JP7297999B2 - Power supply module, AC adapter - Google Patents

Description

The present invention relates to an AC adapter and a power supply module that constitutes the AC adapter.

In recent years, an AC adapter that converts AC power supplied from an outlet, which is an output port of a commercial AC power supply, into DC power, and a plug to be inserted into the outlet and an AC/DC conversion circuit are housed in one housing. AC adapters are widely used. In such an AC adapter, an output port for outputting DC power is provided on a wall surface of the housing that is different from the wall surface on which the plug is provided.

As such an output port, a USB Type-A connector jack conforming to the USB (Universal Serial Bus) standard is often adopted. Also, in recent years, a USB Type-C connector jack may be adopted. In this case, the AC/DC conversion circuit is configured to comply with the USB PD (USB Power Delivery) standard.

In the AC adapter as described above, in order to connect the first electrode and the second electrode constituting the opposite end of the plug to the outlet and the input port of the AC/DC conversion circuit, Conductive means such as solder and screws are used.

However, in these cases, processes such as soldering or screw tightening are required to establish continuity between the first electrode and the second electrode and the input port of the AC/DC conversion circuit.

One aspect of the present invention has been made in view of the problems described above. The object is to provide an AC adapter capable of simplifying the manufacturing process of the AC adapter. Another object of the present invention is to provide a power supply module capable of simplifying the process of connecting the first electrode, the second electrode, and another port.

A power supply module according to a first aspect of the present invention comprises a pair of first and second plugs, each of which is a strip-shaped metal plate, and a pair of plugs, each of which is a metal plate, and one end of each of which is the a first electrode and a second electrode configured to communicate with each of the first plug and the second plug; and a frame housing and holding the plug, the first electrode, and the second electrode. , the other end of the first electrode is a first leaf spring that is pulled out of the frame and that is electrically connected to an input port of a board on which an AC/DC conversion circuit is mounted. and the other end of the second electrode is a second plate spring drawn out of the frame, the second plate electrically connected to the input port of the board on which the AC/DC conversion circuit is mounted. Each of the first plate spring and the second plate spring is configured by a spring, and the direction in which the plug protrudes from the frame is defined as a first direction. is pulled out in a direction opposite to the first direction at a predetermined parallel position, and is substantially parallel to a first plane along the first leaf spring and the second leaf spring at the predetermined position of the frame; , the substrate is placed between the first leaf spring and the second leaf spring at a position outside the frame substantially coinciding with a second plane spaced apart from the first plane by a predetermined distance. A gripping portion is provided for fixing the substrate by sandwiching, and each of the first leaf spring and the second leaf spring resists a force acting in a direction from the second plane toward the first plane. The first leaf spring, the second leaf spring, and the input port are elastically deformed, and the board is sandwiched between the first leaf spring, the second leaf spring, and the gripping portion, and thus the board is held outside the frame. It adopts a configuration that conducts.

According to the above configuration, the elasticity of the first leaf spring and the second leaf spring can be utilized when the first electrode and the second electrode are electrically connected to another port. That is, it is possible to bring the first electrode and the second electrode into good contact with another port without using conductive means such as solder and screws.

Further, according to the above configuration, by inserting the substrate between the first leaf spring and the second leaf spring drawn out along the first plane and the holding portion defining the second plane, the main power feeding is performed. A substrate can be bonded to the module. Since another port can be easily formed on the main surface of the substrate, simply inserting the substrate on which another port is formed between the first leaf spring and the second leaf spring and the holding portion, The first and second electrodes can be electrically connected to another port. Therefore, the power supply module according to the first aspect can simplify the process of establishing electrical continuity between the first electrode and the second electrode and another port. In addition, according to the above configuration, the first leaf spring, the second leaf spring, and the input port are connected to each other by sandwiching the substrate between the holding portion, the first leaf spring, and the second leaf spring at a position outside the frame. Conductive outside the frame. Therefore, it is possible to easily confirm that the input port is electrically connected to the first leaf spring and the second leaf spring visually or using an image.

According to a second aspect of the present invention, in the power supply module according to the first aspect described above, each of the first leaf spring and the second leaf spring is arranged substantially within the first plane. a second area arranged to approach the second plane from the first plane; and a third area arranged to move away from the second plane, wherein the frame includes the first A configuration is adopted in which a support is further provided along the back surface of the first region of each of the leaf spring and the second leaf spring.

According to the above configuration, since the frame is further provided with a support, when another substrate having a port formed thereon is inserted between the first leaf spring and the second leaf spring and the holding portion, Excessive bending of the first region of each of the first leaf spring and the second leaf spring can be prevented. Therefore, each of the first leaf spring and the second leaf spring can be pressed more strongly against another port.

A power supply module according to a third aspect of the present invention is, in the above-described first aspect or second aspect, wherein the frame includes a first frame and a second frame, the plug, the first electrode , the second electrode, and the second frame are configured as a common module to which a plurality of types of substrates or the first frame can be attached.

According to the above configuration, the versatility of the module is improved, and mass production of the module contributes to, for example, a reduction in manufacturing cost.

An AC adapter according to a fourth aspect of the present invention is an AC adapter that outputs DC power supplied from the power supply module according to any one of aspects 1 to 3, the substrate, and the AC/DC conversion circuit. a port; and a housing that accommodates the board, the AC/DC conversion circuit, and the output port.

A power supply module according to an aspect of the present invention can be suitably used for an AC adapter as described above.

In the AC adapter according to a fifth aspect of the present invention, in the fourth aspect described above, an input port for inputting AC power to the AC/DC conversion circuit is provided on a portion of the outer edge of one main surface of the substrate. is provided, and the board includes the first leaf spring and the second leaf spring, and the gripping portion so that the input port is biased by the first leaf spring and the second leaf spring. It adopts a configuration that is grasped by

According to the above configuration, the first electrode, the second electrode, and the input port are electrically connected simply by inserting the substrate on which the input port is formed between the first leaf spring, the second leaf spring, and the grip. be able to. Therefore, the manufacturing process of the AC adapter according to the fifth aspect can be simplified.

An AC adapter according to a sixth aspect of the present invention is an AC adapter according to the fifth aspect described above, wherein the housing includes: (1) a pair of bottoms that are substantially parallel to the one main surface of the substrate and sandwich the substrate; and (2) a pair of side walls and a front wall that are substantially perpendicular to the one main surface and surround the substrate on three sides, and the frame serves as a rear wall that sandwiches the substrate together with the front wall. The pair of side walls has a pair of slots with a spacing substantially corresponding to the width of the substrate and capable of moving the substrate along the first direction, the slots defining one main surface of the substrate. A configuration is employed in which a pair of slots are provided to limit movement along the normal direction.

According to the above configuration, the pair of side walls restrict movement along the width direction (horizontal direction) of the substrate, and the front wall and the frame restrict movement along the direction perpendicular to the width direction (front-rear direction) of the substrate. However, the pair of slots restricts the movement along the normal direction (vertical direction) of the pair of main surfaces of the substrate. That is, the substrate can be fixed in the housing without using fixing means such as adhesives or screws. Therefore, the AC adapter according to the sixth aspect can further simplify the manufacturing process.

In the AC adapter according to a seventh aspect of the present invention, in the sixth aspect described above, the output port is arranged in an outer edge region of the outer edge region of the substrate, the outer edge region being close to the front wall. A region corresponding to the output port of is provided with an opening.

According to the above configuration, the output port can be exposed from the opening only by integrally molding the housing and moving the substrate along the pair of slots. Therefore, the AC adapter according to the seventh aspect can further simplify the manufacturing process.

An AC adapter according to an eighth aspect of the present invention is an AC adapter according to the sixth aspect or the seventh aspect described above, wherein each of the pair of bottom walls has a linear projection protruding from the inner wall of the bottom wall. Alternatively, a configuration is adopted in which a plurality of ribs are formed.

According to the above configuration, a space corresponding to at least the height of the rib can be provided between the substrate and the AC/DC conversion circuit housed in the housing and each of the pair of bottom walls. Further, even when pressure is applied to the pair of bottom walls in a direction that crushes the housing, it is possible to prevent the substrate and the AC/DC conversion circuit from coming into direct contact with each of the pair of bottom walls. . Therefore, the AC adapter according to the eighth aspect can improve resistance to heat generated by the AC/DC conversion circuit.

According to one aspect of the present invention, it is possible to provide an AC adapter capable of simplifying the manufacturing process of the AC adapter. Further, according to one aspect of the present invention, it is possible to provide a power supply module that can simplify the step of connecting the first electrode, the second electrode, and another port.

1A and 1B are a perspective view and an exploded perspective view of an AC adapter according to an embodiment of the present invention; FIG. 2 is a plan view of a housing included in the AC adapter shown in FIG. 1; FIG. 2 is a plan view of a substrate included in the AC adapter shown in FIG. 1; FIG. 2 is a perspective view of a plug, electrode pairs, and a second frame included in the AC adapter shown in FIG. 1; FIG. 5 is a perspective view of the electrode pair shown in FIG. 4; FIG. FIG. 5 is a side view of a first plug that constitutes the plug shown in FIG. 4; Explanatory drawings 35 and 36 are side views of the second frame included in the AC adapter shown in FIG. FIG. 37 is a side view of the first frame included in the AC adapter shown in FIG. 1;

[Outline of AC adapter]
An AC adapter 1 according to one embodiment of the present invention will be described with reference to FIGS. 1 to 6. FIG. FIG. 1 is a perspective view and an exploded perspective view of an AC adapter 1. FIG. FIG. 2 is a plan view of the housing 20 included in the AC adapter 1. FIG. FIG. 3 is a plan view of the substrate 30 provided in the AC adapter 1. FIG. FIG. 4 is a perspective view of the plug 11, the electrode pair 12, and the second frame 132 included in the AC adapter 1. FIG. FIG. 5 is a perspective view of the electrode pair 12. FIG. FIG. 6 is a side view of the first plug 111 that constitutes the plug 11. FIG. In the present embodiment, the main surfaces 30a and 30b, which are the pair of main surfaces of the substrate 30 of the AC adapter 1, are parallel to the zx plane, and the direction in which the plug 11 projects from the frame 13 is An orthogonal coordinate system is defined so that the z-axis positive direction.

As shown in FIG. 1, the AC adapter 1 includes a power supply module 10, a housing 20, and a substrate 30. As shown in FIG. Feeding module 10 is also an embodiment of the present invention.

The power supply module 10 supplies AC power supplied from an outlet, which is an output port of a commercial AC power supply, to an AC/DC conversion circuit 33 (not shown in FIG. 1) via an input port 31 provided on a substrate 30. do. The AC/DC conversion circuit 33 converts the supplied AC power into DC power having a predetermined voltage ratio.

In this embodiment, the output port 32 is a USB Type-A connector jack conforming to the USB (Universal Serial Bus) standard. Therefore, a USB cable having a USB Type-A connector plug at one end can be connected to the output port 32 . The output port 32 outputs DC power supplied from the AC/DC conversion circuit 33 to an external terminal connected via a USB cable. 1, illustration of a specific structure of the output port 32 is omitted.

However, the output port 32 is not limited to a USB Type-A connector jack conforming to the USB standard, and can be appropriately selected from commercially available connector jacks depending on the application. Examples of other connector jacks include a USB Type-C connector jack. Further, when a USB Type-C connector jack is adopted as the output port 32, the AC/DC conversion circuit 33 may be configured to comply with the USB PD (USB Power Delivery) standard.

The AC adapter 1 configured as described above is an example of an AC/DC converter, and functions as a charger for charging an external terminal using a commercial AC power supply.

The configuration of the AC adapter 1 will be described below.

<Power supply module>
The power supply module 10, as shown in the exploded perspective view of FIG. 1, includes a plug 11 that can be plugged into an outlet, an electrode pair 12, and a frame 13. As shown in FIG. The frame 13 has a first frame 131 and a second frame 132 .

(plug)
The plug 11 includes a first plug 111 and a second plug 112, which are paired together. Each of the first plug 111 and the second plug 112 is a strip-shaped metal plate.

As shown in FIG. 4, the first plug 111 and the second plug 112 are electrically insulated and connected (fixed) by the connecting portion 14 so that their relative positions do not change. Columnar protrusions 15 are formed at both ends of the connecting portion 14 along the y-axis direction. The connecting portion 14 is obtained by molding a resin material.

In the present embodiment, the plug 11 adopts a retractable structure that can be protruded from the frame 13 or housed in the frame 13 . However, plug 11 may employ a fixed configuration in which it remains protruding from frame 13 . In the following description, the power supply module 10 in which the plug 11 protrudes from the frame 13 will be used. The plug 11 protrudes from the frame 13 in the positive z-axis direction. The z-axis positive direction is an example of the first direction.

(electrode pair)
The electrode pair 12 has a first electrode 121 and a second electrode 122 . Each of the first electrode 121 and the second electrode 122 is made of a strip-shaped metal plate.

As shown in FIGS. 4, 5, and 6, the first electrode 121 is formed by cutting a metal plate into an "L" shape, and then forming an end 121a as one end and an end 121a as the other end. is obtained by bending the first plate spring 121c. A portion of the first leaf spring 121c other than the end portion 121a and the first leaf spring 121c is referred to as an intermediate portion 121b. The portions corresponding to the corners of the "L" shape in the cut-out state are located in the intermediate portion 121b.

The second electrode 122 is configured similarly to the first electrode 121 . However, the first plug 111 and the second plug 112 are located on the same yz plane, and the first leaf spring 121c and the second leaf spring 122c are located on the plane P1 described later. Further, in order for the first electrode 121 to conduct the first plug 111 and the first leaf spring 121c, and for the second electrode 122 to conduct the second plug 112 and the second leaf spring 122c, The portion 122b is formed smaller than the intermediate portion 121b of the first electrode 121 .

Each of the ends 121a and 122a (see FIG. 5), which is one end of each, is configured to conduct with each of the first plug 111 and the second plug 112, respectively.

Only the first plug 111 of the plugs 11 is shown in FIG. 6, the first plug 111 in a state where the plug 11 is accommodated in the frame 13 is indicated by solid lines, and the first plug 111 in a state in which the plug 11 protrudes from the frame 13 is indicated by phantom lines. Regarding the contents described with reference to FIG. 6, the first plug 111 and the second plug 112 are configured similarly.

As shown in FIG. 6, the first electrode 121 is bent so that the angle between the end portion 121a and the intermediate portion 121b is approximately 135°. A recess 121d is formed at the boundary between the end portion 121a and the intermediate portion 121b.

When the plug 11 is accommodated in the frame 13, the end of the first plug 111 opposite to the side where it is inserted into the outlet) is separated from the end 121a. That is, the first plug 111 and the end portion 121a are not electrically connected.

On the other hand, when the first plug 111 is rotated from the positive direction of the x-axis to the positive direction of the z-axis around the central axis of the projection 15 in order to protrude the plug 11 from the frame 13, the end portion 111a pushes the end portion 121a. The end portion 121a and part of the intermediate portion 121b are bent by bending. Therefore, since the end portion 121a is pressed toward the first plug 111, the first plug 111 and the end portion 121a are electrically connected well.

When the plug 11 protrudes from the frame 13 (that is, the first plug 111 protrudes in the positive direction of the z-axis), the end portion 111a fits into the recess 121d. At this time, the end portion 121a is pressed toward the first plug 111 and the end portion 111a is fitted into the recess 121d, so that the first plug 111 is fixed with a moderate force. In addition, since the end portion 111a is fitted into the concave portion 121d, a click feeling is generated, so that the power supply module 10 can transmit to the user's hand that the plug 11 has protruded from the frame 13. FIG.

Also, the other end portions of the first electrode 121 and the second electrode 122 are respectively pulled out to the outside of the frame 13 . The other ends of the first electrode 121 and the second electrode 122 are formed by bending a metal plate to form a first leaf spring 121c and a second leaf spring 122c, respectively. The first leaf spring 121c and the second leaf spring 122c will be described later with reference to FIGS. 4 and 5. FIG.

(flame)
The frame 13 has a first frame 131 and a second frame 132 . Each of the first frame 131 and the second frame 132 is obtained by molding a resin material.

The first frame 131 functions as an exterior panel of the AC adapter 1 together with a housing described later. Therefore, the outer surface of the first frame 131 is configured to smoothly connect with the outer surface of the housing 20 . A pair of grooves for accommodating the plug 11 is formed on the outer surface of the first frame 131 . The inner surface of the first frame 131 (the surface on the side of the second frame 132 to be described later) is configured to match the surface of the second frame 132 on the side of the first frame 131 . By aligning the inner surface of the first frame 131 with the surface of the second frame 132 on the side of the first frame 131 in this way, when manufacturing a plurality of types of AC adapters 1, each The first frame 131 and the substrate 30 are designed as parts unique to the type of AC adapter 1, and the plug 11, the first electrode 121, the second electrode 122, and the second electrode are designed as parts common to a plurality of types of AC adapters 1. Frame 132 can be designed. That is, since the plug 11, the first electrode 121, the second electrode 122, and the second frame 132 can be used as a common module in a plurality of types of AC adapters 1, the manufacturing unit cost of the AC adapter 1 can be reduced.

The inner side of the first frame 131 is formed with a recess so as to roughly follow the shape of the outer surface. A second frame 132 and an electrode pair 12 are arranged in the recess.

The second frame 132 has irregularities formed on both main surfaces, but the main part is a plate-like member that is two-dimensionally extended. The second frame 132 is fixed to the first frame 131 with two screws (not shown in the exploded perspective view of FIG. 1) so that the main portion of the second frame 132 extends along the xy plane. The second frame 132 may be configured to be fixed to the first frame 131 by a snap fit method without using screws or the like.

In addition, between the surfaces of the first frame 131 and the second frame 132 facing each other, (1) a structure for holding the connecting portion 14 and the projection 15 in a rotatable state around the central axis of the projection 15; 2) A structure in which the electrode pair 12 is fixed by sandwiching intermediate portions 121b and 122b of the first electrode 121 and the second electrode 122 that constitute the electrode pair 12 is formed. The first frame 131 and the second frame 132 configured as described above hold the plug 11 and the electrode pair 12 (the first electrode 121 and the second electrode 122) by sandwiching them.

The frame 13 accommodates the board 30 together with the housing 20 which will be described later. At this time, the frame 13 functions as a rear wall that sandwiches the substrate 30 together with the front wall 25 .

(Structure for holding substrate)
As shown in FIGS. 4 and 5, each of the first leaf spring 121c and the second leaf spring 122c includes first regions 121c1 and 122c1, second regions 121c2 and 122c2, and third regions 121c3 and 122c3, respectively. It is

The first regions 121c1 and 122c1, which are parts of the first leaf spring 121c and the second leaf spring 122c, extend along a plane P1, which is a predetermined plane parallel to the zx plane, toward the z-axis negative direction. is pulled out. Therefore, the first regions 121c1 and 122c1 are arranged substantially within the plane P1. Note that the plane P1 is an example of a plane substantially parallel (parallel in this embodiment) to the z-axis positive direction, and is an example of a first plane.

A second frame 132 of the frame 13 is provided with holding portions 132a to 132c defining a plane P2 substantially parallel to the plane P1 and separated from the plane P1 by a predetermined distance D. Plane P2 is an example of a second plane. Each of the gripping portions 132a to 132c is a plate-like projection projecting in the negative z-axis direction from the surface of the second frame 132 arranged along the xy plane. Each of the gripping portions 132a to 132c defines a plane P2 by forming a plane at the lower end (the end on the positive y-axis direction side).

The second regions 121c2 and 122c2 are regions following the first regions 121c1 and 122c1. The second regions 121c2 and 122c2 are configured to approach the plane P2 from the plane P1 by bending the metal plate.

The third regions 121c3 and 122c3 are regions following the second regions 121c2 and 122c2, and constitute the ends of the first plate spring 121c and the second plate spring 122c. The third regions 121c3 and 122c3 are configured to move away from the plane P2 by bending the metal plate.

With the configuration as described above, a plate-like member (that is, the substrate 30 ) can be inserted.

The thickness of the substrate 30 is thinner than the distance D and thicker than the minimum distance between each of the first electrode 121 and the second electrode 122 and the plane P2 in the state shown in FIG. This minimum value is the distance between the vertex of each of the first electrode 121 and the second electrode 122 and the plane P2. Note that the vertex of the first electrode 121 is located on the boundary between the second region 121c2 and the third region 121c3, and the vertex of each of the second electrodes 122 is located on the boundary between the second region 122c2 and the third region 122c3. To position.

Note that when supports 1311 and 1312, which will be described later, are arranged behind the first regions 121c1 and 122c1 as in the present embodiment, the thickness of the substrate 30 is thinner than the interval D by a predetermined thickness. is preferred. This predetermined thickness is the thickness of the bent boundary region (the length along the y-axis direction) which is the boundary region between the first regions 121c1 and 122c1 and the second regions 121c2 and 122c2.

According to the above configuration, each of the first leaf spring 121c and the second leaf spring 122c and the gripping portions 132a to 132c can grip the substrate 30. As shown in FIG.

In other words, after determining the thickness of the substrate 30, the distance D can be determined in consideration of the configurations of the first leaf spring 121c and the second leaf spring 122c. The interval D can be arbitrarily determined by adjusting the positions of the grips 132a to 132c in the y-axis direction.

Each of the first leaf spring 121c and the second leaf spring 122c is elastically deformed against a force acting in the direction from the plane P2 toward the plane P1 (a force acting along the positive direction of the y-axis). Further, since the second regions 121c2 and 122c2 are inclined from the plane P1 toward the plane P2, the substrate 30 is positioned between each of the first leaf spring 121c and the second leaf spring 122c and the holding portions 132a to 132c. When the first leaf spring 121c and the second leaf spring 122c are inserted, each of the first leaf spring 121c and the second leaf spring 122c can be elastically deformed without causing problems such as being caught.

Further, on the first frame 131 of the frame 13, supports 1311 and 1312 are arranged along the rear surfaces of the first regions 121c1 and 122c1 of the first leaf spring 121c and the second leaf spring 122c, respectively. Here, the rear surfaces of the first regions 121c1 and 122c1 are surfaces opposite to the second regions 121c2 and 122c2 and the third regions 121c3 and 122c3. In this embodiment, the supports 1311 and 1312 are composed of a main portion, which is a plate-like member substantially parallel to the zx plane, and a pair of reinforcing portions provided on both sides of the main portion, which are plates substantially parallel to the yz plane. It is composed of a pair of reinforcing parts that are shaped members.

The structure of the AC adapter 1 will be supplemented below with reference to FIG. Explanatory drawings 35 and 36 of FIG. 7 are side views of the second frame 132 provided in the AC adapter 1. FIG. Explanatory drawing 35 shows a state in which the substrate 30 is omitted from the state of explanatory drawing 36 . FIG. 37 is a side view of the first frame 131 included in the AC adapter 1. FIG. An explanatory diagram 37 shows a state in which the first frame 131 is added to the state of the explanatory diagram 36. FIG. Explanatory diagrams 35 to 37 are obtained by viewing the interior of the AC adapter 1 from the negative direction of the y-axis in the coordinate system shown in FIG. 36 and 37, the first leaf spring 121c and the second leaf spring 122c, which are hidden behind the substrate 30, are indicated by broken lines. 36 and 37, the region where the first leaf spring 121c and the first terminal 311 of the input port 31 are electrically connected, and the second leaf spring 122c and the second terminal 312 of the input port 31 are electrically connected. Each conducting region is illustrated by a dashed line. 36 and 37, the illustration of the first terminal 311 and the second terminal 312 is omitted because it overlaps with the first leaf spring 121c and the second leaf spring 122c and is difficult to see.

35 corresponds to a drawing showing each member shown in FIG. 4 from another angle. As shown in FIG. 35, the grips 132a to 132c are provided on the outer surface of the second frame 132 at positions substantially facing the first leaf spring 121c and the second leaf spring 122c. As a result, the grasping portions 132a to 132c can reliably receive the force generated by the elastic deformation of each of the first leaf spring 121c and the second leaf spring 122c, so that the substrate 30 can be fixed more stably. .

FIG. 36 shows a state in which the board 30 is fixed by sandwiching the board 30 between the first leaf spring 121c, the second leaf spring 122c, and the grips 132a to 132c in the configuration of FIG. In the above state, the first leaf spring 121c and the first terminal 311 of the input port 31 are electrically connected, and the second leaf spring 122c and the second terminal 312 of the input port 31 are electrically connected.

Explanatory drawing 37 shows a state in which the first frame 131 is attached in the configuration of explanatory drawing 36 . The first frame 131 accommodates the plug 11 , the intermediate portion 121 b of the first electrode 121 and the intermediate portion 122 b of the second electrode 122 together with the second frame 132 .

On the other hand, as described above, the first leaf spring 121c and the second leaf spring 122c are drawn out of the frame 13 including the first frame 131 and the second frame 132 . This means that the first plate spring 121c, the second plate spring 122c, and the holding portions 132a to 132c sandwich the substrate 30 at a position outside the frame 13. As shown in FIG. Therefore, as shown in explanatory diagrams 36 and 37, the first plate spring 121c and the first terminal 311 are electrically connected outside the frame 13, and the second plate spring 122c and the second terminal 312 are connected to the frame 13. outside of the According to this configuration, in the process of inserting the substrate 30 between the gripping portion 132a and the first leaf spring 121c and between the gripping portions 132b, 132c and the second leaf spring 122c, the substrate 30 is correctly inserted. Moreover, it is possible to visually check or photograph whether each of the first leaf spring 121c and the second leaf spring 122c and each of the first terminal 311 and the second terminal 312 is electrically connected. In this case, of the pair of main surfaces of the substrate 30, the main surface 30a on which the input port 31 is mounted (the rear surface of the substrate 30 shown in explanatory diagrams 36 and 37) can be seen obliquely.

Further, the module shown in FIG. 35, the substrate 30 attached to the common module including the plug 11, the electrode pair 12, and the second frame 132, the first frame 131, the housing 20, etc., are not standardized. Or it may be substitutable for the shape. In other words, the plug 11, the electrode pair 12 (the first electrode 121 and the second electrode 122), and the second frame 132 preferably form a common module when manufacturing multiple types of AC adapters 1. FIG. By using the plug 11, the electrode pair 12, and the second frame 132 as a common module, any of the plurality of types of substrates 30, any of the plurality of types of first frames 131, and any of the plurality of types of housings 20 can be used as appropriate. A desired type of AC adapter 1 can be manufactured by selecting and combining with a common module. This improves the versatility of the module shown in FIG. 35 and contributes to mass production of the module, for example, to reduce the manufacturing unit cost.

<Case>
The housing 20 is obtained by molding a resin material. As shown in the exploded perspective view of FIG. 1 and FIG. 2, the housing 20 includes bottom walls 21 and 22 which are examples of a pair of bottom walls, side walls 23 and 24 which are examples of a pair of side walls, and a front wall 25. and have.

The outer surfaces of bottom walls 21, 22, side walls 23, 24, and front wall 25 are configured to be generally planar. However, the bottom walls 21 and 22 are configured such that the central region protrudes outward as compared to the outer edge region. The boundary between the front wall 25 and the side walls 23 and the boundary between the front wall 25 and the side walls 24 are both rounded corners so as to form smooth curved surfaces.

The bottom walls 21 and 22 are substantially parallel to the main surfaces 30a and 30b of the substrate 30 and sandwich the substrate 30 therebetween.

The side walls 23, 24 and the front wall 25 are substantially perpendicular to the main surfaces 30a, 30b and surround the substrate 30 on three sides. Further, the side walls 23 and 24 sandwich the substrate 30, and the front wall 25 sandwiches the substrate 30 together with the frame 13 described above.

In this embodiment, the housing 20 and the frame 13 are welded together with the substrate 30 accommodated therein. However, the method of joining the housing 20 and the frame 13 is not limited to welding, and can be selected as appropriate.

The substrate 30 is thus sandwiched from four sides by the housing 20 and the frame 13 . Further, the area of the substrate 30 where the input port 31 is formed is gripped by each of the first leaf spring 121c and the second leaf spring 122c and the gripping portions 132a to 132c.

In addition, on the inner surfaces (inner walls) of the side walls 23 and 24, the spacing is substantially equal to the width of the substrate 30 (the length along the x-axis direction), and the substrate 30 is positioned in the positive z-axis direction and the negative z-axis direction. A pair of slots 231 and 241 are provided which are movable along (see FIG. 2). A region R30 indicated by a phantom line in FIG. 2 is a region in which the substrate 30 is to be accommodated. Slots 231 and 241 are grooves formed in the inner walls of side walls 23 and 24 . Slots 231 and 241 restrict movement of 30a and 30b on substrate 30 along the normal direction (y-axis direction).

As will be described later, in this embodiment, the output port 32 is arranged in an outer edge region of the substrate 30 that is close to the front wall 25 . Therefore, an opening 251 is provided in the area corresponding to the output port 32 of the front wall 25 .

A guide groove 252 is formed in a region surrounding the opening 251 of the front wall 25 so that the thickness of the guide groove 252 is reduced over a constant width. The guide groove 252 is configured such that the outer edge of the output port 32 fits into the guide groove 252 when the substrate 30 is accommodated in the housing 20 and the frame 13 is fused. Therefore, the output port 32 is held in its position by the guide groove 252 .

Guide claws 253 and 254 along the opening 251 are provided near the long sides of the rectangular opening 251 . The guide claws 253 and 254 are plate-like members protruding from the inner wall of the front wall 25 in the positive z-axis direction.

The bottom wall 21 is formed with ribs 255 , 256 , 257 linearly projecting from the inner wall of the bottom wall 21 . The bottom wall 22 is formed with ribs 258 , 259 , 260 linearly projecting from the inner wall of the bottom wall 22 .

In this embodiment, each of the bottom walls 21, 22 is provided with three ribs 255-257 and three ribs 258-260, respectively. However, the number of ribs formed on each of bottom walls 21 and 22 is not limited, and may be one or more. Design parameters such as the height and number of ribs can be appropriately set in consideration of the strength and heat dissipation characteristics of the housing 20 .

<Substrate>
The substrate 30 is a rigid plate-like member whose main portion is made of a dielectric material. A printed circuit board can be adopted for the substrate 30 . The thickness of the substrate 30 is thinner than the distance D shown in FIG. 4 and thicker than the minimum distance between each of the first electrode 121 and the second electrode 122 and the plane P2 in the state shown in FIG. Further, when supports 1311 and 1312, which will be described later, are arranged behind the first regions 121c1 and 122c1 as in the present embodiment, the thickness of the substrate 30 is thinner than the interval D by a predetermined thickness. is preferred. This predetermined thickness is the thickness of the bent boundary region (the length along the y-axis direction) which is the boundary region between the first regions 121c1 and 122c1 and the second regions 121c2 and 122c2. The thickness of the substrate 30 is not limited and can be determined as appropriate.

An input port 31 is mounted on one main surface 30a of the pair of main surfaces of the substrate 30, and an output port 32 and an AC/DC are mounted on the other main surface 30b. A conversion circuit 33 is mounted (see the exploded perspective view of FIG. 1 and FIG. 3). The output port 32 is arranged in the outer edge region of the substrate 30 , which is close to the front wall 25 , corresponding to the position of the opening 251 formed in the housing 20 .

Incidentally, in this embodiment, the AC adapter 1 has one output port 32 . However, the number of output ports 32 provided in the AC adapter 1 is not limited to one, and may be plural. When the number of output ports 32 is plural, the front wall 25 may also have a plurality of openings 251 corresponding to the respective output ports 32 .

1, illustration of the AC/DC conversion circuit 33 mounted on the main surface 30b of the substrate 30 is omitted. In FIG. 3, the specific configuration of the AC/DC conversion circuit 33 is not shown, but the region where the AC/DC conversion circuit 33 is mounted is indicated by a virtual line (chain double-dashed line). In this embodiment, the AC/DC conversion circuit 33 is mounted only on the main surface 30b. However, part of the AC/DC conversion circuit 33 may be mounted on the main surface 30a.

An input port for inputting AC power to the AC/DC conversion circuit 33 is provided at a portion of the outer edge of the main surface 30a (see the exploded perspective view of FIG. 1 and FIG. 3).

As described above, by being inserted between each of the first leaf spring 121c and the second leaf spring 122c and the holding portions 132a to 132c, the substrate 30 is connected to the first leaf spring 121c and the second leaf spring 122c. , and gripping portions 132a to 132c. At this time, the main surface 30b is substantially aligned with the plane P2 by urging the main surface 30a by the first leaf spring 121c and the second leaf spring 122c.

Also, since the first leaf spring 121 c is pressed against the first terminal 311 of the input port 31 and the second leaf spring 122 c is pressed against the second terminal 312 of the input port 31 , AC power is supplied from the electrode pair 12 to the input port 31 . supplied.

As described above, the AC/DC conversion circuit 33 converts the supplied AC power into DC power having a predetermined voltage ratio, and supplies the DC power to the output port 32 . In this embodiment, the rated output of the AC/DC conversion circuit 33 is 10.5W. However, the rated output of the AC/DC conversion circuit 33 is not limited, and can be appropriately set according to desired specifications. If a USB Type-A connector jack is adopted as the output port 32, an example of the rated output is 17W. Further, a USB Type-C connector jack is adopted as the output port 32, and the AC adapter 1 may be an AC adapter conforming to the USB PD standard.

<Effects of power supply module and AC adapter>
As described above, in the power supply module 10 , the other ends of the first electrode 121 and the second electrode 122 that constitute the electrode pair 12 are respectively the first leaf spring 121 c and the second leaf spring 121 c that are pulled out of the frame 13 . It is composed of a plate spring 122c.

According to the above configuration, in the AC adapter 1 having the power supply module 10, the elasticity of the first leaf spring 121c and the second leaf spring 122c can be used when the electrode pair 12 and the input port 31 are electrically connected. can. That is, the electrode pair 12 and the input port 31 can be brought into good contact without using a conductive means such as solder or screws. Therefore, the power supply module 10 can simplify the process of connecting the electrode pair 12 and the input port 31 .

In the power supply module 10, each of the first leaf spring 121c and the second leaf spring 122c is pulled out along the plane P1 and in the negative z-axis direction. , holding portions 132a, 132b, and 132c defining a plane P2 substantially parallel to the plane P1 and separated from the plane P1 by a predetermined distance D, are provided. Each of the first leaf spring 121c and the second leaf spring 122c is elastically deformed by a force acting in the direction from the plane P2 toward the plane P1.

According to the above configuration, the substrate 30 can be joined to the power supply module 10 by inserting the substrate 30 between the first leaf spring 121c, the second leaf spring 122c, and the holding portions 132a, 132b, and 132c. . The electrode pair 12 and the input port 31 are electrically connected only by inserting the substrate 30 on which the input port 31 is formed between the first leaf spring 121c, the second leaf spring 122c, and the grips 132a, 132b, and 132c. be able to. Therefore, the power supply module 10 can further simplify the process of connecting the electrode pair 12 and the input port 31 .

The frame 13 is provided with gripping portions 132a to 132c that fix the substrate 30 by sandwiching the substrate 30 between the first leaf spring 121c and the second leaf spring 122c at positions outside the frame 13. The first plate spring 121c and the second plate spring 122c and the gripping portions 132a to 132c sandwich the substrate 30 at a position outside the frame 13, so that the electrode pair 12 (the first plate spring 121c and the second plate spring 122c) and the input The port 31 and the port 31 are conducted outside the frame 13 . According to said structure, there exist the following effects.

(1) The plug 11, the first electrode 121 and the second electrode 122 are covered by the frame 13 except for the portions where the first leaf spring 121c and the second leaf spring 122c are pulled out, thereby fixing and protecting them. . This also facilitates manufacture, transportation, and sale of the frame 13 housing the plug 11 , the first electrode 121 and the second electrode 122 as a module that is part of the AC adapter 1 .

(2) In the case where the frame 13 covers the plug 11, the first electrode 121 and the second electrode 122 in (1), the first electrode 121 and the second electrode 122 are exposed when connecting each plate spring and the input port. It is not necessary to disassemble the frame 13 to allow it to be installed.

(3) The size of the frame 13 itself can be reduced by fixing the board 30 outside the frame 13 instead of accommodating it in the frame 13 .

(4) Visually confirm that the first terminal 311 and the first leaf spring 121c are electrically connected outside the frame 13, and that the second terminal 312 and the second leaf spring 122c are electrically connected outside the frame 13. Alternatively, it becomes easy to confirm by using an image.

In the power supply module 10, each of the first leaf spring 121c and the second electrode 122 includes first regions 121c1 and 122c1, and the second frame 132 includes supports arranged along the rear surfaces of the first regions 121c1 and 122c1. 1311, 1312 are further provided.

According to the above configuration, since the supports 1311 and 1312 are further provided on the second frame 132, the substrate 30 is arranged between the first leaf spring 121c and the second leaf spring 122c and the holding portions 132a, 132b and 132c. It is possible to prevent the first leaf spring 121c and the second leaf spring 122c from bending too much when they are inserted between them. Therefore, each of the first leaf spring 121c and the second leaf spring 122c can be pressed against the input port 31 more strongly.

The frame 13 includes a first frame 131 and a second frame 132. The plug 11, the electrode pair 12 (the first electrode 121 and the second electrode 122), and the second frame 132 are made of a plurality of types of substrates 30. Alternatively, it is configured as a common module to which the first frame 131 can be attached.

According to the above configuration, the versatility of the module is improved, and mass production of the module contributes to, for example, a reduction in manufacturing cost.

The AC adapter 1 includes a power supply module 10 , a housing 20 , a substrate 30 , an output port 32 and an AC/DC conversion circuit 33 .

A power supply module according to an aspect of the present invention can be suitably used for an AC adapter as described above.

In the AC adapter 1, an input port 31 is provided on a part of the outer edge of the main surface 30a of the substrate 30. are held by the first plate spring 121c and the second plate spring 122c and the holding portions 132a, 132b, and 132c so that is biased by the first plate spring 121c and the second plate spring 122c.

According to the above configuration, the electrode pair 12 and the input port 31 are simply inserted between the first leaf spring 121c and the second leaf spring 122c and the grips 132a, 132b, and 132c. Port 31 can be electrically connected. The manufacturing process of the AC adapter 1 can be simplified.

In the AC adapter 1, the housing 20 includes (1) a pair of bottom walls 21 and 22 sandwiching the board 30, and (2) a pair of side walls 23 and 24 and a front wall 25 surrounding three sides of the board 30. there is The frame 13 functions as a rear wall that sandwiches the substrate 30 together with the front wall 25 . The side walls 23,24 are provided with a pair of slots 231,241.

According to the above configuration, the side walls 23 and 24 restrict movement along the width direction (x-axis direction) of the substrate 30, and the front wall 25 and the frame 13 move in the direction perpendicular to the width direction (z-axis direction) of the substrate 30. ), and slots 231 and 241 limit movement along the normal direction (y-axis direction) of substrate 30 . That is, the substrate can be fixed in the housing without using fixing means such as adhesives or screws. Therefore, the AC adapter 1 can further simplify the manufacturing process.

In the AC adapter 1 , the output port 32 is arranged in an outer edge area of the substrate 30 that is close to the front wall 25 , and an opening 251 is provided in the area of the front wall 25 corresponding to the output port 32 . ing.

According to the above configuration, the output port 32 can be exposed through the opening 251 simply by integrally molding the housing 20 and moving the substrate 30 along the slots 231 and 241 . The manufacturing process of the AC adapter 1 can be further simplified.

In AC adapter 1, ribs 255-260 are formed on each of bottom walls 21 and 22. As shown in FIG.

According to the above configuration, between the substrate 30 and the AC/DC conversion circuit 33 accommodated in the housing 20 and each of the bottom walls 21 and 22, at least the height corresponding to the ribs 255 to 260 is provided. Space can be provided. Further, even when pressure is applied to the bottom walls 21 and 22 in the direction of crushing the housing, the substrate 30 and the AC/DC conversion circuit 33 should be in direct contact with each of the bottom walls 21 and 22. can be prevented. The AC adapter 1 can increase resistance to heat generated by the AC/DC conversion circuit 33 .

[Additional notes]
The present invention is not limited to the above-described embodiments, but can be modified in various ways within the scope of the claims, and can be obtained by appropriately combining technical means disclosed in different embodiments. is also included in the technical scope of the present invention.

1 AC Adapter 10 Power Supply Module 11 Plug 111, 112 First Plug, Second Plug 12 Electrode Pair 121, 122 First Electrode, Second Electrode 121a, 122a End (One End)
121c, 122c first leaf spring, second leaf spring (other end)
121c1, 122c1 First area 121c2, 122c2 Second area 121c3, 122c3 Third area 13 Frame (rear wall)
132a, 132b, 132c Grip 20 Housing 21, 22 Bottom walls (a pair of bottom walls)
23, 24 side walls (pair of side walls)
231, 241 slots (a pair of slots)
25 front wall (front wall)
251 opening 255-266 ribs (a pair of ribs)
30 substrate 30a, 30b main surface (one main surface, other main surface)
31 input port 311, 312 first terminal, second terminal 32 output port 33 AC/DC conversion circuit

Claims (3)

a first plug and a second plug, each of which is a strip-shaped metal plate, form a pair, and one end of the first plug and the second plug is pluggable into an outlet;
a connecting portion provided near the other end of each of the first plug and the second plug, the connecting portion electrically insulating and connecting the first plug and the second plug; ,
a first electrode and a second electrode each made of a metal plate and configured such that one end of each is electrically connected to each of the other end of the first plug and the other end of the second plug; two electrodes;
a frame that holds the plug, the connecting portion, the first electrode, and the second electrode;
the connecting portion switches between a state in which the plug is accommodated and a state in which the plug is protruded by rotating;
In addition to the one end, each of the first electrode and the second electrode has (1) the other end and (2) between the one end and the other end. and an intermediate portion interposed in the
the intermediate portion of each of the first electrode and the second electrode is provided along the plug accommodated in the frame;
the connecting portion rotates in a direction in which the plug approaches the intermediate portion when switching from the protruded state to the accommodated state;
the one end of each of the first electrode and the second electrode is bent in a direction approaching the plug at a boundary with the intermediate portion of each of the first electrode and the second electrode;
The other end of the first electrode is a first leaf spring that is pulled out of the frame and that is electrically connected to an input port of a board on which an AC/DC conversion circuit is mounted. has been
The other end of the second electrode is a second leaf spring that is pulled out of the frame and that is electrically connected to an input port of a board on which an AC/DC conversion circuit is mounted. has been
A power supply module characterized by: The boundary between each of the first electrode and the second electrode has a recess into which the other end of each of the first plug and the second plug is fitted when the plug protrudes from the frame. formed,
The power supply module according to claim 1, characterized in that: The power supply module according to claim 1 or 2;
the substrate;
an output port for outputting the DC power supplied from the AC/DC conversion circuit;
a housing that accommodates the substrate, the AC/DC conversion circuit, and the output port;
An AC adapter characterized by:

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