JP2020167546A - Wireless device - Google Patents

Abstract

To provide a wireless device including a connection component capable of more reliably conducting a printed circuit board for a wireless device with a metal body placed on the periphery of a cabinet of the wireless device with a simple structure.SOLUTION: A wireless device 101 includes: a cabinet 201; a printed circuit board 220 provided with a print pattern; a metal body 210 arranged on the peripheral edge of the cabinet; and a connecting component 230 for electrically connecting a printed circuit board to be placed on the cabinet and the metal body by elastically deforming from a master form.SELECTED DRAWING: Figure 2

Description

The present invention relates to a wireless device.

Patent Document 1 discloses a radio device including a conductive frame member provided along the outer periphery of a housing and a wireless circuit unit that performs wireless communication processing using the frame member as an antenna. There is.

Japanese Unexamined Patent Publication No. 2015-156537 (published on August 27, 2015)

However, Patent Document 1 does not disclose a specific connection structure between the frame member and the wireless circuit unit or the like.

Therefore, the present invention realizes, for example, a wireless device including a connection component capable of more reliably conducting a metal body arranged on a peripheral portion between a printed circuit board of a wireless device and a cabinet of the wireless device with a simple structure. With the goal.

(1) The wireless device according to one aspect of the present invention includes a cabinet, a printed circuit board provided with a print pattern, a metal body disposed on the peripheral edge of the cabinet, the printed circuit board mounted on the cabinet, and the metal. It is characterized by including a connecting component that electrically connects the body by elastically deforming it from the prototype.

(2) The wireless device according to one aspect of the present invention has a fastener that is fastened to an opening that opens to the cabinet while being inserted into an insertion hole provided in the connection component, and when the fastener is fastened, the connection component is fastened. Is characterized in that it conducts with the printed circuit board by elastically deforming in the fastening direction.

(3) The wireless device according to one aspect of the present invention is characterized in that the connecting component is elastically deformed in a substantially horizontal direction to conduct conduction with the metal body in a substantially vertical direction.

(4) The wireless device according to one aspect of the present invention is characterized by including a sub-cabinet that sandwiches the printed circuit board with the cabinet.

(5) The wireless device according to one aspect of the present invention is characterized in that the cabinet or the sub-cabinet is provided with a convex portion that regulates the amount of displacement of the connecting component that is elastically deformed in a substantially horizontal direction.

(6) The wireless device according to one aspect of the present invention is characterized in that the sub-cabinet has an antenna pattern, and the connecting parts are elastically deformed in the fastening direction to conduct conduction with the antenna pattern. ..

(7) The wireless device according to one aspect of the present invention is characterized in that the connecting component is elastically deformed in a substantially horizontal direction to conduct conduction with the metal body in a substantially vertical direction.

(8) The wireless device according to one aspect of the present invention is characterized in that the cabinet has a protrusion through which the connecting component is inserted.

(9) The wireless device according to one aspect of the present invention includes a sub-cabinet provided with a protrusion receiving portion for engaging the protrusion, and the connecting component inserted through the protrusion is elastically deformed in the vertical direction. It is characterized in that it conducts with the printed circuit board.

(10) The wireless device according to one aspect of the present invention is characterized in that the connecting component is elastically deformed in a substantially horizontal direction to conduct conduction with the metal body in a substantially vertical direction.

It is a top view which shows the wireless apparatus which concerns on Embodiment 1 of this invention. It is a top view seen from the back side by removing the rear panel of the wireless device which concerns on Embodiment 1 of this invention. It is a schematic perspective view of the main part which shows each component at the time of connecting a metal body and a printed circuit board in FIG. 2 via a connecting component. It is a side sectional view which shows the state before fitting a connecting part into a cabinet. It is a side sectional view which shows the state after fitting a connecting part into a cabinet. It is a top view seen from the back side with the rear panel of the wireless device which concerns on Embodiment 2 of this invention removed. It is a top view of the main part which shows a metal body and a cabinet. It is a top view of the main part which shows a metal body and a sub-cabinet. It is a top view of the main part which shows a sub-cabinet and a metal body. 9 is a cross-sectional view taken along the line XX of FIG. It is a top view of the main part which shows a sub-cabinet and a metal body. FIG. 11 is a cross-sectional view taken along the line XII-XII of FIG. It is a top view of the main part seen from the back side by removing the rear panel of the wireless device which concerns on Embodiment 3 of this invention. It is a top view of the main part which shows a metal body, a cabinet, a printed circuit board, and connecting parts. It is a top view of the main part which shows the sub-cabinet. It is sectional drawing which shows the state of the connection part before integration of a cabinet and a sub-cabinet. It is sectional drawing which shows the state of the peripheral edge before integration of a cabinet and a sub-cabinet. FIG. 13 is a cross-sectional view taken along the line XVIII-XVIII of FIG. It is a cross-sectional view of XIX-XIX of FIG. It is a circuit diagram of the wireless device shown in FIG.

[Embodiment 1]
Hereinafter, as an embodiment of the present disclosure, a case where the present invention is applied to a smartphone as an example of a wireless device will be described with reference to the drawings. The present invention is not limited to smartphones, and can be generally applied to wireless devices. FIG. 1 is a plan view showing a wireless device according to the present embodiment. FIG. 2 is a plan view of the wireless device according to the present embodiment with the rear panel removed and viewed from the rear side. FIG. 3 is a schematic perspective view of a main part showing each component when the metal body and the printed circuit board in FIG. 2 are connected via the connecting component.

As shown in FIG. 1, the wireless device 101 of the embodiment of the present invention has a display unit 102 for displaying an image, and when the rear panel on the back side thereof is removed, it is the same as the cabinet 201 as shown in FIG. A metal body 210 arranged on the peripheral edge of the cabinet 201, a printed circuit board 220 provided with a print pattern, and a connecting component 230 are provided. Reference numeral 250 in the figure is a battery.

The display unit 102 has a rectangular plate-like structure as a whole in which a display panel for displaying an image, a drive IC, and a touch panel for an operation interface are integrated. For example, the display panel is composed of a liquid crystal panel, a backlight, and the like. Alternatively, it may be composed of a panel such as an OLED (Organic Light Emitting Diode) that emits light by itself.

As shown in FIG. 2, the cabinet 201 has a plate-like structure made of a dielectric and having a substantially rectangular shape in a plan view. The display unit 102 is stored on the front surface side of the cabinet 201, and the printed circuit board 220, the battery 250, the image sensor 260, and the like on which the wireless communication IC and the like are mounted are stored on the back surface side of the cabinet 201.

An opening 202 for fastening the fastener 240 of the connecting component 230, which will be described later, is formed in the upper part of the cabinet 201. The opening 202 is formed so as to be close to the inner wall 212a of the frame body 212 in the left direction of the metal body 210, which will be described later, and the opening 202 is further formed under the convex connection portion 221 of the printed circuit board 220. ing.

A metal body 210 is arranged on the outer peripheral edge of the cabinet 201. The metal body 210 is located on a plane substantially perpendicular to the cabinet 201, which is located on a substantially horizontal surface. The outer shape of the metal body 210 is formed, for example, in a substantially rectangular frame shape, and two gaps 213 and 213 are formed in each of the upward and downward frame bodies 211. The metal body 210 is, for example, conductive and is a metal material, and is made of a material such as SUS.

The cabinet 201 is provided with a printed circuit board 220 in which a circuit or the like for mounting a wireless IC or the like for transmitting and receiving a wireless signal is printed and patterned.

The printed circuit board 220 shown in FIG. 3 has a substantially rectangular shape (see FIG. 2), and a convex connecting portion 221 that electrically connects is formed in the middle portion in the longitudinal direction. A through hole 221a concentric with the opening 202 of the cabinet 201 is formed in the convex connection portion 221. The length of the printed circuit board 220 in the longitudinal direction is formed to be shorter than the length between the frame bodies 211 in the vertical direction. Further, the printed circuit board 220 is configured to mount a wireless IC or the like and cover the surface portion thereof with a shield portion 222 made of metal or the like (see FIG. 2) except for the convex connection portion 221.

The battery 250 (see FIG. 2) has a flat rectangular parallelepiped structure in which electricity is supplied to the communication IC of the display unit 102 and the printed circuit board 220, mounting parts, and the like. The battery 250 is arranged inside the cabinet 201, and the printed circuit board 220 is arranged above the battery 250.

The image sensor 260 is a component that captures a still image or a moving image.

Next, the printed circuit board 220 on a substantially horizontal surface and the metal body 210 on a substantially vertical surface are electrically connected via a connecting component 230 elastically deformed from the prototype described later, and the metal body 210 is Power is supplied from the printed circuit board 220 and functions as an antenna.

As shown in FIGS. 3 and 4, the connecting component 230 has, for example, a substantially cylindrical structure, is made of a material that is elastically deformed, and its outer peripheral edge portion 231 is made of at least a conductive material. An insertion hole 232 is bored in the radial direction (vertical direction) at the central portion of the outer peripheral edge portion 231 in the longitudinal direction. The diameter of the insertion hole 232 is smaller than the diameter of the connecting component 230. Further, the insertion hole 232 and the opening 202 of the cabinet 201 are formed so as to be concentric with each other.

With reference to FIGS. 4 to 5, a method of electrically connecting the printed circuit board 220 mounted on the cabinet 201 and the metal body 210 by using the connection component 230 elastically deformed from the prototype will be described.

As shown in FIG. 4, a printed circuit board 220 is placed on the cabinet 201, and the insertion hole 232 of the connecting component 230, the through hole 221a of the printed circuit board 220, and the opening 202 of the cabinet 201 are concentric with each other. It is placed so that it becomes.

As shown in FIG. 5, in the connecting component 230, the fastener 240 (for example, a screw) is inserted into the insertion hole 232 from the tip 243, and the tip 243 of the fastener 240 protruding outward from the insertion hole 232 is further inserted. It penetrates through the through hole 221a of the connection portion 221 of the printed circuit board 220 and is fitted into the opening 202 opened on the cabinet 201.

By this fitting action, the lower part of the head 241 of the fastener 240 presses the peripheral edge of the insertion hole 232 of the connecting part 230, and this pressing force connects in the radial direction (approximately horizontal direction) orthogonal to the insertion hole 232 of the connecting part 230. The component 230 itself is elastically deformed. A male screw portion is formed on the outer peripheral surface of the shaft portion 242 of the fastener 240, and at the time of fastening, the male screw portion of the shaft portion 242 is fitted into the female screw portion on the inner wall surface of the opening 202 of the cabinet 201. Be matched. The diameter of the head 241 of the fastener 240 is formed to be at least larger than the diameter of the insertion hole 232.

The side sectional view shape of the connecting component 230 is changed from, for example, a substantially circular shape before being pressed by the fastener 240 to a substantially elliptical shape after being pressed by the fastener 240. The substantially elliptical connecting component 230 after being elastically deformed in the fastening direction becomes conductive when the lower region of the outer peripheral edge portion 231 abuts on the convex connecting portion 221 of the printed circuit board 220 located in the substantially horizontal direction. Further, the connecting component 230 is elastically deformed in a substantially horizontal direction so that the lateral region of the outer peripheral edge portion 231 comes into contact with the inner wall 212a of the left frame body 212 of the metal body 210 located in the vertical direction to conduct conduction. The printed circuit board 220 and the metal body 210 in the substantially vertical direction are electrically connected to each other via the elastically deformed connecting component 230. Contact portions for connecting to the printed circuit board 220 and the metal body 210 are formed on the outer peripheral edge portion 231 of the connecting component 230 deformed into an elliptical shape.

By elastically deforming the connecting component 230 in this way, the printed circuit board 220 on the cabinet 201 and the metal body 210 located in a substantially vertical direction can be reliably conducted and electrically connected in a simple and compact structure. For example, when power is supplied from the printed circuit board 220 in the substantially horizontal direction, power can be supplied to the metal body 210 in the substantially vertical direction via the connecting component 230 deformed from the prototype, and the frame body 212 of the metal body 210 functions as an antenna. be able to.

[Embodiment 2]
Embodiment 2 of the present disclosure will be described with reference to FIGS. 6 to 12. The plan view of the wireless device of the second embodiment has the same structure as the wireless device of the first embodiment shown in FIG. 1, and some overlapping description will be omitted.

As shown in FIG. 6, in the wireless device 601 according to the embodiment of the present invention, when the rear panel on the back side thereof is removed, the cabinet 602, the printed circuit board 620 provided with the print pattern, the sub-cabinet 670, the stacked cabinet 602, and the cabinet 602 A metal body 610 surrounding the peripheral edge of the sub-cabinet 670 and a connecting component 630 are provided. Reference numeral 650 in the figure is a battery.

As shown in FIG. 7, the cabinet 602 is provided under the sub-cabinet 670, and has, for example, a plate-like structure made of a dielectric and having a substantially rectangular shape in a plan view. The cabinet 602 is formed with an opening 603 concentric with the insertion hole 672 of the sub-cabinet 670. A connection portion 621 of a printed circuit board 620, which will be described later, is close to the edge of the opening 603 of the cabinet 602. The display unit 102 is stored on the front surface side of the cabinet 602, and the printed circuit board 620, the battery 650, the image sensor 660, and the like on which the sub-cabinet 670 and the wireless communication IC are mounted are stored on the back surface side of the cabinet 602.

Further, a metal body 610 is arranged on the outer peripheral edge of the cabinet 602. The metal body 610 is located on a plane perpendicular to the cabinet 602, which is located on a substantially horizontal plane. The outer shape of the metal body 610 is formed, for example, in the shape of a substantially rectangular frame, and two gaps 613 and 613 are formed in each of the upward and downward frame bodies 611. The metal body 610 is, for example, conductive and is a metal material, and is made of a material such as SUS. A printed circuit board 620 in which a circuit or the like for mounting a wireless IC or the like for transmitting and receiving a wireless signal is printed is arranged between the cabinet 602 and the sub-cabinet 670.

The printed circuit board 620 is formed, for example, in a substantially rectangular shape, and a convex connecting portion 621 that is electrically connected is formed in the middle portion in the longitudinal direction. The convex connection portion 621 is formed so as to be close to the opening 603 of the cabinet 602. The length of the printed circuit board 620 in the longitudinal direction is formed to be shorter than the length of each frame body 611 in the vertical direction. Further, the printed circuit board 620 is configured to mount a wireless IC or the like and cover the surface portion thereof with a shield portion 622 made of metal or the like except for the convex connection portion 621.

As shown in FIG. 10, the connection portion 621 of the printed circuit board 620 and the electrode pad 673b on the back side of the sub-cabinet 670 are electrically connected via a contact spring 683. The printed circuit board supplies power to the antenna pattern (see FIG. 8) on the sub-cabinet and the metal body on the vertical surface.

As shown in FIG. 8, the sub-cabinet 670 has, for example, a plate-like structure made of a dielectric and having a substantially rectangular shape in a plan view.
For example, an antenna pattern 671 is provided on the front surface surface of the sub-cabinet 670, an electrode pad 673a is formed at the base of the antenna pattern 671, and an electrode pad 673a is formed in the center of the electrode pad 673a, which is smaller than the outer size of the pad 673a. An insertion hole 672 having a diameter is bored. At the end of the electrode pad 673a of the antenna pattern 671, a convex portion 674 that regulates the amount of displacement when the connection component 630 described later is elastically deformed is provided.

Further, the antenna pattern 671 of the sub-cabinet 670 is connected to the printed circuit board 620 via the contact spring 683.
In this way, the printed circuit board 620 is provided so as to be sandwiched between the cabinet 602 and the sub-cabinet 670, and by providing the antenna pattern on the surface of the sub-cabinet 670, for example, the ground of the printed circuit board 620 is deteriorated. Since it is possible to secure a physical distance from the parts that cause the problem, more efficient antenna performance can be obtained even with the same cabinet size.

The antenna pattern 671 is, for example, a pattern having conductivity, and is a conductive film formed by printing a conductive paste. Alternatively, it may be metal plating (a conductive film on which metal is vapor-deposited), a conductive film, sheet metal, or the like.

As shown in FIG. 10, on the back side surface of the sub-cabinet 670, an electrode pad 673a on the front side and an electrode pad 673b on the back side that are electrically connected via an insertion hole 672 on the side of the pad are formed on the back side. The electrode pad 673b is connected to the convex connection portion 621 of the printed circuit board 620 via the contact spring 683.
Further, the sub-cabinet 670 has a structure in which a part of the back surface side thereof is cut out in a concave shape for accommodating the printed circuit board 620. When the printed circuit board 620 is placed on the cabinet 602, a gap is formed in the notched storage portion 675 from the upper surface of the printed circuit board 620 to the ceiling portion 675a of the storage portion 675. A conductive film that conducts both front and back electrode pads 673a and 673b is formed on the inner wall of the insertion hole 672.

Next, the printed circuit board 620 on the substantially horizontal surface between the cabinet 602 and the sub-cabinet 670 and the metal body 610 on the perpendicular surface are connected to the elastically deformable connecting component 630 on the sub-cabinet 670 described later. It is electrically connected, and the antenna pattern 671 of the metal body 610 and the sub-cabinet 670 is fed by the printed circuit board 620 and functions as an antenna.

As shown in FIGS. 6 and 10, the connecting component 630 has, for example, a substantially cylindrical structure, is made of a material that is elastically deformed, and its outer peripheral edge portion 631 is made of at least a conductive material. An insertion hole 632 is provided in the radial direction (vertical direction) at the central portion of the outer peripheral edge portion 631 in the longitudinal direction. The diameter of the insertion hole 632 is smaller than the diameter of the connecting component 630.

As shown in FIG. 10, the connecting component 630 is provided with a substantially square plate 680 in order to uniformly deform the peripheral edge of the insertion hole 632 under the head 641 of the fastener 640. That is, the plate 680 is provided between the head portion 641 of the fastener 640 and the outer peripheral edge portion 631 of the connecting component 630 in order to uniformly deform the connecting component 630. The plate 680 may be made of, for example, a metal or a resin other than the metal. Also. A hole through which the fastener 640 is inserted is formed in the center of the plate 680.

The plate 680 and the connecting component 630 may be fixed with, for example, double-sided tape 681. By fixing with the double-sided tape 681, the plate 680 does not fall off from the outer peripheral edge portion 631 of the connecting component 630 during the fastening work of the fastener 640, and the fastener can be fastened efficiently. The double-sided tape is provided with a hole through which the fastener is inserted.

Further, the connecting component 630 and the electrode pad 673a of the sub-cabinet 670 may be fixed with, for example, conductive double-sided tape 682. The conductive double-sided tape 682 is provided to prevent the connecting component 630 on the electrode pad 673a from falling off during the fastening operation of the fastener. Further, since the conductive double-sided tape 682 has a resistance value, it is desirable that the area thereof is small. The conductive double-sided tape is provided with a hole through which the fastener is inserted.

As long as the area where the connection component 630 and the electrode pad 673a of the antenna pattern 671 come into direct contact with each other can be secured, the double-sided tape does not necessarily have to be a conductive double-sided tape, but may be a simple double-sided tape.

A method of connecting the metal body 610, the sub-cabinet 670, and the printed circuit board 620 by using the elastically deformable connecting component 630 will be described with reference to FIGS. 9 to 12.

As shown in FIGS. 9 and 10, a printed circuit board 620 is provided between the cabinet 602 and the sub-cabinet 670, electrically connected via the contact spring 683, and the connecting component 630 is placed on the sub-cabinet 670. Place.

As shown in FIGS. 11 and 12, in the connecting component 630, a fastener 640 (for example, a screw) is inserted into the insertion hole 632, and the tip of the fastener 640 protruding outward from the insertion hole 632 is a sub-cabinet. It is inserted into the insertion hole 672 of the 670 and fitted into the opening 603 opened above the cabinet 602 under the sub-cabinet 670.

By this fitting action, the head 641 of the fastener 640 presses the peripheral edge of the insertion hole 632 of the connecting component 630 via the plate 680, and this pressing force causes the radial direction (approximately horizontal) orthogonal to the insertion hole 632 of the connecting component 630. The connecting component 630 itself is elastically deformed in the direction). The fastener 640 has a male screw portion formed on the outer peripheral surface of the shaft portion 642, and at the time of fixing, the tip 643 of the male screw portion is fitted to the female screw portion on the inner wall surface of the opening 603 of the cabinet 602. .. The diameter of the head 641 of the fastener 640 is formed to be at least larger than the diameter of the insertion hole 632.

The side cross-sectional view shape of the connecting component 630 is, for example, a metal body in which the lateral region of the outer peripheral edge 631 that bulges out is gradually deformed from the prototype of the substantially circular shape before pressing to a substantially elliptical shape by pressing. The other lateral region of the bulging outer peripheral edge 631 is regulated by the convex portion 674 of the sub-cabinet 670 while abutting on the inner wall 612a of the left frame body 612 of the 610.

In this way, the convex portion 674 of the sub-cabinet 670 can limit the position of the connecting component 630. The position of the connecting component 630 is limited to some extent by the fastener 640, but further limited by the convex portion 674 ensures that the metal body 610 and the connecting component 630 are electrically connected.
It conducts with the antenna pattern 671 by elastically deforming in the fastening direction of the connecting component 630, and further conducts with the printed circuit board 620 under the sub-cabinet 670. The connecting component 630 is elastically deformed in the substantially horizontal direction to conduct conduction with the metal body 610 in the substantially vertical direction.

That is, when the other lateral region of the outer peripheral edge portion 631 abuts on the convex portion wall surface 674a, the bulging can be regulated and the optimum displacement amount can be obtained. For example, the optimum displacement amount is a value that does not damage the connecting component 630 due to excessive pressing that tightens the fastener 640 while electrically connecting the connecting component 630 to the metal body 610.
When both side regions of the outer peripheral edge portion 631 of the connecting component 630 come into contact with the metal body 610 and the convex portion 674, a large reaction force is generated, and the fastener 640 generates a reaction force opposite to the fastening direction. Excessive tightening is regulated.

The substantially elliptical connecting component 630 after elastic deformation is electrically connected to the electrode pad 673a on the sub-cabinet 670 in which the lower region 631a of the outer peripheral edge 631 is located in the substantially horizontal direction, and is on the back side of the sub-cabinet 670. The electrode pad 673b is electrically connected to the connection portion 621 of the printed circuit board 620 via the contact spring 683. Both electrode pads on the front and back of the sub-cabinet 673a. The 673b is electrically connected via the conductive film of the insertion hole 672.

In this way, the metal body 610 in the substantially vertical direction and the printed circuit board 620 in the substantially horizontal direction are electrically connected by the elastically deformed connecting component 630 or the like.
The side region of the outer peripheral edge 631 comes into contact with the inner wall 612a of the left frame body 612 of the metal body 610 located in the vertical direction, thereby electrically connecting the printed circuit board 620 and the metal body 610 via the connecting component 630. To do. A contact portion for connecting the electrode pad 673a of the sub-cabinet 670 and the metal body 610 is formed on the outer peripheral edge portion 631 of the connecting component 630 deformed into an elliptical shape.

By elastically deforming the connecting component 630, the printed circuit board 620 under the sub-cabinet 670 and the metal body 610 in a substantially vertical direction can be reliably conducted and electrically connected in a simple and compact structure. For example, power is supplied from the printed circuit board 620 in the substantially horizontal direction, and the metal body 610 in the vertical direction can function as an antenna.

As the ground, for example, the ground layer may be provided on the cabinet or the printed circuit board.

When the metal body 610 is grounded to the ground, a parallel resonance inverted-F antenna is formed by the antenna pattern 671 and the metal body 610 as shown in FIG. 20, so that a wide band antenna characteristic can be obtained.

In the above-described second embodiment, the convex portion is provided on the sub-cabinet, but the convex portion that regulates the displacement amount of the elastic deformation of the connecting component may be provided on the cabinet in the first embodiment.

[Embodiment 3]
Embodiment 3 of the present disclosure will be described with reference to FIGS. 13 to 19. FIG. 13 shows an enlarged view of a main part when the rear panel on the back side of the wireless device shown in FIG. 1 is removed. The plan view of the wireless device of the third embodiment has the same structure as the wireless device of the first embodiment shown in FIG. 1, and some overlapping description will be omitted.
In the wireless device of the third embodiment of the present disclosure, when the connecting component is elastically deformed, the connecting component is inserted into a protrusion standing on the cabinet without using a fastener, and the connecting component is inserted into the cabinet and the back surface of the sub-cabinet. It is configured to be pressed while being sandwiched between the stepped portion on the periphery of the protrusion receiving portion provided on the side.

As shown in FIG. 13, when the rear panel on the back side of the wireless device 1301 according to the embodiment of the present invention is removed, the cabinet 1302, the printed board 1320 provided with the print pattern, the sub-cabinet 1370, the cabinet 1302, and the sub-cabinet are provided. It includes a metal body 1310 that surrounds the periphery of 1370, a connecting component 1330, and a battery (not shown).

As shown in FIG. 14, the cabinet 1302 is provided under the sub-cabinet 1370, and has, for example, a plate-like structure made of a dielectric and having a substantially rectangular shape in a plan view.

The cabinet 1302 is configured to have a protrusion 1304 that is inserted into the insertion hole 1332 of the connection component 1330, which will be described later. Further, a plurality of claw receiving portions 1305 (see FIGS. 14 and 17) used when assembling and integrating the upper sub-cabinet 1370 are provided on the edge portion of the cabinet 1302.

A metal body 1310 is arranged on the outer peripheral edge of the cabinet 1302. The metal body 1310 is located on a plane perpendicular to the cabinet 1302, which is located on a substantially horizontal plane. The outer shape of the metal body 1310 is formed, for example, in a substantially rectangular frame shape, and two gaps 1313 are formed in each of the upward and downward frame bodies 1311. The metal body 1310 is, for example, conductive and is a metal material, and is made of a material such as SUS. A part of the cabinet 1302 is formed by digging down the thickness of the printed circuit board for mounting the printed circuit board. A printed circuit board 1320 in which a circuit or the like for mounting a wireless IC for transmitting and receiving wireless signals is printed is arranged between the cabinet 1302 and the sub-cabinet 1370.

The printed circuit board 1320 is formed in a substantially rectangular shape, for example, and a convex connecting portion 1321 is formed in the middle portion in the longitudinal direction. The convex connecting portion 1321 is formed so as to be close to the protruding portion 1304 of the cabinet 1302. The length of the printed circuit board 1320 in the longitudinal direction is formed shorter than the length between the frame bodies 1311 in the vertical direction. Further, the printed circuit board 1320 is configured to mount a wireless IC or the like and cover the surface portion thereof with a shield portion 1322 made of metal or the like except for the convex connection portion 1321.

The printed circuit board 1320 supplies power to the metal body 1310 on a vertical surface via a connecting component 1330 elastically deformed from the prototype.

As shown in FIG. 15, the sub-cabinet 1370 has, for example, a plate-like structure made of a dielectric and having a substantially rectangular shape in a plan view. As shown in FIG. 17, a substantially claw-shaped claw 1371 that meshes with the claw receiving portion 1305 of the cabinet 1302 is vertically installed on the peripheral edge of the sub-cabinet 1370 on the back surface side.

As shown in FIG. 16, on the back surface side of the sub-cabinet 1370, there is a storage portion for storing the protrusion receiving portion 1372 that receives the protrusion 1304 of the cabinet 1302, the step portion 1373 provided on the peripheral edge of the protrusion receiving portion 1372, and the printed circuit board 1320. 1375 is formed.

Next, the printed circuit board 1320 on a substantially horizontal surface between the cabinet 1302 and the sub-cabinet 1370 and the metal body 1310 on a surface perpendicular to the cabinet 1302 are electrically connected to each other via an elastically deformable connecting component 1330 described later. For example, the metal body 1310 is fed by the printed circuit board 1320 and functions as an antenna.

As shown in FIG. 16, the connecting component 1330 has, for example, a substantially circular structure, is made of an elastically deformable material, and its outer peripheral edge portion 1331 is made of at least a conductive material. An insertion hole 1332 is bored in the radial direction (vertical direction) at the central portion of the outer peripheral edge portion 1331 in the longitudinal direction. The diameter of the insertion hole 1332 is smaller than the diameter of the connecting component 1330.

A method of electrically connecting the printed circuit board to be placed on the cabinet and the metal body by using the elastically deformable connecting parts will be described with reference to FIGS. 16 to 19.

As shown in FIG. 16, the printed circuit board 1320 is placed on the cabinet 1302, and the protrusion 1304 of the cabinet 1302 is inserted into the insertion hole 1332 of the connecting component 1330. The outer peripheral edge portion 1331 of the connecting component 1330 and the connecting portion 1321 of the printed circuit board 1320 are electrically connected to each other in a conductive manner.

As shown in FIGS. 17 and 19, the cabinet 1302 is covered with a sub-cabinet 1370 from above, and a plurality of substantially hook-shaped claws 1371 of the sub-cabinet 1370 and a plurality of claw receiving portions 1305 of the cabinet 1302 are respectively provided. The cabinet 1302 and the sub-cabinet 1370 are integrated with the printed substrate 1320 sandwiched between them.

As shown in FIG. 18, at this time, the connecting component 1330 is pressed by the stepped portion 1373 on the peripheral edge of the protrusion receiving portion 1372 on the back surface side of the sub-cabinet.

That is, the step portion 1373 presses the peripheral edge of the insertion hole of the connecting component 1330 by this meshing action, and the connecting component itself is elastically deformed in the radial direction (substantially horizontal direction) orthogonal to the insertion hole 1332 of the connecting component 1330 due to this pressing force. To do. The diameter of the protrusion of the cabinet is formed to be at least smaller than the diameter of the insertion hole.

The side cross-sectional view shape of the connecting component is, for example, a metal body 1310 in which the lateral region of the outer peripheral edge portion 1331 that bulges out is gradually deformed from the prototype of the substantially circular shape before pressing to a substantially elliptical shape by pressing. It comes into contact with the inner wall 1312a of the left frame body 1312.

The substantially elliptical connecting component after the elastic deformation is electrically deformed in the vertical direction so that the lower region of the outer peripheral edge portion 1331 is electrically connected to the connecting portion 1321 of the printed circuit board 1320 located in the substantially horizontal direction. Be connected. Further, the connecting component is electrically connected to the inner wall 1312a of the left frame body 1312 of the metal body 1310 in which the lateral region of the outer peripheral edge portion 1331 is located in the substantially vertical direction by elastically deforming in the substantially horizontal direction. ..

In this way, the metal body 1310 in the substantially vertical direction and the printed circuit board 1320 in the substantially horizontal direction are electrically connected by being conducted by the elastically deformed connecting component 1330.
By contacting the lateral region of the outer peripheral edge portion 1331 with the inner wall 1312a of the left frame body 1312 of the metal body 1310 located in the substantially vertical direction, the metal body in the substantially vertical direction with the printed circuit board 1320 via the connecting component 1330. Electrically connect to 1310. The outer peripheral edge portion 1331 of the connecting component 1330 deformed into an elliptical shape is formed with a connecting portion 1321 of the printed circuit board 1320 and a contact portion connecting to the metal body 1310, respectively.

In this example, the connecting parts are inserted and fixed through the protrusions on the cabinet, and the connecting parts are pressed by the stepped portion of the sub-cabinet, as compared with the connecting method using the fasteners in the first and second embodiments. Therefore, stable continuity can be obtained between the printed circuit board and the metal body. Further, when the female screw portion cannot be formed in the opening of the cabinet, the connection component and the metal body can be made conductive by the engaging action of the claws between the cabinets.

By elastically deforming the connecting component 1330, the printed circuit board 1320 under the sub-cabinet 1370 and the metal body 1310 in a substantially vertical direction can be reliably and electrically connected with a simple and compact structure. For example, power is supplied from the printed circuit board 1320 in the substantially horizontal direction, and the metal body 1310 in the vertical direction can function as an antenna.

The plate 680 for uniformly deforming the connecting parts according to the second embodiment may be used for uniformly deforming the connecting parts according to the first embodiment.

In each of the above-described embodiments, a frame-shaped metal body is used for the surface perpendicular to the cabinet, but a metal body having an acute-angled surface (inclined surface) with respect to the cabinet may be used. Good. It is possible to reliably and electrically connect such an inclined metal body and a printed circuit board on a substantially horizontal surface with a connecting component that elastically deforms.

The connecting part has a substantially cylindrical structure as an example, but by elastically deforming, it is possible to electrically connect the contact point of one part on a substantially horizontal surface and the contact point of another part on a vertical surface. If possible, other structures such as a hollow cylindrical structure, an elliptical column structure, a prismatic structure, and a polygonal column structure may be used. Further, although the outer peripheral edge of the connecting component is made of a conductive material as an example, the entire part including the inside of the component may be made of a conductive material.

The metal body has been described using a frame-shaped structure as an example, but the structure of the metal body is not limited to the frame shape, and other metal parts and antennas having various shapes constituting charging terminals of electronic devices and the like are used. It also includes metal parts of various shapes that act as elements. A metal body including a metal component on a plane perpendicular to the cabinet can be electrically connected by the elastically deformable connecting component described above.

The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention. Furthermore, new technical features can be formed by combining the technical means disclosed in each embodiment.

101,601,1301 Radio device 102 Display unit 201,602,1302 Cabinet 202,603 Openings 210,610,1310 Metal body 211,611,1311 Upper and lower frame bodies 212,612,1312 Left and right frame bodies 212a, 612a, 1312a Inner wall 213,613.1313 Gap 220,620,1320 Printed board 221,621,1321 Convex connection part 221a Through hole 222,622,1322 Shield part 230,630,1330 Connection part 231,631,1331 Outer peripheral edge part 231a, 631a Lower area 231b, 631b Side area 232,632,1332 Insertion holes 240,640 Fasteners 241,641 Head 242,642 Shaft 243,643 Tip 250,650 Battery 260,660 Imaging element 670,1370 Sub-cabinet 671 Antenna Pattern 672 Insertion hole 673a Front side electrode pad 673b Back side electrode pad 674 Convex part 674a Convex part wall surface 675, 1375 Storage part 675a Ceiling part 680 Plate 681 Double-sided tape 682 Conductive double-sided tape 683 Contact spring 1304 Protrusion part 1305 Claw receiving part 1371 Claw 1372 Projection receiving part 1373 Step part

Claims (10)

With the cabinet
A printed circuit board on which a print pattern is provided and
A metal body arranged on the peripheral edge of the cabinet and
A wireless device comprising: a connecting component that electrically connects the printed circuit board to be placed on the cabinet and the metal body by elastically deforming from the prototype. It has a fastener that is fastened to the opening that opens to the cabinet while being inserted into the insertion hole provided in the connection component.
When the fastener is fastened, the connecting component is elastically deformed in the fastening direction to be electrically connected to the printed circuit board.
The wireless device according to claim 1. The connecting component conducts with the metal body in a substantially vertical direction by elastically deforming in a substantially horizontal direction.
2. The wireless device according to claim 2. A sub-cabinet that sandwiches the printed circuit board with the cabinet is provided.
The wireless device according to claim 1 or 2, wherein the wireless device is characterized by the above. The cabinet or the sub-cabinet is provided with a convex portion that regulates the amount of displacement of the connecting component that elastically deforms in a substantially horizontal direction.
The wireless device according to claim 1 or 4, wherein the wireless device is characterized by the above. The sub-cabinet has an antenna pattern
The connecting component conducts with the antenna pattern by elastically deforming in the fastening direction.
The wireless device according to claim 4 or 5. The connecting component conducts with the metal body in a substantially vertical direction by elastically deforming in a substantially horizontal direction.
The wireless device according to claim 6. The cabinet has a protrusion through which the connecting component is inserted.
The wireless device according to claim 1. A sub-cabinet provided with a protrusion receiving portion for engaging the protrusion is provided.
The connecting component inserted through the protrusion is elastically deformed in the vertical direction to conduct the printed circuit board.
8. The wireless device according to claim 8. The connecting component conducts with the metal body in a substantially vertical direction by elastically deforming in a substantially horizontal direction.
9. The wireless device according to claim 9.

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