JP5041892B2 - Flexible cable, electronic device using the same, and portable terminal device - Google Patents

Description

  The present invention relates to a flexible cable having an improved shielding effect and an electronic device using the flexible cable, in particular, a mobile terminal device.

  Conventionally, flexible cables are often used for internal wiring in portable terminal devices such as mobile phones, PDAs, and notebook personal computers. In particular, in a foldable portable terminal device in which two casings are rotatably connected by hinges, it is indispensable to use a flexible cable for wiring between printed boards provided in the two casings. Yes (Patent Document 1).

  A flexible cable is usually configured by arranging a plurality of conductors in a flexible insulator. A plurality of flexible cables may be used in an overlapping manner, or one flexible cable may be folded into two to be used in duplicate. Further, in order to suppress generation of noise from unnecessary radio wave radiation, a flexible cable for shielding may be used in an overlapping manner.

  18 is a plan view of a conventional flexible cable 91, FIG. 19 is a perspective view showing a partial internal structure of a conventional mobile phone 1j using the flexible cables 90 and 91, and FIG. 20 is a flexible cable 90 and 91 in FIG. It is a side view which shows the lamination | stacking state of.

  In FIG. 18, the flexible cable 91 has a plurality of conductors DU disposed in an insulator ZT, and both ends of the conductor DU are connection terminals ST1 and ST2 for connection to connectors CN1 and CN2. The conductor DU is divided into two conductor groups DU1 and DU2, and the conductor groups DU1 and DU2 and the insulators ZT1 and ZT2 that insulate them are folded at folding points PK1 and P2 to overlap each other. Yes.

  In FIG. 19, a connector CN1 mounted on the printed circuit board 92a provided on the housing KTS of the transmitter side SG and a connector CN2 mounted on the printed circuit board 92b provided on the housing KTG of the receiver side JG. For connection, two flexible cables 91 and one flexible cable 90 are used in a stacked state.

That is, as well shown in FIG. 20, two flexible cables 91 and 91 folded in half are overlapped, and a ground flexible cable 90 is overlapped thereon. The flexible cable 90 has a solid pattern having a width substantially equal to that of the insulator, and is soldered to terminals such as the printed boards 92a and 92b at the respective ends so that both frame grounds (FG) are connected. Connected to each other. As an example of a mobile phone using such a flexible cable, there is a commercially available “F882iES” manufactured by Fujitsu.
JP 2001-119460 A

  However, as described above, in order to connect the transmitter side SG and the receiver side JG, in addition to the flexible cable 91 connecting the connectors CN1 and CN2, the frame ground is connected and shielded. It was necessary to provide the dedicated flexible cable 90 in parallel.

  For this reason, the number of parts increases, the mounting space increases, and the number of work steps for mounting increases, leading to an increase in cost.

  The present invention has been made in view of the above-described problems, and a dedicated flexible cable for connecting a frame ground and performing shielding can be omitted, and the number of parts and work man-hours for mounting can be reduced. An object of the present invention is to provide a flexible cable that can be used.

  The flexible cable according to the present invention is a flexible cable configured such that a plurality of conductors are arranged in an insulator and both ends of the conductor are connected to a connector, and a ground layer is formed in the insulator. The ground layer has a folded ground portion that can be folded back so as to shield the connector in a state where the end portion of the conductor is connected to the connector, and at least one surface of the folded ground portion The ground layer is exposed and can be connected as a frame ground.

  By providing the return ground portion that can be turned back, the connector can be shielded when the end portion of the conductor is connected to the connector. Further, since the ground layer is exposed and can be connected as a frame ground, the flexible cable can be used to connect the frame ground directly to the housing or the shield plate together with the connector of the signal line.

  The ground layer may be exposed on a surface opposite to the surface facing the connector when the folded ground portion is folded. This makes it easy to connect the ground layer to the casing or shield plate when mounted on a printed circuit board.

  The insulator includes a first insulator layer covering a surface on one side of the conductor and the ground layer, and a second insulator layer covering a surface on the other side, and the second insulator layer. A silver paste is applied on the insulator layer, and the silver paste is configured to be electrically connected to the ground layer through a hole provided in the second insulator layer. Good.

  If comprised in this way, a ground layer will be strengthened by uniting a ground layer and a silver paste layer, and a more stable frame ground can be obtained. Further, since the ground layer can be connected by the silver paste layer, the pattern formation of the ground layer is facilitated.

  By forming the branch ground portion, the frame ground can be connected by soldering with the branch ground portion together with the connector connection for the signal line.

  At least one of the branch ground portions may be provided in the folded ground portion. According to this, it becomes easy to connect the branch ground portion in the vicinity of the connector, and it is easy to obtain a stable frame ground.

  According to the present invention, it is possible to omit a dedicated flexible cable for connecting a frame ground and performing shielding, and it is possible to reduce the number of parts and the number of work steps for mounting.

  1 is a front view showing an appearance of a mobile phone 1 according to an embodiment of the present invention, FIG. 2 is a left side view of the mobile phone 1 of FIG. 1, and FIG. 3 is a front view of a state in which the mobile phone 1 is folded. 4 is a left side view of the cellular phone 1 in a folded state, FIG. 5 is a plan view of the cellular phone 1 in a folded state, and FIG. 6 is a rear view of the cellular phone 1 in a folded state.

  1 to 6, the cellular phone 1 according to the present embodiment is a folding type in which a transmitter side (fixed side) SG and a receiver side (movable side) JG are rotatably connected by a hinge HJ. is there. The case KTS of the transmitter side SG includes a front case 11 having an operation unit SB provided on the front surface, and a rear case 12 disposed in contact with the back side of the front case 11. The front case 11 and the rear case 12 are each manufactured by molding (molding) of a synthetic resin such as polycarbonate or ABS resin. A front case 31 and a rear case 32 to be described later are similarly manufactured by resin molding.

  In the operation unit SB, various operation buttons 20 for inputting a telephone number and other information are arranged in a state protruding from the hole provided in the front case 11 to the surface (front surface), and the operation button SB is pressed. Accordingly, a contact or a sensor provided on the printed circuit board 25 described later is configured to detect it. Below the operation unit SB of the front case 11, a voice input port 21 is provided for transmitting a user's voice to an internal microphone.

  As well shown in FIG. 6, the rear case 12 is provided with a sound output port 22 for transmitting sound output from the speaker to the outside, a strap locking portion 23 for attaching a strap, and the like. In addition, a battery housing portion RD is provided inside the rear case 12, and the surface thereof is a detachable battery lid 24. The front case 11 and the rear case 12 are integrated by four screws 19 inserted from the side of the rear case 12 and screwed.

  The housing KTJ of the receiver side JG includes a front case 31 and a rear case 32 disposed in contact with the back side of the front case 31. A main display 33 made of a color LCD is provided on the surface of the front case 31, and an audio output port 34 is provided above the main display 33 for transmitting audio output from an internal receiving speaker. The rear case 32 is provided with a lens window 35 of a built-in camera.

  Next, the structure of the housing KT of the mobile phone 1 will be described.

  FIG. 7 is an exploded perspective view showing the case KTS of the transmitter side SG of the mobile phone 1, and FIG. 8 is an exploded perspective view showing the case KTG of the receiver side JG of the mobile phone 1.

  As shown in FIG. 7, a printed circuit board 25 is arranged inside the front case 11 on the transmitter side SG. LSI, IC, various connectors, speakers, flexible cables, and other various electronic components BH are mounted on the back side of the printed board 25 (the surface on the rear case 12 side). On the front side of the printed circuit board 25 (the surface on the front case 11 side), an input sheet NS on which contacts, sensors, and the like that detect and input operations of the operation buttons 20 are arranged.

  A bottom plate 26 made of a metal plate is attached to the bottom of the battery housing portion RD of the rear case 12 over substantially the entire area. The battery DT is placed on the bottom plate 26, and the battery cover 24 is attached from above the battery DT, and the battery storage portion RD is closed.

  As shown in FIG. 8, a printed circuit board 36 is arranged inside the front case 31 of the receiver side JG. Various electronic components BH are mounted on the back side of the printed circuit board 36 (the surface on the side of the rear case 32). Between the electronic component BH and the rear case 32, a metal plate 37 serving as both a shield for the printed circuit board 36 and the electronic component BH and reinforcement of the housing KTG is provided. Note that there may be a plurality of printed circuit boards 25 and 36.

  In order to connect the connector CN1 mounted on the printed circuit board 25 on the transmitter side SG and the connector CN2 mounted on the printed circuit board 36 on the receiver side JG, two flexible cables 41 are used in a stacked state. ing.

  Next, the flexible cable 41 will be described.

  9 is an enlarged perspective view showing the vicinity of the flexible cable 41, FIG. 10 is a cross-sectional side view showing an arrangement state of the flexible cable 41, and FIG. 11 is an enlarged view showing a portion of the receiver side JG in FIG. 12 is an enlarged view of the transmitter side SG portion of FIG. 10, FIG. 13 is a front view of the flexible cable 41 in a developed state, and FIG. 14 shows patterns of the conductor DU and the ground layer GU of the flexible cable 41. FIG. 15 is a front view showing the pattern of the silver paste layer GUA of the flexible cable 41, FIG. 16 is a cross-sectional view showing the layer structure of the flexible cable 41, and FIG. is there.

  As shown in FIGS. 9 to 12, the flexible cable 41 is provided between the connector CN1 on the printed circuit board 25 on the transmitter side SG and the connector CN2 on the printed circuit board 36 on the receiver side JG. It is arranged in a state of being bent through the space. The flexible cable 41 has bending resistance that can withstand bending at the hinge HJ.

  As shown in FIGS. 13 to 15, in the flexible cable 41, a plurality of conductors DU are disposed in the insulator ZT, and both ends of the conductor DU of the cable body 42 are connected to the connectors CN1 and CN2. Connection terminals ST1 and ST2.

  And the ground layer GU is provided in parts other than the conductor DU in the insulator ZT. The ground layer GU branches from the insulator ZT that insulates the conductor DU together with the insulator ZT that insulates the ground layer GU (see FIG. 14), thereby forming branch ground portions 45 and 46 at two locations.

  Each of the branch ground portions 45 and 46 has arm portions 45b and 46b having a predetermined width, the ground layer GU is exposed at the end portions of the arm portions 45b and 46b, and ground connection portions 45a and 46a are provided. .

  The ground connection portions 45a and 46a are provided so as to be positioned in the vicinity of the connection terminals ST1 and ST2 that are both ends of the conductor DU. That is, it is preferable to provide the ground connection portions 45a and 46a as close to the connectors CN1 and CN2 as possible. Further, the arm portions 45b and 46b are preferably as short and wide as possible.

  One branch ground portion 46 is branched in the vicinity of the connection terminal ST2 of the cable body 42, and has a shape in which a turning point PK5 that is the branch point is slightly constricted, and the arm portion 46b has a conductor DU at the turning point PK5. It is formed so as to be able to be folded back so as to intersect in a state where it is away from.

  That is, in FIG. 13, the arm portion 46b is folded back at the folding point PK5 so as to intersect with the conductor DU and the insulator ZT on the arm portion 46b and extend upward, whereby the ground connection portion 46a is shown in the drawing. It moves to a symmetrical position with respect to the turning point PK5 from the position.

  As described above, by making the branch ground portion 46 foldable, the ground connection portion 46a can be easily pulled out to a location not covered with the flexible cable 41 itself, and the degree of freedom in designing a printed circuit board or the like is improved. To do.

  The ground connection portion 46a of the branch ground portion 46 is soldered HD to a ground terminal 36a on the printed circuit board 36 provided in the vicinity of the connector CN2 (see FIGS. 9 and 11), thereby connecting the frame ground. .

  As shown in FIG. 16, the insulator ZT includes a first insulator layer ZTa that covers one surface of the conductor DU and the ground layer GU, and a second insulator layer ZTb that covers the other surface. The silver paste layer GUA is provided on the second insulator layer ZTb, and the third insulator layer ZTc is provided thereon. The silver paste layer GUA is electrically connected to the ground layer GU through a plurality of holes AM provided in the second insulator layer ZTb. Accordingly, the ground layers GU that are not connected to each other as a pattern in the ground layer GU shown in FIG. 14 are also electrically connected to each other through the silver paste layer GUA. Thus, the ground layer GU and the silver paste layer GUA constitute a substantial ground layer GU that becomes a frame ground as a whole.

  The first insulator layer ZTa is a base film made of a synthetic resin excellent in flexibility and insulation, such as polyimide. The second insulator layer ZTb is a cover lay made of the same material, and the third insulator layer ZTc is a top coat made of the same material. The conductor DU and the ground layer GU are both made of copper foil. However, it is also possible to use a metal material with good conductivity other than copper. The silver paste layer GUA is formed by applying a silver paste. However, it is also possible to use a paste containing a metal material with good conductivity other than silver.

  The thickness of the copper foil is, for example, about 15 to 25 μm, and the thickness of the silver paste layer GUA is, for example, about 20 to 30 μm. Adhesive is used on both surfaces of the copper foil constituting the conductor DU and the ground layer GU, and is adhered to the first insulator layer ZTa and the second insulator layer ZTb.

  A reinforcing film is attached to the connection terminals ST1, 2 with an adhesive.

  The ground layer GU is electrically connected to at least one conductor DU serving as a ground line among the conductors DU. That is, one or more of the plurality of conductors DU are ground lines, and these are electrically connected to the ground layer GU. As a method for connecting them, a method of connecting by a pattern when forming a copper foil pattern, a method of providing a hole AM in the second insulator layer ZTb, applying a silver paste, and connecting to the silver paste layer GUA, Other methods are possible. The conductor DU, which is a ground line, is connected to the connectors CN1 and 2 at the connection terminals ST1 and ST2, and is connected to the ground line at each printed circuit board 25 and 36.

  In FIG. 14, the front side on the paper with respect to the conductor DU and the ground layer GU is the first insulator layer ZTa, and the back side on the paper is the second insulator layer ZTb. In FIG. 15, the front side on the paper surface of the silver paste layer GUA is the second insulator layer ZTb, and the back side on the paper surface is the third insulator layer ZTc.

  By the way, the flexible cable 41 is used in a state where the cable body 42 is doubled by being folded.

  That is, the cable main body 42 of the flexible cable 41 is divided into two cable main bodies 42a and 42b, and is formed into a shape overlapping each other by being folded at the folding points PK1 and PK2. That is, the cable bodies 42a and 42b are formed in a line-symmetric shape in plan view. Therefore, the conductor DU included in the cable main body 42 is divided into two conductor groups DU and DU included in the cable main bodies 42a and 42b, and overlaps each other when folded.

  Further, the ground layer GU forms folded ground portions 44a and 44b that can be folded back so as to shield the connectors CN1 and 2 when the portions of the connection terminals ST1 and ST2 are connected to the connectors CN1 and CN2, respectively.

  That is, in FIGS. 13 to 15, rectangular folded ground portions 44a and 44b are formed on the rightward extensions of the portions of the connection terminals ST1 and ST2. The folded ground portions 44a and 44b can be folded and overlapped to the connection terminals ST1 and ST2 at the folding points PK3 and P4.

  The folded ground portion 44b has a ground layer GU on almost the entire surface, and further has a silver paste layer GUA on a part of the tip side. Then, on one surface of the folded ground portion 44a, the ground layer GU is exposed on the surface and can be connected as a frame ground.

  That is, as shown in FIG. 14, in the rectangular portion BR1 of the folded ground portion 44b, the insulator ZT located on the front side of the paper surface of the ground layer GU, that is, the first insulator layer ZTa shown in FIG. Then, the ground layer GU is exposed to form an exposed ground layer GUR. The exposed ground layer GUR in the folded ground portion 44b becomes the surface of the uppermost layer above the connector CN2 when mounted on the mobile phone 1, and is a metal plate 37 fitted in the rear case 32 as shown in FIG. Are electrically connected to each other through the contact member 38, whereby the frame ground is connected.

  The folded ground portion 44b also shields the connector CN2 and its vicinity by covering the upper surface of the connector CN2.

  The folded ground portion 44a has a ground layer GU and a silver paste layer GUA almost on the entire surface. The folded ground portion 44a covers the upper surface of the connector CN1, thereby shielding the connector CN1 and the vicinity thereof.

  The branch ground portion 45 described above is provided at the lower end portion (the side where the connection terminal ST1 is provided) of the folded ground portion 44a. The ground connection portion 45a of the branch ground portion 45 is soldered HD to a ground terminal 25a on the printed circuit board 25 provided in the vicinity of the connector CN1 (see FIGS. 9 and 12), thereby connecting the frame ground. .

  In FIG. 14, a shield ground portion 44c is formed on the left extension of the cable body 42b on the connection terminal ST2 side. On one surface of the shield ground portion 44c, the ground layer GU is exposed on the surface and can be connected as a frame ground.

  That is, as shown in FIG. 14, in the rectangular portion BR2 on the front end side in the shield ground portion 44c, the insulator ZT located on the front side of the paper surface of the ground layer GU, that is, the first insulator layer shown in FIG. ZTa is deleted, and the ground layer GU is exposed to form an exposed ground layer GUR. When the shield ground portion 44c is mounted on the mobile phone 1, the shield ground portion 44c covers the upper surface of the connector CN1 to shield the vicinity thereof, and when the folded ground portion 44b is not provided or not used, the exposed ground layer The GUR is exposed on the surface of the uppermost layer and is connected to the metal plate 37 via the contact member 38 to connect the frame ground.

  As shown in FIG. 15, the silver paste layer GUA is not provided in the portion of the shield ground portion 44c where the exposed ground layer GUR is provided.

  Further, in FIG. 14, square frame lines are shown in the ground connection portions 45a and 46a. This indicates a position where the insulator ZT is cut when the ground connection portions 45a and 46a are exposed. It is. In FIG. 15, a line along the outer side of the outline of the cable main bodies 42 a and 42 b is shown, and this indicates the range of the overcoat. Therefore, the outer shape of the manufactured flexible cable 41 is as shown in FIG.

  The flexible cable 41 described above can be folded back into three at the folding points PK1 to PK4 shown in FIG. That is, the flexible cable 41 is composed of three parts: a lower part 41a, a middle part 41b, and an upper part 41c with the turning points PK1 to PK4 as boundaries.

  Next, a method for mounting the flexible cable 41 will be described.

  FIG. 17A shows a bottom view of the flexible cable 41 in a developed state. That is, FIG. 17A shows a state where the flexible cable 41 shown in FIG. 13 is turned over.

  In FIG. 17A, adhesive tape (double-sided tape) 47a to 47d is attached to the flexible cable 41 on the back surface of the folded ground portions 44a and 44b, the back surface of the shield ground portion 44c, and a part of the cable body 42b. It is attached.

  First, valley folding is performed at the turn-back points PK1 and PK2, and the shield ground portion 44c and the cable main body 42b of the middle portion 41b (see FIG. 13) are overlapped on the cable main body 42a of the lower portion 41a and are adhered by adhesive tapes 47c and 47d. As a result, the state shown in FIG. In this state, the exposed ground layer GUR provided on the shield ground portion 44c is exposed on the upper surface, so that the exposed ground layer GUR can be used for frame ground connection when used in this state.

  Next, valley folding is performed at the folding points PK3 and P4, and the folded ground portions 44a and 44b of the upper portion 41c are overlaid on the shield ground portion 44c and the cable main body 42b of the middle portion 41b, and are adhered with adhesive tapes 47a and 47b. Further, the branch ground portion 46 is folded back to the back side at the folding point PK5. As a result, the state shown in FIG.

  Part of the adhesive tapes 47a and 47b is actually attached to the upper surfaces of the connectors CN1 and CN2. Therefore, the connection terminals ST1 and ST2 may be inserted into the connectors CN1 and CN2 before the folded ground portions 44a and 44b are folded.

  In the state shown in FIG. 17C, the exposed ground layer GUR provided on the folded ground portion 44b is exposed on the upper surface, and this exposed ground layer GUR is used for connection to the frame ground. In addition, since the ground connection portions 45a and 46a of the branch ground portions 45 and 46 are in a state where the exposed portions of the respective ground layers GU face upward, the ground connection portions 45a and 46a are connected to the ground on the printed circuit boards 25 and 36. Solder to the terminals 25a and 36a. Soldering can be automatically performed by free flow or the like, in addition to manual operation using a soldering iron. When soldering by free flow, it is convenient if the ground connection portions 45a and 46a are exposed on the lower surface side.

  Thus, the exposed ground layer GUR of the folded ground portion 44b and the shield ground portion 44c exposes the surface opposite to the surface facing the connector CN2 when folded. Therefore, the frame ground connection with the rear case 32 or the reinforcing metal plate 37 placed over the printed circuit board 36 is easy.

  Since the flexible cable 41 of the present embodiment includes both connection terminals ST1 and ST2 for connector connection for signal lines and ground connection portions 45a and 46a for soldering for frame ground, the signal line Of course, the frame ground between the two printed circuit boards 25 and 36 can be connected by soldering. Further, the frame ground can be connected between the reinforcing metal plate and the shield plate of the housing KT using the exposed ground layer GUR of the folded ground portion 44b or the shield ground portion 44c. Accordingly, a stable frame ground can be obtained or a stable frame ground connection can be obtained in the mobile phone 1, and noise reduction, static electricity removal, and reduction of unnecessary radio wave radiation can be effectively achieved. Can do.

  In addition, since it is not necessary to use a dedicated flexible cable for connecting the frame ground as in the prior art, the number of parts and the number of work steps for mounting can be reduced.

  An antenna 29 for a wireless communication function is provided along the upper side of the inner side surface of the rear case 12, which is the casing KTS of the transmitter side SG, that is, in the vicinity of the connector CN1 to which the flexible cable 41 is connected. Although provided (see FIG. 10), since the flexible cable 41 has a shielding function, the conductor DU and the connectors CN1 and CN2 are shielded from radio waves radiated from the antenna 29, thereby suppressing the generation of noise. Yes.

  In the embodiment described above, the ground connection portion 46a is folded and connected. However, the ground connection portion 46a may be connected without being folded. Although the exposed ground layer GUR is provided in the shield ground portion 44c, the exposed ground layer GUR may not be provided in the folded ground portion 44b. The adhesive tapes 47a to 47d may be omitted when the folded ground portions 44a and 44b can be pressed by the housing KT after the flexible cable 41 is mounted. Although the two-folded flexible cable 41 has been described, it may be implemented as a flexible cable that does not fold over. Although two connection terminals ST1 and ST2 are provided, one or three or more connection terminals (connector connection portions) may be provided.

  In the above-described embodiment, an example in which one flexible cable 41 is used for connection between the printed boards 25 and 36 has been described. However, two or more depending on the number of connection terminals ST1 and ST2 and the like. The flexible cable 41 may be used, or may be used in combination with a flexible cable having another configuration.

  In the embodiment described above, the foldable mobile phone 1 has been described as an example, but a slide-type or other type of mobile phone may be used.

  In the embodiment described above, the configuration, shape, layer structure, pattern of conductor DU and ground layer GU, pattern of silver paste layer GUA, number of conductors DU, folded ground portions 44a, 44b and branch ground portions in flexible cable 41 The shapes, dimensions, positions, etc. of 45 and 46 can be variously changed in addition to those described above.

  In addition, the structure, configuration, shape, dimensions, material, forming method, manufacturing method, arrangement, number, etc. of the whole or each part of the printed circuit board 25, 36, the connectors CN1, 2, the housing KT, or the cellular phone 1 are described in the present invention. It can be appropriately changed in accordance with the purpose.

  In the example described above, the foldable mobile phone 1 has been described, but the present invention can also be applied to a foldable or non-foldable mobile terminal device and various other electronic devices.

The embodiment described below is also included in this embodiment.
(Appendix 1)
A flexible cable configured such that a plurality of conductors are disposed in an insulator and both ends of the conductors are connected to a connector,
A ground layer is provided in the insulator;
The ground layer has a folded ground portion that can be folded so as to shield the connector in a state where the end of the conductor is connected to the connector,
The ground layer is exposed on at least one surface of the folded ground portion and can be connected as a frame ground.
Flexible cable characterized by that.
(Appendix 2)
The ground layer is exposed on the surface opposite to the surface facing the connector when the folded ground portion is folded.
The flexible cable according to Appendix 1.
(Appendix 3)
The insulator includes a first insulator layer covering a surface on one side of the conductor and the ground layer and a second insulator layer covering a surface on the other side,
A silver paste is applied on the second insulator layer, and the silver paste is electrically connected to the ground layer through a hole provided in the second insulator layer.
The flexible cable according to Appendix 2.
(Appendix 4)
The ground layer is branched from an insulator that insulates the conductor, thereby forming a branch ground portion in at least one place;
At the end of the branch ground part, the ground layer is exposed and a ground connection part is provided,
The flexible cable according to appendix 2 or 3.
(Appendix 5)
At least one of the branch ground portions is provided in the folded ground portion.
The flexible cable according to appendix 4.
(Appendix 6)
The branch ground part has an arm part with a predetermined width, and the ground connection part is provided at the tip of the arm part,
At least one of the branch ground portions is formed so as to be able to be folded so that the arm portion intersects with the conductor in a separated state.
The flexible cable according to appendix 4 or 5.
(Appendix 7)
The ground layer is electrically connected to at least one conductor serving as a ground line of the conductors.
The flexible cable according to any one of appendices 2 to 6.
(Appendix 8)
The conductor is divided into a plurality of conductor groups, and each conductor group and an insulator that insulates the conductor group are folded back so as to overlap each other.
The flexible cable according to any one of appendices 2 to 7.
(Appendix 9)
A flexible cable configured such that a plurality of conductors are disposed in an insulator and both ends of the conductors are connected to a connector,
The conductor is divided into two connector groups formed to connect to the connector at both ends thereof, and two conductor groups from the two connector connections, and the two conductor groups are folded back. A cable body formed in a line symmetrical shape in plan view so as to overlap each other,
The insulator is formed in a line-symmetric shape in plan view so that portions that insulate the cable body overlap each other when the cable body is folded back,
A ground layer is provided in the insulator;
The ground layer is
A folded ground portion that can be folded to shield the connector when the end of the conductor is connected to the connector;
The ground layer is exposed on at least one surface of the folded ground portion and can be connected as a frame ground.
Flexible cable characterized by that.
(Appendix 10)
The flexible cable according to any one of appendices 1 to 9 connects between a printed board provided in one casing of an electronic device having a movable part and a printed board provided in the other casing. Arranged,
One of the ground connection portions is soldered to the ground terminal of the printed circuit board of one housing, and the other is soldered to the ground terminal of the printed circuit board of the other housing.
An electronic device characterized by that.
(Appendix 11)
The electronic device is a mobile phone;
The one casing is a casing on the transmitter side, and the other casing is a casing on the receiver side.
The electronic device according to appendix 10.
(Appendix 12)
The electronic device according to appendix 10 is a mobile terminal device having a wireless communication function,
An antenna for the wireless communication function is provided along a side portion of the inner surface of the housing and in the vicinity of a connector to which the flexible cable is connected.
The portable terminal device characterized by the above-mentioned.

It is a front view which shows the external appearance of the mobile telephone which concerns on one Embodiment of this invention. It is a left view of the mobile phone of FIG. It is a front view of the state which folded the mobile phone. It is a left view of the state which folded the mobile telephone. It is a top view of the state which folded the mobile phone. It is a rear view of the state which folded the mobile telephone. It is a perspective view which decomposes | disassembles and shows the housing | casing by the side of the transmitter of a mobile telephone. It is a perspective view which decomposes | disassembles and shows the housing | casing by the side of the receiver of a mobile telephone. It is a perspective view which expands and shows the vicinity of a flexible cable. It is a cross-sectional side view which shows the arrangement | positioning state of a flexible cable. It is a figure which expands and shows the part by the side of the receiver in FIG. It is a figure which expands and shows the part by the side of the transmitter in FIG. It is a front view in the deployment state of a flexible cable. It is a front view which shows patterns, such as a conductor of a flexible cable. It is a front view which shows the pattern of the silver paste layer of a flexible cable. It is sectional drawing which shows the layer structure of a flexible cable. It is a figure explaining the folding method of a flexible cable. It is a top view of the conventional flexible cable. It is a perspective view which shows some internal structures of the conventional mobile telephone. It is a side view which shows the lamination | stacking state of the flexible cable in FIG.

Explanation of symbols

1 Mobile phone (mobile terminal device, electronic equipment)
25, 36 Printed circuit boards 25a, 36a Ground terminal 29 Antenna 31 Front case (housing)
32 Rear case
41 Flexible cable 42 Cable body 44a, b Folding ground part 44c Shield ground part 45, 46 Branch ground part 45a, 46a Ground connection part 45b, 46b Arm part ST1, 2 Connection terminal (connector connection part)
DU conductor GU ground layer GUR exposed ground layer ZT insulator ZTa first insulator layer (insulator)
ZTb Second insulator layer (insulator)
ZTc Third insulator layer (insulator)
CN1, 2 Connector AM Hole KTS, KTG Housing

Claims (8)

A flexible cable configured such that a plurality of conductors are disposed in an insulator and both ends of the conductors are connected to a connector,
A ground layer is provided in the insulator;
The ground layer has a folded ground portion that can be folded so as to shield the connector in a state where the end of the conductor is connected to the connector,
The ground layer is exposed on at least one surface of the folded ground portion and can be connected as a frame ground.
Flexible cable characterized by that. The ground layer is exposed on the surface opposite to the surface facing the connector when the folded ground portion is folded.
The flexible cable according to claim 1. The insulator includes a first insulator layer covering a surface on one side of the conductor and the ground layer and a second insulator layer covering a surface on the other side,
A silver paste is applied on the second insulator layer, and the silver paste is electrically connected to the ground layer through a hole provided in the second insulator layer.
The flexible cable according to claim 2. The ground layer is branched from an insulator that insulates the conductor, thereby forming a branch ground portion in at least one place;
At the end of the branch ground part, the ground layer is exposed and a ground connection part is provided,
The flexible cable according to claim 2 or 3. At least one of the branch ground portions is provided in the folded ground portion.
The flexible cable according to claim 4. A flexible cable configured such that a plurality of conductors are disposed in an insulator and both ends of the conductors are connected to a connector,
The conductor is divided into two connector groups formed to connect to the connector at both ends thereof, and two conductor groups from the two connector connections, and the two conductor groups are folded back. A cable body formed in a line symmetrical shape in plan view so as to overlap each other,
The insulator is formed in a line-symmetric shape in plan view so that portions that insulate the cable body overlap each other when the cable body is folded back,
A ground layer is provided in the insulator;
The ground layer is
A folded ground portion that can be folded to shield the connector when the end of the conductor is connected to the connector;
The ground layer is exposed on at least one surface of the folded ground portion and can be connected as a frame ground.
Flexible cable characterized by that. A flexible cable according to any one of claims 1 , 2, 3, or 6 is provided between a printed circuit board provided in one housing of an electronic device having a movable part and a printed circuit board provided in the other housing. It is arranged to connect between,
One of the ground connection portions where the ground layer is exposed is soldered to the ground terminal of the printed circuit board of one housing, and the other is soldered to the ground terminal of the printed circuit board of the other housing.
An electronic device characterized by that. The electronic device according to claim 7 is a portable terminal device having a wireless communication function,
An antenna for the wireless communication function is provided along a side portion of the inner surface of the one casing and in the vicinity of a connector to which the flexible cable is connected.
The portable terminal device characterized by the above-mentioned.

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