JP2008258018A - Connector joining structure for flat cable - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To restrain noise radio waves discharged from a joining section between a flat cable and connector. <P>SOLUTION: The tip of a grounding body 7 of a board 8 is joined with a connector body 1, its rear end is connected with an earth plate 9, and the earth plate 9 is brought into contact with a bottom section 3 of a housing 2 while the earth plate 9 is adjacent to a slit 4 for inserting the cable and is in parallel with the slit 4. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention is a pull-in coaxial flat cable for connecting an outdoor receiving antenna to an indoor television or various communication devices, and the midway is drawn into a room over a gap of a window frame such as a sash. In particular, the present invention relates to a connection structure between the flat cable and the connector.

  As shown in FIG. 7 as an example, a conventional coaxial flat cable has a core wire 15 inserted through the center of a polyethylene coating 25, and the outer periphery of the polyethylene coating 25 is coated with a coated stranded wire 17 made of steel wire or aluminum foil. Configure the cable. The reinforcing wires 16 made of steel wire are in contact with both sides thereof, and a pair of aluminum laminate films 18 are joined to each other around them. Both ends of the flat cable 5 thus formed are connected to the connector.

  As an example of the connector, as shown in FIG. 10, a contact terminal 6 serving as a contact seat is disposed on the axis of the metal connector body 1, and a bottomed housing 2 is connected to the rear end of the metal connector body 1. The outer periphery of the housing 2 is covered with a resin casing 14. A slit 4 is formed at the bottom of the resin casing 14 and the housing 2. The slit 4 is substantially aligned with the outer periphery of the flat cable 5, the flat cable 5 is inserted through the slit 4, and the core wire 15 is connected to the contact terminal 6 through the relay substrate 8 (printed substrate). At the same time, the reinforcing wire 16 is grounded to the connector body 1.

JP 2006-19055 A JP-A-8-203350

The through portion of the flat cable 5 is formed as shown in FIG. 5, and the slit 4 provided in the bottom 3 of the housing 2 is formed as shown in FIG.
However, according to experiments by the present inventors, it has been found that noise radio waves are emitted to the outside from a connector having such a connection structure. It is considered that this is because the slit 4 provided in the housing 2 becomes a slit antenna and is radiated from there. That is, it is considered that a radio wave having a wavelength corresponding to the width of the slit 4 and a radio wave of an integral multiple of the wave are particularly strongly emitted from the outside.

The present inventor measured the radiation state of noise radio waves in the connector connection structure of the conventional flat cable. This was performed by supplying a 120 dBμV radio wave from the signal generator 24 to the flat cable under test using a test apparatus as shown in FIG. Then, a dummy resistor was connected to the connector of the device under test, and it was received by a dipole antenna 20 that was 3 m away from the connector, and was measured by a spectrum analyzer 21. Then, a signal of 43 to 61 dBμV was measured as an unnecessary radiated radio wave at a supply frequency of 500 MHz to 2500 MHz in the signal generator 24. Such a noise signal adversely affects various devices, and it is required to reduce the value as much as possible.
Then, this invention makes it a subject to solve the problem which concerns.

According to the present invention, a metal cylindrical housing (2) is provided at the rear end of the metal connector body (1), and a slit provided at the bottom (3) at the rear end of the housing (2). In the flat cable connector connection structure in which the flat cable (5) passes through (4) and the tip of the flat cable (5) and the contact terminal (6) provided on the connector body (1) are connected.
A substrate (8) having a grounding body (7) is disposed in the housing (2) in the axial direction of the housing (2), and the tip of the grounding body (7) is connected to the main body (1). In addition, the ground plate (9) is connected to the rear end,
The ground plate (9) is a flat cable connector connecting structure characterized in that the ground plate (9) is adjacent to the slit (4) and is in parallel with the slit (4) and in contact with the bottom (3).

The present invention according to claim 2 is the method according to claim 1,
The ground plate (9) is made of a leaf spring, and the width thereof is substantially equal to or longer than the length of the slit (4), the rear end portion is curved in a cross-sectional arc shape, and the rear end portion is the bottom portion. A flat cable connector connection structure characterized in that it is in contact with (3).

The present invention described in claim 3 provides the method according to claim 2,
The ground plate (9) has one or more notches (10) in the middle in the width direction at the rear end thereof, and the ground plate (7) of the ground plate (9) and the substrate (8). Is a flat cable connector connection structure connected by a shaft body (11) penetrating them.

The present invention as set forth in claim 4 is characterized in that, in claim 3,
The shaft body (11) has a flat cable connector connection structure made of eyelets or rivets.

  In the connector connection structure of the present invention, the ground plate 9 is adjacent to the slit 4 and is in contact with the bottom 3 of the housing 2 in parallel with the slit 4. The radio wave leaks from the slit 4 by the ground plate 9. Can be reduced. This is confirmed by an experimental comparison between the presence and absence of the earth plate 9.

  In the above configuration, the ground plate 9 is configured by a leaf spring, the width thereof is substantially equal to or greater than the length of the slit 4, the rear end portion is curved in a cross-section arc shape, and the rear end portion is turned to the bottom portion 3. Can be fixed in contact. In this case, the ground plate 9 and the bottom 3 can be brought into elastic contact with each other, so that the leaked radio wave from the slit 4 can be more reliably suppressed.

In the above configuration, one or more notch portions 10 can be provided at the intermediate portion in the width direction at the rear end portion of the earth plate 9. In this case, the ground plate 9 and the bottom 3 of the housing 2 can be reliably brought into contact with each other by a plurality of claw-shaped members, and leaked radio waves from the slit 4 can be more reliably suppressed.
Further, when the shaft body 11 passes through the grounding body 7 and the ground plate 9 of the substrate 8 so that they are connected to each other, the connection is easy and a connection structure with high mass productivity can be obtained.

  In the above configuration, when the shaft body 11 is formed by eyelets or rivets, a flat cable connection structure that is easier to manufacture and assemble can be provided.

Next, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an axial sectional front view of the connection structure of the present invention, FIG. 2 is a partially broken plan view thereof, and FIG. FIG. 4 is a perspective view of the ground plate 9 used in the present invention. In addition, the same code | symbol is attached | subjected about the component same as a prior art. The description of the structure described in FIG. 10 is omitted as much as possible.

  A feature of the structure of the present invention is the presence of the ground plate 9. The ground plate 9 is made of a conductive leaf spring material such as a brass plate or a copper plate, and is formed by press molding as shown in FIG. In this example, two notch portions 10 are arranged apart from each other in the middle of the rear end portion, and claw-shaped curved portions 9a are formed on both sides of each. A pair of holes 19 are formed on both sides of the tip. Then, holes 19 are formed in both the rear end portion of the substrate 8 and both ends of the front end portion of the flat cable 5 at positions aligned with the holes 19, and they are aligned with each other to form a shaft made of conductive eyelets such as brass. 11 is inserted and caulked so that the earth plate 9, the substrate 8, and the aluminum laminated film 18 of the flat cable 5 are integrally fastened and fixed simultaneously.

  A printed grounding body 7 is disposed on the substrate 8 in advance. That is, a pair of lounges made of printed foil is arranged as a grounding body 7 on both sides of the substrate 8, and the substrate 8 is fastened together with the grounding plate 9 by the shaft body 11. Are connected to the grounding body 7. As shown in FIG. 8, the grounding body 7 of the board 8 is integrally formed with the leg portions 8 a provided at both ends of the board 8, and is fitted into the board slit 28 of the connector body 1. The connector body 1 is electrically connected. Further, it is preferable that the grounding body 7 and the connector main body 1 are fixed by soldering more reliably.

  A core wire round (not shown) is arranged at the center position in the width direction of the substrate 8, and the core wire 15 of the flat cable 5 is connected to the round via a solder connection portion 26, and the round is soldered to the contact terminal 6. It is fixed. The contact terminal 6 forms a seat, and a cylindrical insulator 13 is fitted on the outside thereof. Further, an outer screw portion 12 is provided on the outer periphery of the distal end portion of the connector main body 1, and a screw lid provided on a plug (not shown) fitted to the contact terminal 6 is screwed and fastened to the outer screw portion 12. The reinforcing wire 16 of the flat cable 5 is connected to the grounding body 7 of the substrate 8 at the tip end portion thereof by a solder connecting portion 26 as shown in FIG. In this example, the reinforcing wire 16 is made of a thin steel wire strand. As shown in FIGS. 1 and 2, the curved portion 9 a of the earth plate 9 is brought into elastic contact with the bottom 3 of the housing 2.

(Leaked radio wave comparison experiment)
It was found that the flat cable connector connection structure of the present invention configured as described above attenuates noise radio waves by 20 to 30 dB or more as compared with the conventional one. Table 1 shows the measurement results. As shown in FIGS. 1 and 2, the product of the present invention has a ground plate 9, and the comparative product is a conventional product without the ground plate 9. Except for the ground plate, the rest of the product is completely the same as the product of the present invention. Are the same.

The comparative experiment is performed under the following conditions.
As shown in FIG. 9, the device under test 23 is connected to the signal generator 24. A connector according to the present invention and a conventional connector (FIG. 10) are connected to both ends of the device under test 23. The signal generation frequency by the signal generator 24 is 500 MHz, 1000 MHz, 1500 MHz, 2000 MHz, 2500 MHz, and the signal generator 24 is connected to one connector of the device under test 23 and the dummy resistor 22 is connected to the other. It is. A dipole antenna 20 was placed at a position 3 m away from the product under test 23, and a signal leaking from each product under test 23 was received by the spectrum analyzer 21 via the cable 27. At this time, the signal level by the signal generator 24 was 120 dBμV.

As a result of measuring the product of the present invention and the comparative product, the measured values in Table 1 are obtained. Therefore, compared with the comparative product, the product according to the present invention has a noise reduction of 35 dBμV compared to the conventional product, and the noise reduction effect of 23 dBμV at 1000 MHz, 29 dBμV at 1500 MHz, 29 dBμV at 2000 MHz, and 25 dBμV at 2500 MHz. was there.
This is an effect due to the presence of the ground plate 9 of the present invention, and the reason is considered to be as follows. In this type of mounting structure, leaked radio waves are emitted mainly by the gap between the slits 4 acting as a slit antenna, but the earth plate 9 is connected to the housing 2 and the connector main body 1 adjacent to the slits 4. Therefore, it is considered that it affects the radio wave emission of the slit antenna and attenuates it.

The principal part axial cross section front view of the connector connection structure of the flat cable of this invention. The partially broken top view of the connection structure. The partially broken bottom view of the connection structure. The perspective view of the earth plate 9 used for the connection structure of this invention. The VV arrow directional cross-sectional schematic in FIG.

The left view of the housing 2 of the connection structure. The cross-sectional view of the flat cable 5 used for the connection structure. The front view which shows the connection state of the connector main body 1 used for the connection structure, and the board | substrate 8, and the disassembled perspective view in the cross section. The schematic of the experimental apparatus which confirms the effect of this invention. The axial cross-section front view of the connector connection structure of the conventional flat cable.

Explanation of symbols

1 Connector Body 2 Housing 3 Bottom 4 Slit 5 Flat Cable 6 Contact Terminal 7 Grounding Body 8 Board
8a Leg 9 Ground plate
9a Curved part
10 Notch

11 Shaft
12 External thread
13 Tubular insulator
14 Resin casing
15 core wire
16 Reinforcing wire
17 Coated stranded wire
18 Aluminum laminated film
19 holes
20 Dipole antenna

21 Spectrum analyzer
22 Dummy resistor
23 Product under test
24 signal generator
25 Polyethylene coating
26 Connection
27 Cable
28 PCB slit

Claims (4)

A metal cylindrical housing (2) is provided at the rear end of the metal connector body (1), and the flat cable (5) is connected to the slit (4) provided at the bottom (3) of the rear end of the housing (2). In the flat cable connector connection structure that penetrates and the tip of the flat cable (5) and the contact terminal (6) provided on the connector body (1) are connected,
A substrate (8) having a grounding body (7) is disposed in the housing (2) in the axial direction of the housing (2), and the tip of the grounding body (7) is connected to the main body (1). In addition, the ground plate (9) is connected to the rear end,
The flat plate connector connecting structure, wherein the ground plate (9) is adjacent to the slit (4) and is in parallel with the slit (4) and is in contact with the bottom (3). In claim 1,
The ground plate (9) is made of a leaf spring, and the width thereof is substantially equal to or longer than the length of the slit (4), the rear end portion is curved in a cross-sectional arc shape, and the rear end portion is the bottom portion. (3) A flat cable connector connection structure characterized by contacting. In claim 2,
The ground plate (9) has one or more notches (10) in the middle in the width direction at the rear end thereof, and the ground plate (7) of the ground plate (9) and the substrate (8). And a flat cable connector connection structure connected by a shaft (11) passing through them. In claim 3,
A flat cable connector connection structure in which the shaft (11) is made of eyelets or rivets.

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