The present disclosure relates to a connection unit.
Toys are known in which flat plate connection units are magnetically connected so as to be three-dimensionally combined into a variety of shapes.
For example, PTL 1 discloses an intelligent toy having a plurality of plate members (connection units) with magnets provided on its peripheral edge so that they are magnetically connected into a three-dimensional assembly.
If connection units which can be magnetically connected into an assembly can also be electrically connectable to each other, it is possible to provide them with various electrical mechanisms. This makes it possible to provide a toy that is more enjoyable than those whose connection units are simply magnetically connectable into an assembly.
It is therefore an object of present disclosure to solve the above-mentioned problem and to provide a connection unit which is magnetically and electrically connectable.
The present disclosure aims to advantageously solve the problem set forth above, and a connection unit disclosed herein comprises: a body having a substantially flat plate shape; a magnet disposed on at least one side of a peripheral edge of the body; and at least three electrode terminals disposed on the one side of the body, the one side having the magnet disposed thereon, wherein an outer surface of the one side of the body has a curved surface which curves in a thickness direction or a surface having a polygonal cross section, the electrode terminals are disposed along the curved surface or the surface having the polygonal cross section of the outer surface, the at least three electrode terminals comprise one or more positive electrode terminals and one or more negative electrode terminals, and the one or more positive electrode terminals and the one or more negative electrode terminals are disposed on the one side so as to be line-symmetrical about a perpendicular line perpendicular to the one side of the body and crossing the center of the one side of the body. With such a configuration, the connection unit of the present disclosure can be magnetically connected to another connection unit by a magnet disposed at one side of the peripheral edge of the body. At this time, the connection unit can be electrically connected to the other connection unit by electrode terminals disposed at the one side. The connection unit of the present disclosure can therefore be magnetically and electrically connectable to another connection unit. Further, because the electrode terminals are disposed along a curved surface or a surface having a polygonal cross section of the outer surface of the body, it is possible to allow the connection angle θ to have a high degree of freedom when connecting the connection unit of the present disclosure to another connection unit. Also, because the positive electrode terminal(s) and negative electrode terminal(s) are disposed so as to be line-symmetrical about a perpendicular line perpendicular to the one side of the body and crossing the center of the one side of the body, the connection unit of the present disclosure is connectable to another connection unit even if it is turned upside down.
It is preferred that the connection unit of the present disclosure further comprises a circuit element disposed inside the body and the circuit element is electrically connected to the electrode terminals. With such a configuration, the power generated by the circuit element can be output from the electrode terminals, or the power that is input from the electrode terminals can be consumed by the circuit element.
It is preferred that the connection unit of the present disclosure further comprises a wiring board disposed in the inside of the body and the circuit element is electrically connected to the electrode terminals via a wiring of the wiring board. With such a configuration, it is possible to easily establish a connection between the circuit element and the electrode terminals in a space-saving manner.
In the connection unit of the present disclosure, it is preferred that the circuit element comprises an energy harvesting element capable of outputting power, generated by energy harvesting, from the electrode terminals. With such a configuration, the power generated by energy harvesting can be output from the electrode terminals.
In the connection unit of the present disclosure, it is preferred that the circuit element comprises a load element capable of consuming power that is input from the electrode terminals. With such a configuration, the power that is input from the electrode terminals can be consumed by the load element.
In the connection unit of the present disclosure, it is preferred that the load element is a light-emitting element. With such a configuration, the connection unit can be used as a lighting device configured to emit light by means of the power that is input from the electrode terminals.
It is preferred that the connection unit of the present disclosure further comprises at the peripheral edge of the body a load element that is electrically connected to the electrode terminals. With such a configuration, the load element can be easily mounted on the connection unit.
In the connection unit of the present disclosure, it is preferred that the body has a substantially polygonal shape in plan view.
In the connection unit of the present disclosure, it is preferred that the body has a frame shape having an opening.
According to the present disclosure, it is possible to provide a connection unit which is magnetically and electrically connectable.
In the Accompanying Drawings:
Hereinafter, embodiments of the present disclosure will be described with reference to the accompanying drawings. Components common among the drawings are given the same reference numerals.
The connection unit 1, as illustrated in
The body 11 has a substantially flat plate shape. The term “substantially flat plate shape” as used herein means both a flat plate shape and a frame shape having an opening in the inside.
The body 11 has a substantially polygonal shape in plan view. The term “substantially polygonal shape” as used herein means both a general polygonal shape and a polygonal shape whose corners are curved.
The body 11 may be made of resin or other materials.
The magnet 12 is disposed at the peripheral edge of the body 11 as illustrated in
The magnet 12 is magnetically connectable to a magnet 12 of another connection unit 1, allowing the connection units 1 to be magnetically connected to each other.
The magnet 12 may be fixedly or rotatably disposed on the peripheral edge of the body 11. When rotatably disposed, the magnet 12 is, for example, cylindrical in shape and may be disposed on the peripheral edge of the body 11 such that the axis of the cylinder is parallel to the sides of the peripheral edge of the body 11. The cylindrical magnet 12 is rotatable about the axis of the cylinder when a cylindrical or cuboidal cavity that is slightly larger than the cylindrical magnet 12 is formed in the peripheral edge of the body 11 and then the cylindrical magnet 12 is housed in that cavity.
As illustrated in
At least one positive electrode terminal 13 is disposed on one side of the peripheral edge of the body 11 where the magnet 12 is disposed. In the example illustrated in
At least one negative electrode terminal 14 is disposed on one side of the peripheral edge of the body 11 where the magnet 12 is disposed. In the example illustrated in
Referring to the schematic configuration of the cross section illustrated in
The positive electrode terminal 13 and the negative electrode terminal 14 may for example be ribbon-shaped conductors which are disposed along the curved surface of the outer surface 31 of the body 11.
The surface of the positive electrode terminal 13 is composed of conductor. When the connection unit 1 is magnetically connected to another connection unit 1 by means of magnetic coupling by the magnets 12, the surface of the positive electrode terminal 13 of the connection unit 1 contacts the surface of the positive electrode terminal 13 of the other connection unit 1. At this time, the positive electrode terminal 13 of the connection unit 1 is electrically connected to the positive electrode terminal 13 of the other connection unit 1.
The surface of the negative electrode terminal 14 is composed of conductor. When the connection unit 1 is magnetically connected to another connection unit 1 by means of magnetic coupling by the magnets 12, the surface of the negative electrode terminal 14 of the connection unit 1 contacts the surface of the negative electrode terminal 14 of the other connection unit 1. At this time, the negative electrode terminal 14 of the connection unit 1 is electrically connected to the negative electrode terminal 14 of the other connection unit 1.
As illustrated in
While
The negative electrode terminal 14 is also disposed along the curved surface of the outer surface 31 of the body 11 similarly to the positive electrode terminal 13. Thus, the connection angle θ can also have a high degree of freedom as to establishment of an electrical connection between the negative electrode terminal 14-1 and the negative electrode terminal 14-2 illustrated in
As illustrated in
As illustrated in
With the positive electrode terminals 13 being disposed so as to be line-symmetrical about the perpendicular line L as described above, even when the connection unit 1 is turned over, the positive electrode terminal 13 of the connection unit 1 and the positive electrode terminal 13 of another connection unit 1 can be electrically connected to each other at the time when the two connection units 1 are magnetically connected to each other. Similarly, with the negative electrode terminals 14 being disposed so as to be line-symmetrical about the perpendicular line L as described above, even when the connection unit 1 is turned over, the negative electrode terminal 14 of the connection unit 1 and the negative electrode terminal 14 of another connection unit 1 can be electrically connected to each other at the time when the two connection units 1 are magnetically connected to each other.
Thus, with the positive electrode terminals 13 and the negative electrode terminals 14 being disposed so as to be line-symmetrical about the perpendicular L, the user can magnetically connect one connection unit 1 to another regardless the orientation of the surface of the connection units 1. Further, with the positive electrode terminals 13 and the negative electrode terminals 14 being disposed so as to be line-symmetrical about the perpendicular line L, the user can connect the positive electrode terminals 13 to each other and the negative electrode terminals 14 to each other without having to choose a specific side of the peripheral edge of a connection unit 1 for a specific side of the peripheral edge of another connection unit 1 when magnetically connecting the connection units 1 to each other.
A total of at least three positive electrode terminal(s) 13 and negative electrode terminal(s) 14 are disposed on one side of the peripheral edge of the body 11. This makes it possible to dispose the positive electrode terminal(s) 13 and the negative electrode terminal(s) 14 so as to be line-symmetrical about the perpendicular line L.
The circuit element 15 is disposed inside the body 11. The phrase “disposed inside” as used herein means that, when the body 11 has a flat plate shape, the circuit element 15 is disposed in the inside of the body 11 and means that when the body 11 has a frame shape having an opening, at least a portion of the circuit element 15 is disposed in the opening of the body 11.
The circuit element 15 may have a flat plate shape, for example. In the example illustrated in
The circuit element 15 is electrically connected to the positive electrode terminal 13 and the negative electrode terminal 14. The circuit element 15 can be electrically connected to the circuit element 15 of another connection unit when the connection unit 1 is magnetically connected to the other connection unit 1.
The circuit element 15 may include an energy harvesting element capable of outputting power, generated by energy harvesting, from the positive electrode terminal 13 and the negative electrode terminal 14. Alternatively, the circuit element 15 may include a load element capable of consuming power that is input from the positive electrode terminal 13 and the negative electrode terminal 14.
The energy harvesting element is capable of generating power by energy harvesting. That is, the energy harvesting element generates power according to the external environment. Therefore, the power generated by the energy harvesting element varies depending on the external environment. The energy harvesting element has, for example, a solar cell which generates power by utilizing light energy such as sunlight or indoor light. Alternatively, the energy harvesting element has, for example, a thermoelectric conversion element that generates power by utilizing thermal energy such as geothermal heat.
The energy harvesting element of the present embodiment includes a solar cell panel composed of solar cells. The solar cell panel is a member including solar cells configured to output power by photoelectrically converting incident light such as sunlight or indoor light. The types of solar cells to be included in a solar cell panel are broadly classified into inorganic solar cells using an inorganic material, and organic solar cells using an organic material. Examples of inorganic solar cells include silicon (Si) solar cells in which silicon is used and compound solar cells in which a compound is used. Examples of organic solar cells include a low-molecular vapor deposition system using an organic pigment, a polymer coating system using a conductive polymer, a thin film system such as a coating conversion system using a conversion-type semiconductor, and a dye-sensitized system comprising titania, an organic dye, and an electrolyte. Solar cells to be included in a solar cell panel may also include organic-inorganic hybrid solar cells and solar cell using a perovskite compound. The solar cell panel may be in the form of a thin panel. In this case dye-sensitized solar cells formed on a plastic or other film are preferred because it is easy to form a thin solar cell panel. When the solar cell panel is such a thin solar panel, the solar cell panel is not limited to one in which solar cells are formed on a plastic or other film; any mode can be employed as long as the solar cell panel is thin. When the solar cell panel is a thin solar panel, it preferably has a thickness of, for example, 10 μm or more and 3 mm or less from the viewpoint of manufacturing techniques.
The load element is any load capable of consuming power. The load element may be, for example, a light-emitting element such as a light-emitting diode (LED), a speaker, or a secondary battery.
For example, when the connection unit 1-1 illustrated in
Thus, a plurality of connection units 1, when magnetically connected into an assembly, can utilize the power generated by a connection unit 1 to drive the load element of another connection unit 1. This allows the user to enjoy the plurality of connection units 1 as an assembled toy with electrical elements. Also, the user can connect the plurality of connection units 1 into an assembly and enjoy it as an interior accessory such as a lighting device.
The portion of the inside of the body 11, where the circuit element 15 is disposed, is preferably transparent. The circuit element 15 itself is also preferably transparent. The term “transparent” as used herein means not only completely transparent, but also transparent to an extent that light transmittance is relatively high.
When the plurality of connection units 11 including a connection unit 1 having an LED as the circuit element 15 are assembled, for example, the transparency of the body 11 and the circuit element 15 allows the light from the LED to be transmitted to the outside of the three-dimensional assembly. Further, when the plurality of connection units 1 includes a connection unit 1 having a solar cell panel as the circuit element 15 and the connection units 1 are assembled such that the light-receiving surface of the solar cell panel faces toward the inside of the three-dimensional assembly, it is possible to cause the solar cell panel to generate power by the incident light that has passed through the connection unit 1 from the outside.
The body 11 may include a wiring board in the inside of the body 11.
The wiring board 16 may have a frame shape in plan view. The wiring board 16 includes a wiring 17A and a wiring 17B. The wiring board 16 may be a flexible or rigid board, but is preferably a flexible board from the viewpoint of weight reduction.
The wiring 17A is electrically connected to a positive electrode 18A of the circuit element 15. Further, the wiring 17A is connected to the positive electrode terminal 13 at a connection point 19A.
The wiring 17B is electrically connected to a negative electrode 18B of the circuit element 15. Further, the wiring 17B is connected to the negative electrode terminal 14 at a connection point 19B.
In
With the wiring board 16 provided in the inside of the body 11 as described above, it is possible to simply establish a connection between the circuit element 15 and the positive electrode terminal 13 and negative electrode terminal 14 in a space-saving manner.
(First Modification)
The body 11 of the connection unit 1 illustrated in
Thus, the body 11 according to the present embodiment may be of various shapes. This makes it possible to increase the degree of freedom in forming a three-dimensional assembly by combining a plurality of connection units 1.
(Second Modification)
The connection unit 3 has two magnets 12 on each side of the peripheral edge of the body 11. Thus, the number of the magnets 12 disposed on each side of the peripheral edge of the body 11 is not limited to one, which is illustrated in
The connection unit 3 has two positive electrode terminals 13 and one negative electrode terminal 14 on each side of the peripheral edge of the body 11. Thus, the numbers of the positive electrode terminal 13 and the negative electrode terminal 14 disposed on each side of the peripheral edge of the body 11 are not limited to those in the example illustrated in
(Third Modification)
With the light-emitting elements 20 provided on the peripheral edge of the body 11 as described above, when the wiring board 16 configured to connect the light-emitting element 20 which functions as a load element to the positive electrode terminal 13 and the negative electrode terminal 14 is disposed on the peripheral edge of the body 11, it is possible to mount the light-emitting element 20 simultaneously on the wiring board 16. Thus, the connection unit 4 can have a lighting function easily with a small configuration.
(Fourth Modification)
In the connection unit 5, at least one side of the peripheral edge of the body 11 does not have the magnet 12, the positive electrode terminal 13 and the negative electrode terminal 14 which are illustrated in
In the example illustrated in
The one side of the connection unit 5-1 on the positive side of the X-axis and the one side of the connection unit 5-2 on the negative side of the X-axis are connected to each other by connection elements 21. The connection element 21 mechanically and electrically connect the connection unit 5-1 and the connection unit 5-2. The connection element 21 mechanically connects the connection unit 5-1 and the connection unit 5-2 such that the connection angle θ has a degree of freedom that allows the connection unit 5-1 and the connection unit 5-2 to be connected to each other at various connection angles θ.
The one side of the connection unit 5-2 on the negative side of the Y-axis and the one side of the connection unit 5-3 on the positive side of the Y-axis are connected to each other by connection elements 21. The connection element 21 mechanically and electrically connect the connection unit 5-2 and the connection unit 5-3. The connection element 21 mechanically connects the connection unit 5-2 and the connection unit 5-3 such that the connection angle θ has a degree of freedom that allows the connection unit 5-2 and the connection unit 5-3 to be connected to each other at various connection angles θ.
By connecting a plurality of connection units 5 by the connection elements 21 in advance as described above, it is possible to reduce the number of process steps when forming a three-dimensional assembly using, for example, the connection units 5 and connection unit 1 illustrated in
(Fifth Modification)
The body 41 has a flat plate shape. The body 41 is substantially quadrangular in shape in plan view. The body 11 may be made of resin or other material.
The body 41 has a connection surface 45 as illustrated in
The magnets 42 are disposed on the connection surface 45 at positions corresponding to the magnets 12 illustrated in
The positive electrode terminals 43 are disposed on the connection surface 45 at positions corresponding to the positive electrode terminals 13 illustrated in
The negative electrode terminals 44 are disposed on the connection surface 45 at positions corresponding to the negative electrode terminals 14 illustrated in
The motor 50 is disposed in the body 41 as illustrated in
When the connection unit 1 illustrated in
The tires 60 are mechanically connected to the motor 50 via axles so as to be driven by the motor 50 to rotate. When the motor 50 is driven by the power generated by the connection unit 1, the tires 60 rotate accordingly. As the tires 60 rotate, the entire connection unit 6 can travel.
The connection unit 6 may further include a switch for switching the connection between the motor 50 and the positive electrode terminal 43 and negative electrode terminal 44. By providing such a switch, the connection unit 6 can prevent the motor 50 from being driven while the power generated by the connection unit 1 is supplied.
It is possible for the connection unit 6 to place on the connection surface 45 a three-dimensional assembly formed of a plurality of connection units 1 such as those illustrated in
The foregoing description merely illustrates one embodiment of the present disclosure and it goes without saying that various modifications may be made in the claims.
For example, while the body 11 has been described above as having a substantially polygonal shape in plan view, the body 11 may be of shapes which are not substantially polygonal so long it has one side on the peripheral edge, e.g., the remaining portion of the peripheral edge has an arc shape.
According to the present disclosure, it is possible to provide a connection unit which is magnetically and electrically connectable.
Number | Date | Country | Kind |
---|---|---|---|
2018-105174 | May 2018 | JP | national |
The present application is a continuation application of U.S. patent application Ser. No. 17/056,419 filed Nov. 18, 2020, which is a National Stage Application of PCT/JP2019/019086 filed May 14, 2019, which claims priority of Japanese Patent Application No. 2018-105174 filed May 31, 2018. The disclosures of the prior applications are hereby incorporated by reference herein in their entirety.
Number | Date | Country | |
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Parent | 17056419 | Nov 2020 | US |
Child | 18046217 | US |