JP4967619B2 - Stacking connector connection mounting structure and electronic device having the structure - Google Patents

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stacking connector connection mounting structure and an electronic apparatus having the structure. For example, a circuit board stored in a thin casing used in a mobile phone, an FPC (Flexible Printed Circuit), and a TCP (Tape The present invention relates to a connection mounting structure of a stacking connector for connection to and removal from a flexible printed circuit such as Carrier Package) and an electronic apparatus including the structure.

  2. Description of the Related Art Conventionally, in a mobile phone as a small electronic device, for example, a stacking connector that can be easily assembled and an electrical connection between substrates can be easily routed in the device, and the connection is easy. A flexible printed wiring board (FPC) having flexibility is often used. In particular, the adoption of thin stacking connectors has been remarkably increased due to the recent demand for thinner devices.

  For example, a circuit board such as a printed wiring board on which a SIM (Subscriber Identity Module) card connector is mounted and a main circuit board are electrically connected via a flexible printed wiring board having flexibility. A female connector mounted on the main circuit board and a male connector attached to one end of the flexible printed wiring board are connected by fitting (for example, see Patent Document 1).

For example, as shown in FIGS. 7 and 8, a mobile phone employing such a stacking connector includes a front case 101 and a rear case 102 in which various components are housed or attached. In the state, the housing 103 is assembled by fitting. 7 and 8 show a part of the cellular phone as viewed from the back side.
The rear case 102 is formed with an opening 107 for inserting the header 106 of the male connector 105 when the male connector 105 is connected to the female connector 104.

The female connector 104 is mounted so as to be disposed immediately below the opening 107 of the main circuit board 108 disposed on the inner surface of the front case 101, and a frame in which the fitting convex portion 109 of the male connector 105 is fitted. A fitting recess 110 is formed.
The female connector 104 is connected to the main circuit board 108 by soldering via connection terminals 111, 111,... Corresponding to the board side contacts.

The male connector 105 is a plurality of female FPCs that are fitted to the fitting recess 110 in a flat header portion 106 attached to one end of the flexible printed wiring board 112 and connected to the board-side contact corresponding to the inside. A fitting convex portion 109 in which side contacts are arranged in two rows is attached.
The fitting convex portion 109 is connected to the header portion 106 by soldering via connection terminals 113, 113,... Corresponding to the respective FPC side contacts.

When the male connector 105 attached to the flexible printed wiring board 112 is connected to the female connector 104, first, the header portion 106 is disposed immediately above the opening 107 of the front case 101 and then lowered. The fitting convex portion 109 is fitted into the fitting concave portion 110.
Accordingly, the fitting convex portion 109 is fitted into the fitting concave portion 110 in a state where the substrate side contact and the FPC side contact are completely in contact with each other. In this way, the connection between the male connector 105 and the female connector 104 is completed.
JP 2000-331730 A

The problem to be solved is that the female connector and the male connector cannot be easily removed even if the connection is simple.
That is, once the female connector and the male connector are connected to each other by connecting the fitting protrusions to the fitting recesses, the contacts can be removed and then hooked to the tip of the header part of the male connector. There is no choice but to remove the rear case from the front case and pull out the male connector, or pull out the male connector together with the flexible printed wiring board.

For this reason, it takes time and labor for the removal, and there is no guarantee that it can be removed smoothly without causing damage or disconnection. In particular, when the male connector is pulled out together with the flexible printed wiring board, there is a risk of disconnection.
Since the use of low-profile stacking connectors has increased significantly, the damage to parts during insertion of male connectors has also increased, and it has been removed so that it can be quickly replaced when parts are damaged during assembly. Improvements in ease are required.

  The present invention has been made in view of the above circumstances, and includes, for example, a stacking connector connection mounting structure that can be easily and smoothly removed without using a removal tool, and the structure. The purpose is to provide electronic equipment.

In order to solve the above-mentioned problem, the invention according to claim 1 is characterized in that a male connector and a female connector are provided in a housing formed by assembling a pair of frames in a mutually opposing manner. In connection with the mounting mounting structure of the stacking connector that is connected and mounted, in order to separate the frame bodies from each other when the housing is disassembled into the individual frame bodies in the male or female connector, A part of the mechanical force applied between the frames is received as a pulling force, and a pulling force acting part that is pulled out from the female or male connector is provided, and the casing is attached to each of the frames. when decomposing, by cooperation of the drawing force acting on the mechanical force and the pulling force acting portion will be added between the frame member, when the housing is decomposed into the individual frame, the male connector Disconnected from the female connector Te, along with being made to the structure to release the connection of the stacking connector, the one of said frame, when connecting the connectors of the male connector and the female, the female or male An opening for inserting the connector is formed .

  The invention according to claim 2 relates to the stacking connector connection mounting structure according to claim 1, wherein the mechanical force is applied to one of the frames so as to separate the frame from the other frame. And a pulling force imparting portion that presses the pulling force acting portion formed at a predetermined portion of the female or male connector so as to separate the male connector from the female connector. It is characterized by having.

Further, an invention according to claim 3, relates to a connection mounting structure for stacking connectors according to claim 2, wherein said male connector, the first fitting portion in which the first contact terminal portion therein is held The female connector includes a second fitting portion that holds a second contact terminal portion connected to the first contact terminal portion and fits the first fitting portion. It is characterized by having.

According to a fourth aspect of the present invention, there is provided the stacking connector connecting and mounting structure according to the third aspect , wherein the female or male connector has a flat plate shape in which the pulling force acting portion is formed at a predetermined location. The second or first fitting portion is connected to the substrate portion, and the pulling force giving portion is formed at a predetermined portion of the edge portion or the inner wall portion of the opening portion of one of the frame bodies, When the casing is disassembled into the individual frame bodies, the pulling force acting portion is pressed.

According to a fifth aspect of the present invention, there is provided the stacking connector connecting and mounting structure according to the fourth aspect , wherein the pull-out force acting portion is placed on the pull-out force giving portion, whereby the male connector and the above-mentioned connector are mounted. The second fitting portion is positioned with respect to the first fitting portion along a plane substantially orthogonal to the connecting direction to the female connector and the pulling direction.

According to a sixth aspect of the present invention, there is provided the stacking connector connecting and mounting structure according to the fourth aspect , wherein at least a pair of working convex portions as the pulling-out force acting portion is formed on the substrate portion. The edge of the opening of the frame is formed with a recess for removal as the pulling force imparting portion on which the corresponding working convex portion is placed.

According to a seventh aspect of the present invention, there is provided the stacking connector connecting and mounting structure according to the fourth aspect , wherein the substrate portion is formed with at least a pair of working recesses as the pulling force acting portion. The inner wall portion of the opening of the body is characterized in that a removal convex portion is formed as the pulling force imparting portion on which the edge of the corresponding working concave portion is placed.

The invention according to claim 8 relates to the stacking connector connection mounting structure according to any one of claims 1 to 7 , wherein the male connector and the female connector are fitted together. The male or female connector is attached, and the first circuit board fixed to the other frame is connected to the second circuit board to which the female or male connector is attached. In addition, when the housing is disassembled into the individual frames by the cooperation of the mechanical force and the pulling force, the male connector and the female connector are separated, and the first connector is separated. The connection between the circuit board and the second circuit board is released.

According to a ninth aspect of the present invention, there is provided the stacking connector connecting and mounting structure according to the eighth aspect , wherein the female or male connector is attached to one end of a flexible printed circuit as the second circuit board. It is characterized by being attached.

According to a tenth aspect of the present invention, an electronic apparatus includes the stacking connector connection mounting structure according to any one of the first to ninth aspects.

According to the configuration of the present invention, when the housing is disassembled into individual frames, the male connector or the female connector receives a part of the mechanical force applied between the frames in order to separate the frames. A pull- out force acting part that is received as a pull-out force and pulled out from the female or male connector is provided, and mechanical force and pull-out force action applied between the frames when disassembling the housing into individual frames When the housing is disassembled into individual frames by cooperation with the pulling force acting on the part, the male connector and the female connector are separated from each other, and the connection of the stacking connector is released. In addition, an opening for inserting the female connector or the male connector when the male connector and the female connector are connected is formed in one frame body. Easy to remove without using Kill.

  For male or female connectors, when the housing is disassembled into individual frames, in order to separate the frames, the female or male connector receives the remaining mechanical force applied between the frames. A pulling force acting part that is pulled out from the connector is provided, and when disassembling the housing into individual frame bodies, by the cooperation of the mechanical force applied between the frame bodies and the pulling force acting on the pulling force acting part, When the housing is disassembled into individual frames, the male connector and the female connector are separated, and the stacking connector is disconnected. Realized the purpose of removing.

  1 is an exploded perspective view showing the structure of a stacking connector connection mounting structure according to a first embodiment of the present invention, FIG. 2 is a cross-sectional view showing the structure of the stacking connector connection mounting structure, and FIG. 3 is a perspective view showing the configuration of the male connector of the stacking connector connection mounting structure, and is a view of the same male connector as viewed from below. FIG.

  A stacking connector (stacked connector) connection mounting structure 1 of this example is mounted on, for example, a housing 2 of a mobile phone (electronic device), as shown in FIGS. 1 and 2, and a CPU (Central Processing Unit) or a memory. Etc., a female connector 4 mounted on a main circuit board (motherboard) 3 mounted with a main circuit board 3 and other circuit boards (for example, a printed wiring board mounted with a SIM (Subscriber Identity Module) card connector) Are attached to one end of a flexible printed circuit (FPC: Flexible Printed Circuit) 7, and the male connector 8 fitted to the female connector 4 is detachable in a stacked state. The female connector 4 and the male connector are provided with a push-up portion 9 that is connected and formed on the housing 2 for simultaneously pushing up and removing the male connector 8 at the time of removal. Bets is configured so as to facilitate removal by the push-up unit 9.

  The housing 2 is made of a synthetic resin molded product such as ABS resin, for example, and has a front case 11 constituting the front side and a rear case 12 constituting the back side, as shown in FIGS. The assembled front case 11 and rear case 12 are assembled in a detachable manner in a state in which various components are housed or attached by fitting with ribs formed at the peripheral edge. Yes. 1 and 2 show a state in which part of the mobile phone is viewed from the back side.

  By removing the rear case 12 from the front case 11 and pulling it up, the male connector 8 is pushed up by the push-up portion 9 at the same time, and the fitting convex portion 23 is pulled away from the fitting concave portion 19. 8 is removed from the female connector 4.

The rear case 12 is formed with a substantially rectangular opening 13 in plan view that is slightly larger than the header 22 for inserting the header 22 when the male connector 8 is connected to the female connector 4. .
The push-up unit 9 has a pair of removal recesses 14 and 15 formed at predetermined sites on the edge of the opening 13 of the rear case 12.

  The bottom surface of each removal recess 14 (15) is a pressing surface 16 (17) that presses the action protrusion 25 (26) of the header portion 22 of the male connector 8 at the time of removal. The pair of recesses 14 and 15 for removal are formed so as to be symmetrical with respect to the symmetry axis through the predetermined symmetry axis of the opening 13 and the fitting recess 19.

Further, the removal recess 14 (15) has substantially the same outer dimensions as the action projection 25 (26) in plan view, and is parallel to the main circuit board 3 in two directions (for example, on the symmetry axis). Positioning along the direction along the direction perpendicular to the axis of symmetry).
This prevents erroneous insertion of the fitting convex portion 23 into the fitting concave portion 19, and the board-side contact (first contact terminal portion) 18 and the FPC-side contact (second contact terminal portion) 27 are accurately connected. A connection is made.

  In this example, the working convex portion 25 (26) is placed on the pressing surface 16 (17) in a state where the substrate side contact 18 and the FPC side contact 27 are completely in contact with each other. Has been. As a result, by confirming that the action convex portion 25 (26) has abutted against the pressing surface 16 (17), poor connection due to insufficient pressing of the male connector 8 is prevented.

  The female connector 4 is mounted so as to be disposed immediately below the opening 13 of the main circuit board 3 disposed on the inner surface of the front case 11, the fitting convex portion 23 is fitted therein, and a plurality of pins, for example, are provided therein. Have a frame-like fitting recess (housing) 19 arranged in two rows. The female connector 4 is connected to the main circuit board 3 by soldering via connection terminals 21, 21,... Corresponding to the board side contacts 18.

As shown in FIG. 3, the male connector 8 is fitted with a fitting recess 19 in a flat header portion 22 attached to one end of the flexible printed wiring board 7, and connected to a board-side contact corresponding to the inside. Are fitted with fitting projections (housings) 23 in which a plurality of female FPC side contacts 27, 27,... Are arranged in two rows.
The fitting convex portion 23 is connected to the header portion 22 by soldering via connection terminals 24, 24,... Corresponding to the FPC side contacts 27.

The header portion 22 has an action convex portion 25 (26) placed on the pressing surface 16 (17) of the removal concave portion 14 (15).
The FPC contact may be a pin-shaped (male) contact, and the substrate contact may be a female contact.

  When the male connector 8 attached to the flexible printed wiring board 7 is connected to the female connector 4, first, the header portion 22 of the male connector 8 is connected to the pair of working convex portions 25 and 26. After being arranged directly above the opening 13 of the rear case 12 so as to correspond to the external recesses 14 and 15, respectively, the action convex portions 25 (26) are lowered to correspond to the corresponding recesses 14 (15). It is made to mount on the pressing surface 16 (17).

At the same time, the fitting convex portion 23 is fitted into the fitting concave portion 19. The fitting convex portion 23 is pushed into the fitting concave portion 19 until the action convex portion 25 (26) abuts against the pressing surface 16 (17). When the working convex portion 25 (26) hits the pressing surface 16 (17), the fitting convex portion 23 is fitted into the fitting concave portion 19 in a state where the substrate side contact 18 and the FPC side contact 27 are completely in contact with each other. In this way, the connection between the male connector 8 and the female connector 4 is completed.
Thereafter, for example, a connection portion is covered by a battery cover (not shown) (the opening 13 is closed).

  Here, the recess 14 (15) for removal has substantially the same outer dimensions as the action protrusion 25 (26) in plan view, and is in two directions parallel to the main circuit board 3 (for example, the symmetry axis described above). And a direction along the direction perpendicular to the axis of symmetry). As a result, erroneous insertion of the fitting convex portion 23 into the fitting concave portion 19 is prevented, and the male connector 8 and the female connector 4 are accurately connected.

  Further, in this example, the action convex portion 25 (26) of the male connector 8 is placed on the pressing surface 16 (17) in a state where the board side contact 18 and the FPC side contact 27 are completely in contact with each other. By being configured as described above, it is possible to prevent poor connection due to insufficient push-in of the male connector 8 by confirming that the action convex portion 25 (26) hits the pressing surface 16 (17). .

For example, when it is desired to replace the male connector 8 attached to the flexible printed wiring board 7, the rear case 12 is first removed from the front case 11 (for example, the fitted state is released).
Next, for example, the rear case 12 is pulled up while the front case 11 is held and fixed with one hand.

  As a result, the pressing surface 16 (17) of the removing recess 14 (15) pushes up the action convex portion 25 (26) and receives a force so that the header portion 22 is pulled up, so that the fitting convex portion 23 is fitted. At the same time, the FPC side contact 27 is separated from the substrate side contact 18 and is in a disconnected state. Thus, the male connector 8 is removed from the female connector 4.

  Thus, according to the configuration of this example, by removing the rear case 12 from the front case 11 and pulling it up, the male connector 8 is simultaneously pushed up by the removal concave portion 14 (15), and the fitting convexity Since the male connector 8 is detached from the female connector 4 by pulling the portion 23 away from the fitting concave portion 19, the removal concave portion 14 (15) and the action convex portion 25 (26) are provided. The male connector 8 can be easily detached from the female connector 4 without using a tool. Also, it can be removed smoothly without causing damage or disconnection,

Further, the removal recess 14 (15) has substantially the same outer dimensions as the action projection 25 (26) in plan view, and is parallel to the main circuit board 3 in two directions (for example, on the symmetry axis). Positioning in the direction along the direction and the direction orthogonal to the axis of symmetry), the erroneous insertion of the fitting convex portion 23 into the fitting concave portion 19 is prevented, and the male connector 8 and the female connector 4 Can be connected accurately.
In particular, when the male connector and the female connector are directional, it can be easily confirmed by visual observation, and erroneous insertion can be prevented.

  Further, at the time of connection, the action convex portion 25 (26) of the male connector 8 is placed on the pressing surface 16 (17) in a state where the board side contact and the FPC side contact are completely in contact with each other. Therefore, it is possible to prevent a connection failure due to insufficient push-in of the male connector 8 by confirming that the action convex portion 25 (26) hits the pressing surface 16 (17).

  4 is an exploded perspective view showing the structure of the stacking connector connection mounting structure according to the second embodiment of the present invention, FIG. 5 is a cross-sectional view showing the structure of the stacking connector connection mounting structure, and FIG. 6 is a perspective view showing the configuration of the male connector of the stacking connector connection mounting structure, and is a view of the same male connector as viewed from below.

This example is significantly different from the first embodiment described above in that a convex portion is provided on the inner wall of the opening of the housing, and a concave portion is formed in the header portion of the male connector.
Since the other configuration is substantially the same as the configuration of the first embodiment described above, the same components as those of the first embodiment are used in FIGS. 4 to 6 in FIGS. The same reference numerals are used to simplify the description.

  As shown in FIGS. 4 and 5, the stacking connector connection mounting structure 1A of this example is mounted on a housing 31 of a mobile phone, for example, and is mounted on the main circuit board 3 and other circuits. A male connector 33 which is attached to one end of the flexible printed wiring board 7 for connecting to the substrate and is fitted to the female connector 4 is detachably connected and formed on the housing 31 for removal. A push-up portion 34 for simultaneously pushing up and removing the male connector 33 is sometimes provided, and the female connector 4 and the male connector 33 are configured to be easily removed by the push-up portion 34.

As shown in FIGS. 4 and 5, the housing 31 includes a front case 11 that forms the front surface side and a rear case 35 that forms the back surface side. 4 and 5 show a part of the cellular phone as viewed from the back side.
By removing the rear case 35 from the front case 11 and pulling it up, the male connector 33 is pushed up by the push-up portion 34 at the same time, and the fitting convex portion 23 is pulled away from the fitting concave portion 19. 33 is removed from the female connector 4.

In the rear case 35, when the male connector 33 is connected to the female connector 4, a substantially rectangular opening 36 is formed in a plan view that is slightly larger than the header 43 for inserting the header 43. .
The push-up portion 34 has a pair of detachment convex portions 37 and 38 formed at predetermined portions of the inner wall of the opening 36 of the rear case 35.

Each of the detaching projections 37 (38) has a trapezoidal cross section, and its side wall surface is inclined so as to increase in width as it goes downward, and presses the action recess 44 (45) of the male connector 33. The pressing surfaces 39, 39 (41, 41) are used.
The pair of removal projections 37 and 38 are formed so as to be bilaterally symmetric with respect to the symmetry axis through the predetermined symmetry axis of the opening 36 and the fitting recess 19.

Further, the removal projections 37 and 38 have substantially the same outer dimensions as the operation depressions 44 and 45 in plan view, and are parallel to the main circuit board 3 (for example, along the symmetry axis). Positioning along the direction and the direction perpendicular to the axis of symmetry).
As a result, erroneous insertion of the fitting convex portion 23 into the fitting concave portion 19 is prevented, and the male connector 33 and the female connector 4 are accurately connected.

  In this example, the working recess 44 (45) is placed on the pressing surfaces 39 and 39 (41 and 41) in a state where the substrate side contact 42 and the FPC side contact 46 are completely in contact with each other. It is configured as follows. Accordingly, by confirming that the working recess 44 (45) has abutted against both pressing surfaces 39, 39 (41, 41), poor connection due to insufficient pressing of the male connector 33 is prevented.

  The female connector 4 is mounted so as to be disposed immediately below the opening 36 of the main circuit board 3 disposed on the inner surface of the front case 11, the fitting convex portion 23 is fitted therein, and a plurality of pins, for example, are provided therein. .. Have a frame-shaped fitting recess 19 in which two (male) substrate-side contacts 42, 42,... Are arranged in two rows. The female connector 4 is connected to the main circuit board 3 by soldering via connection terminals 21, 21,... Corresponding to the board-side contacts 42.

  As shown in FIG. 6, the male connector 33 is fitted into the flat recess 43 attached to one end of the flexible printed wiring board 7 with the fitting recess 19, and the board-side contact 42 corresponding to the inside A plurality of female FPC-side contacts 46, 46,... To be connected are fitted with a fitting convex portion 23 arranged in two rows.

The fitting convex portion 23 is connected to the header portion 43 by soldering via connection terminals 24, 24,... Corresponding to the respective FPC side contacts 46.
The header portion 43 has a working recess 44 (45) placed on the pressing surfaces 39, 39 (41, 41) of the removal projection 37 (38).
In this example as well, the FPC contact may be a pin-shaped (male) contact, and the substrate contact may be a female contact.

  When the male connector 33 attached to the flexible printed wiring board 7 is connected to the female connector 4, first, the header 43 of the male connector 33 is paired with a pair of working recesses 44 and 45 for removal. After being arranged right above the opening 36 of the rear case 35 so as to correspond to the convex portions 37 and 38, respectively, it is lowered and the edge portion of each action concave portion 44 (45) is correspondingly removed. (38) is placed on the pressing surfaces 39, 39 (41, 41).

At the same time, the fitting convex portion 23 is fitted into the fitting concave portion 19. The fitting convex part 23 is pushed into the fitting concave part 19 until the edge part of the action concave part 44 (45) hits the pressing surfaces 39, 39 (41, 41). When the edge of the working recess 44 (45) abuts against the pressing surfaces 39, 39 (41, 41), the fitting projection 23 is fitted into the fitting recess 23 in a state where the substrate side contact 42 and the FPC side contact 46 are completely in contact with each other. 19 is inserted.
In this way, the connection between the male connector 33 and the female connector 4 is completed.

  Here, the removal projection 37 (38) has substantially the same outer dimensions as the operation recess 44 (45) in plan view, and is in two directions parallel to the main circuit board 3 (for example, the symmetry axis described above). And a direction along the direction perpendicular to the axis of symmetry). As a result, erroneous insertion of the fitting convex portion 23 into the fitting concave portion 19 is prevented, and the male connector 33 and the female connector 4 are accurately connected.

  In this example, the edge of the working recess 44 (45) of the male connector 33 is pressed against the pressing surface 39.39 (41) while the board side contact 42 and the FPC side contact 46 are completely in contact with each other. 41), it is configured to be placed on the male connector 33 by confirming that the working recess 44 (45) has abutted against the pressing surface 39.39 (41, 41). Connection failure due to indentation is prevented.

For example, when it is desired to replace the male connector 33 attached to the flexible printed wiring board 7, the rear case 35 is first removed from the front case 11 (for example, the fitted state is released).
Next, for example, the rear case 35 is pulled up while the front case 11 is held and fixed with one hand.

  Accordingly, the pressing surface 39.39 (41, 41) of the removal convex portion 37 (38) hits the edge portion of the working concave portion 44 (45) to press the header portion 43 so that the header portion 43 is pulled up. Therefore, the fitting convex portion 23 is gradually pulled away from the fitting concave portion 19, and at the same time, the FPC side contact 46 is separated from the substrate side contact 42 and is in a disconnected state. Thus, the male connector 33 is removed from the female connector 4.

According to the configuration of this example, substantially the same effect as that of the first embodiment described above can be obtained.
In addition, positioning can be performed more accurately.

The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and there are design changes and the like without departing from the gist of the present invention. Are also included in the present invention.
For example, in the above-described embodiments, the case has been described in which the front case and the rear case are combined and assembled by fitting with ribs. Anyway.

Moreover, although the case where a synthetic resin casing is used has been described, it is not limited to a synthetic resin, for example, it may be a die-cast molded product made of a magnesium alloy, may be made of other metal, or a metal may be added to the synthetic resin. It is good also as the structure covered.
Further, the present invention can also be applied to a case where a TCP (Tape Carrier Package) is used as a flexible printed circuit instead of an FPC (Flexible Printed Circuit). Further, the present invention is not limited to flexible printed circuits, and can be applied to connection between circuit boards such as double-sided printed wiring boards arranged in parallel to each other.

Alternatively, the male connector may be mounted on the main circuit board, and the female connector may be attached to the flexible printed wiring board.
In addition, the rear case and the male connector do not necessarily have to be provided with a convex portion or a concave portion that fits each other, and in the vicinity of the opening, the rear case and the male connector have a fitting convex portion and a concave concave portion. It suffices if there are at least a pair of overlapping portions on both sides of the sheet. For example, the header portion may be only placed on the edge of the opening.
Further, the present invention is not limited to removing the entire rear case, and only a part of the rear case may be removed to push up the male connector.

Alternatively, the outer case may be covered with the outer case, connected so that the header portion is placed on the outer case, and the outer type body may be removed from the rear case, whereby the male connector may be removed.
When the FPC is pulled out from the side surface of the housing, the rear case does not have to be provided with an opening for pulling out the FPC. In this case, the rear case and the front case may be fitted together after the male connector and the female connector are connected.

Moreover, the header part may serve as the lid. In this case, for example, a recess for placing the peripheral end of the header is formed on the entire periphery of the edge of the opening. Thereby, force can be applied uniformly.
Further, the contacts are not limited to two rows, but may be arranged in one row or three or more rows. Further, the contacts may be configured to simply contact each other without necessarily fitting.
Further, the present invention may be applied to the case where a single casing is used, and the casing is a fold composed of an upper casing and a lower casing that are coupled to each other by a hinge portion (hinge means). The present invention can also be applied to a mobile phone having a possible structure.

Further, in the first embodiment, the male connector may be connected to the female connector in a floating state even if the action convex portion is not necessarily placed on the pressing surface. Thereby, the rear case can be easily removed from the front case.
Further, for example, the working convex portions are not limited to two places, and may be provided in three directions excluding the side connected to the FPC.

  In addition to a mobile phone as an electronic device, the present invention can also be applied to a simple mobile phone (PHS) terminal, a personal digital assistant (PDA), and the like. Furthermore, in addition to portable electronic devices, for example, the present invention can also be applied to other electronic devices having a thin casing.

It is a disassembled perspective view which decomposes | disassembles and shows the structure of the stacking connector connection mounting structure which is 1st Example of this invention. It is sectional drawing which shows the structure of the same stacking connector connection mounting structure. It is the perspective view which shows the structure of the male connector of the same stacking connector connection mounting structure, and is the figure which looked at the same male connector from the downward direction. It is a disassembled perspective view which decomposes | disassembles and shows the structure of the stacking connector connection mounting structure which is 2nd Example of this invention. It is sectional drawing which shows the structure of the same stacking connector connection mounting structure. It is the perspective view which shows the structure of the male connector of the same stacking connector connection mounting structure, and is the figure which looked at the same male connector from the downward direction. It is explanatory drawing for demonstrating a prior art. It is explanatory drawing for demonstrating a prior art.

Explanation of symbols

1,1A Stacking connector connection mounting structure 2,31 Case 3 Main circuit board (first circuit board)
4 Female connector (female connector)
7 Flexible printed circuit board (second circuit board, flexible printed circuit)
8,33 Male connector (male connector)
9, 34 Push-up part 11 Front case (the other frame)
12, 35 Rear case (one frame)
13, 36 Opening 14, 15 Detachment recess (pull-out force imparting part)
16, 17 Press surface 18, 42 Substrate side contact (first contact terminal portion)
19 Fitting recess (first fitting part)
22, 43 Header part (board part)
23 Fitting convex part (second fitting part)
25, 26 Acting convex part (extraction force acting part)
27, 46 FPC side contact (second contact terminal)
37, 38 Detachable convex part (pull-out force giving part)
39, 41 Pressing surface 44, 45 Working recess (pull-out force acting part)

Claims (10)

A stacking connector connection mounting structure in which a male connector and a female connector are connected and mounted inside a casing configured by assembling a pair of frames in a mutually opposing manner. ,
In the male or female connector, when disassembling the housing into the individual frames, a part of mechanical force applied between the frames is used as a pulling force in order to separate the frames. In response, a pulling force acting portion that is pulled out from the female or male connector is provided,
Wherein when decomposing the housing to individual said frame, in cooperation with the drawing force acting on the frame the pulling force acting portion with the applied mechanical force between the body and the housing is the individual frame When disassembled, the male connector and the female connector are separated, and the stacking connector is disconnected .
One of the frames is formed with an opening for inserting the female or male connector when the male connector and the female connector are connected. Stacking connector connection mounting structure.   When the mechanical force is applied to one of the frame bodies so as to separate the frame body from the other frame body, the pulling force acting portion formed at a predetermined portion of the female or male connector is provided. 2. The stacking connector connection mounting structure according to claim 1, further comprising a pulling force imparting portion that presses the male connector and the female connector so as to separate them. The male connector has a first fitting portion in which a first contact terminal portion is held, and the female connector is connected to the first contact terminal portion inside. 3. The stacking connector connection mounting structure according to claim 2 , further comprising a second fitting portion that holds two contact terminal portions and fits the first fitting portion. The female or male connector is configured such that the second or first fitting portion is connected to a flat plate-like substrate portion in which the extraction force acting portion is formed at a predetermined location, and the extraction force is imparted. The part is formed at a predetermined portion of the edge or inner wall of the opening of one of the frames, and presses the pulling force acting part when disassembling the casing into the individual frames. The connection mounting structure for stacking connectors according to claim 3 . The pulling force acting part is placed on the pulling force giving part, so that the second direction along the plane substantially perpendicular to the connecting direction and the pulling direction of the male connector and the female connector is provided. The stacking connector connection mounting structure according to claim 4 , wherein the fitting portion is positioned with respect to the first fitting portion. The substrate portion is formed with at least a pair of acting convex portions as the pulling force acting portion, and the corresponding acting convex portion is placed on an edge of the opening of one of the frames. 5. A stacking connector connecting and mounting structure according to claim 4, wherein a detaching concave portion is formed as a pulling force imparting portion. The substrate portion is formed with at least a pair of working recesses as the pulling force acting portion, and an edge portion of the corresponding working recess is placed on the inner wall portion of the opening of one of the frames. The stacking connector connecting and mounting structure according to claim 4, wherein a detachable convex portion is formed as the pulling force imparting portion. The male connector and the female connector are fitted to each other so that the male or female connector is attached, and the first circuit board fixed to the other frame, and the female When the case is disassembled into the individual frame bodies by the cooperation of the mechanical force and the pulling force together with the second circuit board to which the type or male type connector is attached, the disconnected and female connector with the male connector, either one of claims 1 to 7 connected between the first circuit board and the second circuit board, characterized in that it is released 1 The stacking connector connection mounting structure described in 1. 9. The stacking connector connection mounting structure according to claim 8 , wherein the female or male connector is attached to one end of a flexible printed circuit as the second circuit board. An electronic apparatus comprising the connection mounting structure for stacking connectors according to any one of claims 1 to 9.

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