JP4845596B2 - Flexible board connector - Google Patents

Description

  The present invention relates to a connector for a flexible substrate used for electrically connecting a flexible substrate and another printed circuit board.

FIG. 1A is a cross-sectional view of a conventional flexible board connector.
FIG. 1B is a diagram of a conventional connector for a flexible substrate, which is a cross-sectional view of FIG.
The conventional connector 69 includes a housing 65, a positioning portion 61, a terminal 60, a pressing member 64, and a contact 66, and is fixed and placed on the printed board 90 with an adhesive or solder.

  The housing 65 has a flat surface on which the flexible substrate 70 can be placed, and positioning portions 61 projecting upward are placed on both side ends of the placement plane. The housing 65 accommodates and holds the base portion of the terminal 60 and the integrally formed contact 66.

  The positioning portion 61 is engaged with the hook portion 75 of the inserted flexible board 70 and is fixed to the connector 69 by restricting the flexible board 70 in the width direction.

  The terminal 60 includes a base portion, a contact 66 formed integrally with the base portion, and a rotation support portion 62 that engages and supports the pressing member 64. The terminal 60 is connected to a pattern formed on the printed circuit board 90 by solder or the like.

  The contact 66 has a protruding contact portion 67 that contacts the flexible substrate 70 at the tip. A plurality of contacts are formed at a narrow pitch in the width direction and have elasticity.

  The pressing member 64 is configured to be rotatable with respect to the terminal 60 by the rotation support portion 62. In other words, the pressing member 64 rotates around the pin 63 in the arrow direction. A pressing portion 64A that presses the flexible substrate 70 when the pressing member 64 is rotated downward is formed below the pressing member 64.

  The flexible substrate 70 is coated with an adhesive on one surface of the base film, and is provided with a terminal connected to the contact 66. In addition, the flexible substrate 70 is formed with a hook portion 75 that is hooked on the positioning portion 61 of the connector 69, in other words, positioned.

A method for connecting the flexible substrate 70 and the connector 69 will be described.
When the flexible substrate 70 is inserted into the connector 69, the hook portion 75 is hooked on the positioning portion 61, and the flexible substrate 70 is positioned with respect to the connector 69 in the width direction of the flexible substrate 70 and the insertion / extraction direction with respect to the connector 69. Further, when the pressing member 64 is rotated downward, the pressing portion 64A comes into contact with the flexible substrate 70, the pressing member 64 is pushed upward, and the base of the terminal 60 is also moved upward by the pushed pressing member 64. Lifted. As a result, the contact 66 formed integrally with the base portion of the terminal 60 is also pushed up and brought into contact with the flexible substrate 70. Further, by rotating the pressing member 64 further downward, the flexible board 70 is held between the pressing member 64 and the contact 66, and the flexible board 70 and the board to which the connector 69 is attached are electrically connected. be able to.

As a connector for electrically connecting a flexible substrate and another printed circuit board, there is Patent Document 1 below.
JP 2006-32216 A

  In the conventional connector 69, the hook portion 75 of the flexible substrate 70 comes into contact with the positioning portion 61 when trying to insert the connector horizontally, so that it is difficult to insert the flexible substrate 70. Therefore, the flexible substrate 70 is inserted into the connector 69 from the obliquely upper side of the positioning portion 61 while avoiding the positioning portion 61. However, if the flexible substrate 70 is inserted from obliquely above the positioning portion 61, the flexible substrate 70 and the contact 66 are rubbed together, and the terminal of the flexible substrate 70 may be peeled off or the contact 66 may be damaged, resulting in poor conduction. is there. Further, as shown in FIG. 2, the flexible substrate 70 and the contact 66 come into contact with each other, and the adhesive of the flexible substrate 70 adheres to the contact 66, and foreign matter is likely to adhere to the contact 66, which may cause conduction failure.

  Further, in the case of the electronic device 80 as shown in FIG. 3, the boards having the connectors 69 for connecting to the boards having the flexible boards 70 are connected in a state where the boards and the mounting units are assembled.

If the flexible substrate 70 is too long, the flexible substrate 70 may be pulled out of the connector 69 due to its own weight, routing, or the like.
When connecting a flexible board in such an electronic device, since the flexible board 70 is short, it is more difficult to insert the flexible board 70 into the connector 69, and the flexible board 70 and the contact 66 of the connector 69 may be rubbed together. Extremely high.

  It is an object of the present invention to prevent poor conduction due to adhesion of foreign matter to terminals and contacts of a flexible substrate, peeling of terminals of the flexible substrate, or damage to contacts.

In order to achieve the above object, the present invention provides a connector for connecting a flexible board to another printed circuit board, comprising a conductive contact in contact with the flexible board, and closer to the flexible board insertion side than the contact. A positioning part for positioning the flexible board with respect to the connector; and a cover part for pressing the flexible board against the contact; the positioning part toward a depth direction into which the flexible board is inserted. A taper surface with an increased inclination is formed , and the distance between the apex of the taper surface and the cover portion in the thickness direction when the flexible substrate is inserted is equal to or greater than the thickness of the flexible substrate. Is.

  The apex of the positioning portion may be higher than the thickness of the flexible substrate.

  According to the present invention, since the positioning portion provided in the housing is formed with the tapered surface, the flexible substrate is inserted into the connector along the tapered surface. It is possible to prevent unnecessary contact with the contact. Further, since the flexible substrate can be inserted horizontally, the stress can escape in the horizontal direction even if the flexible substrate and the contact come into contact with each other. Thereby, it can prevent that the terminal of a flexible substrate peels by contact of a flexible substrate and a contact, and can prevent that a contact is pressed and scraped off.

  In addition, when the apex of the positioning portion is higher than the thickness of the flexible substrate, the flexible substrate can be hardly detached from the positioning portion, and positioning can be performed reliably.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 4A is a cross-sectional view of the flexible board connector according to Embodiment 1 of the present invention.
FIG. 4B is a view of the cross-sectional view of FIG.
The connector 19 includes a housing 15, a terminal 10, a cover part 14, and a positioning part 11.

The housing 15 has a plane on which the flexible substrate 70 can be placed, and the positioning portions 11 that protrude upward are placed on both side ends of the placement plane. The housing 15 accommodates and holds the base of the terminal 10 and the integrally formed contact 16.
The terminal 10 is disposed in a housing 15, and a base portion, a contact 16 for electrical connection with a flexible substrate, and a pin 13 that pivotally supports the cover portion 14 are integrally formed. The terminal 10 is connected to a pattern formed on the printed circuit board 90 by solder or the like.
The contacts 16 are for contacting the terminals of the flexible substrate 70 and electrically connecting the substrates, and a plurality of contacts 16 are formed at regular intervals at a narrow pitch in the longitudinal direction of the housing 15 to provide elasticity. Have.
The pin 13 is provided at the base and engages and supports the supported portion 12 of the cover portion 14.

The positioning portion 11 is a protruding piece provided on the housing, and is provided on the front side (insertion direction side) of the flexible substrate 70 with respect to the contact 16 and on both ends in the longitudinal direction of the housing 15.
The positioning portion 11 is formed with a tapered surface 11A whose inclination increases toward the back direction in which the flexible base 70 is inserted. The apex of the taper surface 11A is formed to be equal to or lower than the upper surface of the conventional positioning portion 61.

If the height of the positioning portion 11 is equal to or less than the thickness of the flexible substrate 70, the contact surface with the flexible substrate 70 is reduced, and the positioning portion 11 is not fixed enough to be easily detached. It is formed so as to protrude higher than the thickness and higher than the contact. Further, the distance L between the positioning portion 11 and the pin 13 is at least the thickness of the flexible substrate.
The positioning portions 11 provided at both ends of the housing 16 hook the hook portions 75 of the flexible substrate 70, whereby the position of the flexible substrate 70 can be fixed with respect to the connector 16.

The cover portion 14 is provided above the housing and includes a supported portion 12 that is engaged and supported by a pin 13.
The cover part 14 can be rotated by the supported part 12 being engaged and supported by the pin 13.
When the cover part 14 rotates in the direction of the positioning part 11 (downward), the pressing part 14A of the cover part 14 comes into contact with the flexible substrate, and the cover part 14 is pushed upward. When the pushed-up cover part 14 contacts the terminal 10, the terminal 10 is lifted upward. As a result, the contact 16 formed integrally with the terminal 10 is also pushed up and brought into contact with the flexible substrate 70. Further, by rotating the cover portion 14 further downward, the flexible substrate 70 is held between the cover portion 14 and the contact 16, and the flexible substrate 70 and the substrate to which the connector 19 is attached are electrically connected. be able to.

FIG. 5 is a diagram illustrating a flexible substrate connected to the connector.
The flexible substrate 70 is coated with an adhesive on one surface of the base film, and a terminal connected to the contact 16 of the connector 19 is provided on the adhesive surface. Further, the flexible board 70 is formed with a hook portion 75 that is hooked to the positioning portion 11 of the connector 19, in other words, to be positioned.
Specifically, as shown in FIG. 5B, the flexible substrate 70 is formed by laminating a plurality of films with an adhesive, and a base adhesive is applied to the upper layer so that a pattern serving as a terminal is attached.

  FIG. 6 is a diagram illustrating an insertion state of the flexible board to the flexible board connector according to the first embodiment of the present invention.

First, as shown in FIG. 6A, the flexible substrate 70 is brought into contact with the positioning portion 11 in order to be inserted into the connector 19.

When the flexible board 70 is pushed toward the inside of the connector 19 (in the direction of the contact 16), the flexible board 70 is slid by the tapered surface 11A of the positioning portion 11 and inserted into the inside of the connector 19, as shown in FIG. The upper part of the contact 16 is moved substantially in parallel.
In this way, by forming the tapered surface 11A whose inclination increases toward the depth direction in which the flexible substrate 70 is inserted into the positioning portion 11, the flexible substrate 70 is guided in the insertion direction by the tapered surface 11A. Thereby, the flexible substrate 70 can be smoothly inserted into the connector 19. Further, since the flexible substrate 70 is inserted into the connector 19 with the apex of the tapered surface 11A as a fulcrum, it can be inserted substantially parallel to the contact 16.

  FIG. 6C shows a state in which the flexible board 70 is inserted into the connector and the cover portion 14 is rotated downward. When the cover part 14 is rotated downward with the flexible board 70 inserted into the connector, the pressing part 14A of the cover part 14 comes into contact with the flexible board, and the cover part 14 is pushed upward. When the pushed-up cover part 14 contacts the terminal 10, the terminal 10 is lifted upward. As a result, the contact 16 formed integrally with the terminal 10 is also pushed up and brought into contact with the inserted flexible substrate 70.

Thereafter, the cover portion 14 is further rotated and brought to the closed position shown in FIG. 6D, whereby the flexible substrate is held between the cover portion 14 and the contact 16. When the cover portion 14 is in the closed position, the contact 16 and the terminal of the flexible substrate are in reliable contact, and the flexible substrate 70 and the substrate to which the connector 19 is attached can be electrically connected.

  Thus, according to the present invention, the flexible substrate can be inserted in the horizontal direction with respect to the connector by the tapered surface of the positioning portion 11, so that contact with the contact 16 during insertion can be avoided. Thereby, it is possible to prevent the contact from being scraped off by the stress generated by the contact between the flexible substrate 70 and the contact 16. For example, even if the flexible substrate 70 comes into contact with the contact 16, since the stress is released in the horizontal direction, there is no possibility that the contact 16 is broken.

  Moreover, there is no possibility that the adhesive of the flexible substrate 70 adheres to the contact portion 16 by being inserted in the horizontal direction.

  As a result, it is possible to prevent continuity failure due to adhesion of foreign matter to the terminals and contacts of the flexible substrate, peeling of the terminals of the flexible substrate, or damage to the contacts.

Cross-sectional view of a conventional flexible board connector The figure which shows the flexible substrate insertion state of the connector for conventional flexible substrates The figure which shows the connection of the flexible substrate and connector for flexible substrates in the conventional electronic device Sectional drawing of the connector for flexible substrates which concerns on Example 1 of this invention. Diagram explaining flexible substrate The figure which shows the flexible substrate insertion state of the connector for flexible substrates which concerns on Example 1 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10, 60 Terminal 11, 61 Positioning part 12, 62 Supported part 13, 63 Pin part 14 Cover part 15, 65 Housing 16, 66 Contact 67 Contact part 19, 69 Connector 70 Flexible board 80 Electronic device 90 Printed board

Claims (2)

A connector for connecting a flexible substrate to another printed circuit board,
A conductive contact in contact with the flexible substrate;
A positioning part for positioning the flexible board relative to the connector; provided on the flexible board insertion side of the contact;
A cover portion that presses the flexible substrate against a contact;
The positioning portion is formed with a tapered surface whose inclination increases toward the back direction in which the flexible substrate is inserted, and the distance between the apex of the tapered surface and the cover portion in the thickness direction when the flexible substrate is inserted is A flexible board connector having a thickness equal to or greater than the thickness of the flexible board. The flexible substrate connector according to claim 1, wherein a vertex of the positioning portion is higher than a thickness of the flexible substrate.