the wide portion of the accommodating portion. 5. The narrow-diameter coaxial wire harness j with a substrate according to the second aspect of the patent application, wherein the substantially full length of the narrow coaxial wire harness is accommodated in the state in which the overlapping portion of each of the frames is the largest In the aforementioned wide portion of the part. 6. The small-diameter coaxial wire harness with a substrate according to any one of claims 1 to 5, wherein the plurality of the small-diameter coaxial wires are bundled by a flexible sleeve. 7. The small-diameter coaxial wire harness with a substrate according to any one of the items 1 to 5, wherein the plurality of the small-diameter coaxial wires are wound by a tape other than a specified position, and The portion where the tape is not wound is bent into a wave shape. 8. The small-diameter coaxial wire harness with a substrate according to claim 6 wherein the flexible sleeve is manufactured by weaving a polymer fiber. -28-