JP7539116B2 - Power supply stand - Google Patents

Description

The present disclosure relates generally to power supply stations, and more particularly to power supply stations for supplying power to a power supply target.

Patent document 1 describes a table tap that includes a body with multiple sockets, multiple plug holders that are stored in the body and receive the blades of plugs that are inserted into the sockets, and a power cord that is led out of the body and connected to an external power source.

The table tap described in Patent Document 1 is equipped with a switch that turns on and off the electrical connection between the power cord and multiple blade holders. In Patent Document 1, the operating part of the switch is exposed on the bottom surface of a recess formed in the surface of the device, so that even if the device is stepped on while placed on the floor, erroneous operation of the switch is suppressed.

JP 2015-5367 A

For example, in an environment such as a living room in a house, when the power supply source to a power supply target such as a mobile terminal can be freely arranged, a table tap as described above may be used while placed on the floor, etc. In such a case, the power supply unit (body) of the table tap may be stepped on by someone's foot, or liquid may be spilled on the power supply unit when liquid is spilled on the floor, etc., which may cause a malfunction such as a breakdown of the power supply unit.

This disclosure has been made in consideration of the above-mentioned reasons, and aims to provide a power supply stand that is less susceptible to malfunctions and other problems even when the power supply source to the power supply target is freely positioned.

A power supply stand according to an embodiment of the present disclosure includes a main body and a support. The main body includes a power supply unit for supplying power to a power supply target. The support supports the main body so that the main body stands on an installation surface. The power supply stand is a self-supporting power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery for supplying power to the power supply unit. The power supply stand is capable of supplying power from the battery to the power supply unit without a cord being connected to supply power from an external power source to the power supply stand. The main body includes a first block that houses the battery, a second block having a front surface on which the power supply unit is provided , and a third block having a front surface to which the first block and the second block are fixed such that the second block is located above the first block. The main body includes a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the narrowed portion having a dimension in the front-rear direction smaller than other portions of the main body .
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so that the main body stands on an installation surface. The power supply stand is a free-standing power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery storage unit to which a battery for supplying power to the power supply unit can be attached and detached. The power supply stand is capable of supplying power from the battery to the power supply unit without connection of a cord for supplying power from an external power source to the power supply stand. The main body includes a first block that stores the battery, a second block having a front surface on which the power supply unit is provided , and a third block having a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The main body includes a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the portion having a smaller dimension in the front-rear direction than other portions of the main body.
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so that the main body stands on an installation surface. The power supply stand is a self-supporting power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery for supplying power to the power supply unit and a contact power receiving terminal. The power supply stand can supply power from the battery to the power supply unit without connecting a cord that supplies power from an external power source to the power supply stand. The main body includes a first block that houses the battery, a second block that has the power supply unit, and a third block that has a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The second block further includes a remaining capacity display unit that displays the remaining capacity of the battery. The battery is a secondary battery. The support is attachable to and detachable from a charging stand. The charging stand has the cord and a contact power supply terminal. When the support part is attached to the charging stand and the contact power supply terminal is in contact with the contact power receiving terminal, power from the external power source can be supplied to the power supply part and the battery via the contact power supply terminal and the contact power receiving terminal.
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so that the main body stands on an installation surface. The power supply stand is a self-supporting power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery for supplying power to the power supply unit and a contact power receiving terminal. The power supply stand is capable of supplying power from the battery to the power supply unit without a cord being connected to supply power from an external power source to the power supply stand. The main body includes a first block that houses the battery, a second block that has the power supply unit, and a third block that has a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The main body includes a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the front-rear dimension of which is smaller than other portions of the main body. The battery is a secondary battery. The support part can be attached to and detached from the charging base. The charging base has the cord and a contact power supply terminal. When the support part is attached to the charging base and the contact power supply terminal is in contact with the contact power receiving terminal, power from the external power source can be supplied to the power supply part and the battery via the contact power supply terminal and the contact power receiving terminal.
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so that the main body stands on an installation surface. The power supply stand is a self-supporting power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery storage unit to which a battery for supplying power to the power supply unit can be attached and detached, and a contact power receiving terminal. The power supply stand can supply power from the battery to the power supply unit without connecting a cord that supplies power from an external power source to the power supply stand. The main body includes a first block that stores the battery, a second block that has the power supply unit, and a third block that has a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The second block further includes a remaining capacity display unit that displays the remaining capacity of the battery. The battery is a secondary battery. The support is attachable to and detachable from a charging stand. The charging stand has the cord and a contact power supply terminal. When the support part is attached to the charging stand and the contact power supply terminal is in contact with the contact power receiving terminal, power from the external power source can be supplied to the power supply part and the battery via the contact power supply terminal and the contact power receiving terminal.
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so as to stand the main body on an installation surface. The power supply stand is a self-supporting power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery storage unit to which a battery for supplying power to the power supply unit can be attached and detached, and a contact power receiving terminal. The power supply stand is capable of supplying power from the battery to the power supply unit without connection of a cord for supplying power from an external power source to the power supply stand. The main body includes a first block that stores the battery, a second block that has the power supply unit, and a third block that has a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The main body includes a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the portion having a smaller dimension in the front-rear direction than other portions of the main body. The battery is a secondary battery. The support part is attachable to and detachable from the charging base. The charging base has the cord and a contact power supply terminal. When the support part is attached to the charging base and the contact power supply terminal is in contact with the contact power receiving terminal, power from the external power source can be supplied to the power supply part and the battery via the contact power supply terminal and the contact power receiving terminal.
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so that the main body stands on an installation surface. The power supply stand is a self-supporting power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery for supplying power to the power supply unit and a non-contact power receiving circuit. The power supply stand is capable of supplying power from the battery to the power supply unit without a cord being connected to supply power from an external power source to the power supply stand. The main body includes a first block that houses the battery, a second block that has the power supply unit, and a third block that has a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The second block further includes a remaining capacity display unit that displays the remaining capacity of the battery. The battery is a secondary battery. The support is attachable to and detachable from a charging stand. The charging stand includes the cord and a wireless power supply circuit that wirelessly supplies power to the wireless power receiving circuit. When the support part is attached to the charging stand, power from the external power source can be supplied to the power supply part and the battery via the wireless power supply circuit and the wireless power receiving circuit.
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so that the main body stands on an installation surface. The power supply stand is a self-supporting power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery for supplying power to the power supply unit and a non-contact power receiving circuit. The power supply stand is capable of supplying power from the battery to the power supply unit without a cord being connected to supply power from an external power source to the power supply stand. The main body includes a first block that houses the battery, a second block that has the power supply unit, and a third block that has a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The main body includes a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the front-rear dimension of which is smaller than other portions of the main body. The battery is a secondary battery. The support part can be attached to and detached from the charging base. The charging base includes the cord and a non-contact power supply circuit that supplies power to the non-contact power receiving circuit in a non-contact manner. With the support part attached to the charging base, power from the external power source can be supplied to the power supply part and the battery via the non-contact power supply circuit and the non-contact power receiving circuit.
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so as to stand the main body on an installation surface. The power supply stand is a freestanding power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery storage unit to which a battery for supplying power to the power supply unit can be attached and detached, and a non-contact power receiving circuit. The power supply stand can supply power from the battery to the power supply unit without connecting a cord that supplies power from an external power source to the power supply stand. The main body includes a first block that stores the battery, a second block that has the power supply unit, and a third block that has a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The second block further includes a remaining capacity display unit that displays the remaining capacity of the battery. The battery is a secondary battery. The support part can be attached to and detached from the charging base. The charging base includes the cord and a non-contact power supply circuit that supplies power to the non-contact power receiving circuit in a non-contact manner. With the support part attached to the charging base, power from the external power source can be supplied to the power supply part and the battery via the non-contact power supply circuit and the non-contact power receiving circuit.
A power supply stand according to another aspect of the present disclosure includes a main body and a support. The main body has a power supply unit for supplying power to a power supply target. The support supports the main body so as to stand the main body on an installation surface. The power supply stand is a self-supporting power supply stand that is placed on the installation surface in a portable manner. The power supply stand further includes a battery storage unit to which a battery for supplying power to the power supply unit can be attached and detached, and a non-contact power receiving circuit. The power supply stand is capable of supplying power from the battery to the power supply unit without connection of a cord for supplying power from an external power source to the power supply stand. The main body includes a first block that stores the battery, a second block that has the power supply unit, and a third block that has a front surface to which the first block and the second block are fixed so that the second block is located above the first block. The main body includes a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the portion having a smaller dimension in the front-rear direction than other portions of the main body. The battery is a secondary battery. The support part is attachable to and detachable from the charging base. The charging base has the cord and a non-contact power supply circuit that supplies power to the non-contact power receiving circuit in a non-contact manner. With the support part attached to the charging base, power from the external power source can be supplied to the power supply part and the battery via the non-contact power supply circuit and the non-contact power receiving circuit.

The present disclosure has the advantage that malfunctions and other problems are less likely to occur even when the power supply source to the power supply target is freely arranged.

FIG. 1A is a perspective view of a power supply station according to a first embodiment in a contracted state, and FIG. 1B is a perspective view of the power supply station in an extended state. FIG. 2A is a front view of the power supply station according to the first embodiment, and FIG. 2B is a right side view of the power supply station. FIG. 3 is a schematic diagram showing an example of use of the power supply station. FIG. 4A is an enlarged perspective view of a main part of the power supply stand before a power supply cord is connected, and FIG. 4B is an enlarged perspective view of a main part of the power supply stand after a power supply cord is connected. FIG. 5 is a block diagram showing a schematic configuration of the main body of the power supply station. FIG. 6A is a perspective view showing a main part of a power supply station according to a first modified example of the first embodiment before temporary fixing, and FIG. 6B is a perspective view showing the main part of the power supply station after temporary fixing. FIG. 7 is a perspective view of a power supply station according to a second modification of the first embodiment. FIG. 8 is a perspective view of a power supply station according to a third modified example of the first embodiment. FIG. 9 is a perspective view of a power supply station according to the second embodiment. FIG. 10A is a schematic perspective view showing an example of use of the power supply stand of the above embodiment, and FIG. 10B is a schematic perspective view showing an example of use of the power supply stand according to a modified example of the second embodiment. FIG. 11A is a right side view of the power supply station according to the second embodiment in a state where the protrusion amount of the pressure receiving portion is small, and FIG. 11B is a right side view of the same power supply station in a state where the protrusion amount of the pressure receiving portion is large. FIG. 12A is a perspective view of a power supply stand according to the third embodiment in a state where it is removed from a charging stand, and FIG. 12B is a perspective view of the power supply stand in a state where it is placed on the charging stand. FIG. 13A is an enlarged perspective view of a main part of a power supply station according to a first modified example of the third embodiment, and FIG. 13B is an enlarged perspective view of a main part of a power supply station according to a second modified example of the third embodiment. FIG. 14A is an enlarged perspective view of a main part of a power supply stand according to a third modified example of embodiment 3 with the battery removed, and FIG. 14B is an enlarged perspective view of a main part of the same power supply stand with the battery attached.

(Embodiment 1)
(1) Overview The power supply station 1 (see FIG. 1A) according to this embodiment is a device for supplying power to a power supply target 92 (see FIG. 3). In the present disclosure, the "power supply target" refers to, for example, various home appliances such as vacuum cleaners, air purifiers, and personal computers, as well as mobile terminals such as tablet terminals, smartphones, and mobile phones, or chargers for mobile terminals. In other words, the power supply target 92 receives a supply of power from the power supply station 1.

The power supply stand 1 is used while placed on an installation surface 91 (see FIG. 3), which may be, for example, the floor of a room in a house. As shown in FIGS. 1A and 1B, the power supply stand 1 includes a portable main body 3 having a power supply unit 2 for supplying power to a power supply target 92, and a support 4 for supporting the main body 3. The support 4 supports the main body 3 while placed on the installation surface 91, so that the main body 3 stands on the installation surface 91.

That is, in the power supply stand 1 according to this embodiment, at least the main body 3 is a self-contained and portable power supply device, and the user 93 (see FIG. 3) can freely carry the power supply stand 1 and set it up at any position on the installation surface 91. This allows the power supply source to the power supply target 92 such as a mobile terminal to be freely arranged in an environment such as, for example, a living room of a house. Moreover, the power supply stand 1 is set up so that the main body 3 having the power supply unit 2 stands on the installation surface 91 while being supported by the support unit 4. Therefore, the power supply stand 1 has the advantage that the power supply unit 2 is less likely to break down due to being stepped on by a person's foot or being splashed with liquid when liquid is spilled on the installation surface 91.

(2) Details The configuration of the power supply station 1 according to this embodiment will be described in detail below with reference to FIGS. 1A to 5.

As described above, the power supply stand 1 includes a portable main body 3 and a support 4. The main body 3 includes a power supply unit 2 for supplying power to a power supply target 92 (see FIG. 3). The support 4 supports the main body 3 so that the main body 3 stands on the installation surface 91 (see FIG. 3) while being placed on the installation surface 91. In this disclosure, the "placed state" means a state in which the main body 3 is placed in a specific position on the floor or the like. That is, the support 4 is not placed in a state in which it can be moved freely on the installation surface 91 by casters or the like, but is placed in a state in which a place to be placed at any position on the installation surface 91 is determined. Therefore, the power supply stand 1 according to this embodiment is portable, but is used in a state in which it stands on the installation surface 91, which is, for example, the floor of a room in a house.

In the following description, the direction perpendicular (orthogonal) to the horizontal plane when the power supply stand 1 is placed on the installation surface 91, which is the floor surface, is referred to as the "up-down direction," and the downward (vertical) direction in the up-down direction is referred to as the "downward direction." In addition, in the power supply stand 1, the surface on which the multiple connection ports 21-24 (described later) of the power supply unit 2 are provided is referred to as the front, and the right side when looking at the power supply stand 1 from the front is referred to as the "right side," and the left side is referred to as the "left side." The arrows indicating the "up-down direction," "front-rear direction," and "left-right direction" in the drawings are merely indicated for the purpose of explanation and do not have any substance. However, these directions are not intended to limit the use direction (installation direction) of the power supply stand 1. For example, the "forward direction" defined here may be the right or left side as seen by the user 93 in the actual use of the power supply stand 1.

The power supply unit 2 has multiple connection ports 21 to 24 for connecting the power supply targets 92. The multiple connection ports 21 to 24 are arranged in a line in the up-down direction (vertical direction). As an example in this embodiment, four connection ports 21 to 24 are arranged on the front surface 301 of the main body unit 3 so as to be aligned in a line in the up-down direction.

In this embodiment, the two upper connection ports 21, 22 of the four connection ports 21-24 are USB receptacles into which a USB (Universal Serial Bus) plug can be inserted. Each of these two connection ports 21, 22 is configured to output a DC voltage of 5 V to the power supply target 92 through the USB plug. Also, each of the two lower connection ports 23, 24 of the four connection ports 21-24 is an outlet into which an A-type outlet plug having a pair of plug blades can be inserted. Each of these two connection ports 23, 24 is configured to output an AC voltage of 100 V to the power supply target 92 through the outlet plug. In other words, the power supply unit 2 is configured to be able to output both DC power and AC power, and outputs DC power or AC power from one of the four connection ports 21-24 according to the power supply target 92.

The "power supply unit" in this disclosure may have a function of supplying at least one of AC power and DC power to the power supply target 92, and is not limited to a configuration having a terminal for electrically connecting the power supply target 92, such as a USB receptacle and outlet. For example, the power supply unit 2 may be a power supply port for contactless power supply using a magnetic resonance method or an electromagnetic induction method.

The dimension of the main body 3 in the up-down direction (vertical direction) is greater than both the dimension of the main body 3 in the front-rear direction and the dimension of the main body 3 in the left-right direction. In other words, the main body 3 is formed in a so-called vertically elongated shape that is long in the up-down direction. In this embodiment, the lower end of the main body 3 is fixed to the support part 4 by, for example, gluing or screws.

The main body 3 also has a fixed part 31 and a movable part 32. The fixed part 31 is fixed to the support part 4. The movable part 32 is movable relative to the fixed part 31 in the up-down direction (vertical direction). That is, the main body 3 has a movable part 32 that moves in the up-down direction as shown in Figs. 1A and 1B.

Specifically, the fixed part 31 has a base part 311 and a pole part 312. The base part 311 is fixed to the support part 4. The base part 311 is a resin molded part formed in a triangular shape when viewed from the side, and the front surface is inclined so that the dimension of the base part 311 in the front-to-rear direction becomes smaller as it approaches the upper end. The pole part 312 is a part that extends upward from the upper surface of the base part 311. The pole part 312 is a resin molded part in the shape of a rectangular parallelepiped that is long in the up-down direction and flat in the front-to-rear direction. Here, the base part 311 and the pole part 312 are integrated.

The movable part 32 has a case 321 and a back panel 322. The case 321 is a resin molded product in the shape of a rectangular parallelepiped that is long in the vertical direction and flat in the front-rear direction. As shown in Figs. 2A and 2B, the case 321 is located directly above the pole part 312 of the fixed part 31 so as to have a sense of unity in appearance with the pole part 312, and is configured to have the same shape as the pole part 312 in a plan view. The back panel 322 is a plate-shaped resin molded product that is long in the vertical direction and curved so that the center part in the left-right direction is convex backward. The case 321 is fixed to a position on the front surface of the back panel 322 that is above the center part in the vertical direction. The back panel 322 is held by the fixed part 31 via a slide mechanism so that it can move in the vertical direction along the rear surface of the fixed part 31. The slide mechanism is realized, for example, by using an extension mechanism such as a telescopic structure in which multiple cylindrical bodies with different opening areas are stacked together, or a slide rail.

With the above configuration, as shown by arrow A1 in FIG. 1B, the back panel 322 moves relative to the fixed part 31, and the case 321 moves vertically together with the back panel 322. That is, when the back panel 322 moves upward, the case 321 moves away from the pole part 312, and when the back panel 322 moves downward, the case 321 moves toward the pole part 312. Therefore, when viewed as a whole, the main body part 3 expands and contracts as the movable part 32 moves upward and downward, changing the vertical dimension of the main body part 3.

1A shows a state in which the movable part 32 is located at the lower end of the range of movement, i.e., the main body part 3 is in a "contracted state" in which it is contracted, and FIG. 1B shows a state in which the movable part 32 is located at the upper end of the range of movement, i.e., the main body part 3 is in an "extended state" in which it is extended. In other words, when the main body part 3 is in a contracted state, the height of the power supply stand 1 is at a minimum, and when the main body part 3 is in an extended state, the height of the power supply stand 1 is at a maximum. In this embodiment, as an example, the height of the power supply stand 1 is 600 [mm] in the contracted state and 850 [mm] in the extended state. And, when the main body part 3 is in a contracted state, the entire rear surface of the case 321 and the fixed part 31 is covered by the back panel 322. Therefore, the front surface of the case 321 and the fixed part 31 constitutes the front surface 301 of the main body part 3, and the rear surface of the back panel 322 constitutes the rear surface 302 of the main body part 3.

Here, the power supply unit 2 is provided in the movable unit 32 of the fixed unit 31 and movable unit 32 that constitute the main body unit 3. Specifically, the power supply unit 2 is provided on the front surface of the case 321 of the movable unit 32 (front surface 301 of the main body unit 3). In other words, the power supply unit 2 is disposed at a position higher than at least the fixed unit 31 of the main body unit 3. The height of the power supply unit 2 from the installation surface 91 changes as the movable unit 32 moves in the vertical direction. In this embodiment, the power supply unit 2 has multiple plug-in connection ports 21-24, so that the plug of the power supply target 92 is inserted from the front into the multiple connection ports 21-24 provided on the front surface 301 of the main body unit 3.

The support part 4 is a flat member fixed to the underside of the fixed part 31 (base part 311). In other words, the base part 311 is supported by the support part 4 so as to protrude upward from the upper surface of the support part 4. In this embodiment, the left-right dimension of the front end part of the support part 4 is set to be larger than the left-right dimension of the rear end part of the support part 4, and the support part 4 is T-shaped in a plan view.

Here, the projection point of the center of gravity of the main body 3 onto the top surface of the support part 4 is located between the center and the rear end of the top surface of the support part 4 in the front-to-rear direction. In other words, the projection point of the center of gravity of the main body 3 projected vertically onto the top surface of the support part 4 is set at a position closer to the rear end, not at the center. As a result, even if the power supply stand 1 were to tip over, the front surface 301 of the main body 3 where the power supply unit 2 is provided, that is, the power supply stand 1 is less likely to tip over forward.

The power supply stand 1 according to this embodiment further includes a power supply cord 5 (see FIG. 3) for supplying power to the power supply unit 2. The main body 3 includes a power receiving unit 6 for electrically connecting the power supply cord 5. As with the power supply unit 2, the power receiving unit 6 is provided in the movable unit 32 of the fixed unit 31 and movable unit 32 that constitute the main body 3. In other words, the movable unit 32 includes the power receiving unit 6 for electrically connecting the power supply cord 5.

The power receiving unit 6 is provided in the case 321 of the movable unit 32, similar to the power supply unit 2. Furthermore, the power receiving unit 6 is arranged on the front surface 301 of the main body unit 3 so as to be aligned in a vertical row with the four connection ports 21 to 24 of the power supply unit 2. The power receiving unit 6 is arranged below the lowest connection port 24 of the four connection ports 21 to 24. Specifically, the slightly recessed portion of the front surface of the case 321 below the connection port 24 constitutes the power receiving unit 6. The power receiving unit 6 has a pair of power receiving terminals 61.

A pair of terminals 51 (see FIG. 4A) of the power supply cord 5, which will be described later, contacts (connects) these pair of power receiving terminals 61, thereby electrically connecting the power supply cord 5 to the power receiving unit 6. The end of the power supply cord 5 opposite the pair of terminals 51 is connected to an external power source, so that power is supplied from the external power source to the power receiving unit 6 via the power supply cord 5. In this embodiment, an AC voltage of 100 V is applied to the power receiving unit 6 from the external power source.

A pair of power receiving terminals 61 of the power receiving unit 6 are electrically connected to the four connection ports 21 to 24 of the power supply unit 2 inside the case 321. In this embodiment, since each of the two upper connection ports 21, 22 is a USB receptacle, the power supply unit 2 has an AC/DC conversion unit 20 (see FIG. 5) that converts AC voltage to DC voltage. The AC/DC conversion unit 20 is connected between the power receiving unit 6 and the connection ports 21, 22. In other words, the AC voltage of 100 [V] from an external power source to the power receiving unit 6 is converted to a DC voltage of 5 [V] by the AC/DC conversion unit 20 and supplied to the connection ports 21, 22.

The power supply stand 1 configured as described above is used in a freestanding state on an installation surface 91, which is the floor of a room in a house, as shown in FIG. 3, for example. In the example of FIG. 3, in a scene where a user 93 is sitting on a sofa 94 and using a tablet terminal, which is a power supply target 92, power is supplied to the power supply target 92 by the power supply stand 1. In the example of FIG. 3, the topmost connection port 21 of the four connection ports 21 to 24 is used, and DC power is supplied from the power supply unit 2 to the power supply target 92.

3, the power supply stand 1 is installed near the sofa 94 on the installation surface 91. In other words, since at least the main body 3 of the power supply stand 1 is portable, the power supply stand 1 can be installed at any position on the installation surface 91 depending on the layout of the furniture, and as in the example of FIG. 3, the power supply stand 1 can be easily installed near the user 93. As a result, the user 93 can freely arrange the source of power supply to the power supply target 92 in an environment such as a living room of a house. Moreover, since the power supply stand 1 is freestanding, the area occupied by the power supply stand 1 on the installation surface 91 can be kept small, and the power supply stand 1 is unlikely to get in the way when the user 93 moves around the room. In addition, the power supply stand 1 is unlikely to cause problems such as failure of the power supply unit 2 due to the power supply unit 2 being stepped on by a person's foot or liquid being splashed on the power supply unit 2 when liquid is spilled on the installation surface 91.

3, the height H1 of the power supply stand 1 is 600 mm because the main body 3 is in a shortened state. In this state, the lower end of the power supply unit 2 (the connection port 24 at the lowest level) may interfere with the armrest of the sofa 94. To avoid interference between the power supply unit 2 and the armrest of the sofa 94, the movable part 32 may be moved upward until the height H1 of the power supply stand 1 is about 700 mm. This causes the lower end of the power supply unit 2 (the connection port 24 at the lowest level) to be positioned above the armrest of the sofa 94, making it possible to avoid interference between the power supply unit 2 and the armrest of the sofa 94. In this embodiment, the power supply cord 5 is pulled out downward from the main body 3 as shown in FIG. 3. Therefore, the power supply cord 5 is pulled out from the main body 3 along the front surface 301 of the main body 3, and the power supply cord 5 is less likely to get in the way compared to a configuration in which the power supply cord 5 is pulled out from the main body 3 to the front of the main body 3.

In FIG. 3, an example is shown in which the power supply stand 1 is installed near a sofa 94, but this is not intended to limit the manner in which the power supply stand 1 is used. For example, the power supply stand 1 may be installed near a bed, a low table, a kitchen counter, or the like, or in a location away from furniture.

As shown in Figs. 4A and 4B, the power supply cord 5 has a pair of terminals 51 and a connector housing 52. The pair of terminals 51 are provided at one end of the power supply cord 5. The connector housing 52 holds the pair of terminals 51. In this embodiment, the connector housing 52 is a resin molded product formed into a rectangular parallelepiped shape, and the pair of terminals 51 are provided on one surface of the connector housing 52. An outlet plug is provided at the end of the power supply cord 5 opposite the connector housing 52. Therefore, for example, when the outlet plug of the power supply cord 5 is connected to an external power source such as an outlet installed on a wall of a room, and the pair of terminals 51 are connected to a pair of power receiving terminals 61 of the power receiving unit 6, power is supplied from the external power source to the power receiving unit 6.

As shown in Figs. 4A and 4B, the power supply stand 1 further includes a coupling structure 7 that mechanically couples the power supply cord 5 to the power receiving unit 6 by magnetic force when the power supply cord 5 is electrically connected to the power receiving unit 6. The coupling structure 7 is composed of a pair of metal plates 71 and a pair of magnets 72. The pair of metal plates 71 are embedded around the pair of terminals 51 in the connector housing 52. The pair of magnets 72 are embedded around the pair of power receiving terminals 61 in the power receiving unit 6. The pair of metal plates 71 are made of a ferromagnetic material such as iron, and when brought close to the pair of magnets 72, they are attracted to the pair of magnets 72 by the magnetic force of the pair of magnets 72. When the connector housing 52 is attracted to the power receiving unit 6, the pair of terminals 51 are electrically connected to the pair of power receiving terminals 61.

As shown in FIG. 5, the power supply station 1 according to this embodiment further includes a detection unit 11 and a stop unit 12. The detection unit 11 detects the attitude of the main body unit 3. The stop unit 12 stops the supply of power from the power supply unit 2 to the power supply target 92 based on the attitude of the main body unit 3 detected by the detection unit 11. In this embodiment, the detection unit 11 and the stop unit 12 are stored in the case 321 of the movable unit 32 in the main body unit 3.

The detection unit 11 is, for example, a tilt sensor that detects the tilt of the main body 3 relative to the vertical direction using an acceleration sensor, a gyro sensor, etc. The stop unit 12 is, for example, a switch (including a semiconductor switch and a relay) connected between the power receiving unit 6 (a pair of power receiving terminals 61) and the power supply unit 2. When the detection unit 11 detects a tilt of the main body 3 that exceeds a predetermined value, the stop unit 12 turns off to cut off the connection between the power receiving unit 6 (a pair of power receiving terminals 61) and the power supply unit 2. In this configuration, when the main body 3 falls over or is about to fall over, the detection unit 11 detects the tilt of the main body 3 and activates the stop unit 12. This makes it possible to prevent the main body 3 from falling over while electricity is still flowing to the power supply unit 2.

(3) Modifications The power supply station 1 according to the first embodiment is merely one of various embodiments of the present disclosure. The power supply station 1 according to the first embodiment can be modified in various ways depending on the design and the like as long as the object of the present disclosure can be achieved. Modifications of the first embodiment are listed below. The modifications described below can be applied in appropriate combination.

(3.1) First Modification A power supply stand 1A according to a first modification of the first embodiment differs from the power supply stand 1 according to the first embodiment in that it further includes a fixing structure 41, as shown in Figs. 6A and 6B. The fixing structure 41 is a structure for fixing the support part 4 to a fixed position on the installation surface 91. The "fixing structure" in this disclosure is a structure for fixing the support part 4 to the installation surface 91 in a state in which the layout (arrangement) of the power supply stand 1A can be changed. That is, the fixing structure 41 does not completely fix the support part 4 to the installation surface 91 by, for example, embedding or gluing, but temporarily fixes the main body part 3 to the installation surface 91. Temporarily fixing the support part 4 by the fixing structure 41 makes it less likely for the power supply stand 1A to tip over.

In the example of FIG. 6A, the fixing structure 41 is composed of a pair of holes 411 formed in the support part 4 and a pair of bolts 412. Each of the pair of holes 411 is formed at each of the left and right ends of the front end of the support part 4, and is a hole that is open toward the outside in the left and right direction. As shown in FIG. 6B, the pair of bolts 412 penetrate the support part 4 in the thickness direction (up and down direction) through the pair of holes 411, and are fitted (screwed) into screw holes (nuts) provided in the installation surface 91, thereby fixing the support part 4 in a fixed position on the installation surface 91.

The fixing structure 41 is not limited to the examples in Figs. 6A and 6B as long as it is a structure for temporarily fixing the power supply stand 1A, and may be realized, for example, by an adhesive sheet or hook-and-loop fastener provided between the installation surface 91 and the support part 4. In addition, although this will be described in detail in embodiment 2, the fixing structure 41 for fixing the support part 4 in a fixed position on the installation surface 91 can also be realized by stepping on the support part 4 on a piece of furniture such as a desk 95 (see Fig. 10A).

(3.2) Second Modification A power supply stand 1B according to a second modification of the first embodiment differs from the power supply stand 1 according to the first embodiment in that the main body 3 has a top plate 33, as shown in FIG.

The top plate 33 is provided at the upper end of the main body 3. In the example of FIG. 7, the top plate 33 is a resin molded product formed into a disk shape, and is fixed to the upper end of the front surface of the back panel 322 so as to be located above the case 321. Here, the top plate 33 protrudes further forward from at least the front surface 301 of the main body 3 on which the power supply unit 2 is provided.

In this configuration, even if the power supply stand 1B falls forward, that is, toward the front surface 301 of the main body 3 where the power supply unit 2 is provided, the top plate 33 acts as a support, and a gap is maintained between the front surface 301 of the main body 3 and the installation surface 91. Therefore, even if the power supply stand 1B falls forward, the USB plug or outlet plug connected to the power supply unit 2 is less likely to hit the installation surface 91 and be damaged.

In addition, in the example of FIG. 7, the top panel 33 also functions as a stand for a mobile terminal such as a tablet terminal, a smartphone, or a mobile phone, which is a power supply target 92 electrically connected to the power supply unit 2. In other words, for example, a mobile terminal that is being charged can be placed on the top panel 33.

(3.3) Third Modification A power supply stand 1C according to a third modification of the first embodiment differs from the power supply stand 1 according to the first embodiment in that it further includes a battery 13, as shown in Fig. 8. The battery 13 supplies power to the power supply unit 2. In this disclosure, the "battery" includes, for example, a primary battery, a secondary battery, a solar cell, and the like. In other words, the power supply stand 1C according to the third modification can supply power from the power supply unit 2 to the power supply target 92 without receiving power from an external power source via the power supply cord 5.

8, the battery 13 is stored in the base 311 of the fixing part 31. The battery 13 is, for example, a secondary battery, and is attached to the main body 3 in a state where it can be removed from the main body 3 (base 311). Therefore, the battery 13 can be repeatedly used by charging the battery 13 when it is removed from the main body 3. The power supply stand 1C includes a discharge circuit that supplies the power output from the battery 13 to the power supply unit 2. The discharge circuit includes, for example, an inverter that converts the DC voltage output from the battery 13 into an AC voltage. In addition, in the example of FIG. 8, the power receiving unit 6 is omitted, and a connection port 25 similar to the connection ports 23 and 24 is provided at the position where the power receiving unit 6 was located in the power supply stand 1 according to the first embodiment.

However, the power supply stand 1C is not limited to the above example, and may include a power receiving unit 6 for electrically connecting the power supply cord 5, similar to the power supply stand 1 according to the first embodiment. In this case, the power supply stand 1C includes a charging circuit, so that power for charging the battery 13 can be supplied from an external power source via the power supply cord 5.

(3.4) Other Modifications The power supply stand 1 may further include an operation switch that turns on/off the power supply state to the multiple connection ports 21 to 24 individually or collectively. In this case, the user 93 can operate the operation switch to stop the power supply to the power supply unit 2 (connection ports 21 to 24) when the connection ports 21 to 24 are not in use. Furthermore, the power supply stand 1 may include, for example, a human presence sensor or a timer, and in this case, the power supply state to the multiple connection ports 21 to 24 may be turned on/off individually or collectively by output of the human presence sensor or timer.

The power supply station 1 may further include a display unit that displays the power supply status of the multiple connection ports 21 to 24 individually or collectively. The display unit is realized, for example, using an LED (Light Emitting Diode) or the like. The display unit may be configured to be always lit while power is being supplied to the power receiving unit 6, for example, regardless of the power supply status of the multiple connection ports 21 to 24.

In addition, in the first embodiment, the lower end of the main body 3 is fixed to the support 4, but this is not limiting, and the main body 3 may be configured to be separable from the support 4. Even in this case, the main body 3 is supported by the support 4, so that the power supply stand 1 can stand independently on the installation surface 91. In addition, the lower end of the main body 3 may be formed integrally with the support 4.

The detection unit 11 and the stop unit 12 may also be integrated. For example, the detection unit 11 and the stop unit 12 may be realized by a tip-over switch that uses a photosensor or a metal ball. In this case, the tip-over switch detects the position (upright/tipped over) of the main body unit 3, and stops the supply of power from the power supply unit 2 when it detects that the main body unit 3 has tipped over.

The power supply stand 1 is not limited to be used in residential buildings, but may be used in non-residential facilities such as stores, offices, and factories. Furthermore, the power supply stand 1 is not limited to be used indoors in a room, but may be used outdoors. When used outdoors, the installation surface 91 may be, for example, a terrace, a wooden deck, or the ground. When used outdoors, it is preferable that the power supply stand 1 adopts an appropriate waterproof structure.

The power supply unit 2 (connection ports 23, 24) is not limited to an outlet for 100V AC without a grounding electrode, but may be, for example, an outlet with a grounding electrode, an outlet for 200V AC, or an outlet for DC. The power supply unit 2 (connection ports 23, 24) is not limited to an outlet for type A, but may be, for example, an outlet for type B or type C to which a plug with a pin-shaped plug blade can be connected.

Furthermore, the power supply unit 2 is not limited to a configuration having four connection ports 21 to 24, but may be a configuration having one, two, or three connection ports, or a configuration having five or more connection ports.

The end of the power supply cord 5 opposite the connector housing 52 may be provided with, for example, a harness plug, rather than a power outlet plug that can be connected to an outlet. The harness plug is connected to an external power source such as a joint box installed under the floor in a free access floor (double floor) where wiring is laid under the floor. This allows power to be supplied to the power receiving unit 6 from the external power source such as the joint box via the power supply cord 5.

In addition, multiple power supply stations 1 may be provided. In this case, multiple power supply stations 1 connected to the installation surface 91 may be electrically connected by a feed wiring.

The power receiving unit 6 may also be provided on the support unit 4. The power supply cord 5 does not have to be included in the components of the power supply stand 1. Furthermore, the power supply cord 5 may be pulled out from the main body unit 3 or the support unit 4 in a state where it cannot be removed from the main body unit 3 or the support unit 4.

The power supply unit 2 is not limited to being provided on the front surface 301 of the main body 3, but may be provided on, for example, the rear surface 302, top surface, right side surface, or left side surface of the main body 3. Furthermore, the power supply unit 2 may be provided in a distributed manner on multiple surfaces of the main body 3.

The power supply station 1 may further include a cover that covers the power supply unit 2 when the power supply station 1 is not in use. The cover may cover each of the multiple connection ports 21 to 24 individually, or may cover the multiple connection ports 21 to 24 collectively.

(Embodiment 2)
As shown in Fig. 9, the power supply stand 1D according to this embodiment differs from the power supply stand 1 according to the first embodiment in that the main body 3 does not include a fixed part 31 (see Fig. 1A) and a movable part 32 (see Fig. 1A) that are relatively movable. Hereinafter, common reference numerals will be used to designate the same components as those in the first embodiment, and the description thereof will be omitted as appropriate.

The main body 3 of the power supply station 1D has a first block 34, a second block 35, and a third block 36. The first block 34 corresponds to the fixing part 31 in the first embodiment and is fixed to the support part 4. The first block 34 is a rectangular parallelepiped resin molded product that is long in the vertical direction and flat in the front-rear direction. The second block 35 corresponds to the case 321 in the first embodiment and is a rectangular parallelepiped resin molded product that is long in the vertical direction and flat in the front-rear direction. The third block 36 corresponds to the back panel 322 in the first embodiment and is a plate-shaped resin molded product that is long in the vertical direction and curved so that the center part in the horizontal direction is convex backward. The first block 34 and the second block 35 are aligned in the vertical direction and fixed to the front of the third block 36 so that the second block 35 is located above the first block 34.

In this embodiment, the power receiving unit 6 (see FIG. 11A) is provided in the first block 34. More specifically, the power receiving unit 6 is provided on the right side of the lower end of the first block 34. Therefore, the power supply cord 5 is pulled out from the lower end of the first block 34, as shown in FIG. 9. On the other hand, the power supply unit 2 is provided in the second block 35.

Here, the main body 3 further has a constricted portion 37 in a part of the up-down direction (vertical direction) whose dimension in the front-to-back direction or left-to-right direction is smaller than other parts of the main body 3. In this embodiment, a gap of a predetermined width is provided between the upper surface of the first block 34 and the lower surface of the second block 35, and the part of the third block 36 corresponding to this gap constitutes the constricted portion 37. In other words, the main body 3 has a smaller dimension in the front-to-back direction in the gap between the first block 34 and the second block 35 than other parts, and this part constitutes the constricted portion 37.

The power supply stand 1D configured as described above is used in a freestanding state on an installation surface 91, which is the floor surface of a room in a house, as shown in FIG. 10A, for example. In the example of FIG. 10A, the power supply stand 1D is installed near a desk 95, which is a piece of furniture, and a user sitting on a chair 96 is assumed to use the power supply stand 1D. The "furniture" referred to in this disclosure is not limited to the desk 95, but includes, for example, a chair 96, a storage shelf, and a partition. In the example of FIG. 10A, the desk 95 is installed next to a wall 97, and the power supply stand 1D is installed in the gap between the desk 95 and the wall 97 with the rear surface 302 (see FIG. 11A) of the main body 3 facing the wall 97.

Here, the support part 4 of the power supply stand 1D is stepped on by the legs 952 of the desk 95. As a result, the support part 4 is fixed (temporarily fixed) in a fixed position on the installation surface 91, making it difficult for the power supply stand 1D to tip over. In other words, the support part 4 itself functions as a fixing structure for fixing the support part 4 in a fixed position on the installation surface 91. In this embodiment, in order to allow the support part 4 to be stepped on by furniture such as the desk 95, the thickness of the support part 4 is set smaller (thinner) than in embodiment 1.

As described above, the power receiving unit 6 (see FIG. 11A) is provided on the right side of the lower end of the first block 34. However, the power receiving unit 6 may be provided on the front or left side of the first block 34. That is, the power receiving unit 6 is disposed on the front surface 301 of the main body 3 and at least one of both left and right sides (the right side in this embodiment). Therefore, the power supply stand 1D can be installed next to a wall 97 with the rear surface 302 of the main body 3 facing the wall 97 while avoiding interference between the power supply cord 5 and the wall 97. Moreover, the power supply cord 5 is pulled out from the main body 3 along the wall 97, so that the power supply cord 5 is less likely to get in the way.

Here, the height H2 of the power supply stand 1D is 850 [mm] as an example. On the other hand, the height H11 of the upper surface 953 of the top plate 951 of the desk 95 is generally about 700 [mm]. Therefore, as shown in FIG. 10A, at least a part of the main body 3 protrudes upward from the upper surface 953 of the top plate 951 of the desk 95. In other words, the main body 3 has a protrusion that protrudes upward from a plane including the upper surface 953 of the furniture (desk 95) installed on the installation surface 91. In this embodiment, in the vertical direction, the position of the top plate 951 coincides with the position of the narrowed portion 37 of the main body 3, and the end of the top plate 951 is inserted between the first block 34 and the second block 35. In other words, the narrowed portion 37 is sandwiched between the top plate 951 and the wall 97. Therefore, the second block 35 constitutes the protrusion. Here, the power supply unit 2 is provided on the protrusion (second block 35). This prevents interference between the power supply unit 2 and the fixture (desk 95), improving the usability of the power supply unit 2.

Also, FIG. 10B shows an example of how to use a power supply stand 1E according to a modified example of embodiment 2. This power supply stand 1E is installed under the top plate 951 of a desk 95. The height H12 of the underside of the top plate 951 of the desk 95 is generally 620 mm or more. Therefore, the height H3 of the power supply stand 1E is set to 600 mm, as an example. This allows the power supply stand 1E to be installed so that it fits under the top plate 951, as shown in FIG. 10B.

As described above, the power supply stand 1D according to this embodiment is designed to be installed next to a wall 97 with the rear surface 302 of the main body 3 facing the wall 97, and therefore employs the following two configurations.

In the first configuration, as shown in FIG. 11A, the power supply unit 2 is provided on the front surface 301 of the main body 3, and the rearward protrusion amount of the support unit 4 from the rear surface 302 of the main body 3 is smaller than the forward protrusion amount of the support unit 4 from the front surface 301 of the main body 3. Specifically, the rearward protrusion amount of the support unit 4 from the rear surface 302 of the main body 3 is set to a few centimeters or less. In this embodiment, as shown in FIG. 11A, the rear surface 302 of the main body 3 and the rear surface of the support unit 4 are flush with each other, so the rearward protrusion amount of the support unit 4 from the rear surface 302 of the main body 3 is 0 cm. Therefore, when the power supply stand 1D is installed next to the wall 97, the gap between the rear surface 302 of the main body 3 and the wall 97 can be kept small, and the power supply stand 1D can be installed stably.

In the second configuration, as shown in FIG. 11B, the power supply unit 2 is provided on the front surface 301 of the main body 3, and the main body 3 further has a pressure receiving unit 38 that protrudes rearward at a location on the rear surface 302 of the main body 3 behind the power supply unit 2. In other words, the pressure receiving unit 38 is provided on the rear side of the power supply unit 2 on the main body 3, and protrudes rearward from the rear surface 302 of the main body 3. Therefore, even if a gap occurs between the rear surface 302 of the main body 3 and the wall 97, for example, the thickness of the baseboard 98, it is possible to fill this gap with the pressure receiving unit 38.

In this embodiment, the amount of protrusion of the pressure receiving portion 38 from the rear surface 302 of the main body 3 is variable. As an example, the pressure receiving portion 38 is connected to the main body 3 with a "screw", like an adjuster bolt. Therefore, by rotating the pressure receiving portion 38, the amount of protrusion of the pressure receiving portion 38 from the rear surface 302 of the main body 3 changes from "L1" shown in FIG. 11A to "L2" shown in FIG. 11B (L2>L1). The amount of protrusion of the pressure receiving portion 38 is adjusted according to, for example, the thickness of the baseboard 98.

The height of the power supply stand 1D is 850 mm as an example as described above, but is not limited to this configuration and can be changed as appropriate. However, considering that the power supply stand 1D is installed near a fixture such as a desk 95, it is preferable that the lower end of the power supply unit 2 is at a height of 720 mm or more from the installation surface 91 and the upper end of the power supply unit 2 is at a height of 850 mm or less from the installation surface 91. Similarly, if the power supply stand 1E fits under the top plate 951 of the desk 95, it is preferable that the upper end of the power supply unit 2 is at a height of 600 mm or less from the installation surface 91. Furthermore, if the power supply stand 1E is installed near the sofa 94 (see FIG. 3) as described in the first embodiment, it is preferable that the lower end of the power supply unit 2 is at a height of 550 mm or more from the installation surface 91 to avoid interference with the armrest.

The configuration of embodiment 2 (including modifications) can be applied in appropriate combination with the configuration described in embodiment 1 (including modifications).

(Embodiment 3)
12A and 12B, the power supply station 1F according to this embodiment differs from the power supply station 1D according to the second embodiment in the arrangement of the battery 13, etc. Hereinafter, the same components as those in the second embodiment will be denoted by the same reference numerals and will not be described as appropriate.

That is, the power supply station 1F is similar to the power supply station 1C (see FIG. 8) according to the third modified example of the first embodiment in that it is equipped with a battery 13. Due to the configuration including the battery 13, the power supply station 1F can supply power from the power supply unit 2 to the power supply target 92 without receiving power from an external power source via the power supply cord 5 (see FIG. 9). Furthermore, the power receiving unit 6 is omitted in the power supply station 1F.

The power supply station 1F according to this embodiment further includes a charging circuit 101. The battery 13 is a secondary battery (storage battery) that is charged by the charging circuit 101. That is, in this embodiment, the battery 13 is charged by the charging circuit 101 of the power supply station 1F, so that the battery 13 can be used repeatedly. As an example, the charging circuit 101 is built into the first block 34 of the main body 3. The charging circuit 101 is electrically connected to at least the battery 13 and a non-contact power receiving circuit 104 described later.

The power supply station 1F further includes a discharge circuit 102 that supplies the power output from the battery 13 to the power supply unit 2. The discharge circuit 102 includes, for example, an inverter that converts the DC voltage output from the battery 13 into an AC voltage. As an example, the discharge circuit 102 is built into the first block 34 of the main body unit 3. The discharge circuit 102 is electrically connected to at least the battery 13 and the power supply unit 2.

In this embodiment, the power supply unit 2 can supply power to the power supply target 92 even while the battery 13 is being charged. Specifically, the discharge circuit 102 is also electrically connected to the charging circuit 101, and can supply not only the power output from the battery 13 but also the power output from the charging circuit 101 to the power supply unit 2. As a result, even while the battery 13 is being charged, the power output from the charging circuit 101 can be sent to the power supply unit 2 by the discharge circuit 102, and power can be supplied from the power supply unit 2 to the power supply target 92. In this case, even if the battery 13 is fully charged, the charging circuit 101 continues to operate, so that the charging circuit 101 continuously supplies a small current to the battery 13 by, for example, a trickle charging method.

The power supply station 1F according to this embodiment further includes a remaining capacity display unit 103. The remaining capacity display unit 103 is realized, for example, using an LED (Light Emitting Diode) or the like, and displays the remaining capacity of the battery 13. The remaining capacity of the battery 13 in this disclosure is the relative remaining capacity (RSOC: Relative State Of Charge) obtained by dividing the remaining capacity (RC: Remaining Capacity) of the battery 13 by the full charge capacity (FCC: Full Charge Capacity) of the battery 13. The relative remaining capacity (RSOC) in this disclosure is synonymous with the charging rate (SOC: State Of Charge). As an example, the remaining capacity display unit 103 displays the remaining capacity of the battery 13 by changing the lighting state (on/off, blinking pattern, light color, etc.) according to the remaining capacity of the battery 13.

It is preferable that such a remaining charge display unit 103 is arranged around the power supply unit 2, that is, near the power supply unit 2, so that it is easily noticeable to the user 93 who uses the power supply unit 2. In the example of FIG. 12A and FIG. 12B, the remaining charge display unit 103 is arranged below the four connection ports 21 to 24 of the power supply unit 2 in the second block 35. Furthermore, the remaining charge display unit 103 is arranged on the same surface (front surface 301 in this case) as the power supply unit 2 in the main body unit 3. However, this configuration is not limited, and for example, a frame-shaped light-emitting unit that surrounds each of the four connection ports 21 to 24 of the power supply unit 2 or the entire power supply unit 2 may be provided on the front surface 301 of the main body unit 3, and the remaining charge display unit 103 may be realized by this frame-shaped light-emitting unit. Furthermore, the remaining charge display unit 103 is not limited to being arranged on the same surface (front surface 301 in this case) as the power supply unit 2 in the main body unit 3, and may be arranged on the top surface, right side surface, or left side surface of the main body unit 3, for example.

The power supply station 1F according to this embodiment further includes a non-contact power receiving circuit 104. The non-contact power receiving circuit 104 is supplied with power contactlessly from the non-contact power supply circuit 204. The charging circuit 101 charges the battery 13 with the power supplied to the non-contact power receiving circuit 104. That is, in this embodiment, power is supplied contactlessly to the power supply station 1F by a non-contact power supply method from the charging stand 200 having the non-contact power supply circuit 204.

Specifically, the charging stand 200 has a non-contact power supply circuit 204 for non-contact power supply. The non-contact power supply circuit 204 includes a primary coil. In this embodiment, the primary coil is, as an example, a spiral coil in which a conductor is wound in a spiral shape when viewed in a plane.

12A, the charging stand 200 has a recess 201, a power indicator 202, a power cord 203, and a non-contact power supply circuit 204. The recess 201 is formed on the upper surface of the charging stand 200 to match the shape of the support part 4. The power indicator 202 is realized, for example, using an LED (Light Emitting Diode) or the like, and indicates the power supply state of the non-contact power supply circuit 204. The power cord 203 is electrically connected to the non-contact power supply circuit 204. An outlet plug is provided at the end of the power cord 203 opposite the non-contact power supply circuit 204. Therefore, for example, when the outlet plug of the power cord 203 is connected to an external power source such as an outlet installed on the wall of a room, power is supplied from the external power source to the non-contact power supply circuit 204.

In this embodiment, the non-contact power receiving circuit 104 is disposed on the support portion 4. The non-contact power receiving circuit 104 includes a secondary coil that is electromagnetically coupled (at least one of electric field coupling and magnetic field coupling) with the primary coil. In this embodiment, as an example, the secondary coil is a spiral coil in which a conductor is wound in a spiral shape in a plan view, similar to the primary coil. The non-contact power receiving circuit 104 is electrically connected to the charging circuit 101.

The non-contact power receiving circuit 104 includes a rectifying and smoothing circuit, and rectifies and smoothes the AC voltage generated across the secondary coil. The non-contact power receiving circuit 104 then outputs the DC voltage obtained by rectifying and smoothing to the charging circuit 101.

With the above configuration, the power supply stand 1F is placed on the charging stand 200 as shown in FIG. 12B, and with the support part 4 fitted into the recess 201 of the charging stand 200, power is supplied (transmitted) contactlessly from the contactless power supply circuit 204 of the charging stand 200 to the contactless power receiving circuit 104. The power supply stand 1F according to this embodiment employs a magnetic resonance method (magnetic resonance method) that transmits power by resonating a resonant circuit including a primary coil and a resonant circuit including a secondary coil. However, the method of transmitting power from the charging stand 200 to the power supply stand 1F is not limited to the magnetic resonance method, and may be, for example, an electromagnetic induction method or a microwave transmission method.

The battery 13 has a large capacity by including a plurality of cells electrically connected in series or parallel, or in series and parallel. These cells are integrated by being housed in one case. The battery 13 including the plurality of cells has a so-called vertically elongated shape, as shown in FIG. 12A. The battery 13 having such a shape is housed in a so-called vertically elongated body part 3, which is also long in the vertical direction. That is, the battery 13 is disposed in the body part 3 of the power supply stand 1F. As a result, it is not necessary to provide a space in the support part 4 to house the battery 13, and it is possible to make the thickness of the support part 4 smaller than that of the battery 13, for example. As a result, as described in the second embodiment, it is possible to use the support part 4 by stepping on a piece of furniture such as a desk, thereby fixing (temporarily fixing) the support part 4 in a fixed position on the installation surface 91.

Here, the battery 13 is located below the center of gravity P1 of the main body 3. In other words, the battery 13 is disposed at a position lower than the center of gravity P1 of the main body 3, and the height H21 from the bottom surface of the power supply stand 1F to the top end of the battery 13 is lower than the height H22 from the bottom surface of the power supply stand 1F to the center of gravity P1 of the main body 3 (H21<H22). In other words, the battery 13 is disposed so as to be contained between the center of gravity P1 of the main body 3 and the bottom end of the main body 3. Here, the power supply unit 2 is located above the center of gravity P1 of the main body 3. In other words, the battery 13 is located at least below the power supply unit 2.

In particular, in this embodiment, the battery 13 is positioned even lower than the center of gravity of the entire power supply station 1F including the main body 3 and the support part 4 (which is lower than the center of gravity P1 of the main body 3). Specifically, the battery 13 is positioned at the lowest of the multiple components of the main body 3 (the power supply part 2, the charging circuit 101, the discharging circuit 102, and the battery 13). The battery 13 is positioned so that it fits at a height that is less than 1/2 the height H22 of the center of gravity P1 of the main body 3. In other words, the height H21 of the upper end of the battery 13 is less than 1/2 the height H22 of the center of gravity P1 of the main body 3.

The battery 13 is relatively heavy among the multiple components of the main body 3, so as described above, by positioning it as low as possible in the main body 3, the center of gravity of the entire power supply stand 1F can be lowered, allowing the power supply stand 1F to be installed stably. In other words, the lower the heavier the object is positioned, the lower the center of gravity of the entire power supply stand 1F can be, improving the stability of the power supply stand 1F when installed.

However, the position of the battery 13 is not limited to the above-mentioned position, and the battery 13 may be arranged, for example, above the charging circuit 101 or at the same position (height) as the charging circuit 101 in the vertical direction. The battery 13 may also be arranged above the power supply unit 2 or at the same position (height) as the power supply unit 2 in the vertical direction.

According to the power supply stand 1F of the present embodiment described above, power can be supplied from the power supply unit 2 to the power supply target 92 without receiving power from an external power source via the power supply cord 5. Therefore, the user 93 can more freely place the power supply source for the power supply target 92 in an environment such as a living room of a house, regardless of the location of an outlet or the like. In other words, the power supply stand 1F can be made cordless, which allows for even greater freedom in the placement of the power supply source for the power supply target 92. Moreover, since the power supply stand 1F does not need to receive power from an external power source via the power supply cord 5 when in use, it is possible to prevent the user 93's foot from getting caught on the power supply cord 5.

In particular, in this embodiment, since the battery 13 is a secondary battery, for example, when the power supply stand 1F is not in use, it is possible to charge the battery 13 by placing the power supply stand 1F on the charging stand 200 that is placed in a corner (near a wall, etc.) of a room or the like. Then, only when the power supply stand 1F is in use, the user 93 can remove the power supply stand 1F from the charging stand 200 and move the power supply stand 1F to a position of his/her choice. This allows the power supply stand 1F to be normally placed in a corner (near a wall, etc.) of a room or the like where it is less likely to get in the way.

Next, we will explain a variation of embodiment 3.

Figure 13A shows a main part of a power supply stand 1G according to a first modified example of the third embodiment. The power supply stand 1G differs from the power supply stand 1F according to the third embodiment in that power is supplied from the charging stand 200G by a contact power supply method rather than a non-contact power supply method. In the example of Figure 13A, a pair of contact power receiving terminals 105 is provided on the front end surface of the support part 4. The pair of contact power receiving terminals 105 are electrically connected to the charging circuit 101. Meanwhile, a pair of contact power supply terminals 205 is provided on the inner surface of the recess 201 in the charging stand 200G. With the above configuration, the power supply stand 1G is placed on the charging stand 200G, and the pair of contact power receiving terminals 105 are brought into contact with the pair of contact power supply terminals 205 of the charging stand 200G with the support part 4 fitted into the recess 201 of the charging stand 200G. In this state, power is supplied (transmitted) from the pair of contact power supply terminals 205 of the charging stand 200G to the pair of contact power receiving terminals 105 of the power supply station 1F. In this configuration, the charging circuit 101 for charging the battery 13 is not limited to being provided in the main body 3, but may also be provided in the support part 4 or the charging stand 200G.

Figure 13B shows the main parts of the power supply stand 1H according to the second modified example of the third embodiment. The power supply stand 1H differs from the power supply stand 1F according to the third embodiment in that power is directly supplied from an external power source via the power supply cord 5. In the example of Figure 13B, the power receiving unit 6 is disposed at the lower end of the front surface 301 of the main body 3. The configuration of the power receiving unit 6 is the same as that of the power receiving unit 6 described in the first embodiment. That is, the pair of terminals 51 of the power supply cord 5 contact (connect) with the pair of power receiving terminals 61 of the power receiving unit 6, thereby electrically connecting the power supply cord 5 to the power receiving unit 6. The pair of power receiving terminals 61 are electrically connected to the charging circuit 101. The configuration of the coupling structure 7 (the pair of metal plates 71 and the pair of magnets 72) is also the same as that of the coupling structure 7 described in the first embodiment. With the above configuration, when the power supply cord 5 is electrically connected to the power receiving unit 6 of the power supply stand 1H, power is supplied (transmitted) directly from an external power source to the power receiving unit 6 of the power supply stand 1H via the power supply cord 5.

14A and 14B show the main parts of the power supply stand 1I according to the third modified example of the third embodiment. The power supply stand 1I differs from the power supply stand 1F according to the third embodiment in that the battery 13 is attached to the main body 3 so as to be removable from the main body 3. In the power supply stand 1I, as shown in FIG. 14A, the battery 13 has one battery case 131 that houses a plurality of cells. The battery case 131 is provided with a handle 132. The main body 3 is also formed with a battery housing section 106 of a size and shape that can house the battery case 131. The battery housing section 106 is a recess that opens in a rectangular shape on the front surface 301 of the main body 3. Furthermore, the main body 3 has a battery connector 107 for electrically connecting the battery 13. The battery connector 107 is disposed, for example, on the bottom surface of the battery housing section 106.

In the above configuration, when attaching the battery 13 to the main body 3, the user 93 pushes the battery 13 into the battery housing 106 from the front of the main body 3 to house the battery 13 in the battery housing 106. As a result, the battery 13 is attached to the main body 3 as shown in FIG. 14B. At this time, the connector of the battery 13 is connected to the battery connector 107 on the bottom surface of the battery housing 106, so that the battery 13 and the main body 3 are electrically connected. On the other hand, when removing the battery 13 from the main body 3, the user 93 pulls the battery 13 forward by holding the handle 132, thereby removing the battery 13 from the battery housing 106. In addition, the battery housing 106 may be provided with a locking mechanism for holding the battery 13 so as to prevent the battery 13 from falling off the main body 3 when the battery 13 is attached to the main body 3, i.e., when the battery 13 is attached to the main body 3, the battery housing 106 may be provided with a locking mechanism for holding the battery 13.

In this way, with a configuration in which the battery 13 can be removed from the main body 3, for example, when the battery 13 deteriorates, it becomes easy to replace only the battery 13. Also, if the battery 13 is a secondary battery, it is possible to charge the battery 13 with a dedicated charger and attach it to the main body 3. Furthermore, by using a battery that is also used with other devices, such as an electric vehicle or power tool, as the battery 13, it is possible to share the battery 13 with other devices, or to use the battery 13 charged at the power supply station 1I with other devices. Also, the number or type of the batteries 13 attached to the main body 3 may be changeable. In this case, for example, by changing the number or type of the batteries 13, it is possible to change the capacity or voltage of the batteries 13 attached to the main body 3.

As another variation of the third embodiment, the battery 13 is not limited to a secondary battery, but may be a primary battery, a solar cell, or the like. Furthermore, the battery 13 is not limited to being built into the main body 3, but may be externally attached to the main body 3 or the support part 4, for example. Furthermore, when the battery 13 is a secondary battery, the power supply part 2 does not have to be able to supply power to the power supply target 92 while the battery 13 is being charged.

The configuration of embodiment 3 (including modified examples) can be applied in appropriate combination with the configurations (including modified examples) described in embodiments 1 and 2. For example, as described in embodiment 1, a configuration in which the main body 3 has a fixed part 31 and a movable part 32 can be applied in combination with the configuration of embodiment 3.

(summary)
As described above, the power supply stand (1, 1A to 1I) according to the first aspect includes a portable main body (3) and a support part (4). The main body (3) has a power supply part (2) for supplying power to a power supply target (92). The support part (4) supports the main body (3) so that the main body (3) stands on the installation surface (91) when placed on the installation surface (91).

According to this configuration, the power supply stand (1, 1A to 1I) can be freely carried by the user (93) and installed at any position on the installation surface (91). This allows the power supply source to the power supply target (92) such as a mobile terminal to be freely arranged in an environment such as a living room of a house. Moreover, the main body (3) having the power supply unit (2) is supported by the support unit (4) and installed so as to stand on the installation surface (91). Therefore, in the power supply stand (1, 1A to 1I), the power supply unit (2) is unlikely to be stepped on by a person's foot or to be splashed with liquid when liquid is spilled on the installation surface (91). Therefore, the power supply stand (1, 1A to 1I) has the advantage that malfunctions and other problems are unlikely to occur even when the power supply source to the power supply target (92) is freely arranged.

The power supply station (1, 1A to 1I) according to the second aspect is the first aspect in which the vertical dimension of the main body (3) is greater than both the front-to-rear dimension and the left-to-right dimension of the main body (3).

With this configuration, the main body (3) is elongated in the vertical direction, so that the area occupied by the main body (3) on the installation surface (91) can be kept small.

The power supply station (1, 1A to 1I) according to the third aspect is the first or second aspect, in which the power supply unit (2) has a plurality of connection ports (21 to 25) for connecting the power supply target (92). The plurality of connection ports (21 to 25) are arranged in a line along the vertical direction.

With this configuration, the multiple connection ports (21-25) are arranged at different heights, so that the user (93) can use the connection port that is at the height that is most convenient for the user depending on the situation.

The power supply stand (1, 1A-1I) according to the fourth aspect is any one of the first to third aspects, in which the main body (3) has a fixed part (31) and a movable part (32). The fixed part (31) is fixed to the support part (4). The movable part (32) is movable relative to the fixed part (31) in the vertical direction. The power supply part (2) is provided on the movable part (32).

With this configuration, the height of the power supply unit (2) changes with the movement of the movable unit (32), allowing the user (93) to adjust the height of the power supply unit (2) to a comfortable height depending on the situation.

The power supply station (1, 1A to 1I) according to the fifth aspect is the fourth aspect, and further includes a power supply cord (5) for supplying power to the power supply unit (2). The movable unit (32) has a power receiving unit (6) for electrically connecting the power supply cord (5).

According to this configuration, by connecting the power supply cord (5) to an external power source, it is possible to supply power to the power supply unit (2) even from an external power source located away from the main body unit (3). In addition, since the power receiving unit (6) is provided on the movable unit (32), the configuration for electrically connecting the power supply unit (2) and the power receiving unit (6), which are also provided on the movable unit (32), can be simplified.

The power supply station (1, 1A to 1I) according to the sixth aspect is any one of the first to fourth aspects, and further includes a power supply cord (5) for supplying power to the power supply unit (2). The main body unit (3) has a power receiving unit (6) for electrically connecting the power supply cord (5).

With this configuration, by connecting the power supply cord (5) to an external power source, it is possible to supply power to the power supply unit (2) even from an external power source located away from the main body unit (3).

The power supply stand (1, 1A to 1I) according to the seventh aspect is the fifth or sixth aspect, and further includes a coupling structure (7). The coupling structure (7) mechanically couples the power supply cord (5) to the power receiving unit (6) by magnetic force while the power supply cord (5) is electrically connected to the power receiving unit (6).

With this configuration, for example, when the foot of the user (93) gets caught on the power supply cord (5) and tension is applied to the power supply cord (5), the mechanical connection between the power receiving unit (6) and the power supply cord (5) is easily released. Therefore, the power supply stand (1, 1A to 1I) is less likely to tip over.

The power supply stand (1, 1A to 1I) according to the eighth aspect is any one of the fifth to seventh aspects, in which the power supply unit (2) is provided on the front surface (301) of the main body unit (3). The power receiving unit (6) is disposed on the front surface (301) of the main body unit (3) and at least one of both left and right side surfaces.

This configuration makes it possible to install the power supply stand (1, 1A to 1I) next to a wall (97) with the rear surface (302) of the main body (3) facing the wall (97) while avoiding interference between the power supply cord (5) and the wall (97).

The power supply station (1, 1A-1I) according to the ninth aspect is any one of the first to eighth aspects, and further includes a detection unit (11) and a stop unit (12). The detection unit (11) detects the attitude of the main body unit (3). The stop unit (12) stops the supply of power from the power supply unit (2) to the power supply target (92) based on the attitude of the main body unit (3) detected by the detection unit (11).

According to this configuration, for example, if the main body unit (3) falls over, the power supply from the power supply unit (2) to the power supply target (92) can be automatically stopped.

The power supply stand (1, 1A-1I) according to the tenth aspect is any one of the first to ninth aspects, in which the power supply unit (2) is provided on the front surface (301) of the main body unit (3). The rearward protrusion of the support unit (4) from the rear surface (302) of the main body unit (3) is smaller than the forward protrusion of the support unit (4) from the front surface (301) of the main body unit (3).

With this configuration, when the power supply stand (1, 1A to 1I) is installed next to the wall (97) with the rear surface (302) of the main body (3) facing the wall (97), the gap between the rear surface (302) of the main body (3) and the wall (97) can be kept small.

The power supply stand (1, 1A-1I) according to the eleventh aspect is any one of the first to tenth aspects, in which the power supply unit (2) is provided on the front surface (301) of the main body (3). The main body (3) further has a pressure receiving portion (38) that protrudes rearward from a portion on the rear surface (302) of the main body (3) behind the power supply unit (2).

With this configuration, when the power supply stand (1, 1A-1I) is installed next to the wall (97) with the rear surface (302) of the main body (3) facing the wall (97), the pressure receiving part (38) can reduce the gap that occurs between the rear surface (302) of the main body (3) and the wall (97). For example, when inserting a plug into the power supply part (2), even if a force is applied to the power supply part (2) in a direction that tilts the main body part (3) toward the wall (97), the pressure receiving part (38) can receive this force and suppress the tilt of the main body part (3).

The power supply station (1, 1A to 1I) according to the twelfth aspect is any one of the first to eleventh aspects and further includes a fixing structure (41) for fixing the support part (4) to a fixed position on the installation surface (91).

This configuration makes it less likely for the power supply station (1, 1A to 1I) to tip over.

The power supply stand (1, 1A to 1I) according to the thirteenth aspect is any one of the first to twelfth aspects, in which the main body (3) further has a protruding part that protrudes upward from a plane including the upper surface (953) of the fixture installed on the installation surface (91). The power supply part (2) is provided on the protruding part.

With this configuration, when the power supply stand (1, 1A to 1I) is installed near a fixture, the power supply unit (2) protrudes upward from the top surface (953) of the fixture, improving the usability of the power supply unit (2).

The power supply station (1, 1A-1I) according to the 14th aspect is any one of the first to 13th aspects, in which the main body (3) further has a narrowed portion (37) in a part of the vertical direction whose dimension in the front-rear direction or the left-right direction is smaller than other parts of the main body (3).

According to this configuration, for example, by sandwiching the narrowed portion (37) between the top plate (951) of the desk (95) and the wall (97), the power supply stand (1, 1A to 1I) is less likely to tip over.

The power supply station (1, 1A to 1I) according to the fifteenth aspect further includes a battery (13) for supplying power to the power supply unit (2) in any one of the first to fourteenth aspects.

With this configuration, the power supply stations (1, 1A to 1I) can be made cordless, allowing greater freedom in arranging the power supply source to the power supply target (92).

The power supply station (1, 1A to 1I) according to the 16th aspect is the 15th aspect, in which the battery (13) is located below the center of gravity (P1) of the main body (3).

With this configuration, the relatively heavy battery (13) is positioned below the center of gravity (P1) of the main body (3), so the center of gravity of the entire power supply station (1, 1A to 1I) can be lowered, making it easier to install the power supply station (1, 1A to 1I) stably.

The power supply station (1, 1A to 1I) according to the seventeenth aspect is the fifteenth or sixteenth aspect, in which the battery (13) is located at least below the power supply unit (2).

With this configuration, the relatively heavy battery (13) is positioned lower than the power supply unit (2), so the center of gravity of the entire power supply stand (1, 1A to 1I) can be lowered, making it easier to install the power supply stand (1, 1A to 1I) stably.

The power supply station (1, 1A to 1I) according to the 18th aspect is any one of the 15th to 17th aspects, in which the battery (13) is disposed in the main body (3).

With this configuration, there is no need to provide a battery (13) in the support part (4), so the support part (4) can be made thinner.

The power supply station (1, 1A to 1I) according to the 19th aspect is the 18th aspect, in which the battery (13) is attached to the main body (3) so as to be removable from the main body (3).

This configuration makes it easy to replace only the battery (13) if the battery (13) deteriorates, for example.

The power supply station (1, 1A to 1I) according to the twentieth aspect is any one of the fifteenth to nineteenth aspects, and further includes a remaining capacity display unit (103) that displays the remaining capacity of the battery (13).

With this configuration, the remaining capacity of the battery (13) can be easily checked on the remaining capacity display unit (103).

The power supply station (1, 1A to 1I) according to the 21st aspect is any one of the 15th to 20th aspects, and further includes a charging circuit (101). The battery (13) is a secondary battery that is charged by the charging circuit (101).

With this configuration, the battery (13) can be charged at the power supply station (1, 1A to 1I) itself and can be used repeatedly.

The power supply station (1, 1A to 1I) according to the 22nd aspect is the 21st aspect in which the power supply unit (2) is capable of supplying power to the power supply target (92) even while the battery (13) is being charged.

This configuration allows power to be supplied from the power supply unit (2) to the power supply target (92) without stopping charging the battery (13), improving usability.

The power supply station (1, 1A to 1I) according to the 23rd aspect is the 21st or 22nd aspect, and further includes a non-contact power receiving circuit (104) to which power is supplied contactlessly from the non-contact power supply circuit (204). The charging circuit (101) charges the battery (13) with the power supplied to the non-contact power receiving circuit (104).

With this configuration, there is no need to connect the power supply station (1, 1A to 1I) to a charger or the like, making it easy to charge the battery (13).

Aspects 2 to 23 are not essential configurations for the power supply station (1, 1A to 1I) and may be omitted as appropriate.

REFERENCE SIGNS LIST 1, 1A, 1B, 1C, 1D, 1E, 1F, 1G, 1H, 1I Power supply stand 2 Power supply unit 3 Main body unit 4 Support unit 5 Power supply cord 6 Power receiving unit 11 Detection unit 12 Stop unit 21 to 25 Connection port 31 Fixed unit 32 Movable unit 35 Second block (protruding unit)
37 Narrowed portion 38 Pressure receiving portion 41 Fixed structure 91 Installation surface 92 Power supply target 95 Desk (furniture)
101 Charging circuit 103 Remaining charge display unit 104 Non-contact power receiving circuit 204 Non-contact power supply circuit 301 Front surface 302 Rear surface 953 Top surface of desk (furniture) P1 Center of gravity

Claims (11)

A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
Further comprising a battery for supplying power to the power supply unit,
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block having a front surface on which the power supply portion is provided, and a third block having a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
The main body portion has a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the narrowed portion having a smaller dimension in a front-rear direction than other portions of the main body portion.
Power supply stand. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery storage section into which a battery that supplies power to the power supply section can be attached and detached,
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block having a front surface on which the power supply portion is provided, and a third block having a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
The main body portion has a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the narrowed portion having a smaller dimension in a front-rear direction than other portions of the main body portion.
Power supply stand. The power receiving unit is further provided for electrically connecting the cord.
3. The power supply station according to claim 1 or 2. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery for supplying power to the power supply unit and a contact power receiving terminal,
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block that has the power supply portion, and a third block that has a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
the second block further includes a remaining capacity display unit that displays a remaining capacity of the battery,
the battery is a secondary battery,
The support part is attachable to and detachable from the charging base,
the charging stand includes the cord and a contact power supply terminal,
The support part is attached to the charging stand, and in a state in which the contact power supply terminal is in contact with the contact power receiving terminal, power from the external power source can be supplied to the power supply part and the battery via the contact power supply terminal and the contact power receiving terminal.
Power supply stand. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery for supplying power to the power supply unit and a contact power receiving terminal,
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block that has the power supply portion, and a third block that has a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
the main body portion has a narrowed portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the narrowed portion having a smaller dimension in a front-rear direction than other portions of the main body portion,
the battery is a secondary battery,
The support part is attachable to and detachable from the charging base,
the charging stand includes the cord and a contact power supply terminal,
The support part is attached to the charging stand, and in a state in which the contact power supply terminal is in contact with the contact power receiving terminal, power from the external power source can be supplied to the power supply part and the battery via the contact power supply terminal and the contact power receiving terminal.
Power supply stand. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery accommodating section into which a battery that supplies power to the power supply section can be attached and detached, and a contact power receiving terminal;
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block that has the power supply portion, and a third block that has a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
the second block further includes a remaining capacity display unit that displays a remaining capacity of the battery,
the battery is a secondary battery,
The support part is attachable to and detachable from the charging stand;
the charging stand includes the cord and a contact power supply terminal,
When the support part is attached to the charging stand and the contact power supply terminal is in contact with the contact power receiving terminal, power from the external power source can be supplied to the power supply part and the battery via the contact power supply terminal and the contact power receiving terminal.
Power supply stand. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery accommodating section in which a battery that supplies power to the power supply section can be attached and detached, and a contact power receiving terminal;
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block that has the power supply portion, and a third block that has a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
the main body portion has a constricted portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the constricted portion having a smaller dimension in a front-rear direction than other portions of the main body portion,
the battery is a secondary battery,
The support part is attachable to and detachable from the charging base,
the charging stand includes the cord and a contact power supply terminal,
The support part is attached to the charging stand, and in a state in which the contact power supply terminal is in contact with the contact power receiving terminal, power from the external power source can be supplied to the power supply part and the battery via the contact power supply terminal and the contact power receiving terminal.
Power supply stand. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery for supplying power to the power supply unit and a non-contact power receiving circuit,
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block that has the power supply portion, and a third block that has a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
the second block further includes a remaining capacity display unit that displays a remaining capacity of the battery,
the battery is a secondary battery,
The support part is attachable to and detachable from the charging base,
the charging stand includes the cord and a non-contact power supply circuit that supplies power to the non-contact power receiving circuit in a non-contact manner,
When the support section is attached to the charging stand, power from the external power source can be supplied to the power supply section and the battery via the non-contact power supply circuit and the non-contact power receiving circuit.
Power supply stand. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery for supplying power to the power supply unit and a non-contact power receiving circuit,
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block that has the power supply portion, and a third block that has a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
the main body portion has a constricted portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the constricted portion having a smaller dimension in a front-rear direction than other portions of the main body portion,
the battery is a secondary battery,
The support part is attachable to and detachable from the charging base,
the charging stand includes the cord and a non-contact power supply circuit that supplies power to the non-contact power receiving circuit in a non-contact manner,
When the support section is attached to the charging stand, power from the external power source can be supplied to the power supply section and the battery via the non-contact power supply circuit and the non-contact power receiving circuit.
Power supply stand. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery accommodating section in which a battery that supplies power to the power supply section can be attached and detached, and a non-contact power receiving circuit,
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block that has the power supply portion, and a third block that has a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
the second block further includes a remaining capacity display unit that displays a remaining capacity of the battery,
the battery is a secondary battery,
The support part is attachable to and detachable from the charging base,
the charging stand includes the cord and a non-contact power supply circuit that supplies power to the non-contact power receiving circuit in a non-contact manner,
When the support section is attached to the charging stand, power from the external power source can be supplied to the power supply section and the battery via the non-contact power supply circuit and the non-contact power receiving circuit.
Power supply stand. A main body having a power supply unit for supplying power to a power supply target;
a support portion that supports the main body portion so as to stand the main body portion on an installation surface,
A self-contained power supply stand that is portable and placed on the installation surface,
The device further includes a battery accommodating section in which a battery that supplies power to the power supply section can be attached and detached, and a non-contact power receiving circuit,
The power of the battery can be supplied to the power supply unit without a cord being connected to supply power from an external power source to the power supply station,
the main body portion includes a first block that houses the battery, a second block that has the power supply portion, and a third block that has a front surface to which the first block and the second block are fixed such that the second block is located above the first block;
the main body portion has a constricted portion in a portion of the third block between an upper surface of the first block and a lower surface of the second block, the constricted portion having a smaller dimension in a front-rear direction than other portions of the main body portion,
the battery is a secondary battery,
The support part is attachable to and detachable from the charging base,
the charging stand includes the cord and a non-contact power supply circuit that supplies power to the non-contact power receiving circuit in a non-contact manner,
When the support section is attached to the charging stand, power from the external power source can be supplied to the power supply section and the battery via the non-contact power supply circuit and the non-contact power receiving circuit.
Power supply stand.

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