JP4853436B2 - Feed rail device and communication system - Google Patents

Description

  The present invention relates to a technique for constructing a communication system using a power supply rail.

  When a plurality of communication terminals used in an organization such as a company or a school communicate with each other, it is common to use a network constructed by a LAN (Local Area Network). Communication terminals connected by a LAN communicate with each other without going through a public line, so that there is an advantage that the network state is stable and data can be exchanged at high speed. -

In communication within the same organization, there is often an opportunity to exchange highly confidential information, and ensuring security is also an important issue. Therefore, Patent Document 1 discloses a network system for an apartment house that can easily identify a user of a device connected to a LAN and prevent impersonation of another person in order to improve security.
JP 2001-186141 A

However, with the technique described in Patent Document 1, the server apparatus increases the amount of processing to be performed for authentication, such as performing processing for specifying a person who uses the network, in order to ensure security. Further, if a wired LAN is constructed, if a large number of communication terminals are installed, wiring such as a power cord and a LAN cable becomes complicated, and the aesthetics are impaired. In addition, when changing the installation location of the communication terminal, it is necessary to re-wire the complicated wiring, so that there is a problem that considerable time and effort are required before starting communication.
The present invention has been made in view of such circumstances, and an object thereof is to provide a technique capable of easily managing a network while ensuring security.

  In order to achieve the above-mentioned object, the present invention is connected to a rail body provided with identification information, a power supply conductor provided in the rail body along an extension direction, and a power line connected to the power supply conductor. In a power supply rail device having a power terminal and supplying power to a device connected to the power terminal, reading means for reading identification information provided in the rail main body, and the power line by the device connected to the power terminal And a signal extracting means for extracting a signal output by superimposing on the feeding current, and an addition for generating and adding read information corresponding to the identification information read by the reading means to the signal extracted by the signal extracting means And an output means for superimposing a signal, to which the read information is added by the adding means, on a feeding current and outputting it to the feeding conductor. To provide a device.

  The power supply rail device includes a filter unit that blocks a signal output to the power line by the device so that the signal does not flow to the power supply conductor.

  Further, in the power supply rail device, when the detection unit detects that the device is connected to the power terminal, and the detection unit detects that the device is connected, the identification information is displayed on the reading unit. Reading instruction means for instructing reading, and the reading means may read the identification information in response to an instruction from the reading instruction means.

  Further, in this power supply rail device, an instruction is given to add the read information to a signal received after a predetermined time has elapsed since the signal was extracted by the signal extraction means, and the signal received before the predetermined time has elapsed. May include addition instruction means for instructing not to add the read information, and the addition means may add the read information to the signal in accordance with an instruction from the addition instruction means.

  The identification information may include position information indicating a position of the rail body in the extension direction.

  Further, the present invention has a rail body provided with identification information, a power supply conductor provided in the rail body along an extension direction, and a power terminal connected to the power supply conductor via a power line, In a communication system comprising a power supply rail device that supplies power to a device connected to a power terminal, and a server device connected via the power supply conductor of the power supply rail device, the power supply rail device includes the rail body. A reading means for reading the identification information provided in the apparatus, a signal extracting means for extracting a signal output by superimposing a power supply current on the power line by a device connected to the power terminal, and a signal extracting means An adding means for generating and adding read information corresponding to the identification information read by the reading means to the signal, and a signal with the read information added by the adding means. Is output to the power supply conductor by superimposing the power on the power supply current, and the server device receives the signal output to the power supply conductor by the output means, and the reception means There is provided a communication system comprising control means for determining whether or not to permit communication with a device connected to the power terminal based on the read information added to a received signal.

  In this communication system, the identification information includes position information indicating the position of the rail body in the extension direction, and is based on a feeding current flowing through the power line interposed between the feeding conductor and the power terminal. Power information generating means for generating power consumption information, wherein the output means outputs the power consumption information in association with the position information, and the control means is associated with the power consumption information and the power consumption information. Information related to power consumption by the device may be output according to the position information.

  According to the present invention, it is possible to easily manage a network while ensuring security.

The configuration of the embodiment of the present invention will be described below with reference to the drawings.
(A) Configuration of Embodiment First, a communication system according to the present invention will be described with reference to FIG.
The communication system includes a server device 10, a plurality of client devices 20, 20..., A plurality of PLC dedicated adapters 1, 1. This communication system is a LAN, and uses Ethernet (registered trademark) as a LAN standard. Therefore, in communication, packet data composed of a header portion and a payload portion is exchanged based on various protocols such as TCP (Transmission Control Protocol) / IP (Internet Protocol) and UDP (User Datagram Protocol) / IP. .

  The server device 10 has a computer device (consisting of a CPU, a memory, an interface, etc.) for managing the communication system. The client devices 20, 20... Communicate with the server device 10 via the power line 2, communicate with each other between the client devices 20 under the management of the server device 10, or a network such as the Internet via the communication cable 3. 4 communicates with a communication terminal connected to 4. The PLC dedicated adapters 1, 1,... Are connected to the server device 10 and the client device 20 via USB (Universal Serial Bus) cables. Each PLC-dedicated adapter 1 is connected to a power line 2 and exchanges data between the PLC-dedicated adapters 1 using a PLC (Power Line Communications) method. Specifically, the PLC dedicated adapter 1 superimposes a signal on the feeding current flowing through the power line 2 or extracts a signal from the feeding current.

Next, an example of an installation mode of the communication system in the company 100 will be described with reference to FIG.
2, the company 100 is a three-story building, and the company 100 is provided with a management room 200 and a plurality of rooms 300, 300. The management room 200 is provided on the third floor of the company 100. In the management room 200, a server device 10 that manages a communication system in the company 100 is installed. A plurality of rooms 300 are provided on each of the first floor, the second floor, and the third floor of the company 100, and are rooms of departments such as a sales department and an accounting department. A plurality of client devices 20 are installed in the room 300.

  Moreover, the power supply rail apparatus 30 is installed in the ceiling of the management room 200 and the room 300, and each power supply rail apparatus 30 is connected via the power line. The power line 2 shown in FIG. 1 is provided in the power supply rail device 30, and the server device 10 and the client device 20 are connected to the power line 2 in the power supply rail device 30 via the PLC dedicated adapter 1. The server device 10 is connected to a connection terminal provided on the wall surface of the management room 200 via the communication cable 3. Communication via the network 4 is performed via this connection terminal.

Here, FIG. 3 is a block diagram showing a configuration of the server apparatus 10. As shown in FIG. 3, the server device 10 includes a control unit 11, a display unit 12, an operation unit 13, a storage unit 14, and a first communication interface (hereinafter referred to as “first communication IF unit”) 15. And a second communication interface (hereinafter referred to as “second communication IF unit”) 16.
The control unit 11 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory), and reads out and executes a computer program stored in the ROM or the storage unit 14 to thereby execute the bus. And control each part of the server device 10. The display unit 12 includes a liquid crystal panel and the like, and displays a menu screen and the like for operating the server device 10 under the control of the control unit 11. The operation unit 13 outputs an operation signal corresponding to an operation by a user (hereinafter referred to as “administrator”) managing the server device 10 to the control unit 11. The storage unit 14 is a storage unit for storing a computer executed by the control unit 11 and data used during the execution, and is, for example, a hard disk device. The first communication IF unit 15 and the second communication IF unit 16 are communication means including, for example, a modem. The control unit 11 communicates with the client device 20 by exchanging data via the first communication IF unit 15, while performing communication via the network 4 via the second communication IF unit 16.

The storage unit 14 stores an ID management table 141.
FIG. 4 is a diagram illustrating an example of the ID management table 141. In the ID management table 141, the “rail name” that is the name of the power supply rail device 30, the number of floors in which the power supply rail device 30 is installed and the “room name” that is the name of the room, and the power supply rail device 30 are identified. “Rail ID”, which is identification information for this purpose, is written in association with each other. Focusing on the first row in FIG. 4, “RA1” is written in the rail name field, “1st floor, sales department” is written in the room name field, and “ID10001” is written in the rail ID field. That is, the power supply rail device 30 named “RA1” is installed in the room 300 of the sales department on the first floor of the company 100, and the rail ID “ID10001” is assigned. Further, referring to the second row, the power supply rail device 30 named “RA2” is installed in the room 300 of the sales department on the first floor, and the rail ID is “ID10002”. Referring to the third row, the power supply rail device 30 named “RA3” is installed in the room 300 of the accounting department on the second floor, and the rail ID is “ID20001”. The server device 10 manages each power supply rail device 30 based on the ID management table 141. When a new power supply rail device 30 is installed in the management room 200 or the room 300, the administrator can rewrite the contents of the ID management table 141 by operating the operation unit 13.

Next, FIG. 5 is a block diagram illustrating a configuration of the client device 20.
The client device 20 includes a control unit 21, a display unit 22, an operation unit 23, a storage unit 24, and a communication IF unit 25. The storage unit 24 stores a computer program PRG necessary for the client device 20 to communicate with the server device 10. The client device 20 is supplied with power via a power supply line 26, and a plug 27 is provided at the tip of the client device 20 for insertion into an outlet (see FIG. 6). The functions of the other units are the same as those of the server device 10, and detailed description thereof is omitted.

Next, FIG. 6 is a perspective view showing an overview of the power supply rail device 30 and the client device 20.
As shown in FIG. 6, the power supply rail device 30 includes a rail main body 40 and a power supply conductor 42 (see FIG. 7) provided in the rail main body 40 along the extension direction of the rail. In addition, the rail body 40 is provided with a moving body 50 serving as a support device and a tap device 60. As shown in the figure, the three orthogonal axes are the X, Y, and Z axes, respectively. The tap device 60 is fixed to the moving body 50 by adhesion or a predetermined fixing tool. A power terminal 61 is provided inside the tap device 60. When the plug 27 of the client device 20 is inserted into the plug insertion hole provided on the lower surface, the power supply rail device 30 and the client device 20 are connected to each other. Electrically connected. The moving body 50 is configured to be movable in the direction of arrow a in the figure (axis line parallel to the x-axis direction), so that the electrical connection with the power supply conductor 42 is maintained regardless of the position of movement. It has become. In addition, when moving the moving body 50, the operator holds the tap device 60 to move it.
The electrical connection between the server device 10 and the power supply rail device 30 is the same as described above.

FIG. 7 is a diagram for explaining the configuration of the rail body 40 and the moving body 50 in more detail.
As shown in FIG. 7, the rail body 40 has an outer shape that is formed in a substantially “U” cross section that opens downward and extends in the X-axis direction. A folded portion is formed in the opening so as to extend in the extending direction, and a recessed portion 41 into which a convex portion 51 described later is inserted is formed in the extending direction in each folded portion. On the side surface of the rail body 40, feed conductors 42 and 42 are provided in the extending direction of the rail body 40. The power supply conductor 42 functions as the power line 2 in the power supply rail device 30. In the present embodiment, the surfaces of the power supply conductors 42 and 42 have a shape in which an arc shape having a sufficiently short radius of curvature with respect to the rail body 40 is continuous in the extending direction. The power supply conductor 42 is connected to a commercial power source (none of which is shown).

  On the lower surface of the moving body 50, convex portions 51, 51 to be inserted into the concave portion 41 of the rail body 40 are formed. On the side surface of the moving body 50, a power receiving terminal 52 that is in electrical contact with each power supply conductor 42 of the rail body 40 is provided. The power receiving terminal 52 is provided on the side surface 50 </ b> A of the moving body 50 and the opposite side surface. The power receiving terminal 52 includes a terminal portion (not shown) provided in insertion holes provided on these side surfaces, and a spring (not shown) that urges the terminal portion to the outside. When the terminal portion of the power receiving terminal 52 is pushed out by the elastic force of the spring and is inserted into a portion of each of the arcuate shapes of the power supply conductor 42, the moving body 50 is positioned at an appropriate pitch. ing.

  Further, the power supply rail device 30 has a reading unit 53. The reading unit 53 generates read information corresponding to a mark having identification information provided on the rail body 40, and outputs the read information as a rail ID.

Here, the reading unit 53 will be specifically described.
The reading unit 53 includes a light emitting / receiving unit 531 provided on the moving body 50 side illustrated in FIG. 7 and a bar code 532 provided on the rail body 40 side illustrated in FIG. As shown in FIG. 8 and FIG. 8, a plurality of bar codes 532 are provided on the inner surface of the rail body 40 at predetermined intervals. These bar codes 532 indicate the same identification information. In this case, the bar code 532 is provided on the lower side of the power supply conductor 42 and at a position where the movable body 50 is positioned so that the light emitting / receiving unit 531 can accurately read the code information.
In the present embodiment, a bar code that displays different identification information for each rail body 40 is provided. Therefore, it is possible to know from which rail body 40 the information is from the rail ID (reading information) generated by the reading unit 53.

  Next, an example of the configuration of the tap device 60 will be described with reference to FIG. FIG. 9 is a block diagram illustrating an example of the configuration of the tap device 60. In FIG. 9, the arrows indicate the flow of data, and the double lines indicate the power lines 5, 6, and 7 that supply commercial power. The power line 5 is electrically connected to the power receiving terminal 52 shown in FIG.

The power terminal 61 shown in FIG. 9 is connected to the filter unit 62 and the PLC dedicated adapter 63 via the power lines 6 and 7. The filter unit 62 is connected to the power supply conductor 42 and the PLC dedicated adapter 64 via the power line 5. The filter unit 62 is an LPF (Low Pass Filter), blocks a frequency band equal to or higher than a set cutoff frequency, and passes a signal in a frequency band equal to or lower than the cutoff frequency. In a signal exchanged by the PLC system, a frequency band of about 4 MHz to 28 MHz is used. On the other hand, the frequency band of commercial power is approximately 50 Hz to 60 Hz. That is, in the present embodiment, the signal corresponding to the packet data is blocked by the filter unit 62, but the supply current for commercial power passes through the filter unit 62. Therefore, when the plug 27 of the client device 20, which is an external device, is inserted into the power terminal 61, power is supplied via the power supply line 26. The filter unit 62 blocks the packet data supplied to the power terminal 61 from flowing into the power supply conductor 42 via the power lines 6 and 5 as they are.
In the present embodiment, the client device 20 and the PLC dedicated adapter 1 are connected via a USB cable, and the power supply line 26 and the plug 27 are used as a power cord for communication. Therefore, the power cord for receiving power of the client device 20 is separately connected to a tap device 60 or an outlet (not shown) provided on the wall surface in the company 100.

  The control unit 67 includes a CPU, a ROM, a RAM, and a memory serving as a storage unit, and controls each unit of the tap device 60 by reading and executing a computer program stored in the ROM. The PLC dedicated adapters 63 and 64 have the same functions as the PLC dedicated adapter 1 described above. The first communication IF unit 65 and the second communication IF unit 66 are interface devices for performing communication. The control unit 67 exchanges data via the first communication IF unit 65 and the second communication IF unit 66. The ID storage unit 68 is a storage unit that stores the rail ID generated by the reading unit 53. The control unit 67 causes the reading unit 53 to generate a rail ID at a predetermined timing. When the control unit 67 acquires the rail ID, the control unit 67 stores the rail ID in the ID storage unit 68. The data buffer 69 is a storage unit that temporarily stores packet data.

(B) Operation of Embodiment Next, an example of the operation of the embodiment will be described. It is assumed that the plug of the power cord for supplying power to the server device 10 is inserted into the insertion hole of the tap device 60 in the room 300, and the server device 10 has already been started up.

Here, the procedure of processing in which the client device 20 transmits packet data to the server device 10 will be described with reference to the sequence diagram shown in FIG. In the following description, a case where the client device 20 attempts to start communication with the server device 10 will be described.
First, the user inserts the plug 27 into the insertion hole of the tap device 60 in order to activate the client device 20. When the power switch of the client device 20 is turned on by the user, the client device 20 is activated. Then, when the user instructs communication with the server device 10 by operating the operation unit 23, the control unit 21 starts processing for communicating with the server device 10 accordingly.

  First, the control unit 21 reads the program PRG from the storage unit 24. Then, the control unit 21 executes the program PRG, adds the IP address of the server device 10 to the header part, and transmits packet data including a communication request. The packet data transmitted by the control unit 21 is superimposed on the feeding current and supplied to the tap device 60 via the communication IF unit 25.

When the packet data is supplied to the power terminal 61 of the tap device 60, the control unit 67 receives the packet data extracted by the PLC dedicated adapter 63 via the first communication IF unit 65. Although this packet data flows through the power lines 6 and 7, the packet data is blocked by the filter unit 62 and therefore does not flow through the power line 5. The control unit 67 stores the received packet data in the data buffer 69 (step SB1). Subsequently, the control unit 67 determines whether or not the rail ID is stored in the ID storage unit 68 (step SB2). When determining that the rail ID is not stored in the ID storage unit 68 (step SB2; NO), the control unit 67 instructs the reading unit 53 to generate a rail ID (step SB3). When the rail ID is generated by the reading unit 53, the control unit 67 acquires it, stores it in the ID storage unit 68 (step SB4), and proceeds to step SB5. On the other hand, if the rail ID is stored in the ID storage unit 68, the determination in step SB2 is “YES”, and the process immediately proceeds to step SB5.
In step SB5, the control unit 67 reads the rail ID stored in the ID storage unit 68 and adds it to the header of the packet data.

  Subsequently, the control unit 67 transmits the packet data to the communication terminal (server apparatus 10 in this operation example) corresponding to the IP address added to the header part. At this time, the control unit 67 transmits packet data via the second communication IF unit 66. In this case, the packet data is superimposed on the feeding current flowing through the power line 5 by the PLC dedicated adapter 64. The packet data flowing through the power line 5 is blocked by the filter unit 62 and therefore does not flow to the power terminal 61 side (power lines 6 and 7). This packet data is output to the power supply conductor 42 of the power supply rail device 30 and supplied to the server device 10. At this time, the packet data passes through the tap device 60 to which the server device 10 is connected. Since the packet data is received via the second communication IF unit 66 of the tap device 60, in this case, the control unit 67 transmits the first data through the first communication IF unit 65 without adding a rail ID.

  Then, the control unit 11 of the server device 10 receives the packet data extracted from the feeding current by the PLC dedicated adapter 1 via the first communication IF unit 15. In response to this, the control unit 11 reads the ID management table 141 from the storage unit 14 (step SC1). Subsequently, the control unit 11 collates the contents described in the “rail ID” field of the ID management table 141 shown in FIG. 4 with the rail ID added to the header part of the packet data (step SC2). Then, the power supply rail device 30 is specified based on the rail IDs with which they match (step SC3). For example, when the rail ID “ID10001” is added to the header portion of the packet data, the control unit 11 uses the name “RA1” installed in the room 300 of the sales department on the first floor based on the ID management table 141. It is determined that the packet data is transmitted via the power supply rail device 30. At the same time, the control unit 11 specifies that the power supply rail device 30 is installed in the room 300 of the sales department on the first floor. And the control part 11 permits communication with the client apparatus 20 based on the rail ID added to this packet data collating in step SC2 (step SC4).

At this time, the reason why the control unit 11 permits the communication is that the process of checking the rail ID can be regarded as a process corresponding to the authentication of the client device 20. Explaining the reason, the server device 10 can identify the room in which the server device 10 is installed based on the rail ID if the received packet data is via the power supply rail device 30. . Therefore, it becomes clear that the client device 20 that has requested communication is connected to the power supply rail device 30, and can be regarded as a legitimate access rather than an access from outside the company 100.
When authentication is performed by the server device 10 as described above, the fact that the authentication has been performed (packet data) is transmitted to the client device 20. Note that the transmission path is in the reverse order of the access path from the client apparatus 20 to the server apparatus 10, and the description thereof is omitted.

  As described above, when the communication link between the client device 20 and the server device 10 is established, the client device 20 sequentially transmits packet data to be transmitted to the server device 10. The transmission procedure at this time is the same as steps SB1 to SB5 in FIG. 10 described above. However, since the rail ID is already stored in the ID storage unit 68, the processes of steps SB1, SB2, and SB5 are performed. With this process, the rail ID is added by the control unit 67 to the header part of all packet data output by the client device 20. When the rail ID is added to all the packets in this way, the server device 10 can check the validity of all the packet data.

  In addition, when the control unit 67 of the tap device 60 does not receive another packet data within a predetermined time after receiving the packet data, the control unit 67 clears the rail ID stored in the ID storage unit 68. The case where the control unit 67 does not receive the packet data within a predetermined time is, for example, a case where the communication link via the tap device 60 is canceled. Therefore, the rail ID can be generated at the timing of establishing the communication link by clearing the rail ID when the predetermined time elapses. In this way, when the packet data is output from the client device 20 after the rail ID is cleared, the determination in step SB2 by the control unit 67 is “NO”, and the rail ID is read and stored. (Steps SB3, 4).

  Here, details of packet data transmitted and received in the above-described communication will be described. FIG. 11 is a diagram showing a data structure and a time chart of packet data. FIG. 5A shows a time chart showing how packet data is received by the tap device 60. FIG. 6B is a diagram showing a time chart (FIG. 5B) showing how packet data is transmitted by the tap device 60. FIG.

  For example, reception of packet data having a data structure as shown in FIG. 5A is started by the control unit 67 at time t = t0, and is completed at time t = t2. Then, the rail ID is added by the control unit 67, and the packet data having the data structure shown in FIG. Therefore, the time when transmission of packet data is started is t1 (where t1> t0) as shown in FIG. That is, it takes a time corresponding to t1 to t0 until the control unit 67 receives the packet data and transmits it. Therefore, when receiving the packet data from the client device 20, the control unit 67 stores these in the data buffer 69. And the control part 67 reads packet data in an order from what was previously stored in the data buffer 69, and performs the said process.

Next, a processing procedure when the server apparatus 10 transmits packet data to the client apparatus 20 will be described.
First, the control unit 11 of the server device 10 adds the IP address of the client device 20 to the header portion of the packet data and transmits the packet data via the first communication IF unit 15. When receiving the packet data via the second communication IF unit 66, the control unit 67 of the tap device 60 executes a process for adding a rail ID (same as steps SB1 to SB5 in FIG. 10). Subsequently, the control unit 67 transmits the packet data to the communication terminal (in this operation example, the client device 20) corresponding to the IP address described in the header part. When receiving the packet data via the communication IF unit 25, the control unit 21 of the client device 20 performs control according to the packet data.
According to such a procedure, the client device 20 sequentially transmits packet data to be transmitted to the server device 10.

  According to this operation, the rail ID is also added to the packet data received by the client device 20, but the client device 20 does not perform control using the rail ID. Therefore, the control unit 67 of the tap device 60 may not add the rail ID to the packet data output from the server device 10. In order for the control unit 67 to add the rail ID only when necessary, for example, the tap device 60 is provided with a switch for switching whether or not to add the rail ID. In this case, the switch of the tap device 60 to which the server device 10 is connected is turned off, and the control unit 67 does not add the rail ID accordingly. On the other hand, the switch of the tap device 60 to which the client device 20 is connected is turned on, and the control unit 67 adds a rail ID accordingly.

  As described above, in this communication system, communication can be started quickly without exchanging a large amount of packet data for authentication, and a complicated operation for authentication can be performed by the user of the client device 20. There is no force against it. Therefore, according to this embodiment, it is possible to quickly start communication while ensuring security.

(C) Modified Example The embodiment described above may be modified as follows. These modifications can be appropriately combined with each other.
(1) In the embodiment described above, the control unit 67 of the tap device 60 adds the rail ID to all received packet data. However, the rail ID may be added to only some packet data. Good. Here, FIG. 12 is a diagram showing a time chart showing how packet data is exchanged. As shown in FIG. 12, a plurality of packet data Pa1, Pa2,... Pa, n transmitted by the client device 20 has a short transmission time interval. Also, in the packet data Pb1, Pb2,... Pb, m of responses by the server device 10, the time interval between these transmissions is short. On the other hand, as shown in the figure, the transmission time interval T1 between Pa, n and Pb1 is considerably longer than the above time interval. This is because the server device 10 and the client device 20 have undergone a process of determining the content and generating packet data corresponding to the packet data in response to the received packet data before transmission. .

For this reason, when a plurality of packet data are transmitted at a relatively short time interval, it can be determined that the transmission sources of these packet data are the same (that is, the added rail ID is the same). Based on this, the control unit 67 of the tap device 60 adds the rail ID only to the packet data received after the time when the packet data is not received exceeds the predetermined time T2, and received before the predetermined time T2 elapses. The rail ID is not added to the packet data (step SB5 in FIG. 10 is omitted). In the example of FIG. 12, the packet data to which the rail ID is added are Pa1 and Pb1 indicated by hatching, and no rail ID is added to the other packet data. In this way, the server device 10 can determine the legitimacy of packet data to which no rail ID is added.
Further, the control unit 67 may generate packet data to which a rail ID is separately added instead of adding a rail ID to the header portion of the received packet data.

(2) In the above-described embodiment, when the control unit 67 determines that the rail ID is not stored in the ID storage unit 68, the control unit 67 instructs the reading unit 53 to generate the rail ID. The timing of this instruction is not limited to this. For example, it may be when the plug of the power cord is inserted into the insertion hole of the tap device 60. As a specific detection method, for example, a light amount detection means such as a phototransistor is provided near the insertion hole in the tap device 60 at a position where the plug does not contact, and when the plug is inserted, the light amount detection means The detected light quantity is blocked or reduced. Thereby, the control part 67 can judge that the plug was inserted by monitoring the light quantity from this light quantity detection means.

  Moreover, as shown to Fig.13 (a), the structure which uses the structure which provides insertion sensor PD in the vicinity of the insertion hole inside the tap apparatus 60 may be sufficient. The insertion sensor PD has a coil L that circulates around the plug P. When a plug is inserted into the insertion hole and a feeding current flows through the plug, an induced power due to this current is generated in the coil L. ing. When the insertion sensor PD detects that the power plug P is connected by the induced power of the coil L, the insertion sensor PD supplies the detection signal S to the control unit 67. When acquiring the detection signal S, the controller 67 determines that the plug has been inserted.

Moreover, FIG.13 (b) is the figure which looked at the power cord and the insertion hole vicinity of the tap apparatus 60 from the side surface. As shown in FIG. 5B, when the plug P is inserted into the insertion hole of the tap device 60, the power terminal 61 is configured to be in close contact so as to be electrically connected. ing. That is, the width between the portions (contact portions) 61a and 61a of the power terminal 61 in contact with the plug is narrower than the length of the plug. Therefore, when the plug P is inserted, the plug P and the contact parts 61a, 61a open in the direction of the arrow in the figure, and distortion occurs. Therefore, a strain gauge such as a strain gauge for detecting the strain is provided in the tap device 60, and the control unit 67 determines that the plug is inserted when the strain of the contact portion 61a measured by the strain gauge exceeds a threshold value. You may make it judge.
Also, the timing at which the control unit 67 instructs the generation of the rail ID does not have to be at the start of communication. For example, when a certain time elapses or when it is instructed by the server device 10 according to the operation of the administrator. But you can.

(3) In the above-described embodiment, when the plug of the power cord is inserted into the insertion hole of the tap device 60, the server device 10 permits the communication to the device that attempts communication through the plug. This is because it is clear that the tap device 60 is installed in the company, and the device that uses the tap device 60 is a device in the company 100, and security is guaranteed. Because.
In addition to this, user authentication processing using a password or the like may be performed. For example, an information processing apparatus such as a PC generally has a function of allowing a user to input authentication information such as a user ID and a password for user management, and permitting login to the apparatus if the authentication is successful. It is equipped. Therefore, using this, the server apparatus 10 manages the login password for each client apparatus 20. Then, at the start of communication, the server device 10 causes the client device 20 to transmit a login password, and when the authentication is successful, the server device 10 permits communication with the client device 20. Thus, higher security can be realized by adding authentication by the tap device 60 and authentication by a password or the like.

(4) In order to ensure a higher level of security, the insertion hole of the tap device 60 shown in FIG. 6 may be formed in a special shape so that the plug of the power cord cannot be directly inserted. For example, the insertion hole has an “S” shape as shown in FIG. And in order to connect with such a tap apparatus 60, the adapter 400 which an administrator manages is prepared. The administrator lends out the adapter 400 having the configuration shown in the perspective view of FIG. On the back surface of the adapter 400, an insertion hole having the same shape as that shown in FIG. 6 is provided as shown in FIG. A power terminal (not shown) provided in the insertion hole is electrically connected to the terminal portion 401. The user who has received the adapter 400 inserts the plug of the power cord into the insertion hole on the back surface of the adapter 400, and inserts the terminal portion 401 of the adapter 400 into the insertion hole of the tap device 60. Thereby, the tap device 60 and the client device 20 are electrically connected. In this way, since the administrator manages the user who lent out the adapter 400, the user who is physically allowed to communicate with the server device 10 can be managed, and security can be further secured.

(5) In the above-described embodiment, the communication IF unit 25 of the client device 20 and the PLC dedicated adapter 1 are connected via a USB cable. Therefore, it is necessary to separately connect a power cord to the tap device 60 or another outlet as a power receiving means for the client device 20 to operate, or to include an internal battery or a battery. In order to avoid these, the following configuration may be adopted.

  The power terminal 61 is supplied with a feeding current on which packet data is superimposed, and is supplied to the PLC dedicated adapter 1 via a power cord. Therefore, the client device 20 may receive power from the PLC dedicated adapter 1. For this purpose, an insertion hole is provided in the rear surface of the PLC adapter 1 or the like. When the plug of the power cord for receiving power of the client device 20 is inserted into the insertion hole, the client device 20 is electrically connected to a power terminal (not shown), and the client device 20 receives power.

  Further, if a single power cord for communication and power reception can be realized, there is an advantage that the number of necessary power cords can be further reduced. Therefore, the PLC dedicated adapter 1 may be built in the client device 20. In this way, in the client device 20, the power supply current is supplied to the PLC dedicated adapter 1 via the power cord, while the power supply current can be used for power reception.

(6) In the above-described embodiment, since the rail ID is used as identification information for identifying the rail body 40, the plurality of barcodes 532 provided on the rail body 40 all have the same identification information. If the identification information of each bar code provided on the rail body 40 is different, the bar code reading information can include the rail ID and position information indicating the position of the rail body 40 in the extending direction. Therefore, the server device 10 can also identify the position of the tap device 60 according to the identification information. If this is utilized, the present invention can be applied as follows.

For example, when the client device 20 uses one tap device 60 for communication and power reception as in the modification (5), the server device 10 can manage the power consumption for each client device 20.
In a company or the like, one client device 20 is assigned to each employee and is installed at each employee's desk. In this case, each client device 20 is kept connected to the same tap device 60, and the tap device 60 is not moved. In this case, specifying the position of the tap device 60 can be regarded as equivalent to specifying the client device 20 that uses the tap device 60.

  The tap device 60 has an ammeter 500 at the position of the broken line 500 shown in FIG. 9 in order to measure the current value of the feeding current. The ammeter 500 is inserted between the power supply conductor 42 and the filter unit 62 (and the PLC dedicated adapter 64), and measures the current value of the power supply current flowing into the power line 5. The ammeter 500 periodically measures a current value, and the control unit 67 sequentially stores the current value in a memory. When the administrator instructs the tap device 60 to display power consumption via the server device 10, the control unit 11 requests each tap device 60 to transmit a current value, and the control unit of the tap device 60. 67 transmits the barcode reading information and the current value in association with each other. At this time, the current value transmitted by the control unit 67 is an average current value of the feeding current in a predetermined period. In order to grasp the power consumption amount within a predetermined period, the control unit 67 of the tap device 60 clears the current value stored in the memory in response to an instruction from the server device 10.

  The control unit 11 of the server device 10 calculates the power consumption of each tap device 60 based on the received current value and the voltage value of the use voltage. And the control part 11 writes this in the power management table 142 as shown in FIG. In FIG. 15, “power amount (W · h; watt hour)” indicating the power consumption amount in a predetermined period is written. Then, the control unit 11 causes the display unit 12 to display a list of power consumption amounts for each tap device 60 based on the power management table 142.

  FIG. 15 is a diagram illustrating an example of the power management table 142. In the power management table 142, the “rail name” that is the name of the power supply rail device 30, the number of floors where the power supply rail device 30 is installed and the “room name” that is the name of the room, and the power supply rail device 30 are identified. “Rail ID”, which is identification information to be used, is associated with “Position ID” corresponding to position information corresponding to each barcode provided on the rail body 40, and “Electric energy (W · h)” Has been written. Looking at the first line in FIG. 16, the rail name field is “RA1”, the room name field is “1st floor, sales department”, the rail ID field is “ID10001”, and the position ID field is In the fields of “# 001” and “Power amount (W · h)”, “2800” is written. This is because the power supply rail device 30 named “RA1” is installed in the room 300 of the sales department on the first floor of the company 100, is assigned the rail ID “ID10001”, and is located at the position of the position ID “# 001”. It shows that “2800 Watt hours” has been consumed via the tap device 60. With reference to the power management table 142, the control unit 11 can grasp the power consumption for each tap device 60. Further, if the client device 20 connected to each tap device 60 can be specified based on the position ID, the server device 10 can easily grasp the power consumption for each client device 20.

Further, the server device 10 may instruct the ammeter 500 of each tap device 60 to measure the current value of the feeding current, and cause the current value (instantaneous current value) measured according to this to be transmitted. Good. If it does in this way, according to this electric current value, the server apparatus 10 can judge in real time whether each client apparatus 20 connected to the tap apparatus 60 is starting. Further, if the client device 20 in which the server device 10 is activated is specified, it is possible to easily grasp overtime employees.
The current value transmitted by the control unit 67 may be a current value representing the maximum current (peak current) in a predetermined period.

  Further, the tap device 60 may manage time information in order to manage power consumption within a predetermined period. In this case, the tap device 60 has a built-in timer, and the control unit 67 may store the current value in association with the time information (or time information).

A wattmeter may be used instead of the ammeter 500. In this case, the control unit 67 of the tap device 60 may transmit the power value of the instantaneous power or the power value of the highest power consumption (peak power) according to the measured value of the power meter. Good. Moreover, the control part 67 may transmit the power consumption in a predetermined period using an integrating wattmeter.
As described above, the control unit 67 generates information (power consumption information) regarding the power consumption determined based on the current of the feeding current flowing through the power line 5 and transmits the information to the server device 10. Then, the server device 10 causes the display unit 12 to display information (such as a list or a graph) on the power consumption by the client device 20 based on the power consumption information and the read information associated with the power consumption information. Or store it in the unit 14.

  Also, this read information can be used when establishing a communication link, for example. In this case, the server device 10 identifies the position of the tap device 60 that transmitted the packet data based on the read information, and identifies the user of the client device 20 according to this. Then, the server device 10 immediately establishes a communication link when it detects read information that specifies that a director such as the president of the company 100 is a user, and performs authentication information such as a password when other read information is detected. It can also be used to establish a communication link. As described above, the server device 10 can easily identify which information is transmitted from where based on the read information.

(7) In the above-described embodiment, the server device 10 specifies the power supply rail device 30 that supplied the packet data based on the rail ID that the tap device 60 adds to the packet data. In order to realize a function equivalent to this, a relay device 600 such as a router may be connected to each power supply rail device, and the relay device 600 may perform processing related to addition of a rail ID.
This method will be specifically described below.

  FIG. 16 is a view of a room 300 as viewed from above, and shows an example of an installation mode of the power supply rail device 30 and the relay device 600 in the room 300. In this figure, three power supply rail devices 30a are installed in the room 300, and each power supply rail device 30a is connected via power lines 8a and 8b. Further, the relay device 600 is connected to the power supply conductor of the power supply rail device 30a via the power line 8c. The relay device 600 is connected to a power supply conductor of another power supply rail device via the power line 9. A bar code or the like for displaying identification information is not provided on the rail main body of these power supply rail devices 30a. Further, the tap device 60a may have a function of supplying a feeding current to the power terminal, and the configuration provided in the above-described embodiment may be omitted.

FIG. 17 is a block diagram showing a configuration of relay apparatus 600.
The control unit 601 includes a CPU, a ROM, and a RAM, and controls each unit of the relay apparatus 600 via the bus by reading and executing a computer program stored in the ROM. The storage unit 602 is a storage unit for storing data used during execution of processing, and is, for example, a hard disk device. The first communication IF unit 603 and the second communication IF unit 604 are communication means including, for example, a modem. The PLC dedicated adapters 605 and 606 have the same functions as the PLC dedicated adapter 1 described above. The first communication IF unit 603 and the second communication IF unit 604 are interface devices for performing communication. The control unit 601 exchanges data via the first communication IF unit 603 or the second communication IF unit 604. Specifically, the control unit 601 transmits packet data to the power supply conductor of the power supply rail device 30a via the first communication IF unit 603, or receives packet data there. On the other hand, the control unit 601 exchanges data with the server device 10 via the second communication IF unit 604. The data buffer 607 has the same function as the data buffer 69 of the embodiment.
The storage unit 602 of the relay device 600 stores a rail ID assigned to each relay device 600 at the time of installation. In this rail ID, the rail ID can be updated according to the control by the server device 10.

Here, the procedure of processing executed by the control unit 601 of the relay apparatus 600 will be described with reference to the flowchart shown in FIG. In the following operation example, a case where the control unit 601 receives packet data via the first communication IF unit 603 will be described.
First, when receiving the packet data via the first communication IF unit 603, the control unit 601 stores the packet data in the data buffer 607 (step SD1). Packet data received by the control unit 601 via the first communication IF unit 603 is transmitted by the client device 20. Subsequently, the control unit 601 reads packet data in order from the data stored in the data buffer 607 previously. The control unit 601 reads the rail ID from the storage unit 602 and adds it to the header portion of the received packet data (step SD2). Then, the control unit 601 transmits the packet data to the transmission destination (that is, the server device 10) corresponding to the IP address indicating the transmission destination added to the header section via the second communication IF unit 604 (Step SD3). ). Also in this configuration, the server device 10 can identify the room 300 that supplied the packet data based on the rail ID, and therefore, for the same reason as in the embodiment, the verification of the rail ID can be regarded as authentication.

On the other hand, when the control unit 601 receives packet data from the server device 10 via the second communication IF unit 604, the control unit 601 sends a device (client device 20) corresponding to the IP address indicating the transmission destination added to the header to the device (client device 20). Packet data is transmitted to the power supply rail device 30a via the first communication IF unit 603.
The above is description of the operation | movement which the relay apparatus 600 performs.

  As described above, even if the relay device 600 has a function for adding a rail ID, the server device 10 can check the rail ID. In addition, since each tap device 60a of the power supply rail device 30a only needs to have a function as a power supply means, it is possible to expect an effect of cost reduction for installation of the communication system.

Moreover, you may make it the installation aspect of the electric power feeding rail apparatus 30 and the relay apparatus 600 as follows. As shown in FIG. 19A, relay devices 600, 600, and 600 may be provided for the power supply rail devices 30a, 30a, and 30a, respectively. In this case, each relay device 600 is connected to the power supply conductor of each power supply rail device 30a via power lines 8a, 8b, and 8c. As shown in FIG. 19B, only one relay device 600 may be installed in the room 300 and connected to the three power supply rail devices 30a through the power lines 8a, 8b, and 8c. In this case, the first communication IF unit 603 needs a number of ports corresponding to the number of connections. According to this configuration, since the relay device 600 can assign a rail ID to each power supply rail device 30a, the server device 10 can also identify the power supply rail device 30a that supplied the packet data.
Further, the PLC dedicated adapters 605 and 606 may be provided as external devices of the relay device 600.

(8) In the embodiment described above, the reading unit 53 is configured by the light emitting / receiving unit 531 and the barcode 532, but the configuration of the means for acquiring the rail ID is not limited thereto. For example, the reading unit may be configured using a magnetic sensor. In this case, a semiconductor Hall element, a semiconductor magnetoresistive element, or the like is used as the detection unit, and the detection target unit is a magnetized part applied to the part of the magnetic material. The magnetized part to be detected is magnetized at predetermined intervals, and the magnetic field at the magnetized part is made different for each feeding rail device 30. Thereby, identification information can be detected based on the detection signal from a detection part. In addition, any means may be used as long as it reads (detects) information corresponding to read information provided on the rail body 40, such as an optical sensor.

It is a figure explaining the structure of the communication system which concerns on embodiment of this invention. It is a figure explaining an example of the installation aspect of the communication system in a company. It is a block diagram which shows the structure of a server apparatus. It is the figure which showed an example of ID management table. It is a block diagram which shows the structure of a client apparatus. It is a perspective view which shows the external appearance of a feed rail apparatus and a client apparatus. It is a figure explaining the structure of a rail main body and a moving body in detail. It is the figure which represented typically the barcode provided in the rail main body side. It is a block diagram which shows an example of a structure of a tap apparatus. It is a sequence diagram which shows the procedure of operation | movement of a communication system. It is a figure showing the data structure and time chart of packet data. It is the figure which showed the time chart which shows the mode of exchange of packet data. It is the figure which showed an example of the detection means which detects plug insertion. It is a figure explaining the structure of the tap apparatus which has the insertion hole of a special shape, and an adapter. It is the figure which showed an example of the power management table. It is the figure which showed an example of the installation aspect of the electric power feeding rail apparatus and relay apparatus in a room. It is a block diagram which shows the structure of a relay apparatus. It is a flowchart which shows the procedure of operation | movement of a relay apparatus. It is the figure which showed an example of the installation aspect of the electric power feeding rail apparatus and relay apparatus in a room.

Explanation of symbols

1, 63, 64, 605, 606 ... PLC dedicated adapter, 10 ... Server device, 100 ... Company, 11, 21, 67, 601 ... Control unit, 12, 22 ... Operation unit, 13, 23 ... Display unit, 14, 24, 602, storage unit, 141, ID management table, 142, power management table, 15, 65, 603, first communication IF unit, 16, 66, 604, second communication IF unit, 2, 5, 6, 7 8, 8a, 8b, 8c, 9 ... power line, 20 ... client device, 200 ... management room, 21 ... control unit, 25 ... communication IF unit, 26 ... feeder line, 27 ... plug, 3 ... communication cable, 30, 30 ... Power feeding rail device, 300 ... Room, 4 ... Network, 40 ... Rail body, 400 ... Adapter, 401 ... Terminal portion, 42 ... Feeding conductor, 50 ... Moving body, 500 ... Ammeter, 52 ... Power receiving terminal, 53 ... Reading unit 531 ... Light emitting / receiving unit, 532 ... Bar code, 60, 60a ... Tap device, 600 ... Relay device, 607, 69 ... Data buffer, 61 ... Power terminal, 62 ... Filter unit, 67 ... Control unit, 68 ... ID storage unit .

Claims (7)

A rail body provided with identification information; a power supply conductor provided along the extending direction of the rail body; and a power terminal connected to the power supply conductor via a power line, and connected to the power terminal. In the power supply rail device that supplies power to the device,
Reading means for reading the identification information provided in the rail body;
A signal extraction means for extracting a signal output by superimposing a power supply current on the power line by a device connected to the power terminal;
Adding means for generating and adding read information corresponding to the identification information read by the reading means to the signal extracted by the signal extracting means;
An output rail device comprising: output means for superimposing a signal, to which the read information is added by the adding means, on a feeding current and outputting the signal to the feeding conductor. The power supply rail device according to claim 1, further comprising: a filter unit that blocks a signal output to the power line by the device so as not to flow to the power supply conductor. Detecting means for detecting that a device is connected to the power terminal;
A reading instruction means for instructing the reading means to read the identification information when the detection means detects that the device is connected, and
The power supply rail device according to claim 1, wherein the reading unit reads the identification information in accordance with an instruction from the reading instruction unit. An instruction is given to add the read information to a signal received after a predetermined time elapses after the signal is extracted by the signal extraction means, and the read information is not added to the signal received before the predetermined time elapses. Additional instruction means for instructing
The power supply rail device according to claim 1, wherein the adding unit adds the read information to the signal in accordance with an instruction from the adding instruction unit.   The feed rail device according to claim 1, wherein the identification information includes position information indicating a position of the rail body in the extension direction. A rail body provided with identification information; a power supply conductor provided along the extending direction of the rail body; and a power terminal connected to the power supply conductor via a power line, and connected to the power terminal. In a communication system comprising a power supply rail device for supplying power to a device and a server device connected via the power supply conductor of the power supply rail device,
The power supply rail device is
Reading means for reading the identification information provided in the rail body;
A signal extraction means for extracting a signal output by superimposing a power supply current on the power line by a device connected to the power terminal;
Adding means for generating and adding read information corresponding to the identification information read by the reading means to the signal extracted by the signal extracting means;
Output means for superimposing a signal to which the read information is added by the adding means on a feeding current and outputting it to the feeding conductor;
The server device
Receiving means for receiving a signal output to the power supply conductor by the output means;
Control means for determining whether or not to permit communication with the device connected to the power terminal based on the read information added to the signal received by the receiving means. The identification information has position information indicating a position of the rail body in the extension direction,
Power information generating means for generating power consumption information from a power supply current flowing through the power line interposed between the power supply conductor and the power terminal,
The output means outputs the power consumption information in association with the position information;
The communication system according to claim 6, wherein the control unit outputs information related to power consumption by the device according to the power consumption information and the position information associated with the power consumption information.

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