JP2009159683A - Building with noncontact power feed function, and noncontact power feed outlet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a building with noncontact power feed function which can prevent deterioration in the designability of the building and in a space performance caused in a power distribution system, can easily supply power to electrical apparatuses and has high safety, and to provide a noncontact power feed outlet. <P>SOLUTION: Noncontact power feed portions 10 for generating a high-frequency magnetic field are disposed inside each of a wall panel P1, a ceiling panel P2 and a floor panel P3 or rear surfaces P1b, P2b, P3b of the panels of a building H, and noncontact power receiving portions 20 for feeding power to a DC apparatus U by receiving the power from the power feeed portions 10 in a noncontact manner, by utilizing electromagnetic induction, based on the high-frequency magnetic field generated by the noncontact power feed portions 10 are provided on positions opposing to the noncontact power feed portions 10 in the surfaces P1a, P2a, P3a of the panels, instead of outlets provided on the surfaces P1a, P2a, P3a of the panels P1, P2, P3 of the building H and feed power to a load by allowing a conductor electrically connected to the load to contact the load. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a building with a non-contact power feeding function and a non-contact power feeding outlet.

  2. Description of the Related Art Conventionally, power distribution systems disposed in buildings such as houses and offices include an AC power distribution system that supplies commercial power and a DC power distribution system that supplies DC power obtained by converting commercial power into DC voltage.

The power distribution system installed in these buildings has openings in the building materials that make up the wall, ceiling, and floor of the building, and electrical equipment is installed in contact outlets such as outlets and hook ceilings installed in these openings. A power supply is supplied to each electric device by a direct contact between a contact (conductor) provided directly on the contact or a contact provided via a connection line (see, for example, Patent Documents 1 and 2).
Japanese Patent Laid-Open No. 2-276212 Japanese Patent Laid-Open No. 7-15835

  However, in the above conventional technique, in order to install outlets such as outlets, it is necessary to provide openings on the wall surface, ceiling surface, and floor surface of the building, and the appearance of the building after installation is not good. In addition, the user needs to connect a contact of an electric device to an outlet such as an outlet, and there is a risk of electric shock because a conductor for power feeding is exposed.

  The present invention has been made in view of the above reasons, and its purpose is to prevent deterioration of the design and space of the building due to the power distribution system, as well as easy contact with the power supply to the load and high safety. It is to provide a building with a power feeding function and a contactless power feeding outlet.

  The invention of claim 1 is provided on one surface of a building material that constitutes a wall, ceiling, or floor of a building, and instead of an outlet that supplies power to the load by contact with a conductor that is electrically connected to the load, A non-contact power feeding unit that generates a magnetic field is placed in the building material or on the other surface of the building material, and the load that receives power received from the non-contact power feeding unit in a non-contact manner using electromagnetic induction caused by the high-frequency magnetic field generated by the non-contact power feeding unit The non-contact power receiving unit to be supplied to is arranged at a position facing the non-contact power feeding unit on one surface of the building material.

  According to the present invention, since it is possible to supply power in a building without contact, there is no need to provide a contact outlet such as an outlet or a hook ceiling in the building, the construction can be simplified, and one side of the building material can be provided. Since the power feeding member does not protrude, the side walls, ceiling, and floor of the building look good, and they do not get in the way. In addition, the user can operate the load simply by mounting the non-contact power receiving unit opposite to the non-contact power feeding unit, which makes it easy to use and does not expose the conductor for power feeding. There is no. Thus, it is possible to prevent the deterioration of the design and space of the building due to the power distribution system, and it is possible to provide a building with a non-contact power feeding function that can easily supply power to the load and has high safety.

  The invention of claim 2 is the contactless power receiving unit according to claim 1, wherein a plurality of the non-contact power feeding units are arranged in the building material of the building or the other surface of the building material, and the non-contact power receiving unit is located at a position facing the non-contact power feeding unit on one surface of the building material. It is provided with the attachment means which attaches detachably.

  According to the present invention, the user can install the non-contact power receiving unit at an appropriate position according to the load to be used, and can obtain excellent usability.

  According to a third aspect of the present invention, in the second aspect, the non-contact power feeding unit includes a coil that generates a high-frequency magnetic field when supplied with a high-frequency current, and the non-contact power receiving unit faces the non-contact power feeding units. Driving object detecting means for detecting whether or not arranged, and driving means for generating a high-frequency magnetic field by supplying a predetermined high-frequency current to a coil of a non-contact power feeding section arranged so that the non-contact power receiving section faces each other. It is characterized by providing.

  According to the present invention, not all the non-contact power feeding units are driven at all times, but only the non-contact power feeding units arranged so that the non-contact power receiving units are opposed to each other are driven, so that unnecessary power is consumed. Energy saving.

  According to a fourth aspect of the present invention, in the third aspect of the present invention, the drive target detection unit is configured to switch a non-contact power feeding unit to be driven in a constant period during which only one of the plurality of non-contact power feeding units is driven. It is generated every hour, and the impedance viewed from the non-contact power feeding unit being driven during the detectable period is measured, and the non-contact power receiving unit is arranged to face the non-contact power feeding unit based on the measured impedance. It is characterized by determining whether or not.

  According to the present invention, it is possible to reliably detect whether or not the non-contact power receiving unit is arranged to face each non-contact power feeding unit.

  A fifth aspect of the present invention is characterized in that, in any one of the first to fourth aspects, the non-contact power feeding unit is movably installed on the other surface of the building material of the building.

  According to the present invention, the user can easily change the power supply point by changing the type of load to be used, the layout, or the like.

  The invention of claim 6 is any one of claims 2 to 5, wherein the attachment means generates a suction force via a building material between the non-contact power supply unit and the non-contact power reception unit, and the suction force A non-contact power receiving unit is detachably attached to a position facing the non-contact power feeding unit on one surface of the building material.

  According to the present invention, it is not necessary to separately provide attachment means such as screws and locking means, and the configuration can be simplified and the attachment work can be simplified.

  A seventh aspect of the present invention is that, in the sixth aspect, the attachment means includes a non-contact power feeding portion on one surface of the building material by an attractive force generated between the magnets respectively provided in the non-contact power feeding portion and the non-contact power receiving portion. A non-contact power receiving unit is detachably attached at a position opposite to.

  According to the present invention, it is not necessary to separately provide attachment means such as screws and locking means, and the configuration can be simplified and the attachment work can be simplified. Furthermore, when the non-contact power receiving unit is moved on one surface of the building material, the non-contact power feeding unit is also pulled by the non-contact power receiving unit due to the attractive force between the magnet of the non-contact power feeding unit and the magnet of the non-contact power receiving unit. Thus, it can move in the same direction on the other surface of the building material and maintain the power supply state.

  The invention according to claim 8 is provided on one side of the building material constituting the wall, ceiling, or floor of the building, and instead of the outlet for supplying electric power to the load by contact with a conductor electrically connected to the load. Provided with high-frequency magnetic field generating means for generating a high-frequency magnetic field disposed inside or on the other surface of the building material, and supplying electric power received in a non-contact manner using electromagnetic induction by the high-frequency magnetic field generated by the high-frequency magnetic field generating means to the load The non-contact power receiving unit is arranged at a position facing the high-frequency magnetic field generating means on one surface of the building material.

  According to the present invention, since it is possible to supply power in a building without contact, there is no need to provide a contact outlet such as an outlet or a hook ceiling in the building, the construction can be simplified, and one side of the building material can be provided. Since the power feeding member does not protrude, the side walls, ceiling, and floor of the building look good, and they do not get in the way. In addition, the user can operate the load simply by mounting the non-contact power receiving unit opposite to the non-contact power feeding unit, which makes it easy to use and does not expose the conductor for power feeding. There is no. Thus, it is possible to prevent deterioration of the design and space of the building due to the power distribution system, and it is possible to provide a non-contact power supply outlet that can easily supply power to the load and has high safety.

  As described above, according to the present invention, there is an effect that it is possible to prevent deterioration of the design and space of the building due to the power distribution system, and it is easy to supply power to the electrical equipment and to obtain high safety.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
The building with a non-contact power feeding function of this embodiment includes a non-contact power feeding system in a building H such as a house, and is provided directly on an electrical device (load) on a contact outlet such as a conventional outlet or hook ceiling. Instead of supplying power to an electrical device that is performed by direct contact between a contact (conductor) or a contact provided via a connection line, power is supplied to the electrical device in a non-contact manner.

  In the present embodiment, the power distribution system in the building H is constituted by a DC power distribution system. First, an outline of this power distribution system will be described with reference to FIG.

  The embodiments described below are described assuming a detached house as a building to which the present invention is applied, but this does not preclude the application of the technical idea of the present invention to an apartment house. As shown in FIG. 11, the building H is provided with a DC power supply unit 101 that outputs DC power and a DC device U ′ that is an electric device driven by the DC power, and the output of the DC power supply unit 101 DC power is supplied to the DC device U ′ through the DC supply line Wdc connected to the end. A current flowing through the DC supply line Wdc is monitored between the DC power supply unit 101 and the DC device U ′, and when an abnormality is detected, the DC power supply unit 101 to the DC device U ′ is detected on the DC power supply line Wdc. A DC breaker 114 is provided to limit or cut off the power supply.

  The DC supply line Wdc is used as both a DC power supply path and a communication path, and is connected to the DC supply line Wdc by superimposing a communication signal for transmitting data on a DC voltage using a high-frequency carrier wave. Enables communication between devices. This technique is similar to a power line carrier technique in which a communication signal is superimposed on an AC voltage in a power line that supplies AC power.

  The DC supply line Wdc is connected to the home server 116 via the DC power supply unit 101. The home server 116 is a main device that constructs a home communication network (hereinafter referred to as “home network”), and communicates with a subsystem or the like constructed by the DC device U ′ in the home network.

  In the illustrated example, the subsystem includes an information equipment system K101 including an information system DC equipment U ′ such as a personal computer, a wireless access point, a router, and an IP telephone, and an illumination system DC equipment U ′ such as a lighting fixture. There are lighting systems K102 and K105, an intercom system K103 composed of a DC device U ′ for dealing with visitors and monitoring intruders, and a residential alarm system K104 composed of an alarm DC device U ′ such as a fire detector. Each subsystem constitutes a self-supporting distributed system, and can operate even with the subsystem alone.

  The above-described DC breaker 114 is provided in association with a subsystem. In the illustrated example, four DCs are associated with the information equipment system K101, the lighting system K102 and the intercom system K103, the house alarm system K104, and the lighting system K105. A breaker 114 is provided. When a plurality of subsystems are associated with one DC breaker 114, a connection box 121 for dividing the system of the DC supply line Wdc is provided for each subsystem. In the illustrated example, a connection box 121 is provided between the illumination system K102 and the intercom system K103.

  As the information equipment system K101, there is provided an information equipment system K101 comprising a direct current equipment U ′ connected to a direct current outlet 131 arranged in advance in the building H in the form of a wall outlet or a floor outlet (constructed during construction of the building H). .

  As the lighting systems K102 and K105, the lighting system K102 including a lighting fixture (DC device U ′) arranged in advance in the building H and the lighting fixture (DC device U ′) connected to the hook ceiling 132 arranged in advance on the ceiling. And an illumination system K105. At the time of interior construction of the building H, the contractor attaches the lighting fixture to the hook ceiling 132, or the resident himself attaches the lighting fixture.

  In addition to using an infrared remote control device, a control instruction for the lighting apparatus that is the DC device U ′ constituting the lighting system K102 can be given using a communication signal from the switch 141 connected to the DC supply line Wdc. That is, the switch 141 has a communication function together with the DC device U ′. In addition, a control instruction may be given by a communication signal from another DC device U 'in the home network or the home server 116 regardless of the operation of the switch 141. The instructions to the lighting fixture include lighting, extinguishing, dimming, and blinking lighting.

  Arbitrary DC equipment U ′ can be connected to the DC outlet 131 and the hooking ceiling 132 described above, and since DC power is output to the connected DC equipment U ′, the DC outlet 131 and the hooking ceiling 132 will be described below. When it is not necessary to distinguish, it is called a “DC outlet”.

  These DC outlets have a contact (such as a plug blade or conductor piece of a plug (not shown)) directly provided on the DC device U ′ or a plug-in connection port into which a contact provided via a connection line is inserted. The contact holder that directly contacts the contact inserted into the connection port is held by the container, and power is supplied in a contact manner. When the DC device U 'connected to the DC outlet has a communication function, a communication signal can be transmitted through the DC supply line Wdc. A communication function is provided not only in the DC device U 'but also in the DC outlet.

  The home server 116 not only is connected to the home network, but also has a connection port connected to the wide area network NT that constructs the Internet. When the in-home server 116 is connected to the wide area network NT, it is possible to receive services from the center server 200 that is a computer server connected to the wide area network NT.

  The service provided by the center server 200 is a service that enables monitoring and control of equipment (mainly DC equipment U ′ including other equipment having a communication function) connected to the home network through the wide area network NT. There is. This service makes it possible to monitor and control devices connected to the home network using a communication terminal (not shown) having a browser function such as a personal computer, Internet TV, or mobile phone.

  The in-home server 116 has both functions of communication with the center server 200 connected to the wide area network NT and communication with equipment connected to the home network, and identification information on equipment in the home network ( Here, it is assumed that an IP address is used).

  The home server 116 enables monitoring and control of home devices through the center server 200 from a communication terminal connected to the wide area network NT by using a communication function with the center server 200. The center server 200 mediates between home devices and communication terminals on the wide area network NT.

  When monitoring and controlling home devices from a communication terminal, monitoring and control requests are stored in the center server 200, and the home device periodically performs one-way polling communication to monitor from the communication terminal. And receive control requests. With this operation, it is possible to monitor and control devices in the house from the communication terminal.

  Further, when an event that should be notified to the communication terminal, such as a fire detection, occurs in the home device, the home device notifies the center server 200, and the center server 200 notifies the communication terminal by e-mail.

  An important function among the communication functions with the home network in the home server 116 is the detection and management of devices constituting the home network. The home server 116 automatically detects devices connected to the home network by applying UPnP (Universal Plug and Play). The home server 116 includes a display device 117 having a browser function, and displays a list of detected devices on the display device 117. The display device 117 has a configuration with a touch panel type or an operation unit, and can perform an operation of selecting desired contents from options displayed on the screen of the display device 117. Therefore, the user (contractor or householder) of the home server 116 can monitor or control the device on the screen of the display device 117. The display device 117 may be provided separately from the home server 116.

  The in-home server 116 manages information related to device connection, and grasps the type, function, and address of the device connected to the home network. Accordingly, the devices in the home network can be operated in conjunction with each other. Information on the connection of the device is automatically detected as described above. In order to operate the device in an interlocking manner, the device itself is automatically associated with the attribute held by the device itself, and the home server 116 is configured as a personal computer. It is also possible to connect various information terminals and use the browser function of the information terminals to associate devices.

  Each device holds the relationship of the interlocking operation of the devices. Therefore, the device can operate in an interlocked manner without passing through the home server 116. By associating the linked operations for each device, for example, by operating a switch that is a device, it is possible to turn on or off the lighting fixture that is the device. In many cases, the association of the interlocking operations is performed within the subsystem, but the association beyond the subsystem is also possible.

  By the way, the DC power supply unit 101 basically generates DC power by power conversion of an AC power supply AC supplied from outside the house like a commercial power supply. In the configuration shown in the figure, the AC power source AC is input to an AC / DC converter 112 including a switching power source through a main circuit breaker 111 attached to the distribution board 110 as an internal unit. The DC power output from the AC / DC converter 112 is connected to each DC breaker 114 through the cooperative control unit 113.

  The DC power supply unit 101 is provided with a secondary battery 162 in preparation for a period in which power is not supplied from the AC power supply AC (for example, a power failure period of the commercial power supply AC). It is also possible to use a solar cell 161 or a fuel cell 163 that generates DC power. The solar battery 161, the secondary battery 162, and the fuel battery 163 are distributed power supplies with respect to the main power supply including the AC / DC converter 112 that generates DC power from the AC power supply AC. In the illustrated example, the solar cell 161, the secondary battery 162, and the fuel cell 163 include a circuit unit that controls the output voltage, and the secondary battery 162 includes a circuit unit that controls charging as well as discharging.

  Of the distributed power sources, the solar cell 161 and the fuel cell 163 are not necessarily provided, but the secondary battery 162 is preferably provided. The secondary battery 162 is charged in a timely manner by a main power source or other distributed power source, and the secondary battery 162 is discharged not only in a period in which power is not supplied from the AC power source AC but also in a timely manner as necessary. The cooperation control unit 113 performs charge / discharge of the secondary battery 162 and cooperation between the main power source and the distributed power source. That is, the cooperative control unit 113 functions as a DC power control unit that controls the distribution of power from the main power supply and the distributed power supply configuring the DC power supply unit 101 to the DC equipment U ′. Note that a configuration may be adopted in which the outputs of the solar cell 161, the secondary battery 162, and the fuel cell 163 are converted into AC power and used as input power of the AC / DC converter 112.

  Since the driving voltage of the DC device U ′ is selected from a plurality of types of voltages depending on the device, a DC / DC converter is provided in the cooperative control unit 113 to convert the DC voltage obtained from the main power source and the distributed power source into the necessary voltage. It is desirable to do. Normally, one type of voltage is supplied to one subsystem (or DC equipment U ′ connected to one DC breaker 114), but three or more wires are supplied to one subsystem. A plurality of types of voltages may be used. Alternatively, it is possible to adopt a configuration in which the DC supply line Wdc is of a two-wire type and the voltage applied between the lines is changed with time. The DC / DC converter may be provided in a plurality of dispersed manners like the DC breaker.

  In the above configuration example, only one AC / DC converter 112 is illustrated, but a plurality of AC / DC converters 112 can be arranged in parallel, and when a plurality of AC / DC converters 112 are provided. It is desirable to increase or decrease the number of AC / DC converters 112 that are operated according to the magnitude of the load.

  The AC / DC converter 112, the cooperative control unit 113, the DC breaker 114, the solar cell 161, the secondary battery 162, and the fuel cell 163 described above are provided with a communication function, and the main power source, the distributed power source, and the DC device U ′ are connected. It is possible to perform a cooperative operation to deal with the load status including it. The communication signal used for this communication is transmitted in the form of being superimposed on the DC voltage in the same manner as the communication signal used for the DC device U '.

  In the above example, the AC / DC converter 112 is arranged in the distribution board 110 in order to convert the AC power output from the main breaker 111 into DC power by the AC / DC converter 112. On the output side, a branch breaker (not shown) provided in the distribution board 110 branches the AC supply line into a plurality of systems, and an AC / DC converter is provided on the AC supply line of each system to convert it into DC power for each system. You may employ | adopt the structure to do.

  In this case, since the AC / DC converter can be provided for each floor or room of the building H, the AC / DC converter can be managed for each system, and the DC device U ′ using DC power can be managed. Since the distance of the direct current supply line Wdc is reduced, the power loss due to the voltage drop in the direct current supply line Wdc can be reduced. Also, the main breaker 111 and the branch breaker are housed in the distribution board 110, and the AC / DC converter 112, the cooperative control unit 113, the DC breaker 114, and the home server 116 are housed in a separate board from the distribution board 110. Also good.

  In the building with a non-contact power supply function of the present embodiment, the non-contact power supply system is applied to a DC distribution system that supplies DC power to DC devices in the above distribution system, and FIG. 1 is an outline of the room R1 in the building H. The figure is shown. The room R1 is surrounded by building materials including a wall panel P1 provided in four directions (only three wall panels P1 are shown in FIG. 1), a ceiling panel P2 provided in the upper part, and a floor panel P3 provided in the lower part. .

  The wall panel P1, the ceiling panel P2, and the floor panel P3 (collectively referred to as panel P) each incorporate a plurality of non-contact power supply units 10 used in the non-contact power supply system. Constitutes a non-contact power supply outlet for supplying DC power instead of the DC outlet 131 and the hooking ceiling 132 which are the contact type DC outlets. As shown in FIG. 2, the non-contact power feeding unit 10 includes a high frequency power generation circuit 11 that converts DC power supplied via the DC supply line Wdc into high frequency power, and high frequency power from the high frequency power generation circuit 11. It is comprised with the primary coil L1 which generate | occur | produces a high frequency magnetic field by being supplied. Moreover, if each side facing the room R1 of the wall panel P1, the ceiling panel P2, and the floor panel P3 is a surface P1a, P2a, P3a (collectively referred to as a panel surface Pa), the wall surface facing the non-contact power feeding unit 10 A mark indicating the feeding point X is provided on P1a, the ceiling surface P2a, and the floor surface P3a, and the user in the room R1 can visually recognize the feeding point X.

  The high frequency power generation circuit 11 converts a DC voltage into a high frequency voltage by switching an internal switching element (not shown) at a high frequency, and applies the high frequency voltage to both ends of the primary coil L1 to apply the high frequency voltage to the primary coil L1. A high frequency current is supplied to the primary coil L1, and the primary coil L1 generates a high frequency magnetic field by the high frequency current. Note that a circuit configuration for converting a DC voltage into a high-frequency voltage using a switching element is well known, and a description thereof will be omitted.

  Moreover, as shown in FIG. 1, DC equipment U is installed on the wall surface P1a, the ceiling surface P2a, and the floor surface P3a. The wall surface P1a is provided with an auxiliary illumination LED light U1 and the like, and the ceiling surface P2a is used for a main illumination ceiling light U2, an auxiliary illumination spotlight U3, an air conditioning fan U4, and a security system. A human sensor U5, a speaker U6 provided with wireless communication means for outputting sound, an access point U7 used for a wireless LAN, and the like are installed. On the floor surface P3a, a standlight U8 for auxiliary lighting, a mat heater for heating, etc. U9 etc. are installed.

  As shown in FIG. 2, each DC device U includes a non-contact power receiving unit 20 used in a non-contact power supply system, and a functional unit 21 (for example, an illumination function, an air conditioning function, a sensor function, a communication function, and a speaker function) of each DC device. LAN hub function, heating function, etc.). In addition to the configuration in which the non-contact power receiving unit 20 is integrated into the DC device U and the function unit 21, the non-contact power receiving unit 20 is formed as a single unit, and the device body including the function unit 21 is connected to the power source cord CD. Alternatively, the operation power supply may be supplied. When the non-contact power receiving unit 20 is formed as a single unit, the device main body can be arbitrarily arranged regardless of the position of the non-contact power feeding unit 10, and the non-contact power receiving unit 20 can be easily attached and detached.

  The non-contact power receiving unit 20 is disposed at each position (feed point X) of the wall surface P1a, the ceiling surface P2a, and the floor surface P3a facing the non-contact power feeding unit 10 in the wall panel P1, the ceiling panel P2, and the floor panel P3. Is done. The non-contact power receiving unit 20 is electromagnetically coupled to the primary coil L1 of the non-contact power feeding unit 10 and a secondary voltage is induced by electromagnetic induction when the high frequency magnetic field generated by the non-contact power feeding unit 10 is linked. A coil L2, a rectifier DB for full-wave rectification of the secondary voltage generated at both ends of the secondary coil L2, an inductor La connected in series to the rectified output on the positive side of the rectifier DB, and rectification via the inductor La A smoothing capacitor Ca that smoothes the voltage is supplied. The voltage across the smoothing capacitor Ca is supplied to the function unit 21 and serves as an operating power source for the function unit 21. Further, a constant voltage function may be added by providing a series regulator or chopper circuit at the output of the smoothing capacitor Ca. Furthermore, as indicated by a broken line in FIG. 2, a resonance capacitor C2 may be connected in parallel to the secondary coil L2 to improve the power reception capability from the primary coil L1.

  In the present embodiment, the non-contact power receiving unit 20 and the non-contact power receiving unit 20 are provided at positions facing the non-contact power feeding unit 10 on the wall surface P1a, the ceiling surface P2a, and the floor surface P3a (power feeding point X). An attachment means for detachably attaching the DC device U is provided.

  As shown in FIGS. 3 (a) and 3 (b), the attachment means is composed of magnets M1a and M1b provided in the non-contact power feeding unit 10 and magnets M2a and M2b provided in the non-contact power receiving unit 20. . The magnets M1a and M1b provided in the non-contact power feeding unit 10 are each formed in a substantially L shape, one side is magnetized to the S pole and the other side is magnetized to the N pole, and the end surfaces of the magnets M1a and M1b that are different from each other The non-contact power feeding unit 10 is attached to the inside of a rectangular frame formed so as to face each other. Further, the magnets M2a and M2b provided in the non-contact power receiving unit 20 are each formed in a substantially L shape, and one side is magnetized to an S pole and the other side is an N pole, and the magnets M2a and M2b are different from each other. The non-contact power receiving unit 20 is attached to the inside of a rectangular frame formed by facing the end faces.

  Therefore, when the non-contact power feeding unit 10 and the non-contact power receiving unit 20 face each other through the wall panel P1, the ceiling panel P2, and the floor panel P3, the magnets M1a and M1b and the magnets M2a and M2b have different polarities. Are opposed to each other, a magnetic attractive force is generated between the magnets M1a and M1b and the magnets M2a and M2b, and the non-contact power receiving unit 20 is correctly opposed to the non-contact power feeding unit 10 on the power feeding point X. Installed in the mounting direction. For example, when the mounting direction is shifted by 90 degrees, the same polarity of the magnets M1a, M1b and the magnets M2a, M2b are opposed to each other, and a magnetic repulsive force is generated between the magnets M1a, M1b and the magnets M2a, M2b. Thus, the non-contact power receiving unit 20 cannot be installed on the power feeding point X so as to face the non-contact power feeding unit 10. This is because there is a mounting direction in which the mutual electromagnetic coupling is maximized due to the respective core shapes of the primary coil L1 and the secondary coil L2, so that the non-contact power receiving unit 20 is always installed in the correct mounting direction. The correct mounting direction described above is the direction in which the degree of electromagnetic coupling between the primary coil L1 and the secondary coil L2 is the highest. The magnetic attractive force at this time generates a force capable of attaching each DC device U incorporating the non-contact power receiving unit 20 or the single non-contact power receiving unit 20 to the wall surface P1a, the ceiling surface P2a, and the floor surface P3a.

  Therefore, when the user brings the DC device U including the non-contact power receiving unit 20 or the non-contact power receiving unit 20 alone close to the power supply point X, the non-contact power receiving unit 20 is brought into contact with the non-contact power feeding unit 10 by the magnetic attraction force. It is correctly mounted opposite to the. Then, the non-contact power receiving unit 20 receives power from the non-contact power feeding unit 10 in a non-contact manner by electromagnetic induction by a high-frequency magnetic field generated by the non-contact power feeding unit 10 and supplies operating power to the functional unit 21 of the DC device U.

  Further, the relative position and installation environment of the primary coil L1 in the non-contact power feeding unit 10 and the secondary coil L2 of the non-contact power receiving unit 20, the frequency, size and range of the high-frequency magnetic field generated by the primary coil L1, magnets The structure of the attaching means comprising M1a, M1b and magnets M2a, M2b is standardized according to the standard. That is, the high-frequency magnetic field generated by the non-contact power supply unit 10 is a magnetic field having a predetermined frequency and a predetermined intensity based on a predetermined standard within a predetermined range, and the position where the non-contact power supply unit 10 is installed on the panel P. Also, when the non-contact power receiving unit 20 is installed on the panel surface Pa, the relative position (distance, direction, etc.) with the non-contact power feeding unit 10 is also determined by the predetermined standard. Yes. Therefore, the power received by the non-contact power receiving unit 20 from the non-contact power feeding unit 10 is within a specified range, and the configuration of the functional unit 21 can be simplified (for example, the operable input range can be designed to be narrow). .

  And the non-contact electric power feeding part 10 is each incorporated in the several location in the wall panel P1, the ceiling panel P2, and the floor panel P3, and a user according to the direct current | flow apparatus U to be used with the standardization of said each part. The DC device U or the non-contact power receiving unit 20 alone can be easily installed at an appropriate position, and excellent usability can be obtained.

  Further, the non-contact power feeding unit 10 has a form in which the surface of the non-contact power feeding part 10 is arranged flush with the panel surface Pa and a form in which the non-contact power feeding part 10 is incorporated in the panel P. However, since the power supply member does not protrude on the panel surface Pa, for example, the appearance of the side walls, the ceiling, and the floor in the room R1 does not harm the design and space of the room when a plurality of non-contact power supply units 10 are installed. It is possible to improve the performance, to make it possible to install furniture and the like in close contact with the wall, and to obtain an effect that does not get in the way.

  As described above, in the present embodiment, in the DC power distribution system (see FIG. 11), since the DC equipment U in the room R1 can be supplied in a non-contact manner, a contact type DC outlet such as the DC outlet 131 or the hooking ceiling 132 is used. Is not required in the building H, the construction can be simplified, and since the power feeding member does not protrude from the panel surface Pa, the appearance of the side wall, ceiling, and floor surface of the building H is improved, and further, it does not get in the way. In addition, since the user can operate the DC device U simply by attaching the DC device U to be used to the power supply point X, it is easy to use and there is no danger of electric shock because the conductor for power supply is not exposed. Absent. Thus, in this embodiment, it is possible to prevent deterioration of the design and space of the building H due to the power distribution system, and it is easy to supply power to the DC device U and to obtain high safety.

  Furthermore, so-called layout-free is realized in which the arrangement of the non-contact power feeding unit 10 constituting the non-contact power feeding outlet, the arrangement of the non-contact power receiving unit 20 on the load side, and the arrangement of furniture and the like in the building H can be freely performed. Yes.

  Further, since the DC device U and the non-contact power receiving unit 20 alone are attached to the non-contact power feeding unit 10 in the wall panel P1, the ceiling panel P2, and the floor panel P3 by using magnetic attraction force, screws and locking It is not necessary to separately provide attachment means such as means, so that the configuration can be simplified and the attachment work can be simplified.

  Further, the DC device U or the non-contact power receiving unit 20 alone may be attached to the wall surface P1a, the ceiling surface P2a, and the floor surface P3a by attaching means such as screws, hook-and-loop fasteners, suction cups, adhesive resin, and double-sided tape. These attachment means may be used in combination with the attachment means using the magnet.

  Furthermore, instead of incorporating a plurality of non-contact power feeding units 10 in the wall panel P1, ceiling panel P2, and floor panel P3, as shown in FIG. 4, the wall panel P1, ceiling panel P2, and floor panel P3 face the room R1. A configuration may be employed in which a sheet S incorporating a plurality of non-contact power feeding units 10 is laid on each back surface P1b, P2b, P3b (collectively referred to as panel back surface Pb). In this case, the addition and deletion of the feeding point X can be performed by adding and deleting the sheet S on the wall back surface P1b, the ceiling back surface P2b, and the floor back surface P3b. It can be carried out.

  Next, in this embodiment, although the several non-contact electric power feeding part 10 is arrange | positioned in the building H, not all the non-contact electric power feeding parts 10 are always driven, but the non-contact electric power receiving part 20 arrange | positions facing. The structure which drives only the non-contact electric power feeding part 10 currently provided is provided, and it demonstrates below using FIG.

  First, a predetermined number of non-contact power supply units 10 are defined as one block B (in FIG. 5, four non-contact power supply units 10a to 10d constitute block B). Are supplied with DC power from the DC supply line Wdc via the respective contacts 311 of the relays 31a to 31d. The relay coils 312 of the relays 31a to 31d are connected between the control power source Vcc and the ground level via the collectors and emitters of the transistors 32a to 32d, and the bases of the transistors 32a to 32d are connected to the controller 40. Connected to the output.

  The controller 40 individually controls the outputs to the bases of the transistors 32a to 32d to turn on and off the transistors 32a to 32d. The relay coil 312 is connected to the turned-on transistors 32 (32a to 32d). In the relay 31 (31a to 31d), the contact 311 is turned on, DC power is supplied to the corresponding non-contact power supply unit 10 (10a to 10d), and the non-contact power supply unit 10 is driven.

  The relays 31a to 31d, the transistors 32a to 32d, and the controller 40 constitute the drive control unit A. In the drive control unit A, the non-contact power reception unit 20 is disposed so as to face the non-contact power supply units 10a to 10d. Driving object detecting means for detecting whether or not, and driving means for generating a high-frequency magnetic field by supplying a rated current to the primary coil L1 of the non-contact power feeding section 10 disposed so as to face the non-contact power receiving section 20 are formed. ing. In addition, this drive control part A is arrange | positioned on wall back surface P1b, ceiling back surface P2b, and floor back surface P3b (In this case, the door which can be opened and closed is provided in the panel P, and maintenance of the drive control part A can be performed easily. Or in the distribution board 110 shown in FIG.

  First, the controller 40 generates a period during which only one of the four transistors 32a to 32d is turned on at regular intervals during a normal power feeding operation, so that one of the four non-contact power feeding units 10a to 10d. A detectable period in which only one is driven and the others are stopped is generated at regular intervals by sequentially switching the non-contact power feeding unit 10 to be driven. That is, a detectable period T1 in which only the non-contact power supply unit 10a is driven → a detectable period T2 in which only the non-contact power supply unit 10b is driven → a detectable period T3 in which only the non-contact power supply unit 10c is driven → only the non-contact power supply unit 10d Detectable periods T4 during which are driven are sequentially generated at regular intervals during normal power feeding operation, and this operation is repeated.

  And the input part of the controller 40 is connected between the both ends of each primary coil L1 of non-contact electric power feeding part 10a-10d (refer FIG. 2), and the controller 40 is non-contact electric power feeding part 10a in the detectable period T1-T4. -10d, the impedance of the power reception side (hereinafter referred to as power reception side impedance) is measured. The power receiving side impedance is different between the case where the non-contact power receiving unit 20 is not installed facing the non-contact power feeding unit 10 and the case where the non-contact power receiving unit 20 is installed facing the non-contact power feeding unit 10. The controller 40 has different values, and the controller 40 has a normal value (power-receiving-side impedance when the non-contact power-receiving unit 20 is not installed) to a predetermined value (power-receiving-side impedance when the non-contact power-receiving unit 20 is installed). It is determined that the non-contact power receiving unit 20 has been installed when the change is made. The change pattern of the power-receiving-side impedance before and after installation of the non-contact power receiving unit 20 includes each setting of the primary coil L1 and the secondary coil L2 (self-inductance, mutual inductance, etc.), the non-contact power receiving unit 20 and the functional unit 21. For example, when a metal plate, a magnetic body, or the like is arranged facing the non-contact power feeding unit 10, the power receiving side impedance change pattern is designed so as to change in a predetermined pattern. Is different from the predetermined pattern, the controller 40 does not drive the non-contact power feeding unit 10.

  In this manner, the controller 40 determines whether or not the non-contact power receiving unit 20 is installed facing each non-contact power feeding unit 10 in the detectable periods T1 to T4 that occur at regular intervals during a normal power feeding operation. The non-contact power receiving unit 20 is driven to drive all the non-contact power feeding units 10 opposed to each other, and the normal to the non-contact power receiving unit 20 except for the detectable periods T1 to T4. The power feeding operation is performed.

  That is, as shown in the flowchart of FIG. 6, the controller 40 first turns on only one of the four transistors 32 a to 32 d (S 1), drives the corresponding non-contact power feeding unit 10, and The power receiving side impedance viewed from the non-contact power feeding unit 10 is measured (S2), and whether or not the non-contact power receiving unit 20 is installed facing the non-contact power feeding unit 10 is determined based on the measured power receiving side impedance. (S3). And based on this determination result, the output of the non-contact power feeding unit 10 is adjusted, and when the non-contact power receiving unit 20 is installed, the driving state of the non-contact power feeding unit 10 is continuously set to the rated output, If the non-contact power receiving unit 20 is not installed, the transistor 32 that was turned on in step S1 is turned off to stop driving the non-contact power feeding unit 10 and make the output zero (S4). Thereafter, normal power feeding is performed to drive all the non-contact power feeding units 10 that are installed so that the non-contact power receiving unit 20 is opposed to each other (S5), and after a certain period of time (S6), among the four transistors 32a to 32d The next one is turned on (S7), and the above steps S2 to S7 are repeated.

  In addition, in the detectable period T1 to T4, only one of the non-contact power supply units 10a to 10d is driven and the other non-contact power supply unit 10 is stopped. The non-contact power receiving unit 20 installed has a period during which the power cannot be received at regular intervals during a normal power feeding operation. Therefore, the smoothing capacitor Ca of the non-contact power receiving unit 20 is set to a capacity capable of supplying power to the functional unit 21 in the detectable periods T1 to T4, and compensates for the power supply operation in the non-power receiving period.

  In this way, not all the non-contact power supply units 10 are driven all the time, but only the non-contact power supply unit 10 disposed so that the non-contact power reception unit 20 is opposed to each other is driven, and thus unnecessary power is consumed. Energy saving can be achieved.

  Further, as shown in FIG. 7, the non-contact power feeding system of the present embodiment may be applied to a bathroom R <b> 2 in the building H or a location facing the outside of the building H. For example, a plurality of non-contact power supply units 10 are incorporated in the wall panel P11 of the bath R2, and the wall surface P11a of the wall panel P11 has an LED light U11 used as bath lighting, a speaker U12 that outputs sound, and a relaxing effect. Aroma apparatus U13 and the like that generate a scent are installed. Moreover, the non-contact electric power feeding part 10 is integrated also in the outer wall panel P21 of the building H, and the functional part 21 of the DC equipment U15 such as a spotlight U14 for crime prevention or a vacuum cleaner is provided on the wall surface P21a of the outer wall panel P21. A non-contact power receiving unit 20 or the like that supplies operating power via a power cord CD is installed.

(Embodiment 2)
The building with a non-contact power feeding function of the present embodiment has substantially the same configuration as that of the first embodiment, but each non-contact power feeding unit 10 is configured to be movable on the wall back surface P1b, the ceiling back surface P2b, and the floor back surface P3b. Different points. In addition, the same code | symbol is attached | subjected to the structure similar to Embodiment 1, and description is abbreviate | omitted.

  First, as shown in FIGS. 3A and 3B, the magnets M1a and M1b provided in the non-contact power feeding unit 10 and the magnets M2a and M2b provided in the non-contact power receiving unit 20 are different from each other. The non-contact power receiving unit 20 and the non-contact power receiving unit 10 are opposed to each other through the panel P1, the ceiling panel P2, and the floor panel P3, and magnetic attraction is generated between the magnets M1a and M1b and the magnets M2a and M2b. It is attached opposite to.

  Then, as shown in FIG. 8, when the non-contact power receiving unit 20 is moved on the panel surface Pa, between the magnets M1a and M1b of the non-contact power feeding unit 10 and the magnets M2a and M2b of the non-contact power receiving unit 20 The non-contact power feeding unit 10 is also pulled by the non-contact power receiving unit 20 by the suction force, and moves on the panel back surface Pb in the same direction, so that the power feeding state can be maintained.

  Moreover, if a wheel (not shown) is provided on the panel back surface Pb side of the non-contact power feeding unit 10 and the panel surface Pa side of the non-contact power receiving unit 20, the above movement can be easily performed.

  Thus, the user can easily change the feeding point by changing the type or layout of the DC device U to be used.

(Embodiment 3)
The building with a non-contact power feeding function of the present embodiment has substantially the same configuration as that of the first or second embodiment, but detects whether or not the non-contact power receiving unit 20 is disposed facing the non-contact power feeding unit 10. The configuration is different. In addition, the same code | symbol is attached | subjected to the structure similar to Embodiment 1 or 2, and description is abbreviate | omitted.

  The contactless power supply unit 10 of the present embodiment is always connected to the DC supply line Wdc, and the high frequency power generation circuit 11 can switch the high frequency current flowing through the primary coil L1 to the rated current, standby current, and zero ( Rated current> standby current> zero). In a standby state in which the non-contact power receiving unit 20 is not disposed so as to face the non-contact power feeding unit 10, a standby current smaller than the rated current is passed through the primary coil L1.

  As shown in FIG. 9, the non-contact power receiving unit 20 is provided with a modulation unit 22 connected to both ends of the secondary coil L <b> 2. When the non-contact power receiving unit 20 is installed facing the non-contact power feeding unit 10, the non-contact power receiving unit 20 A secondary voltage is generated at both ends of the secondary coil L2, and a voltage obtained by rectifying and smoothing the secondary voltage is used as an operation power supply, and a power supply request signal is superimposed on the secondary voltage to be modulated (for example, a sinusoidal secondary voltage). The voltage waveform is changed every predetermined period). Then, a signal induced by the power supply request signal superimposed on the secondary voltage is generated at both ends of the primary coil L1 of the non-contact power supply unit 10, and the high-frequency power generation circuit 11 starts from the voltage at both ends of the primary coil L1. By demodulating the induced signal, it is detected that the non-contact power reception unit 20 is disposed facing the signal. And if the high frequency electric power generation circuit 11 detects that the non-contact power receiving part 20 is arrange | positioned facing, a rated current will be sent through the primary coil L1, and the normal electric power feeding to the non-contact power receiving part 20 will be started.

  Even during normal power feeding, the high-frequency power generation circuit 11 continues the demodulation process for the voltage across the primary coil L1, and when the induced signal is no longer detected, it determines that the non-contact power receiving unit 20 has been removed, The current flowing through the coil L1 is switched to the standby current.

  That is, the high-frequency power generation circuit 11 and the modulation unit 22 form driving target detection means for detecting whether or not the non-contact power receiving unit 20 is disposed so as to face the non-contact power feeding units 10a to 10d. The circuit 11 forms drive means for generating a high-frequency magnetic field by supplying a rated current to the primary coil L1 of the non-contact power feeding unit 10 disposed so as to face the non-contact power receiving unit 20.

  In this detection method, since the other non-contact power supply unit 10 can detect the installation state of the non-contact power reception unit 20 in a state where power supply to the non-contact power reception unit 20 is continued, as in the first embodiment, There is no need to increase the capacity of the smoothing capacitor Ca of the non-contact power receiving unit 20. Furthermore, it is not necessary to provide the controller 40.

  Moreover, not all the non-contact electric power feeding parts 10 always flow a rated current to the primary coil L1, but only the non-contact electric power feeding part 10 with which the non-contact electric power receiving part 20 is arrange | positioned facing is applied to a primary coil L1. Since the other non-contact power receiving unit flows a standby current smaller than the rated current to the primary coil L1, unnecessary power consumption can be suppressed and energy saving can be achieved.

(Embodiment 4)
The building with a non-contact power feeding function of the present embodiment has substantially the same configuration as that of the first or second embodiment, but detects whether or not the non-contact power receiving unit 20 is disposed facing the non-contact power feeding unit 10. The configuration is different. In addition, the same code | symbol is attached | subjected to the structure similar to Embodiment 1 or 2, and description is abbreviate | omitted.

  The contactless power supply unit 10 of the present embodiment is always connected to the DC supply line Wdc, and the high frequency power generation circuit 11 can switch the high frequency current flowing through the primary coil L1 to the rated current, standby current, and zero ( Rated current> standby current> zero). In a standby state in which the non-contact power receiving unit 20 is not disposed so as to face the non-contact power feeding unit 10, a standby current smaller than the rated current is passed through the primary coil L1.

  Further, as shown in FIG. 10, the wireless receiving unit 12 is provided in the non-contact power feeding unit 10, and the wireless transmitting unit 23 is provided in the non-contact power receiving unit 20, and between the wireless transmitting unit 23 and the wireless receiving unit 12. Then, transmission / reception of radio signals by radio waves is performed.

  When the non-contact power receiving unit 20 is installed facing the non-contact power feeding unit 10, a secondary voltage is generated at both ends of the secondary coil L2 by the standby current of the primary coil L1, and the secondary voltage is rectified and smoothed. The power transmission request signal is transmitted from the wireless transmission unit 23 using the obtained voltage as an operating power source. Then, the wireless reception unit 12 of the non-contact power supply unit 10 receives this power supply request signal, and the high-frequency power generation circuit 11 detects that the non-contact power reception unit 20 is disposed facing the power supply request signal. . And if the high frequency electric power generation circuit 11 detects that the non-contact power receiving part 20 is arrange | positioned facing, a rated current will be sent through the primary coil L1, and the normal electric power feeding to the non-contact power receiving part 20 will be started.

  If the power supply request signal is not received during normal power supply, the high-frequency power generation circuit 11 determines that the non-contact power reception unit 20 has been removed, and switches the current flowing through the primary coil L1 to the standby current.

  That is, the drive target detection means for detecting whether or not the non-contact power receiving unit 20 is disposed so as to face the non-contact power feeding units 10a to 10d by the high-frequency power generation circuit 11, the radio reception unit 12, and the radio transmission unit 23. The driving means for generating a high frequency magnetic field by supplying a rated current to the primary coil L1 of the non-contact power feeding unit 10 disposed so as to face the non-contact power receiving unit 20 is formed in the high-frequency power generation circuit 11. .

  In this detection method, since the other non-contact power supply unit 10 can detect the installation state of the non-contact power reception unit 20 in a state where power supply to the non-contact power reception unit 20 is continued, as in the first embodiment, There is no need to increase the capacity of the smoothing capacitor Ca of the non-contact power receiving unit 20. Furthermore, it is not necessary to provide the controller 40.

  Moreover, not all the non-contact electric power feeding parts 10 always flow a rated current to the primary coil L1, but only the non-contact electric power feeding part 10 with which the non-contact electric power receiving part 20 is arrange | positioned facing is applied to a primary coil L1. Since the other non-contact power receiving unit flows a standby current smaller than the rated current to the primary coil L1, unnecessary power consumption can be suppressed and energy saving can be achieved.

  Moreover, transmission / reception of the power supply request signal from the non-contact power reception unit 20 to the non-contact power supply unit 10 may be performed via a wire.

  In the first to fourth embodiments, the non-contact power feeding system is applied to the DC distribution system in the power distribution system shown in FIG. 11, but the same non-contact power feeding system as that of each embodiment is applied to the AC distribution system (not shown). May be. In this case, a rectifying means for rectifying the commercial power supply is provided at the input stage of the non-contact power supply unit 10, and a DC / AC conversion device such as an inverter device is provided at the output stage of the non-contact power reception unit 20.

It is a figure which shows the structure of the building with a non-contact electric power feeding function of Embodiment 1, and arrangement | positioning of a non-contact electric power feeding outlet. It is a figure which shows the structure of the non-contact electric power feeding system same as the above. (A) is the figure which shows arrangement | positioning of the magnet which the non-contact electric power feeding part same as the above comprises, (b) is a figure which respectively shows arrangement | positioning of the magnet which the non-contact electric power receiving part comprises. It is a figure which shows another structure of arrangement | positioning of a non-contact electric power feeding part same as the above. It is a figure which shows the structure of the drive control part of a non-contact electric power feeding part same as the above. It is a figure which shows the operation | movement flowchart of a drive control part same as the above. It is a figure which shows another structure of the building with a non-contact electric power feeding function same as the above. It is a figure which shows the structure of the non-contact electric power feeding system in the building with a non-contact electric power feeding function of Embodiment 2. FIG. It is a figure which shows the structure of the non-contact electric power feeding system in the building with a non-contact electric power feeding function of Embodiment 3. FIG. It is a figure which shows the structure of the non-contact electric power feeding system in the building with a non-contact electric power feeding function of Embodiment 4. FIG. It is a figure which shows the whole structure of a power distribution system.

Explanation of symbols

H building P1 wall panel P2 ceiling panel P3 floor panel P1a wall surface P2a ceiling surface P3a floor surface P1b wall back surface P2b ceiling back surface P3b floor back surface 10 non-contact power feeding unit 20 non-contact power receiving unit U DC device

Claims (8)

  Contactless power supply that generates a high-frequency magnetic field instead of an outlet that is installed on one side of the building material that constitutes the building wall, ceiling, or floor, and that is connected to a conductor that is electrically connected to the load. A non-contact power receiving unit that supplies power received from the non-contact power feeding unit in a non-contact manner to the load by using electromagnetic induction by a high-frequency magnetic field generated by the non-contact power feeding unit. Is disposed at a position on one surface of the building material facing the non-contact power feeding unit. A building with a non-contact power feeding function.   A plurality of the non-contact power feeding units are arranged in the building material of the building or on the other surface of the building material, and include a mounting unit that detachably attaches the non-contact power receiving unit at a position facing the non-contact power feeding unit on one surface of the building material. The building with a non-contact power feeding function according to claim 1. The non-contact power supply unit includes a coil that generates a high-frequency magnetic field by being supplied with a high-frequency current,
Drive target detection means for detecting whether or not a non-contact power receiving unit is disposed opposite to each non-contact power feeding unit, and a predetermined high frequency to a coil of the non-contact power feeding unit disposed so as to be opposed to the non-contact power receiving unit The building with a non-contact power feeding function according to claim 2, further comprising driving means for supplying a current to generate a high-frequency magnetic field.   The drive target detecting means generates a detectable period for driving only one of the plurality of non-contact power supply units at a predetermined time by sequentially switching the non-contact power supply unit to be driven, and is being driven during the detectable period Measure the impedance of the non-contact power feeding unit viewed from the power receiving side, and determine whether or not the non-contact power receiving unit is disposed opposite to the non-contact power feeding unit based on the measured impedance The building with a non-contact power feeding function according to claim 3.   The building with a non-contact power feeding function according to claim 1, wherein the non-contact power feeding unit is movably installed on the other surface of the building material of the building.   The attachment means generates a suction force via a building material between the non-contact power supply unit and the non-contact power reception unit, and the suction force causes the non-contact power reception at a position facing the non-contact power supply unit on one surface of the building material. 6. The building with a non-contact power feeding function according to claim 2, wherein the part is detachably attached.   The attachment means can be detachably attached to the non-contact power receiving portion at a position facing the non-contact power feeding portion on one surface of the building material by an attractive force generated between magnets respectively provided in the non-contact power feeding portion and the non-contact power receiving portion. The structure with a non-contact power feeding function according to claim 6, wherein the structure is attached to the structure.   Instead of an outlet that is provided on one side of the building material that constitutes the wall or ceiling or floor of the building and that supplies electrical power to the load by contact with a conductor that is electrically connected to the load, it is placed in the building material or on the other side of the building material. A non-contact power receiving unit that includes a high-frequency magnetic field generating unit that generates a high-frequency magnetic field and that supplies non-contact power received to the load using electromagnetic induction by the high-frequency magnetic field generated by the high-frequency magnetic field generating unit. A non-contact power supply outlet, wherein the non-contact power supply outlet is disposed at a position facing the high-frequency magnetic field generating means on one surface.

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