JP2009151947A - Dc outlet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a DC outlet capable of acquiring adapted voltage value information of a DC device to be connected, and corresponding to a difference of an adapted voltage. <P>SOLUTION: The DC outlet 1 includes an input terminal part 2 to which a DC power supply line Wdc from a distribution board is connected, a plug connection part 3 to which a plug 102a of the DC device 102 is detachably connected, and which supplies a DC power input to the input terminal part 2 to the DC device 102 through the plug 102a, an input voltage detection circuit 4 for detecting a voltage value of the DC voltage input to the input terminal part 2, a device voltage detection circuit 5 for detecting an adapted voltage value of the DC device 102 by receiving the adapted voltage value information superimposed to the DC voltage and transmitted from the DC device 102 connected to the plug connection part 3, and a display circuit 6 for displaying whether the DC voltage value detected by the input voltage detection circuit 4 is different from an adapted voltage indicated by the adapted voltage value information or not by light and sound. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a DC outlet.

  2. Description of the Related Art Conventionally, an AC outlet is provided in which a plug of a load device is detachably connected, and operating power is supplied to the load device via the plug (see, for example, Patent Document 1).

The outlet disclosed in the above-mentioned patent document is for supplying AC power to the load device, and since many of the load devices for AC used in general households operate at AC 100V, the electric device used is used. I was able to use it with AC load equipment connected to any outlet without worrying about the applicable voltage value.
JP-A-5-207626

  By the way, in recent years, introduction of fuel cells and solar power generation facilities to homes is progressing. In such homes, direct current power generated by fuel cells and solar power generation facilities is connected to direct current outlets installed in each room. It has been studied to connect and use a DC device that operates by receiving DC power supplied to the DC outlet.

  Since there are devices that operate with multiple types of DC voltage values such as 6V system, 12V system, 24V system, etc., as DC devices that operate upon receiving DC power supply, 6V system, 12V system, There are a plurality of types of systems such as a 24V system, and there is a possibility that DC devices having different applicable voltage values are connected to an outlet.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a DC outlet that can acquire information on the voltage value of a connected DC device and can cope with a difference in voltage. It is in.

  In order to achieve the above object, according to the first aspect of the present invention, a plug of a DC device is detachably connected, a plug connection portion for supplying DC power to the DC device via the plug, and a plug connection portion. And a voltage information acquisition unit that acquires appropriate voltage value information indicating the applicable voltage of the DC device.

  According to a second aspect of the present invention, in the first aspect of the present invention, the voltage information acquiring unit receives a signal for receiving the appropriate voltage value information superimposed on the DC voltage and transmitted from the DC device connected to the plug connection unit. It is characterized by comprising means.

  According to a third aspect of the present invention, in the first aspect of the invention, the voltage information acquisition unit includes a storage medium that is provided in the plug and stores the adaptive voltage value information in a non-contact readable state from the outside. It comprises signal reading means for reading the adaptive voltage value information in a non-contact manner.

  According to a fourth aspect of the present invention, in any one of the first to third aspects of the present invention, a voltage detection unit that detects a DC voltage value of DC power supplied to the DC device from the plug connection unit, and the voltage detection unit detects And a display unit for displaying whether or not the DC voltage value is different from the adaptive voltage indicated by the adaptive voltage value information.

  According to a fifth aspect of the present invention, in any one of the first to third aspects of the present invention, the voltage conversion unit that converts the voltage value of the DC power supplied from the outside and supplies the voltage to the plug connection unit, and the compatible voltage value information A voltage control unit that controls the output of the voltage conversion unit so that the output voltage of the voltage conversion unit has an appropriate voltage value is provided.

  According to a sixth aspect of the invention, in the fifth aspect of the invention, when the plug of the DC device is connected, the voltage control unit outputs voltage information in a state where the voltage converter outputs a minimum operating voltage lower than the compatible voltage. And the voltage control unit changes the output voltage of the voltage conversion unit from the lowest operating voltage to the adaptive voltage based on the adaptive voltage value information.

  According to the first aspect of the present invention, since the voltage information acquisition unit acquires the appropriate voltage value information of the DC device, it is possible to perform processing according to the applicable voltage of the connected DC device.

  According to the invention of claim 2, since the DC device transmits the adaptive voltage value information superimposed on the DC voltage, there is no need to add a separate signal line in order to transmit the adaptive voltage value information, The compatible voltage value information can be transmitted using the power line.

  According to the invention of claim 3, when the plug of the DC device is brought close to the communicable range of the signal reading means, the compatible voltage value information is read from the storage medium provided in the plug. Applicable voltage value information can be read before connection.

  According to the invention of claim 4, it is possible to easily determine whether or not the DC voltage supplied from the plug connection portion is different from the compatible voltage of the DC device from the display on the display portion. By the way, when the wiring length from the distribution board that supplies DC power to the branch circuit to the DC outlet is long, the DC voltage supplied from the plug connection is lower than the compatible voltage of the DC device due to the voltage drop in the DC power supply line. In this case as well, it is possible to easily determine whether or not the supply voltage is different from the compatible voltage of the DC device from the display on the display unit.

  According to the invention of claim 5, since the output voltage from the voltage converter is changed in accordance with the compatible voltage of the DC device, it is possible to connect DC devices of various compatible voltages.

  According to the invention of claim 6, since the compatible voltage value information is acquired from the DC device in a state where the minimum operating voltage is output from the voltage converter, the compatible voltage is obtained when the plug of the DC device is connected. It is possible to prevent the exceeding voltage from being applied to the DC device.

  Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1)
Embodiment 1 of this invention is demonstrated based on FIGS. The DC outlet 1 according to the present embodiment is used in a DC power distribution system to be described later. A plug of a DC device 102 that operates by receiving supply of DC power is detachably connected to the connected DC device 102. In contrast, DC power is supplied.

  FIG. 1 is a block diagram of a DC outlet 1 according to the present embodiment, in which an input terminal portion 2 to which a DC feed line Wdc from a distribution board 110 described later is connected and a plug 102a of a DC device 102 are detachably connected. A plug connection unit 3 for supplying DC power input to the input terminal unit 2 to the DC device 102 via the plug 102a; and an input voltage detection circuit 4 for detecting the voltage value of the DC voltage input to the input terminal unit 2. (Voltage detection unit) and a device voltage for detecting a suitable voltage value of the DC device 102 by receiving the suitable voltage value information transmitted superimposed on the DC voltage from the DC device 102 connected to the plug connection unit 3 Whether or not the DC voltage value detected by the detection circuit 5 (signal receiving means, voltage information acquisition unit) and the input voltage detection circuit 4 is different from the matching voltage indicated by the matching voltage value information is a two-color light emitting die. And a display circuit 6 to be displayed (display section) by ringing sound emission color or buzzer 6b of over de 6a. In this DC outlet 1, the apparatus voltage detection circuit 5 acquires the information on the appropriate voltage value of the DC device 102, so that processing according to the applicable voltage of the connected DC device 102 can be performed. In addition, since the DC device 102 transmits the adaptive voltage value information superimposed on the DC voltage, it is not necessary to add a separate signal line to transmit the adaptive voltage value information, and the DC device 102 is adapted using the power line. Voltage value information can be transmitted.

  By the way, when the wiring length from the distribution board 110 provided in the house to the DC outlet 1 is long, a voltage drop occurs in the DC power supply line Wdc, and the DC voltage supplied from the plug connection unit 3 (that is, the input terminal unit). DC voltage input to 2) may be lower than the compatible voltage of the DC device 102. Here, in the DC outlet 1 of the present embodiment, when the input voltage matches the compatible voltage of the DC device 102, the display circuit 6 lights the light emitting diode 6a in green and the input voltage falls below the compatible voltage. Since the display circuit 6 lights up the light emitting diode 6a in red and sounds the buzzer 6b, it is determined whether or not an appropriate voltage is supplied based on the emission color of the light emitting diode 6a and the sound of the buzzer 6b. It can be easily distinguished. Therefore, even if the DC device 102 is connected to the DC outlet 1, if the DC device 102 becomes inoperable because no suitable voltage is supplied, the direct current is detected from the light emission color of the light emitting diode 6a and the sound of the buzzer 6b. The reason for the malfunction of the device 102 can be determined.

  Moreover, as shown in FIG.2 and FIG.3, as for the container 10 of the DC outlet 1 of this embodiment, the front surface was open | released using the thermosetting synthetic resin (for example, urea resin) excellent in tracking resistance. A body 11 formed in a rectangular parallelepiped shape and a cover 12 formed in a rectangular parallelepiped shape whose rear surface is opened using a synthetic resin having elasticity and excellent tracking resistance (for example, polybutylene terephthalate = PBT). It is formed by bonding. The container 10 has a prescribed unit dimension to be described later. In the following description, unless otherwise specified, the vertical and horizontal directions are defined in the direction shown in FIG. 2A, and the front in FIG. Accordingly, the lower side in FIG. 2B is the rear side.

  A pair of assembly claws 13 project from the left and right end faces of the body 11. On the other hand, shoulders 14 project from the left and right ends of the cover 12, and assembly pieces 15 project from the rear edge of each shoulder 14 toward the body 11. Each assembly piece 15 is formed with a pair of engagement holes 16 for engaging with the assembly claws 13 provided in the body 11 in an uneven manner. At the front end of the assembly claw 13, a guide surface 13a that is inclined so as to reduce the amount of protrusion from the body 11 toward the front is formed. Therefore, when the cover 12 is assembled to the body 11, the assembly piece 15 is bent along the guide surface 13 a, and finally the engagement hole 16 provided in the assembly piece 15 is fitted to the assembly claw 13, thereby The cover 12 is joined. Thus, since the assembly piece 15 needs to be bent, the cover 12 is formed of a synthetic resin having elasticity.

  Inside the body 11, a blade receiving member 20a for a positive electrode and a blade receiving member 20b for a negative electrode are accommodated. Each blade receiving member 20a, 20b is formed in the same shape, and includes a pair of spring pieces 21 facing each other and a connecting piece 22 that continuously joins the base portions of both spring pieces 21 together. A terminal piece 23 is formed integrally with the spring piece 21 so as to protrude from both side edges of the one spring piece 21 in a direction away from each other. A printed wiring board (not shown) on which each circuit element described in FIG. 1 is formed is housed on the bottom side of the body 11 and electrically connected to the blade receiving members 20a and 20b. Yes.

  Furthermore, a lock spring 24 is disposed inside the body 11 so as to face the terminal pieces 23 of the blade receiving members 20a and 20b. The locking spring 24 is formed by bending one end portion of the belt plate into a J shape to form a contact piece 25 and bending the other end portion into an S shape to form a locking piece 26. The contact piece 25 and the locking piece 26 are accommodated in the body 11 so as to face the terminal piece 23. A release button 27 for releasing the connection state of the electric wires is housed so as to face the lock pieces 26 of the two lock springs 24. A partition wall 17 that is inserted between the blade receiving members 20a and 20b is provided inside the body 11.

  An electric wire insertion opening (not shown) is opened on the bottom surface of the body 11 so that an electric wire can be introduced between the terminal piece 23 and the lock spring 24. When the core wire from which the wire of the DC power supply line Wdc is peeled is introduced into the body 11 through this wire insertion port, the wire core wire is inserted between the lock spring 24 and the terminal piece 23, and contact is made. The electric wire is clamped between the terminal piece 23 by the spring force of the piece 25 and the locking piece 26, and the locking piece 26 bites into the electric wire, so that the electric wire cannot be pulled out. On the other hand, when releasing the connection state of the electric wire, the release button is inserted by inserting the tip of a tool such as a flat-blade screwdriver from an operation hole (not shown) opened in the bottom surface of the body 11 at a portion corresponding to the release button 27. When 27 is pushed, the lock button 26 is bent in the direction away from the electric wire by the release button 27, so that the locked state of the electric wire is released and the electric wire can be easily pulled out. Here, the above-mentioned input terminal part 2 is comprised from the terminal piece 23, the lock spring 24, etc. of each blade receiving member 20a, 20b.

  On the other hand, the front wall of the cover 12 is formed with one insertion portion 18 into which a pair of plug blades 102b provided on the plug 102a of the DC device 102 are inserted and removed. The blade receiving members 20a and 20b have a pair of insertion openings 18a and 18b that open at portions corresponding to the spring pieces 21 and 21, respectively. Here, the plug connecting portion 3 described above is configured by the insertion portion 18 and the blade receiving members 20a and 20b. The insertion openings 18a and 18b have different lengths on the positive electrode side and the negative electrode side to prevent erroneous connection. Further, a window hole 12a for exposing the light emitting portion of the light emitting diode 6a mounted on the above-described printed wiring board is provided in the upper right portion of the front wall of the cover 12.

  In addition, in this embodiment, although the insertion part 18 of the plug connection part 3 is comprised by the insertion ports 18a and 18b in which a pair of parallel plug blades are inserted, the structure of the plug connection part 3 is limited to said structure. The plug connection portion 3 may have the insertion ports 18a and 18b into which the round pin-shaped contact pins are inserted as shown in FIG. 4 (a), as shown in FIG. 4 (a). Alternatively, the plug connection unit 3 having the plug 18 having a shape conforming to IEC 60906-3 may be used, and the present invention can be applied to the DC outlet 1 having the plug connection unit 3 of various forms.

  The above-described container 10 is attached to a conventionally known plate used when, for example, an embedded wiring device is attached to a construction surface, and the shoulder 14 provided on both sides of the cover 12 is attached to the plate. A pair of attachment claws 19 are provided in a protruding manner for coupling. An inclined surface 19 a is formed at the front end portion of the mounting claw 19 so as to decrease the amount of protrusion from the shoulder portion 14 toward the front. The container body 10 of the present embodiment is formed in such a size that it can be attached to the above-mentioned standardized plate in a short width direction and can be attached up to three pieces. One piece is called module size. Here, the size of the vessel 10 is not limited to the size of one module, and may be formed to have a size of two modules or three modules.

  In the present embodiment, it is determined whether or not the supply voltage to the DC device 102 is different from the compatible voltage of the DC device 102 on the DC outlet 1 side. However, as shown in FIG. A determination circuit 102c that determines whether or not the supply voltage from the outlet 1 is an appropriate voltage, and a transmission circuit 102d that superimposes the determination result of the determination circuit 102c on the DC voltage and transmits the DC voltage to the DC outlet 1 are provided. A receiving circuit 7 is provided for receiving a signal transmitted by superimposing the direct current voltage on the direct current voltage from the transmission circuit 102d of the direct current device 102 connected to the plug connection unit 3, and the display circuit 6 emits light based on the received content of the reception circuit 7. You may make it control the light emission state of the diode 6a, and the ringing state of the buzzer 6b. In this circuit, when the plug 102 a of the DC device 102 is connected to the plug connection unit 3, a DC voltage is supplied from the DC outlet 1 to the DC device 102. Whether or not the determination circuit 102c and the transmission circuit 102d of the DC device 102 start to operate by feeding from the DC outlet 1, and whether or not the DC voltage value supplied from the DC outlet 1 by the determination circuit 102c is different from its own adaptable voltage. And the determination result is transmitted from the transmission circuit 102d. At this time, the receiving circuit 7 of the DC outlet 1 receives the signal transmitted from the transmitting circuit 102d of the DC device 102, and the display circuit 6 switches the emission color of the light emitting diode 6a based on the received content, or the buzzer 6b is turned on. Since the ringing or stopping is performed, it is possible to easily determine whether or not the suitable voltage is supplied based on the emission color of the light emitting diode 6a and the ringing sound of the buzzer 6b as described above.

  In addition, as shown in FIG. 6, an RF tag 102e (storage medium) that stores, in a non-contact-readable manner, suitable voltage value information indicating a suitable voltage of the DC device 102 is incorporated in the plug 102a of the DC device 102. At the same time, the DC outlet 1 is provided with a reader 8 that reads the voltage value information in a non-contact manner by performing short-range wireless communication using an electromagnetic field or radio wave with the RF tag 102a provided on the plug 102a. The display circuit 6 determines whether the DC voltage value detected by the input voltage detection circuit 4 is different from the adaptive voltage indicated by the adaptive voltage value information based on the adaptive voltage value information read by the reader 8. The determination result may be displayed by the emission color of the light emitting diode 6a or the sound of the buzzer 6b. Since the reader 8 and the RF tag 102e have a conventionally known configuration, illustration and description are omitted.

  In this circuit, when the plug 102 a incorporating the RF tag 102 e is brought close to the DC outlet 1, the RF tag 102 e that enters the communicable area of the reader 8 starts operation upon receiving power supply from the reader 8. The adaptive voltage value information is transmitted from the tag 102e by a radio signal. The adaptive voltage value information transmitted from the RF tag 102e as a radio signal is received by the reader 8 and sent to the display circuit 6. The display circuit 6 detects the input voltage detected by the input voltage detection circuit 4, and the reader 8 Compare with the adapted voltage value indicated by the received adapted voltage value information. Here, when the input voltage matches the conforming voltage of the DC device 102, the display circuit 6 lights the light emitting diode 6a in green, and when the input voltage falls below the conforming voltage, the display circuit 6 displays the light emitting diode 6a. Is lit red and the buzzer 6b is sounded. Therefore, according to this configuration, when the plug 102a is connected to the DC outlet 1, that is, when the RF tag 102e incorporated in the plug 102a enters the communicable range of the reader 8, the conforming voltage value is applied from the RF tag 102e. Information can be read, and it can be easily determined whether or not a suitable voltage is supplied based on the emission color of the light emitting diode 6a and the sound of the buzzer 6b.

(Embodiment 2)
A second embodiment of the present invention will be described with reference to FIGS. In addition, since the DC outlet 1 of this embodiment is provided with the same structure as the DC outlet 1 demonstrated in Embodiment 1, the same code | symbol is attached | subjected to a common component and the description is abbreviate | omitted.

  FIG. 7 is a block diagram of the DC outlet 1 of the present embodiment, in which the input terminal 2 to which the DC power supply line Wdc from the distribution board 110 is connected and the plug 102a of the DC device 102 are detachably connected. The connection unit 3, the DC-DC converter 30 (voltage conversion unit) that converts the voltage value of the DC power input to the input terminal unit 2 and supplies it to the plug connection unit 3, and the DC signal input to the input terminal unit 2 By receiving the input voltage detection circuit 4 (voltage detection unit) that detects the voltage value of the voltage and the compatible voltage value information that is transmitted by being superimposed on the DC voltage from the DC device 102 connected to the plug connection unit 3, The device voltage detection circuit 5 (signal receiving means, voltage information acquisition unit) that detects the compatible voltage value of the DC device 102, the detected voltage value of the input voltage detection circuit 4, and the DC device 102 detected by the device voltage detection circuit 5 A control circuit 31 (voltage control unit) is provided for controlling the output of the DC-DC converter 30 so that the output voltage of the DC-DC converter 30 becomes the appropriate voltage value of the DC device 102 based on the compatible voltage value. Yes.

  FIG. 8 shows the DC voltage value and the plug connection portion 3 in the midway position of the DC power supply line Wdc from the distribution board 110 (position P1 in the drawing) to the input terminal portion 2 (position P2 in the drawing) of the DC outlet 1. DC voltage values at the output terminals (position P3 in the figure) are respectively shown. When the wiring length from the distribution board 110 to the DC outlet 1 becomes longer, the voltage drop in the DC power supply line Wdc causes the DC outlet 1 to Input voltage Vin gradually decreases, and may be lower than the applicable voltage value V1 of the DC device 102 connected to the DC outlet 1. When the input voltage Vin to the DC outlet 1 becomes a voltage V2 lower than the normal operating voltage ΔV1 of the DC apparatus 102, the DC apparatus 102 is connected to the DC outlet 1 that does not include the DC-DC converter 30. The DC device 102 may not operate normally. On the other hand, in the DC outlet 1 of the present embodiment, the device voltage detection circuit 5 detects the compatible voltage value V1 of the DC device 102 in the same manner as described in the first embodiment, and the input voltage detection circuit 4 Since the input voltage Vin is detected, the control circuit 31 controls the operation of the DC-DC converter 30 so that the output voltage of the DC-DC converter 30 matches the adaptive voltage value V1 of the DC device 102. A suitable voltage can be supplied to the DC device 102 connected to the DC outlet 1 to operate normally. Further, since the control circuit 31 changes the output voltage of the DC-DC converter 30 in accordance with the compatible voltage of the DC device 102, it is possible to connect the DC devices 102 of various compatible voltages.

  Further, if the DC voltage V3 supplied from the distribution board 110 to the DC outlet 1 is originally different from the applicable voltage value V1 of the DC device 102, even if there is no voltage drop in the DC power supply line Wdc, the input voltage There is a possibility that the voltage Vin is lower than the minimum operating voltage V2 of the DC device 102. Even in such a case, in the DC outlet 1 of this embodiment, the control circuit 31 is set so that the output voltage matches the compatible voltage of the DC device 102. Since the output voltage of the DC-DC converter 30 is controlled, a suitable voltage can be supplied to the DC device 102 connected to the DC outlet 1 so as to operate normally.

  In the present embodiment, the device voltage detection circuit 5 receives compatible voltage value information from the DC device 102 by transmitting / receiving a signal superimposed on the DC voltage to / from the DC device 102 connected to the DC outlet 1. However, as described in the first embodiment, the RF tag storing the compatible voltage value information is incorporated in the plug 102a of the DC device 102, and a reader is provided in the DC outlet 1, so that the compatible voltage can be contacted without contact from the RF tag. Value information may be read. Further, a switching switch for switching the output voltage may be provided in the DC outlet 1 so that the control circuit 31 switches the output voltage of the DC-DC converter 30 in accordance with the switching operation of the switching switch by the user.

(Embodiment 3)
A third embodiment of the present invention will be described with reference to FIGS. In addition, since the DC outlet 1 of this embodiment is provided with the same structure as the DC outlet 1 demonstrated in Embodiment 1, the same code | symbol is attached | subjected to a common component and the description is abbreviate | omitted.

  FIG. 9 is a block diagram of the DC outlet 1 of the present embodiment, in which the input terminal portion 2 to which the DC power supply line Wdc from the distribution board 110 is connected and the plug 102a of the DC device 102 are detachably connected. The connection unit 3, the DC-DC converter 30 (voltage conversion unit) that converts the voltage value of the direct-current power input to the input terminal unit 2 and supplies the converted voltage value to the plug connection unit 3, and the direct current connected to the plug connection unit 3 Based on the information received by the voltage signal receiving circuit 32 and the voltage signal receiving circuit 32 (voltage information acquisition unit) that receives the signal transmitted from the device 102 while being superimposed on the DC voltage, the output voltage Vout of the DC-DC converter 30 Is provided with a control circuit 31 (voltage control unit) that controls the output voltage Vout of the DC-DC converter 30 so that the voltage becomes an adapted voltage value of the DC device 102.

  Here, the operation of the DC outlet 1 of the present embodiment will be described with reference to FIG. In the DC outlet 1 described in the second embodiment, when the DC device 102 is connected, the input voltage Vin is output as it is, and when the appropriate voltage value information is acquired from the DC device 102 thereafter, the output voltage is converted to the appropriate voltage V1. However, in this embodiment, when the plug 102a of the DC device 102 is not connected (time t1), the control circuit 31 controls the output voltage Vout of the DC-DC converter 30 to 0V. ing.

  The DC outlet 1 includes a detection switch (not shown) that detects the insertion of the plug 102a. When the plug 102a of the DC device 102 is connected to the plug connection portion 3, the insertion of the plug 102a is detected by the detection switch. Thus, a detection signal is given to the control circuit 31. When the insertion detection signal is input from the detection switch at time t2, the control circuit 31 starts the operation of the DC-DC converter 30 and gradually increases the output voltage Vout of the DC-DC converter 30 from 0V. When the output voltage Vout of the DC-DC converter 30 exceeds the minimum operating voltage of the DC device 102, the DC device 102 starts to operate.

  The DC device 102 includes a determination circuit 102c that determines whether or not the output voltage Vout of the DC outlet 1 is the appropriate voltage V1, and a transmission circuit 102d that superimposes the determination result of the determination circuit 102c on the DC voltage and transmits it to the DC outlet 1. If the determination circuit 102c determines that the output voltage Vout has increased to the compatible voltage V1 at time t3, the determination result of the determination circuit 102c is transmitted from the transmission circuit 102d to the DC outlet 1.

  On the other hand, in the DC outlet 1, when the voltage signal receiving circuit 32 receives the signal transmitted from the DC device 102 at time t3, the control circuit 31 uses the received content of the signal received by the voltage signal receiving circuit 32, Since it is determined that the compatible voltage V1 of the DC device 102 has been reached, the gradual increase control of the output voltage Vout of the DC-DC converter 30 is stopped, and the output voltage Vout is controlled to a constant value (compatible voltage V1). A suitable voltage can be supplied to the DC device 102 connected to 1 to operate normally. Here, in the present embodiment, a voltage information acquisition unit is configured by the voltage signal receiving circuit 32 that acquires information (adapted voltage value information) indicating that the adapted voltage has been reached from the DC device 102.

  As described above, in the present embodiment, when the plug 102a of the DC device 102 is connected to the plug connection unit 3, the output voltage of the DC-DC converter 30 is 0 V, and thereafter, the control circuit 31 operates as a DC-DC converter. Since the output voltage of the DC-DC converter 30 is controlled to a constant value when the output voltage reaches the appropriate voltage, the output voltage of the power supply 30 is adapted to the DC device 102 when the plug 102a is connected. A high voltage exceeding the voltage is not applied, and it is possible to prevent an excessive stress from being applied to the internal circuit of the DC device 102.

  In the present embodiment, when the DC device 102 is connected to the plug connection unit 3, the control circuit 31 gradually increases the output voltage of the DC-DC converter 30 from 0V, as shown in FIG. 10B. A voltage (for example, 5V) at which the transmission circuit 102d of the DC device 102 can operate may be output at the time when the DC device 102 is connected (time t11), and the operation of the DC outlet 1 in this case will be described below. To do. In this case, it is only necessary to provide the transmission circuit 102d on the DC device 102 side, and the determination circuit 102c described above is unnecessary.

  In a state where the plug 102a of the DC device 102 is not connected, the control circuit 31 controls the output voltage Vout of the DC-DC converter 30 to 0V. Thereafter, when the plug 102 a of the DC device 102 is connected to the plug connection unit 3 at time t <b> 11, insertion of the plug 102 a is detected by the detection switch, and a detection signal is given to the control circuit 31. When the insertion detection signal is input from the detection switch at time t11, the control circuit 31 starts the operation of the DC-DC converter 30 and controls the output voltage Vout of the DC-DC converter 30 to 5V. At this time, the DC device 102 receives the voltage supply from the DC outlet 1, and the transmission circuit 102d starts operating, and outputs the appropriate voltage value information indicating the appropriate voltage value from the transmission circuit 102d.

  In the DC outlet 1, when the voltage signal receiving circuit 32 receives the signal transmitted from the DC device 102 at time t <b> 12, the control circuit 31 uses the compatible voltage value information received by the voltage signal receiving circuit 32. Since the output voltage Vout of the DC-DC converter 30 is controlled to the suitable voltage V1 (time t13), the suitable voltage can be supplied to the DC device 102 connected to the DC outlet 1 so as to operate normally. .

  As described above, in this embodiment, when the plug 102a of the DC device 102 is connected to the plug connection unit 3, the output voltage of the DC-DC converter 30 is set to the lowest operating voltage lower than the compatible voltage of the DC device 102. In this state, the voltage signal receiving circuit 32 as a voltage information acquisition unit acquires the appropriate voltage value information from the DC device 102, and the control circuit 31 reduces the output voltage of the DC-DC converter 30 to the lowest level based on the applicable voltage value information. Since the operating voltage is changed to the compatible voltage, a high voltage exceeding the compatible voltage is not applied to the DC device 102 when the plug 102a is connected, and excessive stress is applied to the internal circuit of the DC device 102. Can be prevented.

(Embodiment 4)
Embodiment 4 of the present invention will be described with reference to FIG. In addition, since the DC outlet 1 of this embodiment is provided with the same structure as the DC outlet 1 demonstrated in Embodiment 1, the same code | symbol is attached | subjected to a common component and the description is abbreviate | omitted.

  FIG. 11 is a block diagram of the DC outlet 1 of the present embodiment, in which the input terminal 2 to which the DC power supply line Wdc from the distribution board 110 is connected and the plug 102a of the DC device 102 are detachably connected. The connection unit 3, the DC-DC converter 30 (voltage conversion unit) that converts the voltage value of the DC power input to the input terminal unit 2 and supplies it to the plug connection unit 3, and the DC signal input to the input terminal unit 2 An input voltage detection circuit 4 (voltage detection unit) that detects the voltage value of the voltage; a reader 8 that reads the appropriate voltage value information from the RF tag 102a provided on the plug 102a of the DC device 102; and the input voltage detection circuit 4 DC-DC converter so that the output voltage of the DC-DC converter 30 becomes the appropriate voltage value of the DC device 102 based on the detected voltage value of the current and the compatible voltage value information read by the reader 8. And a control circuit 31 (voltage control unit) for controlling the output of 30.

  Here, the plug 102a of the DC device 102 incorporates an RF tag 102e in which the compatible voltage value information is stored in a non-contact readable state, and when such a plug 102a is brought close to the DC outlet 1, The RF tag 102e entering the communicable area of the reader 8 starts operation upon receiving power supply from the reader 8, and the adaptive voltage value information is transmitted from the RF tag 102e by a radio signal. The adaptive voltage value information transmitted from the RF tag 102 e as a radio signal is received by the reader 8 and sent to the control circuit 31. The control circuit 31 receives the input voltage value detected by the input voltage detection circuit 4. The control circuit 31 uses the voltage value of the input voltage and the adaptive voltage value information input from the reader 8. In addition, since the operation of the DC-DC converter 30 is controlled so that the output voltage Vout of the DC-DC converter 30 matches the compatible voltage value V1 of the DC device 102, the DC device 102 connected to the DC outlet 1 is connected to the DC device 102. On the other hand, a suitable voltage can be supplied to operate normally.

  By the way, the DC outlet 1 described in each of the above-described embodiments is used in the following DC distribution system. Here, a description will be given assuming a detached house as a building to which the present invention is applied, but this does not preclude applying the technical idea of the present invention to an apartment house. As shown in FIG. 12, the house H is provided with a DC power supply unit 101 that outputs DC power and a DC device 102 as a load driven by the DC power, and an output end of the DC power supply unit 101. DC power is supplied to the DC device 102 through the DC power supply line Wdc connected to the. A current flowing through the DC power supply line Wdc is monitored between the DC power supply unit 101 and the DC device 102, and when an abnormality is detected, power is supplied from the DC power supply unit 101 to the DC device 102 on the DC power supply line Wdc. A DC breaker 114 is provided for limiting or blocking the current.

  The DC power supply line Wdc is used as a DC power supply path and also as a communication path, and is connected to the DC power 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 power supply line Wdc is connected to the home server 116 via the DC power supply unit 101. The in-home server 116 is a main device for constructing a home communication network (hereinafter referred to as “home network”), and communicates with a subsystem constructed by the DC device 102 in the home network.

  In the example shown in the drawing, as an subsystem, an illumination system comprising an information equipment system K101 comprising an information-system DC device 102 such as a personal computer, a wireless access point, a router, and an IP telephone, and an illumination system DC equipment 102 such as a lighting fixture. K102, K105, entrance system K103 composed of DC device 102 for dealing with visitors, monitoring intruders, etc., and residential alarm system K104 composed of alarm DC device 102 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 entrance 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 that divides the system of the DC power 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 entrance system K103.

  As the information equipment system K101, there is provided an information equipment system K101 composed of the DC equipment 102 connected to the DC outlet 1 arranged in advance in the house H (constructed during construction of the house H) in the form of a wall outlet or a floor outlet.

  The lighting systems K102 and K105 include a lighting system K102 composed of a lighting device (DC device 102) arranged in advance in the house H and a lighting device (DC device 102) connected to a hook ceiling 132 arranged in advance on the ceiling. An illumination system K105 is provided. At the time of interior construction of the house H, the contractor attaches the lighting fixture to the hook ceiling 132, or the householder 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 102 constituting the lighting system K102 can be given using a communication signal from the switch 141 connected to the DC power supply line Wdc. That is, the switch 141 has a communication function together with the DC device 102. In addition, a control instruction may be given by a communication signal from another DC device 102 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 devices 102 can be connected to the DC outlet 1 and the hooking ceiling 132 described above, and DC power is output to the connected DC devices 102. Therefore, the DC outlet 1 and the hooking ceiling 132 are distinguished below. When it is not necessary, it is called “DC outlet”.

  These DC outlets have a plug-in connection port (for example, the plug-in portion 18) into which a contact (for example, the plug blade 102b in the above example) provided directly on the DC device 102 is inserted. A contact holder (for example, blade receiving members 20a, 20b) that directly contacts the contact inserted into the container is held by the container. That is, the direct current outlet supplies power in a contact manner. When the DC device 102 connected to the DC outlet has a communication function, a communication signal can be transmitted through the DC power supply line Wdc. A communication function is provided not only in the DC device 102 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 includes a service that enables monitoring and control of equipment (including mainly the DC equipment 102 but also other equipment having a communication function) connected to the home network through the wide area network NT. is there. 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 constituting the DC power supply unit 101 to the DC devices 102. 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 102 is selected from a plurality of types of voltages depending on the device, the cooperative control unit 113 is provided with a DC / DC converter to convert the DC voltage obtained from the main power source and the distributed power source into the necessary voltage. Is desirable. Normally, one type of voltage is supplied to one subsystem (or DC device 102 connected to one DC breaker 114), but three or more wires are used for one subsystem. A plurality of types of voltages may be supplied. Alternatively, it is also possible to adopt a configuration in which the DC power supply line Wdc is 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 include a main power source, a distributed power source, and a DC device 102. It is possible to perform cooperative operations that deal with the load status. 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 102.

  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 DC supply unit can be provided for each floor or room of the house H, the DC supply unit can be managed for each system, and the direct current to the DC device 102 using DC power can be managed. Since the distance of the feed line Wdc is reduced, power loss due to a voltage drop in the DC feed 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.

1 is a schematic block diagram of a DC outlet according to a first embodiment. The same as above, (a) is a front view, (b) is a bottom view, and (c) is a left side view. It is an exploded perspective view same as the above. (A) (b) is a front view which shows the other structure of a plug connection part same as the above. It is a schematic block diagram which shows the other structure same as the above. It is a schematic block diagram which shows another structure same as the above. 6 is a schematic block diagram of a DC outlet according to Embodiment 2. FIG. It is explanatory drawing explaining operation | movement same as the above. 6 is a schematic block diagram of a DC outlet according to Embodiment 3. FIG. (A) (b) is explanatory drawing explaining operation | movement same as the above. FIG. 6 is a schematic block diagram of a DC outlet according to a fourth embodiment. 1 is a system configuration diagram of a DC power distribution system using a DC outlet according to each embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 DC outlet 2 Input terminal part 3 Plug connection part 4 Input voltage detection circuit 5 Equipment voltage detection circuit (voltage information acquisition part)
6 Display Circuit 102 DC Device 102a Plug Wdc DC Power Feed Line

Claims (6)

  A plug of a DC device that operates in response to the supply of DC power is detachably connected, a plug connection unit that supplies DC power to the DC device via the plug, and a DC device connected to the plug connection unit, A DC outlet comprising: a voltage information acquisition unit that acquires adaptive voltage value information indicating a compatible voltage of a DC device.   2. The direct current according to claim 1, wherein the voltage information acquisition unit includes signal receiving means for receiving adaptive voltage value information transmitted by being superimposed on a DC voltage from a DC device connected to the plug connection unit. Outlet.   The voltage information acquisition unit includes a signal reading unit that is provided in the plug and reads the adaptive voltage value information in a non-contact manner from a storage medium that stores the adaptive voltage value information in a non-contact-readable state from the outside. The DC outlet according to claim 1.   A voltage detection unit that detects a DC voltage value of DC power supplied from the plug connection unit to the DC device, and whether or not the DC voltage value detected by the voltage detection unit is different from the adaptation voltage indicated by the adaptation voltage value information. A DC outlet according to any one of claims 1 to 3, further comprising a display unit that displays   A voltage conversion unit that converts a voltage value of DC power supplied from the outside and supplies the plug connection unit, and an output voltage of the voltage conversion unit based on the adaptive voltage value information becomes the adaptive voltage value The DC outlet according to any one of claims 1 to 3, further comprising a voltage control unit that controls an output of the voltage conversion unit.   In a state where the voltage control unit outputs a minimum operating voltage lower than the compatible voltage from the voltage conversion unit when the plug of the DC device is connected, the voltage information acquisition unit acquires the appropriate voltage value information. 6. The DC outlet according to claim 5, wherein the voltage control unit changes the output voltage of the voltage conversion unit from the minimum operating voltage to the adaptive voltage based on the adaptive voltage value information.

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