Patent Grant
7223106
This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2004-267243, filed Sep. 14, 2004, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a connector which is interposed between two opposing wiring boards and which electrically connects the wiring boards to each other, as well as to a method for holding the connector unit between wiring boards. Furthermore, the invention relates to an electronic apparatus, such as a portable computer, having the connector.
2. Background Art
In an electronic apparatus, such as a portable computer or a cellular phone, two printed wiring boards disposed so as to face each other are electrically connected together by way of a connector known as a stacking connector.
The connector has a first connector body mounted on one printed wiring board and a second connector body mounted on the other printed wiring board. The first and second connector bodies are removably fitted together, and interposed between the two printed wiring boards, as well.
The first and second connector bodies respectively support a plurality of lead terminals. Each of the lead terminals has a first section soldered onto a pad on the printed wiring board, and a second section exposed to a fit portion between the first and second connector bodies. When the first connector body and the second connector body are fitted together, the second sections of the lead terminals of the first and second connector bodies are brought into contact. By means of this contact, the two printed wiring boards are electrically connected.
Meanwhile, in a conventional connector, mounting strength of the first connector body with respect to the printing wiring board and that of the second connector body are likely to depend on strength of the respective soldered portions of the lead terminals. Therefore, when an absolute amount of solder is reduced with an increase in density of pads or with miniaturization of lead terminals, cracks often arise in a soldered portion of the lead terminal as a result of a large external force being exerted on the soldered portion between the lead terminal and the corresponding pad. This crack becomes greatly responsible for faulty continuity of the connector unit.
A conventionally-practiced countermeasure against the above is to individually fix the first and second connector bodies to the printed wiring boards by means of screws. Hence, since the external force exerted on the soldered portion between the lead terminal and the pad is received by the screw, damage, which may otherwise be inflicted on the soldered portion, can be prevented.
In another known example of a connector unit, a positioning pin is fixed on a first connector body, and a through hole, which allows insertion of the pin, is formed in a second connector body and in a printed wiring board—on which the second connector body is to be mounted. In the connector, the positioning pin continually passes through the two printed wiring boards, and the first and second connector bodies. Therefore, external force exerted on a soldered portion between a lead terminal and a pad and on a contact portion between the lead terminals can be received by the pin (see, e.g., JP-A-2002-319441).
When the first and second connector bodies are individually fixed to the printed wiring boards by means of screws, mounting strength of the first and second connector bodies with respect to the printed wiring boards is increased. However, the positions of the first and second connector bodies remain constrained by means of merely fitting.
Therefore, when, for instance, a strong impact, or stress resulting from a difference in thermal expansion is exerted on a fit portion between the first connector body and the second connector body, inevitably unbearable force is applied on a contact portion between the lead terminals. As a result, the contact state between the lead terminals is changed, whereby plating layers covering the surface of the lead terminals are sometimes exfoliated.
In particular, when a contact pressure between the lead terminals is low, an impact applied on the first and second connector bodies causes the lead terminals to vibrate, and sometimes to rub against each other. As a result, the plating layers on the surfaces of the lead terminals are shaved off, and metal powder produced by the shaving stays between the lead terminals as sludge. Consequently, contact resistance between the lead terminals is increased, thereby inducing a problem of heating of the connector or occurrence of faulty continuity.
Meanwhile, according to JP-A-2002-319441, a clearance is present between an outer face of a pin and an inner face of an insertion hole for allowing insertion of the pin. Accordingly, although the pin passes through the printed wiring boards, and the first and second connector bodies, the printed wiring boards, the first connector body, and the second connector body cannot be constrained firmly so as not to move each other.
Therefore, the configuration disclosed in JP-A-2002-319441 includes a problem that, when, for instance, large force is exerted on the connector, the soldered portion between the lead terminal and the pad is cracked and that a contact state between the lead terminals becomes unreliable.
The present invention aims at providing a connector which can ensure sufficient mounting strength of the first and second connector bodies with respect to the first and second printed wiring boards, and can reduce stress applied on the contact portion between the lead terminals, to thus enhance reliability of electric connection; as well as a method for holding the connector.
Another object of the invention is to provide an electronic apparatus having the connector.
The invention provides a connector including: a first connector body having a plurality of first lead terminals soldered onto a first wiring board; a second connector body having a plurality of second lead terminals soldered onto a second wiring board; a screw member; and a fastening member engageable to the screw member; wherein the first connector body and the second connector body are engaged with each other to bring the first lead terminals and the second lead terminals into contact such that the first lead terminals and the second terminals electrically connect the first wiring board to the second wiring board; and the first and second wiring boards and the first and second connector bodies are integrally fastened together by engaging the screw member to the fastening member.
The invention may a connector including: a first connector body having a plurality of first lead terminals soldered onto a first wiring board; a second connector body having a plurality of second lead terminals soldered onto a second wiring board; a first screw member; and a second screw member; wherein the first connector body and the second connector body are engaged with each other to bring the first lead terminals and the second lead terminals into contact such that the first lead terminals and the second terminals electrically connect the first wiring board to the second wiring board; and the first and second wiring boards and the first and second connector bodies are integrally fastened together by the first screw member and the second screw member.
The invention provides an electronic apparatus including: an enclosure; a first wiring board contained in the enclosure; a second wiring board contained in the enclosure so as to oppose the first wiring board; and a connector unit interposed between the first wiring board and the second wiring board; wherein the connector unit includes: a first connector body having a plurality of first lead terminals soldered onto a first wiring board, a second connector body having a plurality of second lead terminals soldered onto a second wiring board, a screw member, and a fastening member engageable to the screw member; the first connector body and the second connector body are engaged with each other to bring the first lead terminals and the second lead terminals into contact such that the first lead terminals and the second terminals electrically connect the first wiring board to the second wiring board; and the first and second wiring boards and the first and second connector bodies are integrally fastened together by engaging the screw member to the fastening member.
According to the invention, a load for preventing relative movement between the first printed wiring board, the second printed wiring board, the first connector body, and the second connector body can be applied, thereby providing firm restraint. Therefore, damage which may be otherwise be inflicted on the soldered portions between the first and second printed wiring boards and the lead terminals can be prevented, and stress applied on a contact portion between lead terminals can be reduced, thereby enhancing reliability of electric connection.
The present invention may be more readily described with reference to the accompanying drawings:
Hereinbelow, a first embodiment of the invention will be described by reference to
The display unit 3 comprises a display housing 8, and a liquid crystal display device 9 contained in the display housing 8. The display unit 3, which is connected to a rear end of the enclosure 4 by way of an unillustrated hinge, is pivotable between a closed position and an open position. At the closed position, the display unit 3 is laid on the enclosure 4 in such a manner as to cover the keyboard 6 from above. At the open position, the display unit 3 stands from the rear end of the enclosure 4 in such a manner as to expose the keyboard 6.
As shown in
A stacking connector 15 serving as a connector unit is interposed between the first printed wiring board 11 and the second printed wiring board 12. The stacking connector 15, which electrically connects the first printed wiring board 11 and the second printed wiring board 12, has a first connector body 16 serving as a plug portion and a second connector body 17 serving as a socket portion as shown in
The first connector body 16, formed from a synthetic resin, is mounted on a lower face 11a of the first printed wiring board 11. The first connector body 16 has a base 18 and terminal support section 19. The base has the geometry of a strip extending along the lower face 11a of the first printed wiring board 11. The terminal support section 19 projects downward from the base 18, and extends along the longitudinal direction of the base 18.
The terminal support section 19 has a pair of side faces 19a and 19b. The side faces 19a and 19b are arranged along the longitudinal direction of the terminal support section 19 in parallel with each other. The terminal support section 19 supports a plurality of first lead terminals 20. The first lead terminals 20 are aligned in a row along the side surfaces 19a and 19b of the terminal support section 19 with an interval therebetween.
Each of the first lead terminals 20 is formed from a metal material, for instance, a metal material predominantly composed of copper. The surface of the first lead terminal 20 is covered with a gold plating layer. The first lead terminal 20 has first sections 21 and second sections 22. The first sections 21 have the geometry of a pin of a size conforming to pads 23 located on the lower face 11a of the first printed wiring board 11. The first sections 21 are arranged so as to extend from opposite side sections of the base 18 along the lower face 11a of the first printed wiring board 11. The second sections 22 are exposed on the side faces 19a and 19b of the terminal support section 19, and have such elasticity as to be capable of elastic deformation in the direction approaching and departing to and from the side face 19a and 19b.
The first sections 21 of the first lead terminal 20 are soldered onto the pads 23 on the first printed wiring board 11, whereby fillets 24 is formed between the pads 23 and the first sections 21. By means of soldering, the pads 23 and the first lead terminal 20 are electrically connected together, and the first connector body 16 is mechanically retained on the first printed wiring board 11.
As shown in
The second connector body 17, formed from a synthetic resin, is mounted on an upper face 12a of the second printed wiring board 12. The second connector body 17 has the geometry of an elongated rectangular solid, and has a fitting recess 30 which is open upward. In the fitting recess 30, the terminal support section 19 of the first connector body 16 is removably fit. As a result of this fitting, the first connector body 16 and the second connector body 17 are integrally joined together.
The fitting recess 30 has a pair of side walls 31a and 31b serving as terminal support sections. The side walls 31a and 31b face each other, and extend in the longitudinal direction of the second connector body 17. The side walls 31a and 31b respectively support a plurality of second lead terminals 32. The second lead terminals 32 are formed from a metal material, for instance, a metal material predominantly composed of copper. The surface of the second lead terminals 32 are covered with gold plating layers.
The second lead terminal 32 has first sections 33 and second sections 34. The first sections 33 have the geometry of a pin of a size conforming to pads 35 disposed on the upper face 12a of the second printed wiring board 12. The first sections 33 are arranged so as to extend from opposite side sections of the second connector body 17 along the upper face 12a of the second printed wiring board 12. The second sections 34 have the geometry of a pin extending in the direction perpendicular to the first sections 33. The second sections 34 are aligned in a row along inner faces of the side walls 31a and 31b of the fitting recess 30. Accordingly, the second sections 34 of the second lead terminals 32 are exposed to the fitting recess 30.
As shown in
As shown in
When the terminal support section 19 of the first connector body 16 is fitted in the fitting recess 30 of the second connector body 17, the second sections 22 of the first lead terminals 20 and the second sections 34 of the second lead terminals 32 are brought into contact with each other. In particular, since the second sections 22 of the first lead terminals 20 have elasticity, contact pressure between the first lead terminals 20 and the second lead terminals 32 can be ensured. Accordingly, as a result of occurrence of a contact between the first and second lead terminals 20 and 32, the first printed wiring board 11 and the second printed wiring board 12 are electrically connected.
Furthermore, as shown in
Accordingly, the screw-receiving sections 26a, 26b of the first connector body 16, and the screw-receiving sections 38a, 38b of the second connector body 17 face each other with a fit portion between the terminal support section 19 and the fitting recess 30 therebetween. As a result, as shown in
In a state where the first connector body 16 and the second connector body 17 are fitted together, the stacking connector 15 configured as above is coupled to the first and second printed wiring boards 11 and 12 by way of a pair of fixing screws 42 and 43 serving as screw members, and a nut plate 44 serving as a fastening member.
As shown in
The nut plate 44 has the geometry of a strip extending in the longitudinal direction of the second connector body 17. The nut plate 44 has a pair of screw holes 45, and overlaps a lower face 12b of the second printed wiring board 12. The screw holes 45 are spaced from each other in the longitudinal direction of the nut plate 44 so as to conform to the insertion holes 40 in the second printed wiring board 12.
In addition, the nut plate 44 has a pair of anchor sections 46a and 45b. The anchor sections 46a and 46b are located at opposite ends spaced in the longitudinal direction of the nut plate 44. The anchor section 46a and 46b are temporarily fixed to the lower face 12b of the second printed wiring board 12 by means of, for instance, soldering. As a result of the temporal fixation, the screw holes 45 are brought into communication with the insertion holes 40 in the second printed wiring board 12.
The fixing screws 42 and 43 are caused to pass through the first and second printed wiring boards 11 and 12, and the first and second connector bodies 16 and 17; and thereafter screwed into the screw holes 45 in the nut plate 44. As a result of this screwing-in, the first and second printed wiring boards 11 and 12, and the first and second connector bodies 16 and 17 are integrally pinched between heads 42a, 43a of the fixing crews 42, 43, and the nut plate 44. Put another way, when the fixing screws 42 and 43 are screwed in, the first printed wiring board 11, the second printed wiring board 12, the first connector body 16, and the second connector body 17 receive a load for restraining relative movement therebetween.
Next, processes for electrically connecting the first printed wiring board 11 to the second printed wiring board 12 with use of the stacking connector 15 will be described.
First, the first lead terminals 20 of the first connector body 16 are soldered onto the pads 23 on the first printed wiring board 11, thereby mounting the first connector body 16 on the lower face 11a of the first printed wiring board 11. Similarly, the second lead terminals 32 of the second connector body 17 are soldered onto the pads 35 on the second printed wiring board 12, thereby mounting the second connector body 17 on the upper face 12a of the second printed wiring board 12.
Next, the terminal support section 19 of the first connector body 16 is fitted in the fitting recess 30 of the second connector body 17. Hence, a gap G between the first printed wiring board 11 and the second printed wiring board 12 is set. Accordingly, the second sections 22 of the first lead terminals 20 and the second sections 34 of the second lead terminals 32 are brought into contact with each other, thereby electrically connecting the first printed wiring board 11 to the second printed wiring board 12 by way of the first and second lead terminals 20 and 32.
Next, the fixing screws 42 and 43 are inserted through the insertion holes 28 in the first printed wiring board 11 from above. Subsequently, the fixing screws 42 and 43 are caused to continually pass through the through holes 27 in the first connector body 16, the through holes 39 in the second connector body 17, and the insertion holes 40 in the second printed wiring board 12.
Finally, penetrating edges of the fixing screws 42 and 43 are screwed into the screw holes 45 in the nut plate 44. As a result of this screwing-in, the first printed wiring board 11 and the second printed wiring board 2, and the first connector body 16 and the second connector body 17 are integrally fastened together. Consequently, a load for restraining relative movement between the first printed wiring board 11, the second printed wiring board 12, and the stacking connector 15 is applied, whereby the operation for electrically connecting the first printed wiring board 11 to the second printed wiring board 12 is completed.
According to the first embodiment of the invention, the first printed wiring board 11, the second printed wiring board 12, the first connector body 16, and the second connector body 17 can be restrained firmly so as to prevent occurrence of relative movements therebetween.
Therefore, when, for instance, a strong impact, or stress resulting from a difference in thermal expansion is exerted on the fit portion between the first connector body 16 and the second connector body 17, the fixing screws 42 and 43 can receive much of this impact and stress. Accordingly, stress applied an the soldered portions between the first and second lead terminals 20, 32 and the pads 23, 35; and that applied on the contact portions between the first lead terminals 20 and the second lead terminals 32 can be reduced.
Accordingly, damage which may otherwise be inflicted on the soldered portions of the first and second lead terminals 20 and 32 can be prevented; and a favorable contact between the first and second lead terminals 20 and 32 can be maintained. Hence, reliability of electric connection of the stacking connector 15 is enhanced.
In addition, according to the first embodiment, the nut plate 44 is temporarily fixed to the lower face 12b of the second printed wiring board 12 prior to screwing-in of the fixing screws 42 and 43. Therefore, a necessity for holding the nut plate 44 by hand at the time of fastening the fixing screws 42 and 43 is negated, thereby facilitating fastening work of the fixing screws 42 and 43.
Meanwhile, in the first embodiment, the fixing screws are inserted from the first printed wiring board toward the second printed wiring board; however, the invention is not limited thereto. For instance, the fixing screws may be inserted from the second printed wiring board toward the first printed wiring board. In this case, the nut plate is temporarily fixed to the first printed wiring board.
In the second embodiment, a nut 51 is employed as a fastening member. However, in other respects, the stacking connector 15 is identical in configuration with that of the first embodiment. Hence, elements identical with those of the first embodiment are denoted by the same reference numerals, and repeated descriptions are omitted.
The cylinder section 52 has a flange 54. The flange 54 projects radially outward from one end of the cylinder section 52, and overlaps the lower face 12h of the second printed wiring board 12. A periphery of the flange 54 is fixedly mounted directly on the lower face 12b of the second printed wiring board 12 by means of soldering, or the like.
The fixing screw 42, which continually passes through the first and second printed wiring boards 11 and 12, and the first and second connector bodies 16 and 17, is screwed into the female thread 53 in the nut 51. As a result of this screwing action, a load for restraining relative movement between the first printed wiring board 11, the second printed wiring board 12, the first connector body 16, and the second connector body 17 can be applied, thereby yielding the same effect as that yielded in the first embodiment.
The third embodiment differs from the first embodiment in configuration of restraint for preventing relative movement between the first printed wiring board 11, the second printed wiring board 12, and the stacking connector 15. In other respects, the stacking connector 15 is identical in basic configuration with that of the first embodiment.
A first screw hole 62 is formed in the first section 61a of the screw-receiving section 38a. The first screw hole 62 is continuous with the insertion hole 28 in the first printed wiring board 11. A second screw hole 63 is formed in the second section 61b of the screw-receiving section 38a. The second screw hole 63 is continuous with the insertion hole 40 in the second printed wiring board 12. Therefore, in the present embodiment, the insertion hole 28 in the first printed wiring board 11 and the insertion hole 40 in the second printed wiring board 12 are offset in the direction crossing the longitudinal direction of the first and second connector body 16, 17.
The screw-receiving section 26a of the first connector body 16 is interposed between the first section 61a of the screw-receiving section 38a and the lower face 11a of the first printed wiring board 11. The screw-receiving section 26a has a through hole 64. The through hole 64 in the screw-receiving section 26a, the insertion hole 28 in the first printed wiring board 11, and the first screw hole 62 in the first screw-receiving section 61a are coaxially aligned in a row.
The first printed wiring board 11, the first connector body 16, and the second connector body 17 are fastened together by way of the first fixing screw 65 serving as a first fastening member. The first fixing screw 65 is inserted through the insertion hole 28 and in the through hole 64 from above the first printed wiring board 11; and a penetrating end of the first fixing screw 65 is screwed into the first screw hole 62.
The second printed wiring board 12 and the second connector body 17 are fastened together by way of the second fixing screw 66 serving as a second fastening member. The second fixing screw 66 is inserted through the insertion hole 40 from below the second printed wiring board 12; and a penetrating end of the second fixing screw 66 is screwed into the second screw hole 63.
The process for electrically connecting the first and second printed wiring boards 11 and 12 to each other with use of the stacking connector 15 having the above-described configuration will be described.
The process from a step of soldering the first and second connector bodies 16 and 17 onto the first and second printed wiring boards 11 and 12, to a step of fitting the first and second connector bodies 16 and 17 each other is analogous to that of the first embodiment.
After completion of fitting of the first and second connector bodies 16 and 17, the first fixing screw 65 is inserted through the insertion hole 28 in the first printed wiring board 11 from above; and is screwed into the first screw hole 62 in the second connector body 17. In conjunction therewith, the second fixing screw 66 is inserted through the insertion hole 40 in the second printed wiring board 12 from below; and is screwed into the second screw hole 63 in the second connector body 17.
As a result of this screwing-in, the first connector body 16 is coupled to the first printed wiring board 11, and the second connector body 17 is coupled to the second printed wiring board 12; and the first and second connector bodies 16 and 17 are integrally fastened together between the first and second printed wiring boards 11 and 12.
Consequently, a load for restraining relative movement between the first printed wiring board 11, the second printed wiring board 12, and the stacking connector 15 is applied, whereby the operation for electrically connecting the first printed wiring board 11 to the second printed wiring board 12 is completed.
The fourth embodiment differs from the first embodiment in configuration of restraint for preventing relative movement between the first printed wiring board 11, the second printed wiring board 12, and the stacking connector 15. In other respects, the stacking connector 15 is identical in basic configuration with that of the first embodiment.
As shown in
The spacer sections 71a and 71b respectively have through holes 72 at the center thereof. Each of the through hole 72 is formed coaxially with the insertion hole 28 in the first printed wiring board 11 and the insertion hole 40 in the second printed wiring board 12.
The second connector body 17 has a pair of end faces 73 (only one end face 73 is shown in the drawing). The end faces 73 are located at opposite longitudinal ends of the second connector body 17; and stand upright from the upper face 12a of the second printed wiring board 12.
In a state where the first connector body 16 and the second connector body 17 are fitted together, the end faces 73 of the second connector body 17 are brought into contact with the spacer sections 71a and 71b of the first connector body 16. Therefore, the second connector body 17 is interposed between the spacer sections 71a and 71b of the first connector body 16, thereby being pinched by the spacer sections 71a and 71b.
The first printed wiring board 11, the second printed wiring board 12, and the first connector body 16 are integrally fastened together by way of the fixing screws 42 and 43, and a nut 74 serving as a fastening member. The fixing screw 42 and 43 are respectively inserted through the insertion holes 23 from above the first printed wiring board 11. The fixing screws 42, 43 are arranged so as to continually pass through the through holes 72 in the spacer sections 71a, 71b, and the insertion holes 40 in the second printed wiring board 12.
The nut 74 has a cylinder section 75 to be fitted in the insertion hole 40 in the second printed wiring board 12. A female thread 76 is formed in an inner face of the cylinder section 75. In addition, the cylinder section 75 has a flange 77. The flange 77 projects radially outward from an end of the cylinder section 75, and overlaps the lower face 12b of the second printed wiring board 12. A periphery of the flange 77 is fixedly mounted directly on the lower face 12b of the second printed wiring board 12 by means of soldering, or the like.
The fixing screws 42, 43, which continually pass through the first and second printed wiring boards 11 and 12, and the spacer sections 71a, 71b, are screwed into the female threads 76 in the nuts 74. As a result of this screwing-in, the first and the second connector bodies 16 and 17 are integrally fastened between the first printed wiring board 11 and the second printed wiring board 12.
The process for electrically connecting the first and second printed wiring boards 11 and 12 to each other with use of the stacking connector 15 configured as above will be described.
The process from a step of soldering the first and second connector bodies 16 and 17 onto the first and second printed wiring boards 11 and 12, to a step of fitting together the first and second connector bodies 16 and 17 is analogous to that of the first embodiment.
When the first connector body 16 and the second connector body 17 are fitted together, the second connector body 17 is pinched between the spacer sections 71a and 71b of the first connector body 16. This pinching maintains a firm fitted state between the first connector body 16 and the second connector body 17.
In conjunction therewith, the spacer sections 71a and 71b are interposed between the lower face 11a of the first printed wiring board 11 and the upper face 12a of the second printed wiring board 12, thereby setting the gap G between the first printed wiring board 11 and the second printed wiring board 12.
Next, the fixing screws 42, 43 are inserted through the insertion holes 28 in the first printed wiring board 11 from above. The fixing screws 42, 43 pass through the through holes 72 in the spacer sections 71a, 71b; and are screwed into the female threads 76 in the nuts 74. By means of this screwing action, the first and the second connector bodies 16 and 17, which are fitted together between the first printed wiring board 11 and the second printed wiring board 12, are integrally fastened together.
Consequently, a load for restraining relative motion between the first printed wiring board 11, the second printed wiring board 12, and the stacking connector 15 is applied, whereby the operation for electrically connecting the first printed wiring board 11 and the second printed wiring board 12 to each other is completed.
Meanwhile, in the fourth embodiment, the spacer sections are disposed on the first connector body. However, the invention is not limited thereto. For instance, the spacer sections may be disposed on the second connector body; and the nut may be fixedly mounted directly on the first printed wiring board.
The fifth embodiment is a development of the second embodiment. Hence, elements identical with those of the second embodiment are denoted by the same reference numerals, and repeated descriptions are omitted.
When the first connector body 16 and the second connector body 17 are fitted together, the guide pipe 81 passes through the through hole 39 in the screw-receiving section 38a; and a penetrating end of the guide pipe 81 is inserted into the insertion hole in the second printed wiring board 12.
The fixing screw 42 passes through the through hole 28 in the first printed wiring board 11 and the guide pipe 81, and is screwed into the female thread 53 in the nut 51. As a result of this screwing-in, the first printed wiring board 11, the second printed wiring board 12, the first connector body 16, and the second connector body 17 are firmly restrained so as to prevent relative movement therebetween.
The sixth embodiment differs from the second embodiment in configuration of the nut 51. In other respects, the stacking connector 15 is identical in basic configuration with that of the second embodiment.
The fixing screw 42 passes through the through hole 28 in the first printed wiring board 11 and the guide section 81, and is screwed into the female thread 53 in the nut 51. As a result of this screwing-in, the first printed wiring board 11, the second printed wiring board 12, the first connector body 16, and the second connector body 17 are firmly restrained so as to prevent relative movement therebetween.
Meanwhile, in the sixth embodiment, the fixing screw may be inserted from the second printed wiring board toward the first printed wiring board; and the nut may be fixedly mounted directly on the first printed wiring board. In this case, the guide section of the nut passes through the screw-receiving section of the first connector body.
The seventh embodiment differs from the first embodiment in that the fixing screw 42 is screwed into the bottom wall 4a of the enclosure 4; and in other respects, the seventh embodiment is identical in configuration with the first embodiment.
Furthermore, the boss 100 has a screw hole 102 open into the support face 101. The screw hole 102 opposes the insertion hole 40 in the second printed wiring board 12.
The fixing screw 42 continually passes through the insertion hole 28 in the first printed wiring board 11, the through hole 27 in the screw-receiving section 26a, the through hole 39 in the screw-receiving section 38a, and the insertion hole 40 in the second printed wiring board 12; and is screwed into the screw hole 102 in the boss 100. As a result of this screwing-in, the first and second printed wiring boards 11 and 12, and the first and second connector bodies 16 and 17 are pinched between the head 42a of the fixing screw 42 and the support face 101 of the boss 100. Accordingly, the boss 100 also functions as a fastening member.
Therefore, the present embodiment is also configured such that, when the fixing screw 42 is screwed in, such a load as to restrain relative movement is applied on the first and second printed wiring boards 11 and 12, and the first and second connector bodies 16 and 17.
Meanwhile, an electronic apparatus according to the invention is not limited to a portable computer. For instance, the invention can also be embodied as another electronic apparatus, such as a cellular phone or a FDA (personal digital assistant), in a similar manner.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2004-267243 | Sep 2004 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 4523883 | Peterson et al. | Jun 1985 | A |
| 4577402 | Swanstrom | Mar 1986 | A |
| 4587377 | Rodseth | May 1986 | A |
| 4929185 | Wong et al. | May 1990 | A |
| 4971565 | Fox, Jr. | Nov 1990 | A |
| 5380211 | Kawaguchi et al. | Jan 1995 | A |
| 5502982 | Venetucci | Apr 1996 | A |
| 5575686 | Noschese | Nov 1996 | A |
| 6019613 | Kataoka et al. | Feb 2000 | A |
| 6249442 | Watanabe | Jun 2001 | B1 |
| 6280202 | Alden et al. | Aug 2001 | B1 |
| 6377445 | Davis et al. | Apr 2002 | B1 |
| 6409526 | Malone et al. | Jun 2002 | B1 |
| 6431879 | Brekosky et al. | Aug 2002 | B2 |
| 6669422 | Sterle | Dec 2003 | B1 |
| 6690582 | Sumida | Feb 2004 | B2 |
| 6843629 | Farral et al. | Jan 2005 | B2 |
| 20030113183 | McAfee | Jun 2003 | A1 |
| 20040258500 | Ireland | Dec 2004 | A1 |
| Number | Date | Country |
|---|---|---|
| 2002-319441 | Oct 2002 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20060057869 A1 | Mar 2006 | US |
