KR20100101422A - Shield flat cable - Google Patents

Abstract

PURPOSE: A shield flat cable is provided to reduce the change of characteristic impedance by attaching a grand tape to the lower surface of a reinforcing tape. CONSTITUTION: A plurality of flat conductors(13) are arranged with a predetermined interval. A first and a second insulation resin film cover a plurality of flat conductors. A shield film covers the first and the second insulation resin film. A reinforcing tape(16) is attached to the outer surface of the second insulating film. One end of a first grand tape(15a) is attached to the first insulating film. The other end of a second grand tape(15b) is overlapped with the shield film. A second grand tape is attached to the reinforcing tape. A part of the second grand tape is overlapped with the shield film.

Description

Sealed Flat Cable {SHIELD FLAT CABLE}

The present invention relates to a shield flat cable with an electronic shield function that can be used for Low Voltage Differential Signaling (LVDS).

In recent years, LVDS has been used in wiring to liquid crystal monitors, which reduces the number of wirings and transmits signals at differential small amplitudes. In LVDS, the characteristic impedance is set to about 100Ω.

Japanese Patent Laid-Open No. 2006-32003 discloses a flat cable as wiring in an electronic device applied to LVDS. Japanese Utility Model Registration No. 3096395 discloses providing a common grand portion for a plurality of signal lines in order to make the characteristic impedance constant for each signal line of a flat cable.

Japanese Patent Laid-Open No. 2005-93178 discloses a shielded flat cable. In this shielded flat cable, the plurality of flat conductors are interposed between the upper and lower sides of the insulating layer and covered with a shield coating tape having a metal layer. The metal layer is electrically connected to a flat ground conductor for a predetermined ground through an opening provided in the insulating layer.

FIG. 5A is a perspective view illustrating the terminal portion 2 in the conventional shielded flat cable 1. In the shielded flat cable 1, the plurality of flat conductors 3 are insulated and covered with an insulating resin film 4 (upper film 4a, lower film 4b) from above and below. At the end of the shielded flat cable 1, the upper film 4a is removed, and the part which becomes the terminal of the flat conductor 3 is exposed, and the cable terminal part 2 is formed. In addition, the reinforcing tape 6 can be attached to the lower film 4b which is not removed from the cable terminal part 2, and it is set as the form which can be connected to an electrical connector.

The ground tape 5 for ground connection is attached to the upper film 4a in the position which does not generate | occur | produce the balanced conductor 3 and an electrical short. The grand tape 5 is electrically connected to any of the balanced conductors for grounding by the method disclosed in Japanese Utility Model Registration No. 3096395 or Japanese Patent Laid-Open No. 2005-93178 (not shown). On the outer surface of the shielded flat cable 1, a shield film 7 which is a film made of a three-layered shape of an insulating layer, a metal layer, and a conductive adhesive layer is wound so that a part thereof overlaps, and the balanced conductor 3 is wound from the outside. It is shielded. The shield film 7 is electrically connected to the grand tape 5. The characteristic impedance of the shielded flat cable 1 is set to a predetermined value (for example, about 100?) By changing the relative dielectric constant, thickness, and the like of the insulating resin film 4.

In the terminal portion 2 of the shielded flat cable 1, the balanced conductor 3 is exposed due to the insertion connection to the electrical connector. Therefore, the characteristic impedance of the end from the grand tape 5 changes. FIG. 5B is a conceptual diagram illustrating the characteristic impedance in the terminal unit 2. The impedance decreases at the cable terminal portion 2. If such a change in impedance exists in the signal transmission path, there is a fear that reflection of the transmission signal occurs, resulting in transmission loss.

Japanese Laid-Open Patent Publication No. 2006-32003 describes that the characteristic impedance of a flat cable is 100?, Which is a predetermined value. However, the configuration of the terminal portion is not clear, and explanation to the impedance in the vicinity of the cable terminal portion cannot be made. In addition, although it is disclosed to add an electromagnetic interference (EMI) preventive metal coupling, since there is no shield layer, it is not clear how to prevent the relationship with characteristic impedance and EMI.

An object of the present invention is to provide a shielded flat cable that is shielded over the entire cable length and has a small change in impedance at the cable end portion.

The shielded flat cable of the present invention includes a plurality of flat conductors arranged at predetermined intervals, a first insulating resin film and a second insulating resin film which are insulated and coated with a plurality of flat conductors from above and below the arrangement surface; And a shield film covering the first insulating resin film and the second insulating resin film. In the shielded flat cable, the tip of the first insulating film is removed at at least one end thereof, so that a plurality of balanced conductors are exposed from the side of the first insulating film, and the tip of the second insulating film is formed of a plurality of flat conductors. It is in line with the tip. The shielded flat cable has a reinforcing tape attached to an outer surface of the second insulating film at one end, and a first end on the first insulating film, one end of which is attached a predetermined distance from the end of the first insulating film and the other end of the shield film. And a first grand tape, which is electrically connected to each other, and a second grand tape attached to the reinforcing tape and partially connected to the shield film.

In one aspect of the present invention, the first and second grand tapes are integrally formed, and are folded at the fold and attached to both sides. In another aspect, the shield film is attached to cover both edges of the cable length direction. In still another aspect, a dielectric film having a relative dielectric constant of 2.2 to 3.2 is disposed between the shield film and the insulating resin film, and the impedance is adjusted to a predetermined value.

According to the present invention, it is possible to reduce the change in the characteristic impedance at the terminal portion of the shielded flat cable and to realize good signal transmission.

Embodiments of the present invention are described below with reference to the drawings. The drawings are for illustrative purposes and are not intended to limit the scope of the invention. In the drawings, like reference numerals designate like parts in order to avoid duplication of description. The ratio of dimensions in the drawings is not necessarily accurate.

1: (A) is a perspective view which shows the terminal part in the shielded flat cable 11 which concerns on embodiment of this invention. In the shielded flat cable 11, the plurality of flat conductors 13 are formed from the upper and lower films 14a (the first insulating film) and the lower film 14b (the second insulating film) which are the insulating resin films 14. It is interposed and insulated. And at the at least one edge part, the upper film 14a is removed and the part used as the connection terminal of the balanced conductor 13 is exposed, and the cable terminal part 12 is formed. Moreover, in the cable terminal part 12, the reinforcement tape 16 is affixed to the lower film 14b which was not removed, the strength is reinforced, and it is set as the shape which can be connected to an electrical connector (not shown). The end of the reinforcing tape 16 coincides with the end of the lower insulating film 14b to reinforce the whole end in terms of strength.

A ground tape 15a (first ground tape) for ground connection is attached to the upper film 14a. The grand tape 15a is separated from the balanced conductor 13 exposed near the tip of the upper film 14a to such an extent that no short circuit occurs electrically (for example, 3 mm to 4 mm). In addition, as mentioned later, the ground tape 15a is electrically connected with any of the balanced conductors 13, and is grounded.

The lower surface of the reinforcing tape 16 is also attached with a grand tape 15b (second grand tape) similar to the grand tape 15a. The grand tape 15a and the grand tape 15b face each other via the balanced conductor 13. The grand tape 15b is at the end side as shown by the distance T from the tip of the grand tape 15a, and is connected between the connector contacts when the shielded flat cable 11 is inserted into and connected to the electrical connector. It is attached so as not to be electrically shorted. By providing the grand tape 15b, it is possible to avoid a large change in capacitance between the connector and the grand tape and to suppress a large change in the characteristic impedance.

The seal films 17a and 17b overlap a part of the grand tapes 15a and 15b, are attached to each other through the cable from the top and the bottom over the entire length of the cable, and are bonded to each other by closing the ears 20 of both edges. have. The shield films 17a and 17b are ground-connected via the grand tapes 15a and 15b to give the cable a shield function. In addition, the shield films 17a and 17b form a uniform capacitance (capacitor capacitance) in the cable region except for the vicinity of the terminal, with a plurality of balanced conductors 13 operating as signal lines, and realize a uniform impedance. have.

The characteristic impedance is determined by the capacitor capacitance distributed between the balanced conductor 13 serving as a signal line and the shield films 17a and 17b. This capacitor capacity can be set by changing the dielectric constant and film thickness of the insulated resin film 14. When it is difficult to obtain a predetermined characteristic impedance (for example, 100 Ω for LVDS) using only the insulating resin film 14, a low dielectric film having a low dielectric constant between the insulating resin film 14 and the shield films 17a and 17b. By arranging (18a, 18b), a predetermined characteristic impedance is obtained.

1B is a cross-sectional view of the shielded flat cable 11. The balanced conductor 13 consists of electroconductive metal foil, such as copper foil and tin plating interlocking foil. The size and arrangement of the balanced conductor 13 are 12 µm to 50 µm in thickness, 0.2 mm to 0.3 mm in width, and 0.3 mm to 0.5 mm intervals, considering the current value of signal transmission and the slidability of the cable.

Each of the upper film 14a and the lower film 14b consists of two layers, an insulating layer 28 and an adhesive layer 22. As the insulating layer 28, a resin material excellent in flexibility is used, for example, a resin film having general versatility such as a polyester resin, a polyphenylene sulfide resin, a polyimide resin, and the thickness thereof is 9 µm to 50 µm. As polyester resin, resin materials, such as polyethylene terephthalate resin, polyethylene naphthalate resin, and polybutylene naphthalate resin, are mentioned. Among these resin films, the use of polyethylene terephthalate resin is preferred from the viewpoint of electrical characteristics, mechanical characteristics, cost, and the like. Moreover, by using the resin film which consists of polyimide and polyphenylene sulfide, it becomes possible to have heat resistance which satisfies the safety certification (UL standard) issued by Underwriters Laboratories Inc ..

The adhesive layer 22 is made of a resin material, and examples thereof include an adhesive in which a flame retardant is added to a polyester resin or a polyolefin resin. This adhesive bond layer is formed in thickness of 20 micrometers-50 micrometers. The upper film 14a and the lower film 14b are adhered together, integrated, and bonded together by applying heat with a heating roller while facing the adhesive layer 22 via the equilibrium conductor 13.

The first and second grand tapes 15a and 15b consist of the conductive layer 23 and the adhesive layer 24. For example, tin-plated copper foil having a thickness of about 18 μm to 35 μm is used for the conductive layer 23, and in consideration of bending resistance, it is preferable to use a rolled copper foil. The adhesive layer 24 is laminated in the order of an acrylic adhesive layer, a resin substrate, and an adhesive layer, for example, and the thickness of the whole combined with the conductive layer 23 becomes about 85 micrometers-125 micrometers according to the dimension of a connector. Gland tapes 15a and 15b are cut into tape-shaped ones to a predetermined length and attached to the upper film and the lower film.

As for the shield films 17a and 17b, the thing of the three-layered structure of the resin layer 25, the shield layer 26, and the electrically conductive adhesive layer 27 is used, for example. The resin layer 25 is a film base material, it prevents peeling and corrosion of the shield layer 26, and aims at maintaining the reliability of a cable. A resin film having a thickness of about 9 μm of polyethylene terephthalate is used for the resin layer 25. The shield layer 26 is formed by depositing a conductive metal such as silver on the back surface of the resin film of the resin layer 25, for example.

In addition to adhesion to the insulating resin film 14, the conductive adhesive layer 27 obtains electrical conduction with the grand tapes 15a and 15b to generate a shield function. For example, the silver paste on the silver vapor deposition surface of the shield layer 26 is used. It is formed by applying (paste). The seal films 17a and 17b are attached to the outer periphery of the insulated resin film 14 directly or via the low dielectric films 18a and 18b in the thickness of the whole, about 30 micrometers.

A part of the conductive layers 23 of the grand tapes 15a and 15b is in electrical contact with the conductive adhesive layer 27 of the shield film 17. In addition, any of the balanced conductors 13 among the insulating films 14a and 14b becomes a gland line, but at least a portion of the upper portion or the lower portion is removed in the longitudinal direction so that the conductive adhesive layer 27 of the gland line and the sealing film 17 is formed. It is in electrical contact. When the low dielectric films 18a and 18b are present, part of the low dielectric films 18a and 18b is also removed so that the gland wires and the conductive adhesive layer 27 are in electrical contact with each other. In this way, the grand tapes 15a and 15b, the seal film 17 and the grand line are electrically conductive. By grounding the gland wires, the gland tape and the seal film are also grounded.

The low dielectric films 18a and 18b are used when a predetermined characteristic impedance cannot be obtained only by the insulating resin film 14. As the low dielectric films 18a and 18b, those having a low dielectric property and having a resin material excellent in flexibility and workability as main components can be used. For example, low dielectric properties and flexibility include polyolefin resins, such as polypropylene (PP), polyethylene resin (PE), acid-modified polyethylene resin, ethylene vinyl acetate copolymer (EVA), ethylene ethyl acrylate, and the like. Can be mentioned. Moreover, low density polyethylene resin (LDPE) and linear low density polyethylene resin (LLDPE) are mentioned as excellent in low dielectric constant and workability.

The low dielectric films 18a and 18b are used by overlapping the insulating resin film 14 with, for example, a dielectric constant of 2.2 to 3.2 and a thickness of about 100 to 350 m. As a result, the characteristic impedance of the shielded flat cable can be set to any value within the range of 50?

2: (A) is a perspective view which shows the terminal part in the shielded flat cable 21 which concerns on other embodiment of this invention. As for the shield flat cable 21, the 1st grand tape 15a and the 2nd grand tape 15b in the shield flat cable 11 are carried out by one grand tape 15 (FIG. 2 (B)). To form. The grand tape 15 is formed by integrally forming the first grand tape portion 15d and the second grand tape portion 15e via the folded portion 15c. Moreover, in the grand tape 15, the 2nd grand tape part 15e side has made the width | variety larger than the distance T of FIG. 1 from the 1st grand tape part 15d.

The grand tape 15 is attached to the upper film 14a on the exposed side of the balanced conductor 13 with the first grand tape portion 15d, and then folded at the folded portion 15c, so that the second grand tape portion ( 15e) is attached to the outer surface of the lower reinforcing tape 16. In the grand tape 15, the first grand tape portion 15d and the second grand tape portion 15e do not need to be conducted with a balanced conductor individually set for ground connection. In addition, since the 1st grand tape part 15d and the 2nd grand tape part 15e can be managed as one grand tape 15, there are few parts and it becomes easy to manage.

3: (A) is a perspective view which shows the terminal part in the shielded flat cable 31 which concerns on other embodiment of this invention. The shielded flat cable 31 is an example in which the upper shield film 17a and the lower shield film 17b of the shielded flat cable 11 are integrally formed of one shielded film 17. (FIG. 3B). The shield film 17 has a shield film 17e attached to the lower side (reinforcement tape side) at the center portion, and has a shield film 17d attached to the upper side via the folded portion 17c at both sides thereof. .

The shield film 17e is attached to the low dielectric film so as to partially overlap the second shield tape 15b attached to the reinforcing tape side. Portions of the shield film 17d on both sides are bent to surround the cable-side edge at the folded portion 17c and are attached to the low dielectric film. The shield films 17d on both sides are attached to each other so as to have an overlap in the middle portion of the upper surface of the cable along the longitudinal direction and are closed.

As for the sealed film 17, the ear | edge part 20 which generate | occur | produces when employ | adopting two upper and lower shield films 17a and 17b does not generate | occur | produce. As a result, in the conductor of the shield layer exposed to the ear portion 20, the problem of causing an electrical short in the wiring device can be avoided. In addition to processing the tip 17f of the shielded film 17 according to the shape of the grand tape, the shielded film 17 can be used as it is without any special processing on the tape-like film. This reduces the number of parts, making it easier to manage.

4: (A) and (B) are perspective views which show the terminal part in the shielded flat cable 41A, 41B which concerns on other embodiment of this invention. The cable 41A is an example in which the low dielectric film is provided to the edge of the cable terminal portion in the shielded flat cable 11, and the cable 41B is the low dielectric film in the shielded flat cable 31 to the edge of the cable terminal portion. This is an example. In the sealed flat cable 41A, the upper grand tape 15a is attached to the upper surface of the low dielectric film 18a. On the lower side, the reinforcing tape 16 functions as an insulator. For this reason, the low dielectric film 18b may not be laminated on the outer surface of the reinforcing tape 16. Also in the shielded flat cable 41B, the shape of the shield film 17 is the same as that of the cable 41A.

In either case, the low dielectric films 18a and 18b laminated with the insulating resin film 14 are formed between the capacitor conductors formed between the balanced conductor 13 of the signal line and the shielded films 17a and 17b which are grounded. By changing the capacitance), a predetermined characteristic impedance is realized. The low dielectric films 18a and 18b can increase the characteristic impedance by increasing the characteristic impedance by decreasing the dielectric constant and increasing the thickness thereof. Therefore, in order to reduce the change of the characteristic impedance in the cable terminal part 12 with a shielded flat cable, it is preferable that a uniform insulator (dielectric material) exists as long as possible to the edge of a cable terminal part.

As described above, by providing the low dielectric films 18a and 18b to the edge of the cable terminal portion 12 in a range without any problems, the capacitor capacity can be uniformly distributed over the entire cable length. And as mentioned above, by providing the ground tape in a cable terminal part also in a reinforcement tape side, it can be set as the shielded flat cable which has a stable predetermined characteristic impedance.

1: (A) is a perspective view which shows the terminal part in the shielded flat cable which concerns on embodiment of this invention, FIG. 1 (B) is a figure which shows the aa cross section in FIG. ,

FIG. 2A is a perspective view showing a terminal portion in a shielded flat cable according to another embodiment of the present invention, and FIG. 2B is a perspective view showing a grand tape in this embodiment;

3: (A) is a perspective view which shows the terminal part in the shielded flat cable which concerns on another embodiment of this invention, and FIG. 3 (B) is a perspective view which shows the shield film in this embodiment. ,

4 (A) and (B) are perspective views showing a terminal portion in a shielded flat cable according to still another embodiment of the present invention;

Fig. 5A is a perspective view showing a terminal portion in a conventional shielded flat cable, and Fig. 5B is a conceptual diagram illustrating characteristic impedance in the terminal portion.

Explanation of symbols for the main parts of the drawings

11, 21, 31, 41A, 41B: Sealed Flat Cable

12 cable terminal 13 balanced conductor

14: insulating resin film 14a: first insulating film

14b: 2nd insulating film 15a: 1st grand tape

15b: second grand tape 15c: folded portion

16: Reinforcement tape 17a, 17b: Seal film

18a, 18b: low dielectric film 20: ear

23: conductive layer 24: adhesive layer

25: resin layer 26: shield layer

27: conductive adhesive layer

Claims (4)

A plurality of flat conductors arranged at predetermined intervals, a first insulating resin film and a second insulating resin film which are insulated and coated with the plurality of flat conductors from above and below the arrangement surface, the first insulating resin film, and In a shield flat cable comprising a shield film covering a second insulating resin film, At at least one end portion, the distal end of the first insulating film is removed so that the plurality of balanced conductors are exposed from the side of the first insulating film, and the distal end of the second insulating film is formed from the distal ends of the plurality of balanced conductors. Matches, The shielded flat cable is at the end, Reinforcing tape attached to the outer surface of the second insulating film, A first grand tape having one end attached to the first insulating film at a predetermined distance from an end of the first insulating film, and the other end overlapping the shield film and electrically connected thereto; A second grand tape attached to the reinforcing tape, a portion of which is electrically connected to the shield film in an overlapping manner; Sealed flat cable. The method of claim 1, The first grand tape and the second grand tape are integrally formed, and are folded at the fold and attached to both sides. Sealed flat cable. The method according to claim 1 or 2, The shield film is attached to surround both sides of the cable longitudinal direction, characterized in that attached Sealed flat cable. 4. The method according to any one of claims 1 to 3, A dielectric film having a relative dielectric constant of 2.2 to 3.2 is disposed between the shielded film and the insulating resin film, and the impedance is adjusted to a predetermined value. Sealed flat cable.

Images