KR200351526Y1 - A power line communication based service addition type meter gateway and a casing structure thereof, a power line communication system using the same - Google Patents

Abstract

The present invention relates to a service-added meter gateway based on a power line communication network and a casing structure thereof, and a power line communication system using the same. The present invention provides an additional service in addition to a remote meter based on a power line communication network. Provides a service additional meter gateway that can perform the service data metering according to the additional service provided independently of the meter reading. In addition, in the present invention, the additional service metering is physically separated from the meter reading and the functional separation, and the power metering function and the service metering function are independently managed through a single service additional meter gateway. Therefore, the present invention can provide simple and convenient management and operation to utility managers and network operators, and can perform remote meter reading, additional service provision, and additional service metering stably, and perform data use authentication, data security, and data management. Can be performed stably. Furthermore, the present invention provides a variety of high quality services to subscribers at low cost as well as related equipment and service providing companies through the competition between the existing carrier-oriented network and service industry and the utility-oriented network and service. It can be expected to have the effect of widening the choice between telephone network and power grid.

Description

A power line communication-based meter gateway and its casing structure, and a power line communication system using the same

The present invention relates to a service-added meter gateway based on a power line communication network and a structure thereof, and a power line communication system using the same. The present invention provides an additional service in addition to a remote meter reading based on the power line communication network, and provides a meter reading and an additional service for a remote meter reading. The present invention relates to a service-added meter gateway and casing structure thereof, and a power line communication system using the same, to enable service metering according to functional independence and physical independence.

In general, power line communication (PLC) refers to a method of transmitting voice and data signals at high speed by superposing a high frequency signal on a low voltage distribution line or a high voltage distribution line installed indoors or outdoors. In particular, with the desire to intelligently control the customer's facilities, the demand for connecting information appliances such as TV (TeleVision), computers, camcorders, etc. installed in the consumer has increased along with the development of information devices. High-speed power line communication research is actively conducted in the field.

Recent advances in powerline communication modem technology enable high-speed transmission of several Mbbs, and another new capability to compete with asymmetric digital subscriber line (ADSL) over telephone lines or cable modems with coaxial cables. It is emerging as an access network. Therefore, when the development of such power line communication technology is commercialized, power providers can directly use the network for the advancement of power information such as automatic meter reading (AMR) and distribution automation, and provide high-speed information transmission services such as the Internet. You can expect rental revenue.

As described above, in the power line communication, as well as convenience of network connection as well as wireless communication, high-speed bidirectional communication is being attempted to add an additional service function in addition to the remote meter reading. Here, the additional service refers to service data and content data provided through a data communication network. However, the technology for adding an additional service function in addition to the remote meter reading in power line communication is still insufficient, and there are no alternatives related to metering, security, authentication, management, and operation according to the provision of the additional service.

Therefore, the present invention has been devised to solve the above problems, and can provide additional services in addition to the remote meter reading based on the power line communication network, and independently perform the metering of the power amount for the remote meter reading and the service metering according to the provision of the additional service. Its purpose is to provide a service-added meter gateway.

In addition, the present invention operates additional service functions independently based on power meter reading and two-way data communication so that the metering and power management functions are maintained as they are, while the additional service metering functions are physically independent as well as functional independent. Another purpose is to provide a service-added meter gateway that allows power metering and service metering functions to be managed independently from each other.

In addition, the present invention provides a power line communication system that efficiently charges the charge according to the remote meter reading and additional service metering by stably performing remote meter reading, additional service data and additional service meter reading using a service gateway meter gateway There is another purpose.

In addition, the present invention provides a power line communication system that provides a stable service for remote meter reading, supplementary service data provision and supplementary service metering data use authentication, data security, and data management using a meter-based gateway. There is a purpose.

1 is an overall configuration diagram of a service additional power line communication system according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating a subscriber network and a home network of the service supplementary powerline communication system shown in FIG. 1.

FIG. 3 is a detailed configuration diagram of the local information control apparatus shown in FIG. 1.

FIG. 4 is a detailed configuration diagram of the service additive meter gateway illustrated in FIG. 1.

5A through 5E are casing structure diagrams of the service-added meter gateway shown in FIG. 4.

6 is a block diagram of the indoor information control device shown in FIG.

FIG. 7 is an external view of the indoor information control device shown in FIG. 6.

8 is a block diagram of the terminal shown in FIG.

9 is a configuration diagram of the remote control.

FIG. 10 is an external view of the remote controller shown in FIG. 9.

11A and 11B are diagrams for explaining data encryption and decryption using a common encryption key.

12A and 12B are diagrams for explaining data encryption and decryption using a private encryption key.

<Explanation of symbols for the main parts of the drawings>

10: power company server 20: network operator server

30: service provider server 40: data communication network

50: local information control device 60: column transformer

70: transmission and distribution line 80: outdoor incoming line

90: indoor lead wire H1 to Hm: customer

M1 to Mm: Meter Gateway D1 to Dm: Home Information Control Device

T1 to Tn: terminal

510, 620, 710, 810: power line communication module

511, 6211, 711, 811: power line coupler

512, 542, 552, 6122, 6212, 6232, 712, 762, 772, 112: Receive filter unit

513, 543, 553, 6123, 6213, 6233, 713, 763, 773, 113: reception amplifier

514, 544, 554, 6124, 6214, 6234, 714, 764, 774, 114: power line communication unit

515, 545, 556, 6125, 6215, 6235, 715, 765, 775, 115: Transmission filter unit

516, 545, 555, 6126, 6216, 6236, 716, 766, 776, 116: transmission amplifier

520, 622, 720, 120: central processing unit

530, 624, 730, 130: data storage

540, 612, 623, 760, 110: wireless data communication module

541, 6121, 6231, 761, 111: wireless communication port section

544, 6124, 6234, 764, 114: wireless data communication unit

550, 770: wired data communication module

551, 771: wired communication port 554, 774: wired data communication

610: power metering unit 611: power metering module

6111: current / voltage detector 6112: power amount calculator

6113: power amount processing unit 6114: power amount display unit

620: service metering unit 625, 740, 140: data display unit

626: service / content data metering unit 627: operation switch

625a, 790, 840: LED display unit 610a: power metering casing

620a: service metering casing 6231a: receiving port

6231b: Transmission port 613: Input terminal

614: output terminal 615: DC power supply for power meter

629: DC power supply unit for the service metering unit 616: current transformer

630: support member 612a, 622a, 660: fastening member

651, 661: sealing member 621a: cover

150: status display unit 160: motion control input unit

161: encryption key writing control unit 162: encryption key reading control unit

161a: encryption key entry button 162a: encryption key read button

170: power supply section 628: serial port section

780: encryption key registration start portion 780a:

750a: subscriber operation button unit

According to an aspect of the present invention for achieving the above object, the high-speed power line communication with the local information control device through the subscriber network, the high-speed power line communication with the terminals of the customer through the home network, the home network A meter gateway comprising a power amount meter for reading the amount of power used by the customer from the meter to provide the meter reading data to the area information control device through the subscriber network, wherein the area information control device according to the request signal of the terminal Service data provided through the subscriber network from the mobile station to the terminal, and the service data is metered based on service / content type, service usage time, service / content download count, content information amount, unit information, and control service count Metered service data measured by the local information A service add-on meter gateway is provided that includes a service meter that transmits to a control device.

In addition, according to another aspect of the present invention to achieve the above object, the input terminal to the outdoor lead-in constituting the subscriber network and the output terminal fetching the indoor lead-out constituting the indoor network is arranged in parallel with each other A power amount metering unit casing provided with a terminal casing, a first cover which is fastened to an upper end of the terminal casing, the power amount metering unit is built in, and a front cover is fastened by a first sealing member to protect the power metering unit; A service including a service metering casing detachable through the upper end and the support member of the metering unit casing, the service metering unit is built in, and a front cover is fastened by a second sealing member to protect the service metering unit. A casing structure of an additional meter gateway is provided.

In addition, according to another aspect of the present invention for realizing the above object, there is provided a power line communication system using the service-added meter gateway.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the preferred embodiments disclosed below, but can be implemented in a variety of different forms, only this embodiment is intended to complete the disclosure of the present invention and the scope of the invention to those skilled in the art It is provided to inform you completely.

FIG. 1 is an overall configuration diagram of a service supplementary powerline communication system according to a preferred embodiment of the present invention, and FIG. 2 is a diagram illustrating a subscriber network and a home network of the service supplementary powerline communication system shown in FIG. Here, the subscriber network is a network made through the outdoor incoming line 80, the home network refers to a network made through the indoor incoming line (90).

1 and 2, a service-added power line communication system according to a preferred embodiment of the present invention is a local information control device 50 for performing high-speed two-way communication with an external server through a data communication network 40, and this area Meter gateways M1 to Mm that perform high-speed power line communication through the information control device 50 and the outdoor leader line 80, and the meter gateways M1 to Mm and the indoor leader line 90 in the house. The indoor information control device (D1 to Dm) for performing the high-speed power line communication through, and the indoor information control device (D1 to Dm) and a plurality of terminals (T1 to Tn) for performing high-speed power line communication in the home.

[External server]

The external server includes a power provider server 10, a network operator server 20, and a plurality of service provider servers 30, and the data communication network 40 (e.g., based on Transmission Control Protocol / Internet Protocol) (TCP / IP). , Broadband integrated network, wide area network, Internet, premises information network, etc.) to perform a high-speed two-way communication with a plurality of local information control device 50. The power provider server 10, the network provider server 20, and the service provider server 30 are interconnected through a data communication network 40 or other communication network.

The power service provider server 10 receives a power reading amount of each customer H1 to Hm from the local information control device 50 through the data communication network 40 in real time. Here, the power meter reading amount refers to the amount of power used by each consumer H1 to Hm. The power provider server 10 sets and charges a power usage fee for each customer H1 to Hm based on the amount of power reading provided from the local information controller 50. Here, as the power meter reading amount of the total amount of power used by the monthly, weekly, nightly, date, time zone of all the customers (H1 to Hm) assigned to one local information control device 50, each customer (H1 to Hm) monthly, daytime, nightly, date, time of day can be used such as the amount of power and instantaneous power.

The network operator server 20 receives a service reading amount of each customer H1 to Hm from the local information control device 50 through the data communication network 40 in real time. Here, the service meter reading amount includes a service / content type used by the subscriber, a service / content usage time, and a service / content usage amount. The network operator server 20 sets and charges a service fee for each customer H1 to Hm based on the service reading amount provided from the local information controller 50. Here, the service meter reading amount may include the service usage time and the type of service / content used, service / content usage, and frequency of use of content by monthly, weekly, nightly, date, and time zone of each customer (H1 to Hm). have.

The plurality of service provider servers 30 provide service / content data to the respective meter gateways M1 to Mm through the data communication network 40 corresponding to the service model of each service company. That is, the service provider server 30 provides corresponding service / content data when there is a request for service / content data from each of the meter gateways M1 to Mm through the data communication network 40.

The external server may further include a gas / water service provider server (not shown) and a security management service provider server (not shown). The gas / water service provider server receives the gas / water meter reading amount of each customer H1 to Hm from the local information control device 50 through the data communication network 40 in real time. Here, the gas / water reading amount refers to the gas / water usage amount used in each of the customers H1 to Hm. The gas / water service provider server sets and charges the gas / water use fee of each customer H1 to Hm based on the gas / water use amount provided from the local information controller 50. Here, as the gas / water meter reading amount, the sum of the monthly, weekly, nightly, date, and time zone usage amounts of all the customers (H1 to Hm) assigned to one local information control device 50, and each customer (H1) To Hm) may be used monthly, weekly, nightly, date, time zone. The security management service provider server is a server that manages the security of each customer (H1 to Hm), and receives an internal image of each customer (H1 to Hm) photographed through an IP camera, and charges the corresponding charge. .

In the following description, the power reading amount and gas / water reading amount provided from each of the meter gateways M1 to Mm will be referred to as meter reading data, and data provided from the service provider server 30, service / content data, and the like. The data will be named as service data.

[Regional Information Control Device]

The local information control device 50 is installed at least one for each access network to perform high-speed power line communication with all meter gateways M1 to Mm constituting the subscriber network. The local information controller 50 performs high-speed power line communication through the meter gateways M1 to Mm and the outdoor lead-in line 80 installed at each of the customers H1 to Hm, respectively. In addition, data communication is performed with an external server through the data communication network 40. Here, the outdoor lead wire 80 refers to a distribution line of 110 / 220V extending from the output terminal of the columnar transformer 60 and installed between the local information control device 50 and each of the meter gateways M1 to Mm.

The local information control device 50 receives meter reading data from the meter gateways M1 to Mm through the outdoor lead wire 80 and provides the power provider server 10 through the data communication network 40. At this time, the local information controller 50 temporarily stores the meter data transmitted from the meter gateways M1 to Mm in the data storage unit (see '530' in FIG. 3), and then from the power provider server 10. When the request signal for the meter reading data is received, the meter reading data stored in the data storage unit 530 is extracted and provided to the power service provider server 10 through the data communication network 40. In this way, the local information controller 50 receives the meter reading data, that is, the gas / water reading from the meter gateways M1 to Mm, and provides the reading data to the gas / water company server through the data communication network 40. However, the local information control device 50 according to the preferred embodiment of the present invention is not limited thereto, and a request signal for power reading amount or gas / water reading amount from the power company server 10 or the gas / water supply company server. Even if there is no predetermined transmission time arrives, the power reading or the gas / water reading may be sequentially drawn out according to the predetermined time and provided through the data communication network 40.

In addition, the local information controller 50 connects the meter gateways M1 to Mm, the network operator server 20 and the service provider server 30 in real time (ON-line) through the data communication network 40. The local information controller 50 receives a signal for requesting an internet connection with the service provider server 30 from the meter gateways M1 through Mm. Perform internet access. As a result, the service provider server 30 provides service data to the meter gateways M1 to Mm.

In addition, the local information controller 50 stores the common cryptographic key K0 in the data storage unit (see '530' of FIG. 3) to perform secure communication with each of the meter gateways M1 to Mm (or, Registration, and then encrypted data is transmitted from the meter gateways M1 to Mm, and the encrypted data is decrypted using this common encryption key K0. Here, the common encryption key K0 is an encryption key for the data frame in the power line communication using the subscriber network, i.e., the outdoor lead wire 80, and the area information controller 50 and the meter gateways M1 to Mm. Encryption key for communication. The encrypted data provided from the meter gateways M1 to Mm refers to the data encrypted using the common encryption key K0.

As shown in FIG. 3, the local information controller 50 includes a power line communication module 510, a central processing unit 520, a data storage unit 530, a wired data communication module 540, and a wireless data communication module. The unit 550 and a power supply unit (not shown) for supplying power. Here, the power supply unit uses the supply power supplied through the outdoor lead wire (80).

The power line communication module unit 510 receives meter reading data from the outdoor lead wire 80. In addition, the power line communication module unit 510 receives the Internet access signal and other data from the outdoor incoming line 80, and wires the service data, the meter data request signal, and the control signal received from the wired data communication module unit 550. Received from the data communication module unit 550 and sent to the outdoor incoming line (80). The power line communication module unit 510 includes a power line coupler 511, a reception filter unit 512, a reception amplifier unit 513, a power line communication unit 514, a transmission filter unit 515, and a transmission amplifier unit 516. It includes.

The power line coupler 511 is connected to the outdoor lead wire 80 to detect and receive meter data, Internet connection signal and other data transmitted from the meter gateways M1 to Mm from the outdoor lead wire 80. Transmit to filter unit 512. The power line coupler 511 carries the service data, the request signal, and the control signal transmitted from the transmission amplifier 516 to the outdoor lead wire 80. The power line coupler 511 is configured to include a transformer (not shown) having a primary side connected to an outdoor lead wire 80 and a secondary side connected to a reception filter unit 512 and a transmission amplifier unit 516, respectively. In addition, a fuse, a varistor, a resistor, a zener diode, or the like may be appropriately configured to minimize noise.

The reception filter unit 512 and the reception amplifier unit 513 are data converters for converting a reception data signal, and the reception filter unit 512 may include noise included in the reception data signal transmitted from the power line coupler 511. The predetermined frequency band is filtered and transmitted to the reception amplifier 513. The reception amplifier 513 amplifies the reception data signal filtered and transmitted through the reception filter unit 512 at a predetermined amplification ratio, thereby power line. Transmit to communication unit 514.

The transmission filter unit 515 and the transmission amplifier unit 516 are data converters for converting a data signal for transmission, and the transmission filter unit 515 is a noise or predetermined signal included in the transmission data transmitted from the power line communication unit 514. The frequency band is filtered and transmitted to the transmission amplifier 516, and the transmission amplifier 516 amplifies the transmission data signal filtered and transmitted through the transmission filter 515 at a predetermined amplification ratio, thereby power supply coupler 511. To send.

The power line communication unit 514 is a modulation / demodulation module in which a chip for power line communication is embedded. As the modulation / demodulation method, orthogonal frequency division multiplexing (OFDM), code division multiple access (CDMA), or the like is used for high-speed communication. Can be. For example, the power line communication unit 514 demodulates a reception data signal, that is, an analog signal transmitted from the reception amplification unit 513, into a digital signal and transmits the demodulated data signal to the central processing unit 520. Then, the transmission data signal transmitted from the central processing unit 520, that is, the digital signal is modulated into an analog signal and transmitted to the transmission filter unit 515.

On the other hand, the wired data communication module unit 550 is a service data transmitted from the data communication network 40, meter reading request signal, control signal and security data of the power provider server 10, gas / water service provider server and security management service provider server Receive the request signal. The wired data communication module unit 550 provides meter reading data to the power service provider server 10 and the gas / water service provider server through the data communication network 40 in response to the request signal. Then, the security data is provided to the security management service provider server. In addition, the wired data communication module unit 550 provides the service data, the request signal, and the control signal to the central processing unit 520. Data provided to the central processing unit 520 is transmitted to the outdoor tugboat 80 through the power line communication module unit 510. The wired data communication module unit 550 includes a wired communication port unit 551, a reception filter unit 552, a reception amplifier unit 553, a wired data communication unit 554, a transmission filter unit 556, and a transmission amplifier unit ( 555).

The wired communication port unit 551 is a port connected to the data communication network 40. The wired communication port unit 551 receives service data, a request signal, and a control signal transmitted from an external server through the data communication network 40 and transmits it to the reception filter unit 552. do. The meter reading data, the Internet access signal, and other data transmitted from the transmission amplifier 556 are transmitted to the external server through the data communication network 40.

The reception filter unit 552 and the reception amplifier unit 553 are data conversion units for converting a reception data signal, and the reception filter unit 552 is included in the reception data signal transmitted from the wired communication port unit 551. The noise or a predetermined frequency band is filtered and transmitted to the reception amplifier 553. The reception amplifier 553 amplifies the reception data signal filtered and transmitted through the reception filter 552 at a predetermined amplification ratio, thereby wired data. Transfer to the communication unit 554.

The transmission filter unit 556 and the transmission amplifying unit 555 are conversion units for converting a data signal for transmission, and the transmission filter unit 556 is a noise included in the transmission data signal transmitted from the wired data communication unit 554. The predetermined frequency band is filtered out and transmitted to the transmission amplifier 555. The transmission amplifier 555 amplifies the transmission data signal filtered and transmitted through the transmission filter 556 at a predetermined amplification ratio, thereby providing a wired communication port. Send to section 551.

The wired data communication unit 554 demodulates a reception data signal transmitted from the reception amplifier 553, that is, an analog signal into a digital signal, and transmits the demodulated signal to the central processing unit 520, or the transmission data transmitted from the central processing unit 520. The signal, that is, the digital signal is modulated into an analog signal and transmitted to the transmission filter unit 556.

On the other hand, the wireless data communication module unit 540 is a wireless infrared communication module unit, such as a PDA (Personal Digital Assistant), a notebook (notebook computer) or a remote control (remote control) in which an external device, for example, a wireless infrared communication device is embedded. The common encryption key K0 is received from the mobile encryption key registration device and stored in the data storage unit 530. Here, the PDA, notebook, and remote control may be managed by the network operator. One example remote control 100 is shown in Figures 9 and 10, a detailed description thereof will be described later. In addition, the wireless data communication module unit 540 provides the common encryption key K0 stored in the data storage unit 530 to the encryption key registration device when the common encryption key K0 is requested. The wireless data communication module unit 540 includes a wireless communication port unit 541, a reception filter unit 542, a reception amplifier unit 543, a wireless data communication unit 544, a transmission filter unit 545, and a transmission amplifier unit ( 546).

The wireless communication port unit 541 is a wireless infrared communication port. A receiving port (not shown) for receiving the common encryption key K0 from the encryption key registration device and transmitting the received encryption key K0 to the reception filter unit 542, and a transmission amplifier 546. It includes a transmission port (not shown) for providing a common encryption key (K0) transmitted from) to the encryption key registration device. Here, the encryption key registration device is a device such as a PDA, a notebook or a remote controller with a built-in wireless infrared communication device as described above to read the common encryption key (K0) from the transmission port of the wireless communication port unit 541, or The common encryption key K0 is transmitted to the reception port of the communication port 541.

The reception filter unit 542 and the reception amplifying unit 543 are reception data conversion units, and the reception filter unit 542 is a reception data signal including a common encryption key K0 transmitted from the wireless communication port unit 541. The noise included in the filter is filtered and transmitted to the reception amplifier 543, and the reception amplifier 543 amplifies the reception data signal filtered through the reception filter 542 at a predetermined amplification ratio, thereby transmitting the wireless data communication unit 544. To send).

The transmission filter unit 545 and the transmission amplifying unit 546 are transmission data conversion units, and the transmission filter unit 545 is used to transmit data signals including the common encryption key K0 transmitted from the wireless data communication unit 544. The included noise is filtered and transmitted to the transmission amplifier 546, and the transmission amplifier 546 amplifies the transmission data signal filtered through the transmission filter unit 545 at a predetermined amplification ratio to wireless communication port unit 541. To send).

The wireless data communication unit 544 demodulates a reception data signal transmitted from the reception amplifier 543, that is, an analog signal into a digital signal, and transmits the demodulated data to the central processing unit 520 or the transmission data transmitted from the central processing unit 520. The signal, that is, the digital signal is modulated into an analog signal and transmitted to the transmission filter unit 545.

Meanwhile, the central processing unit 520 stores the common encryption key K0 transmitted from the receiving port of the wireless data communication module unit 540 in the data storage unit 530, while storing the data when the common encryption key K0 is requested. The common encryption key K0 stored in the unit 530 is provided to the encryption key registration device through the transmission port of the wireless data communication module unit 540. In this case, the common encryption key K0 may be registered at the time of manufacture or installation of the local information control device 50.

When the central processing unit 520 receives a request for the common encryption key K0 from the encryption key registration device, the central processing unit 520 performs an authentication procedure for the encryption key registration device. The authentication procedure is a procedure for determining whether the encryption key registration device is a legitimate device that can be provided with the common encryption key (K0). For example, after registering the predetermined information about the legitimate encryption key registration device, the information and request is made. By comparing the information of the encryption key registration device to attempt to determine the legitimate encryption key registration device. In addition, after registering the preset password, if the same password is entered in the request, it may be allowed to authenticate. If the encryption key registration device attempting a request is not a valid registration device through the authentication procedure, the central processing unit 520 does not provide a common encryption key K0, or the common encryption key input from the encryption key registration device. Do not register the key K0. Through this authentication procedure, unauthorized communication devices or facilities can be illegally accessed to the subscriber network and distorted or acquired, such as illegally accessing the subscriber network.

In addition, the central processing unit 520 stores the meter reading data transmitted from the power line communication module unit 510 in the data storage unit 530, while corresponding to the request signal transmitted from the wired communication module unit 550. The meter data is extracted from the plurality of meter data stored at 530 and provided to the data communication network 40 through the wired communication module unit 550. The central processing unit 520 temporarily stores the service data transmitted from the wired communication module unit 550 in the data storage unit 530 and transmits the service data to the power line communication module unit 510.

On the other hand, the data storage unit 530 is a nonvolatile memory (ROM), such as a flash memory (flash memory), and a random access memory (RAM). In the data storage unit 530, the meter reading data transmitted from the central processing unit 520 is classified into customers (H1 to Hm), monthly, weekly, nightly, date, and time zone and stored in real time. In addition, the data storage unit 530 stores the common encryption key K0. At this time, it is preferable to store the common encryption key K0 in the ROM which is a nonvolatile memory. As a result, even when the power is cut off, the common encryption key K0 is maintained as it is stored in the data storage unit 530. In addition, the data storage unit 530 stores service data received by the wired data communication module unit 550 and provided through the central processing unit 520 in the RAM.

[Meter gateway]

The service-added meter gateways M1 to Mm are installed one at each customer H1 to Hm at the site where the meter is previously installed. The meter gateways M1 to Mm perform power line communication with the local information control device 50 through the outdoor lead wire 80. In addition, the meter gateways M1 to Mm perform power line communication with the indoor information control devices D1 to Dm and the terminals T1 to Tn respectively installed inside the customers H1 to Hm through the indoor lead wire 90. .

The meter gateways M1 to Mm receive service data from the local information controller 50 through the outdoor lead wire 80 and temporarily store the data in the data storage unit (see '624' in FIG. 4). For example, a large amount of content data is temporarily stored. In this way, the service data stored in the data storage unit 624 is provided to the terminals T1 to Tn through the indoor incoming line 90 upon request. In addition, the meter gateways M1 to Mm measure intangible information such as service data and content data included in the service data provided to the terminals T1 to Tn. For example, the service metering method includes a time-based service metering method, a content-type service metering method, and unit information and a controlled service metering method. Detailed description thereof will be described later.

In addition, the meter gateways M1 to Mm measure the power consumption of the corresponding customers H1 to Hm and provide them to the local information control device 50 through the outdoor lead line 80. In addition, the meter gateways M1 to Mm receive the gas / water usage from the indoor information control devices D1 to Dm and provide the gas information to the local information control device 50 through the outdoor lead line 80. Here, the meter gateways M1 to Mm may be provided with gas / water readings directly from the terminals T1 to Tn.

In addition, the meter gateways M1 to Mm receive the common encryption key K0 and the private encryption keys K1 to Km, and store the data in the data storage unit. Encrypts and decrypts the data using the encryption key K0, and encrypts the data using the respective private encryption keys K1 to Km when transmitting and receiving data with the indoor information control devices D1 to Dm and the terminals T1 to Tn. Decrypt Here, 'K0' to 'Km' are different encryption keys.

The meter gateways M1 to Mm include an electric power meter 610 and a service meter 620 as shown in FIG. 4. The power meter 610 includes a power meter module 611 and a wireless data communication module 612, and the service meter 620 includes a power line communication module 621, a central processing unit 622, and wireless data. The communication module unit 623, the data storage unit 624, the data display unit 625, the service / content data metering operation unit 626, and the operation switch unit 627 are included. The power meter 610 is connected to the service meter 620 through the serial port unit 628.

The electricity amount meter 610 measures the power consumption of the corresponding customers H1 to Hm in real time and transmits the power amount to the central processor 622 of the service meter 620 through the serial port unit 628.

The power amount measurement module unit 611 includes a current / voltage detector 6111, a power amount calculator 6112, a power amount processor 6113, and a power amount display 6151. The current / voltage detector 6111 detects the current / voltage from a supply power supply (AC power supply) supplied to the corresponding customer through the outdoor lead wire 80. The power amount calculator 6112 calculates the power amount using the current / voltage detected by the current / voltage detector 6111. The power amount processor 6113 provides the power amount detected by the power amount calculator 6112 to the power line communication module unit 621 through the serial port unit 628. The power amount display unit 6114 displays the power amount provided from the power amount processor 6113 in real time.

The wireless data communication module unit 612 is a wireless infrared communication module unit which receives a control signal transmitted from an external infrared remote controller (not shown) and transmits the control signal to the power amount processor 6131 of the power meter module 611. . In addition, the amount of power provided from the power meter module 611 may be provided to an external infrared communication device (not shown). Here, the external infrared communication device may be a PDA or laptop capable of infrared communication.

The wireless data communication module unit 612 includes a wireless communication port unit 6121, a reception filter unit 6122, a reception amplifier unit 6223, a wireless data communication unit 6224, a transmission filter unit 6125, and a transmission amplifier unit ( 6126). The wireless communication port unit 6121 is a wireless infrared communication port unit and receives a control signal transmitted from an external infrared remote controller. The reception filter unit 6122 filters the control signal received by the wireless communication port unit 6121. The reception amplifier 6223 amplifies the filtered control signal. The wireless data communication unit 6224 demodulates the amplified control signal and provides the amplified control signal to the power amount processor 6113. The power amount processing unit 6113 is controlled by the control signal. In addition, the amount of power is provided to an external device through the wireless data communication unit 6224, the transmission filter unit 6225, the transmission amplifier unit 6262, and the wireless communication port unit 6121 at the request of the electric power.

On the other hand, although not shown, the power meter 610 further includes a central processing unit, a data storage unit, a power line communication module unit, and the like to independently read the metering data to the outdoor lead wire 80 separately from the service metering unit 620. It may be transmitted to the local information control device 50 through. The central processing unit, the data storage unit, and the power line communication module unit may be configured in the same configuration as the central processing unit 622, the data storage unit 624, and the power line communication module unit 6214 to be described in the service metering unit 620. . As such, by configuring the power amount metering unit 610 independently of the service metering unit 620, it is possible to provide simple and convenient management and operation to the power company manager and the network operator.

The service metering unit 620 first receives the service data provided through the outdoor tugboat 80 from the local information controller 50 and provides them to each terminal T1 to Tn. In addition, intangible information such as service data and content data included in the service data is measured. In addition, the service metering unit 620 receives the common encryption key K0 and the private encryption keys K1 to Km, and receives the local information control device 50, the indoor information control devices D1 to Dm, or the terminals T1 to Tn. When the encrypted data is transmitted from the C), the encrypted data is decrypted using the common encryption key K0 or the private encryption keys K1 to Km. In addition, the service metering unit 620, if you want to transfer data to the local information control device 50, the indoor information control device (D1 to Dm) or the terminals (T1 to Tn), the common encryption key (K0) or private encryption key Data is encrypted by using (K1 to Km).

The power line communication module unit 621 detects various data such as service data, meter reading data, or Internet connection data transmitted through the outdoor lead wire 80 or the indoor lead wire 90. Various data such as meter reading data, service meter reading data, or Internet connection data are carried on the outdoor tugboat 80, while service data is carried on the indoor tugboat 90. Here, the service meter reading data is a metered value of the service data.

The power line communication module unit 621 includes a power line coupler 6211, a reception filter unit 6212, a reception amplifier unit 6213, a power line communication unit 6214, a transmission filter unit 6215, and a transmission amplifier unit 6216. do. First, the data receiving operation will be described. The power line coupler 6221 detects various data from the outdoor lead wire 80 or the indoor lead wire 90 and provides the received data to the reception filter part 6212. The reception filter part 6212 filters the data provided from the power line coupler 6211. The reception amplifier 6213 provides the data provided from the reception filter 6212 to the power line communication unit 6214. For example, the data detected from the outdoor lead wire 80 is provided to the subscriber network power communication unit, and the data detected from the indoor lead wire 90 is provided to the indoor network power communication unit. The power line communication unit 6214 demodulates this data and transmits it to the central processing unit 622. The data transmission operation will be described. The power line communication unit 6214 modulates the data transmitted from the central processing unit 622 and provides it to the transmission filter unit 6215. The transmission filter unit 6215 filters the data provided from the power line communication unit 6214. The transmission amplification unit 6216 provides the data provided from the transmission filter unit 6215 to the power line coupler 6211. The power line coupler 6211 carries data provided from the transmission amplifier 6216 to the outdoor lead wire 80 or the indoor lead wire 90.

The wireless data communication module unit 623 is a wireless infrared communication module unit similar to the wireless data communication module unit 540 of the local information control device 50. The wireless data communication module unit 623 uses a common encryption key K0 and a private encryption key from a mobile encryption key registration device. While receiving (K1 to Km), it provides a common encryption key (K0) and private encryption keys (K1 to Km) registered with the mobile encryption key registration device. The wireless data communication module unit 623 includes a wireless communication port unit 6321, a reception filter unit 6322, a reception amplifier unit 6303, a wireless data communication unit 6164, a transmission filter unit 6235, and a transmission amplifier unit ( 6236).

The central processing unit 622 stores the common encryption key K0 and the private encryption keys K1 to Km transmitted from the receiving port of the wireless data communication module unit 623 in the ROM of the data storage unit 624, while requesting the request. The common encryption key K0 and the private encryption keys K1 to Km stored in the city data storage unit 624 are provided to the encryption key registration device through the transmission port of the wireless data communication module unit 6161. The central processing unit 622 stores the power reading amount provided from the serial port unit 628 and the gas / water reading reading amount provided from the power line communication module unit 620 in the data storage unit 624. In addition, the central processing unit 622 stores the service data provided from the power line communication module unit 620, in particular, a large amount of content data in the data storage unit 624, and displays the service data in the data display unit 625.

The data storage unit 624 is composed of ROM and RAM, and the meter reading data transmitted from the central processing unit 622 is classified by customer (H1 to Hm), monthly, weekly, nightly, date, and time zone. Stored in real time. In addition, the data storage unit 624 stores the private encryption key of any one of the common encryption key (K0) and private encryption keys (K1 to Km). The data storage unit 624 stores service data provided from the central processing unit 520, in particular, content data having a large capacity. In addition, the data storage 624 stores the service data reading amount measured through the service / content data meter 626.

The service / content data meter 626 receives the service data and measures the amount of service / content included in the service data. As described above, the metering method includes a time type service metering method, a content type service metering method, and a unit information and controlled service metering method. This is because service data are largely classified into time-based services, content-type services, and unit information and controlled services. Here, the time type service refers to a type of service that can charge a fee by measuring a service providing time. The content and information type service mainly refers to a type of service that can charge a fee by measuring the amount of information and data provided from an external service provider. Here, the content type service mainly means a stream type content service, and the information type service means a service that provides relatively small amount of information such as mail, text message, traffic / weather information, and the like. In addition, the controlled service refers to a type of service that can charge a one-time control service request such as door control, lighting, and control of a remote device.

Unlike other services, time-based service metering is an important metering indicator. Accordingly, information necessary for the metering of timed services includes a service classification code, a service request time, a service requester information, and a service start time with respect to service initiation, and a service classification code and service termination request with respect to service termination. Time, service requester information, and service end time. In addition, information required for time-based service metering after the service is started includes main event information generated when the service is performed, service execution time for each service classification (continuously updated at a predetermined time), and the like.

In addition, a large amount of information is often generated in the time service. For example, when an external intrusion occurs in a security service and an indoor surveillance camera (IP camera) installed in the premises photographs it, a large amount of image information is generated. The meter gateways M1 to Mm collect the image information and store the most recent information in the data storage unit 624 once, and the previous image information may be stored in the home information control devices D1 to Dm or the local information control device ( 50) to store temporarily. If the user wants to view the image information from outside, the consent of the subscriber is required. For the protection of the subscriber information, the image information stored in the local information control device 50 is encrypted using a common encryption key (K0) to protect privacy. To be made.

In the content-type service metering method, the amount of information and the type of information of the service provided are important metering indicators. Accordingly, information necessary for the metering of the content type service includes a service classification code, a content service weight classification code, a service request time, service requester information, and the like in relation to service initiation. The content service weight classification code is a code indicating a charge weight of the provided content and is provided to the subscriber in advance when the content service provider assigns the content to each content and the subscriber requests the content through the indoor information control devices D1 to Dm. After the service is started, the information to be managed becomes the main information generated when the service is performed and the total amount of information (in Mbyte) of the information type service.

Unit information and controlled service metering methods are important indicators of the number of information requests rather than the amount or time of information provided. Accordingly, information necessary for the metering of the unit information and the controlled service includes a service classification code, a service request time, and service requester information. As described above, the unit information and the controlled service may include relatively small amounts of information such as weather, traffic, news, and mail, and remote light / door / home / household control.

Hereinafter, the time-based service metering method of the service metering methods will be described as an example. For example, the subscriber requests time-based service start through the indoor information control devices D1 to Dm. On the other hand, in the case of outdoors, the subscriber may remotely request a time type service using a wireless data communication network or an internet network. Meanwhile, the meter gateways M1 to Mm receive the time type service request signals provided from the home information control devices D1 to Dm, and service classification codes, service request times, and service start requestors for services requested by subscribers. (Subscriber) information is detected and stored in the data storage unit 624. In addition, the meter gateways M1 to Mm provide the service request signal of the subscriber to the service provider server 30 through the local information controller 50. The service provider server 30 transmits the corresponding service data to the meter gateways M1 to Mm through the local information controller 50 in response to the service request signal. The meter gateways M1 to Mm receive service data, detect the transmission time of the service data, and store the service data in the data storage 624. Subsequently, when the subscriber requests termination of the timed service through the indoor information control devices D1 to Dm, the meter gateways M1 to Mm are provided with a service termination request signal, and the service for the service requesting the termination of the service The classification code, service termination request time, and service requester information are detected and stored in the data storage 624. In response to the service termination request signal, the service provider server 30 terminates the transmission of the service data. Meanwhile, the service / content data metering unit 626 of the meter gateways M1 to Mm stores the service classification code, service request time and service start requestor information stored when the service start request is stored in the data storage unit 624, and the service end. The time-based service usage is calculated based on the stored service classification code, service termination request time, and service termination requester information. In this case, the service / content data metering unit 626 calculates service usage in consideration of the main event information and service execution time for each service classification generated after the start of the service when time-based service metering.

The data display unit 625 displays information (including service fee information) about the service that the subscriber wants to request or the service being requested. In addition, various other service data are displayed. For example, the data display unit 625 may be an electroluminescence display (ELD) or a liquid crystal display (LCD).

5A to 5E are outline views showing the casing structure of the meter gates M1 to Mm shown in FIG. 4, FIG. 5A is a front view, FIG. 5B is an internal perspective view, and FIGS. 5C and 5D are side views. 5E is a separation diagram.

5A to 5E, the service-added meter gateways M1 to Mm according to the preferred embodiment of the present invention are made up of the service metering unit 620 and the power metering unit 610 as described above. The service metering unit 620 and the power metering unit 610 are fastened through the support unit to be detachable from each other as shown in FIG. 5E as independent devices.

The service metering unit 620 and the power metering unit 610 shown in FIG. 4 are respectively built in a board form inside the square casings 620a and 610a. Hereinafter, the casing 620a is called a service meter casing, and the casing 610a is called a power meter casing. Two support members 630 provided at the upper end of the power meter casing 610a are inserted into the lower end of the service meter casing 620a so that the service meter casing 620a is supported by the power meter casing 610a. A support groove (not shown) is provided. In addition, the service metering unit casing 620a is fastened by the fastening member 150. The fastening member 150 includes an upper member 622a installed at the end of the cover 621a of the service metering unit casing 620a, and the amount of power. It consists of a lower member 612a provided at the upper front end of the metering section casing 610a, that is, the portion corresponding to the fastening member 622a, and the two members 612a and 622a are locked by the sealing member 651. Then, the power meter casing 610a is provided with a fastening member 660 in the same configuration as the fastening member 650 so as to be locked by the sealing member 661 is sealed by the power operator.

As shown in FIG. 5A, the service metering casing 620a includes a data display unit 625 shown in FIG. 4, transmission / reception ports 6301a and 6231b of a wireless communication port unit 6161, and a light emitting diode (LED) display unit. 625a, the operation switch unit 627 is located. As described above, the data display unit 625 displays information (including service charge information) about the service that the subscriber wants to request or the service being requested. The receiving port 6321a is a port for registering the common encryption key K0 and the private encryption keys K1 to Km, and receiving an external control signal. The transmission port 6321b is a port for transmitting the common encryption key K0 and the private encryption keys K1 to Km to the external encryption key registration device. The LED display unit 625a displays the progress state of the service data. On the other hand, the LED display unit 625a indicates whether or not the service provided by the subscriber through the ON / OFF (ON / OFF), the faster the LED flashing speed indicates that the rate of the service provided is higher, The lower the speed at which the LED blinks, the lower the cost of the service provided. The operation switch unit 627 is installed between the power line communication module unit 620 and the outdoor lead wire 80 as a power switch, and controls an alternating current (AC) power supplied to the service metering unit 620 to operate overall. To control.

Meanwhile, as shown in FIG. 5B, the outdoor lead wire 80 is connected to an input terminal 613 installed at the lower end of the power metering casing 610a to be connected to a direct current (DC) power supply unit 615 for the power meter. do. Here, the AC power supplied through the outdoor lead wire 80 is converted into direct current by the DC power supply unit 615 for the electric power metering unit and supplied to the electric power metering unit 610. Meanwhile, the AC power supplied through the outdoor lead wire 80 inserted into the input terminal 613 is supplied to the indoor lead wire 90 through the output terminal 614 via the current transformer CT 616. . The AC power output to the current transformer 616 is supplied to the DC power supply unit 629 for the service metering unit via the service metering terminal. The DC power supply unit 629 for the service metering unit converts AC power into DC power and is supplied to the service metering unit 620. At this time, the operation switch unit 627 is installed between the service metering unit terminal and the service metering unit DC power supply 629 to control the power supplied to the service metering unit to control the overall operation of the service metering unit 620.

As described above, the meter gateways M1 to Mm have a service metering function and a power metering function separately, and the energy metering unit and the service metering unit such as the electric power amount are in charge of the independent metering functions. The power amount meter 610 and the service meter 620 are sealed by separate sealing members 651 and 661 for independence of operation and management of the power meter 610 and the service meter 620. Through this, the electric power company and the network operator may separately manage the electric power meter 610 and the service meter 620. When the network operator wants to maintain and repair the service metering unit 620, the network operator may release the sealing member 651 and then open the cover 621a as shown in FIG. 5D. In addition, as described above, the DC power supply unit 629 for the service metering unit uses an AC power source on the output side (load side), and has an operation switch unit 627 to turn the power supply ON / OFF from the network management company. To be able. That is, when the subscriber applies for the service, the network operator releases the sealing member 651 of the service metering unit 620 and opens the cover 621a of the service metering unit 620 to open the service metering unit 620. After the power is turned on, the cover 621a is closed again and then sealed using the sealing member 651 of the service metering unit 620.

For reference, the meter gateways M1 to Mm independently operate the service metering unit 620 as described above. Accordingly, a fee should be charged for the amount of power used to drive the service metering unit 620. In this case, the power amount metering unit 610 is configured to read together the amount of power used by the service metering unit 620, and the network operator bears the charge for the amount of power used by the metered service metering unit 620. .

[Indoor Information Control Device]

The indoor information control devices D1 to Dm are installed one by one inside the customers H1 to Hm, and are connected to the meter gateways M1 to Mm through the indoor lead wire 90 to perform power line communication. A user terminal having a man-machine interface (MMI) unit, that is, a control input unit 750 illustrated in FIG. 6, to allow a subscriber to request a service such as information and content. The indoor information control devices D1 to Dm form one indoor network through the meter gateways M1 to Mm, the terminals T1 to Tn, and the indoor lead wire 90. Each home network shares the same single private encryption key to perform data encryption and decryption in common. For example, the indoor information control device D1 shares data with the meter gateway M1, the terminals T1 through Tn, and the private encryption key K1 in common.

As shown in FIG. 6, the indoor information control devices D1 to Dm may include a power line communication module 710, a central processing unit 720, a data storage unit 730, a data display unit 740, a control input unit 750, The wireless data communication module unit 760, a wired data communication module unit 770, and an encryption key input initiation unit 780 are included.

The power line communication module unit 710 detects various data such as service data, meter reading data, or Internet connection data transmitted through the indoor lead wire 90. Then, various types of data such as meter reading data, service meter reading data, or internet connection data are carried on the indoor incoming line 90. The power line communication module unit 621 is similar to the power line communication module unit 621 of the meter gateways M1 to Mm shown in FIG. 4, and includes a power line coupler 711, a reception filter unit 712, and a reception amplifier unit 712. 713, a power line communication unit 714, a transmission filter unit 715, and a transmission amplifier unit 716.

The wireless data communication module unit 760 is a wireless infrared communication module unit and receives a corresponding private encryption key among private encryption keys K1 to Km from a mobile encryption key registration device. Here, as described above, a mobile encryption key registration device may be a PDA, a notebook, or a remote controller 100 in which a wireless infrared communication device is embedded. The wireless data communication module unit 760 is similar to the wireless data communication module unit 623 of the meter gateways M1 to Mm shown in FIG. 4, and includes a wireless communication port unit 761, a reception filter unit 762, and the like. A reception amplifier 763, a wireless data communication unit 764, a transmission filter unit 765 and a transmission amplifier unit 766. In addition, the wireless data communication module unit 760 may perform wireless data communication with a terminal performing wireless data communication among the terminals T1 to Tn.

The wired data communication module unit 770 transmits and receives data through a separate communication line with a terminal performing data communication among the terminals T1 to Tn, such as a computer, a VoIP phone, an IP camera, or a security management controller (not shown). Module to do this. The wired data communication module unit 770 includes a wired communication port unit 771 (eg, RJ45, USB), a reception filter unit 772, a reception amplifier unit 773, a wired data communication unit 774, a transmission filter unit ( 775 and a transmission amplifier 776. If the high-speed power line communication with the terminals T1 to Tn is possible through the indoor lead wire 90, the wired data communication module unit 770 may not be installed.

The central processing unit 720 stores in the ROM of the data storage unit 730 any one of the private encryption key (K1 to Km) transmitted from the receiving port of the wireless data communication module unit 760. The private encryption key stored in the data storage unit 730 performs data communication with the corresponding meter gateways and the terminals T1 through Tn among the meter gateways M1 through Mm. In addition, the central processing unit 720 stores the gas / water reading reading provided from the power line communication module unit 710 in the data storage unit 730 and transmits it to the corresponding meter gateway when requested. In addition, the central processing unit 720 stores the service data provided from the power line communication module unit 710, in particular, a large amount of content data in the data storage unit 730, and provides them to the terminals T1 to Tn upon request. This service data is displayed on the data display unit 740.

The data storage unit 730 is composed of a ROM and a RAM, and the gas / water readings transmitted from the central processing unit 720 are classified into monthly, weekly, nightly, date, time zone, and the like, and are stored in real time. In addition, the data storage unit 730 stores a private encryption key. In addition, the data storage unit 730 stores service data provided from the central processing unit 720, in particular, content data having a large capacity.

The control input unit 750 provides an interface between the subscriber and the indoor information control devices D1 to Dm so that the subscriber can request a service through the indoor information control devices D1 to Dm. The subscriber operates the subscriber operation button unit 750a shown in FIG. 7A to request service data, that is, a service such as service / content.

The encryption key registration initiation unit 780 switches the state of the indoor information control devices D1 to Dm to the registration standby mode in order to register the private encryption keys K1 to Km in the indoor information control devices D1 to Dm. The subscriber closes the remote controller 100, which is an encryption key registration device, to the wireless communication port unit 761 of the indoor information control devices D1 to Dm, and then registers an encryption key registration start pin installed in the indoor information control devices D1 to Dm. 7B) (see FIG. 7B). As a result, the indoor information control devices D1 to Dm prepare to store the private encryption keys K1 to Km. 7B is a side view of the indoor information control devices D1 to Dm viewed from the side.

The data display unit 740 displays information (including service fee information) about the service that the subscriber wants to request or the service being requested. In addition, various other service data are displayed.

On the other hand, as shown in Figure 7a LED display unit 790 is installed next to the data display unit 740 to indicate whether the service provided by the subscriber through the ON / OFF (ON / OFF), LED The faster the flashing speed indicates that the service fee is higher, and the lower the speed at which the LED blinks, the lower the service fee is.

[terminal]

The terminals T1 to Tn are gas / water meters having a power line communication module embedded therein to perform high-speed power line communication with the indoor information control devices D1 to Dm and the meter gateways M1 to Mm through the indoor lead wire 90. And it includes a sensor, an actuator (actuator), a home appliance, a wiring device (outlet), a lamp, a computer, a VoIP phone, an IP camera, a security device with a built-in power line communication modem. For example, the home appliance may be an air conditioner, a refrigerator, a TV, an audio, or the like. As described above, the terminals T1 to Tn perform high-speed power line communication with the indoor information control devices D1 to Dm and the meter gateways M1 to Mm through a power line communication modem or a power line communication module. In addition, the terminals T1 to Tn share the same private encryption key with the meter gateways M1 to Mm and the terminals T1 to Tn in the same manner as the home information control devices D1 to Dm, and share data and decrypt data in common. Perform

For example, as illustrated in FIG. 8, the terminals T1 to Tn may include a power line communication module unit 810, a central processing unit 820, a data storage unit 830, an LED display unit 840, and a wireless data communication module unit. 850. Here, the terminals T1 to Tn illustrated in FIG. 8 are components that are commonly required for all the terminals T1 to Tn regardless of the type of terminal for power line communication.

The power line communication module unit 810 detects various data such as service data, control signals, or Internet connection data transmitted through the indoor lead wire 90. Then, a variety of data such as meter reading data, service request signal is sent to the indoor incoming line (90). The power line communication module unit 810 includes a power line coupler 811, a reception filter unit 812, a reception amplifier unit 813, a power line communication unit 814, a transmission filter unit 815, and a transmission amplifier unit 816. do.

The wireless data communication module unit 850 is a wireless infrared communication module unit and receives a corresponding private encryption key among private encryption keys K1 to Km from a mobile encryption key registration device. Here, as described above, a mobile encryption key registration device may be a PDA, a notebook, or a remote controller 100 in which a wireless infrared communication device is embedded. The wireless data communication module unit 850 includes a wireless communication port unit 851, a reception filter unit 852, a reception amplifier unit 853, a wireless data communication unit 854, a transmission filter unit 855, and a transmission amplifier unit ( 856). In addition, the wireless data communication module unit 850 may perform wireless communication with a wireless communication device used separately by a subscriber. That is, it provides a wireless interface between the subscriber and the terminals (T1 to Tn).

The central processing unit 820 stores any one of the private encryption keys K1 to Km transmitted from the receiving port of the wireless data communication module unit 840 in the ROM of the data storage unit 830. The private encryption key stored in the data storage unit 830 performs data communication with the corresponding meter gateways and the terminals T1 through Tn among the meter gateways M1 through Mm. In addition, the central processing unit 820 stores the service data transmitted from the power line communication module unit 810 in the data storage unit 830, or transmits to a corresponding communication device, such as a computer, a VoIP phone, an IP camera or a security device. In addition, the central processing unit 820 stores the gas / water readings read through the gas / water meter in the data storage unit 830.

The data storage unit 830 is composed of a ROM and a RAM, and the gas / water readings transmitted from the central processing unit 820 are classified into monthly, weekly, nightly, date, time zone, and the like, and are stored in real time. In addition, the data storage unit 830 stores a private encryption key. In addition, the data storage unit 830 may store service data provided from the central processing unit 820, particularly content data having a large capacity.

The LED display unit 840 indicates whether or not the service provided by the subscriber through the on / off, the faster the speed of the LED blinks indicating that the service fee is higher, the lower the speed of the LED blinks It also has a function of indicating that the lower the fee of the service provided.

Meanwhile, a description will be given of a mobile encryption key registration apparatus with reference to FIGS. 9 and 10. 9 is a configuration diagram of a remote controller 100 among mobile encryption key registration devices, and FIG. 10 is an external view of the remote controller 100 having the configuration of FIG. 9.

As shown in FIG. 9, the remote controller 100 includes a wireless data communication module 110, a central processing unit 120, a data storage unit 130, a status display unit 150, an operation control input unit 160, and a power supply unit ( 170). In addition, the remote controller 100 may further include a status display unit 150.

The wireless data communication module unit 110 is a wireless infrared communication module unit, and the wireless data communication module unit 540 of the local information control device 50 shown in FIG. 3 or the meter gateways M1 to Mm shown in FIG. 4. Wireless infrared communication is performed with the wireless data communication module unit 623 of FIG. 8 or the wireless data communication module unit 810 of the terminals T1 to Tn shown in FIG. 8. The wireless data communication module unit 110 includes a wireless communication port unit 111, a reception filter unit 112, a reception amplifier unit 113, a wireless data communication unit 114, a transmission filter unit 115, and a transmission amplifier unit ( 116).

The central processing unit 120 withdraws the common encryption key K0 and / or the private encryption keys K1 to Km stored in the ROM, which is a nonvolatile memory of the data storage unit 130, under the control of the operation control input unit 160. The common encryption key K0 and / or the private encryption keys K1 to Km provided from the wireless data communication module unit 110 are provided to the ROM of the data storage unit 130 while being provided to the wireless data communication module unit 110. Save it. The central processing unit 120 displays the write (W) or read (R) process of the common encryption key K0 and / or the private encryption keys K1 to Km on the status display unit 150. In addition, the central processing unit 120 may display such a writing or reading process through the data display unit 140.

The data storage unit 130 is composed of a ROM and a RAM. The ROM stores a common encryption key K0 and / or private encryption keys K1 to Km at or after the remote controller 100 is manufactured. For example, when the common encryption key K0 and the private encryption key K1 are registered in the meter gateway M1, that is, the data encryption unit 130 of the remote controller 100 provided to one subscriber has a common password. The key K0 and the private encryption key K1 are stored. On the other hand, if you want to register the common encryption key (K0) in the local information control device 50, all of the common encryption key (K0) is stored in the data storage unit 130 of the remote control (100).

The status display unit 150 is composed of at least one LED as shown in Figure 10, and displays the writing process or reading process of the common encryption key (K0) and / or private encryption keys (K1 to Km). For example, the red light emits light when the writing or reading process fails, and the green light emits light when the writing or reading process is successful.

The operation control input unit 160 includes an encryption key writing control unit 161 and an encryption key reading control unit 162. The encryption key writing control unit 161 controls the central processing unit 120 to transmit the common encryption key K0 and / or private encryption keys K1 to Km through the wireless data communication module unit 110 through the meter gateways M1 to M1. Mm), the area information controller 50, the indoor information controllers D1 to Dm, or the terminals T1 to Tn. The encryption key reading control unit 162 controls the central processing unit 120 to control the common encryption key K0 and / or the private encryption key K1 to the meter gateways M1 to Mm through the wireless data communication module unit 110. Control to read Km).

The front part of the remote controller 100 is provided with an encryption key write button 161a and an encryption key read button 162a as shown in FIG. For example, the subscriber moves the wireless communication port 111 of the remote controller 100 to the wireless communication port 6121 of the meter gateways M1 to Mm, and then pushes the encryption key read button 162a to the meter gateway. The common encryption key K0 and / or the private encryption keys K1 to Km stored in the data storage unit 624 of M1 to Mm are downloaded. At this time, when the common encryption key K0 and / or the private encryption keys K1 to Km are normally downloaded and stored in the data storage unit 130, the LED 150 emits green light. Otherwise it emits red light.

On the other hand, as described above, the registration process of the common encryption key (K0) to the local information control device 50 should be performed. Accordingly, hereinafter, the registration process of the common encryption key K0 will be described using the remote controller 100.

First, the case where the common encryption key K0 is stored in the data storage unit 624 of the meter gateways M1 to Mm will be described. The network operator reads the common encryption key K0 stored in the data storage unit 624 of the meter gateways M1 to Mm using, for example, the remote controller 100. That is, the wireless communication port 111 of the remote controller 100 is stored in the data storage unit 624 in proximity to the transmission port unit 6161a of the wireless communication port unit 6161 of the meter gateways M1 to Mm. Read the common encryption key K0. The common encryption key K0 thus read is stored in the data storage 130 of the remote controller 100. Thereafter, the remote controller 100 is approached to the wireless communication port unit 531 of the local information controller 50 to transmit the common encryption key K0 stored in the data storage unit 130 to the local information controller 50. . The common encryption key K0 transmitted to the local information control device 50 is stored in the data storage unit 530.

Another method is not to register the common encryption key K0 at the time of shipment of the meter gateways M1 to Mm as described above, but generate the common encryption key K0 in the local information controller 50. To store in the data storage unit 530. Here, the common encryption key K0 may be provided through wireless communication or wired communication instead of the generation method. In this case, it is possible to register the common encryption key K0 in the local information control device 50 only by a limited administrator, that is, an administrator having authority. That is, as described above, it is also possible to remotely register the access password of the local information control device 50 in the management center. Thereafter, the wireless communication port 111 of the remote controller 100 is approached to the transmission port of the wireless communication port 541 of the local information controller 50, and the common encryption key K0 previously stored in the data storage 530. ). The common encryption key K0 thus read is stored in the data storage 130 of the remote controller 100. Thereafter, the remote controller 100 is brought close to the receiving port portion 6251b of the meter gateways M1 to Mm, and the common encryption key KO stored in the data storage unit 130 is transmitted to the meter gateways M1 to Mm. do. The common encryption key K0 transmitted to the meter gateways M1 to Mm is stored in the data storage unit 624 of the meter gateways M1 to Mm.

On the other hand, the private encryption key (K1 to Km) registration process of the indoor information control devices (D1 to Dm) and the terminals (T1 to Tn) is carried out in the same manner as described above. That is, withdraw the private encryption keys K1 to Km from the meter gateways M1 to Mm using the remote controller 100, and then store the data of the indoor information control devices D1 to Dm and the terminals T1 to Tn. Stored in the units (730, 830).

Hereinafter, a method of transmitting and receiving data according to a preferred embodiment of the present invention will be described with reference to FIGS. 11A and 11B, 12A, and 12B. For convenience of description, data transmission and reception between the local information control device 50 and the meter gateway M1 and data transmission and reception between the meter gateway M1 and the indoor information control device D1 will be described as an example. .

As shown in FIG. 11A, when a message Hello is to be transmitted from the local information controller 50 to the meter gateway K1, the local information controller 50 uses the common encryption key K0. Encrypt the message. The local information controller 50 transmits the encrypted message E _k0 (Hello) to the meter gateway M1. At this time, the encrypted message E _k0 (Hello) is provided to the meter gateway M1 via the outdoor drop line 80. The meter gateway M1 detects the encrypted message E _k0 (Hello) and then decrypts it using the common encryption key K0 to obtain the decrypted message Hello.

As shown in FIG. 11B, when a message Hello is to be transmitted from the meter gateway M1 to the local information controller 50 mutually authenticated with the meter gateway M1, the meter gateway M1. The encryption encrypts the message Hello using the common encryption key K0 and provides it to the local information controller 50 through the outdoor drop line 80. The local information controller 50 receives the encrypted data E _k0 (Hello), and then decrypts the encrypted data E _k0 (Hello) using the common encryption key K0 to decrypt the decrypted message ( Hello).

12A and 12B, data transmission and reception between the meter gateway M1 and the indoor information control device D1 is performed in the same manner as described above. For example, the meter gateway M1 and the indoor information control device D1 perform data encryption / decryption by using a private encryption key K1 that is used in common with each other. That is, data encryption and decryption is performed using the same private encryption key shared between the meter gateway, the indoor information control device, and the terminal connected to each other by the indoor network.

Although the technical spirit of the present invention described above has been described in detail in the preferred embodiments, it should be noted that the above-described preferred embodiments are for the purpose of description and not of limitation. In addition, the present invention will be understood by those of ordinary skill in the art that various embodiments are possible within the scope of the technical idea of the present invention.

As described above, according to the present invention, a service-added meter gateway capable of providing an additional service in addition to the remote meter reading based on the power line communication network, and performing service metering according to the power meter reading and the additional service provision for the remote meter reading ( By providing a meter gateway, it is possible to simultaneously perform power meter reading and service meter reading through a single meter gateway.

In addition, according to the present invention, by operating the additional service functions independently based on the power meter reading and two-way data communication, the additional service metering function is physically independent as well as functional independent while maintaining the power meter reading and power management functions. By providing a service-added meter gateway that can manage power metering and service metering functions independently from one meter gateway, it can provide simple and convenient management and operation for utility managers and network operators.

In addition, according to the present invention, a power line communication system capable of stably performing remote meter reading, supplementary service provision and supplementary service metering using a metered service gateway, and performing data use authentication, data security, and data management stably. By providing, we can expect the effect of providing new business opportunities for utilities in the convergence of the power industry and the telecommunications and service industries. Furthermore, the competition between the existing carrier-oriented network and service industry and the utility-oriented network and service provides consumers with a wider range of high-quality services at lower cost, as well as the telephone network and related equipment and service providers. It is expected to contribute greatly to the vitalization of the equipment, service, and content industries, as it is expected to broaden the choice of power grids.

Claims (25)

Performs high-speed power line communication with the local information control device through the subscriber network, performs high-speed power line communication with the terminals of the customer through the home network, and read the metered data read by reading the amount of power used by the customer from the home network In the meter gateway comprising a power meter for providing to the local information control device through a subscriber network, Service / content type, service usage time, service / content download count, content information amount, unit information, and the like, by providing the service data provided from the local information controller through the subscriber network according to the request signal of the terminal to the terminal; And a service metering unit for metering the service data through a control service providing frequency and transmitting the metered service data to the local information controller. The method of claim 1, The service metering unit detects the service classification code, the service request time, the service requester information and the service start time as the first data related to the service start when the type of service data requested by the terminal corresponds to the time type service. And a service classification code, a service termination request time, a service requester information, and a service termination time as second data related to the service data meter to compare and analyze the first and second data to meter the service data. The method of claim 1, When the type of service data requested by the terminal corresponds to a content type service, the service metering unit detects a service classification code, a content service weight classification code, a service request time, and service requester information as data related to service initiation. A service gateway meter for metering the service data according to a service weight classification code. The method of claim 1, The service metering unit detects a service classification code, a service request time and service requester information when the type of service data requested by the terminal corresponds to unit information and a controlled service, and measures the service data according to the number of information requests. Service add-on meter gateway. The method of claim 1, The service metering unit includes a direct current (DC) power supply unit for converting an AC voltage supplied through an outdoor lead wire constituting the subscriber network independently of the power metering unit into a DC voltage to use as an operating power source. way. The method of claim 1, The service metering unit is embedded in a board form inside the service metering unit casing installed on the upper end of the power metering unit casing through a support member so that the power metering unit is detachable from the power metering unit casing built in a board form. Service add-on meter gateway. The method of claim 6, And a cover installed on the front side of the service metering unit casing to be sealed by a sealing member to maintain a sealed state to protect the service metering unit. The method of claim 6, And an operation switch operated by a subscriber in the front portion of the service metering unit casing to switch on / off the power of the service metering unit. The method of claim 6, And a light emitting diode (LED) display configured to display a service state of the service data on a front surface of the service metering unit casing. The method of claim 9, The LED display unit is maintained in an ON state when the service data is serviced, and is maintained in an OFF state when the service data is not serviced, and a speed of blinking according to the service data being serviced is variable. Service-enabled meter gateway. The method of claim 1, And the service metering unit performs data transmission / reception with the area information controller using a common encryption key shared with the area information controller. The method of claim 1, And the service metering unit performs data transmission / reception with the terminal using a private encryption key shared in common with each terminal of the corresponding customer. The method of claim 1, wherein the service metering unit, A power line communication module unit for detecting service data or internet access data transmitted through the subscriber network or the home network, and sending the service meter reading data or the internet access data to the subscriber network; A common encryption key shared in common with the local information control device and a private encryption key shared in common with each terminal of a corresponding customer are provided from an encryption key registration device capable of external wireless infrared communication, or a request of the encryption key registration device. A wireless data communication module unit for providing the common encryption key and the private encryption key to the encryption key registration device; Decoded encrypted data of the area information control device provided through the subscriber network using the common encryption key transmitted from the wireless data communication module unit, or data provided to the area information control device through the subscriber network. Encrypt the data and decrypt the encrypted data of the terminal provided through the indoor network using the private encryption key transmitted from the wireless data communication module, or encrypt the data provided to the terminal through the domestic network. A central processing unit; A data storage unit including a non-volatile memory storing the common encryption key and the private encryption key received through the wireless data communication module unit and temporarily storing the metering data and the service data detected through the power line communication module unit; A data display unit displaying the transmission / reception state of the service data in real time; And The service data detected through the power line communication module unit is provided, and the service data is received through the service / content type, the service usage time, the service download frequency, the content information amount, the unit information, and the controlled service. A service add-on meter gateway that includes a service / content data meter to meter service data. In the casing structure of the service-added meter gateway of claim 1, A terminal casing in which the input terminal through which the outdoor lead wire constituting the subscriber network is drawn in and the output terminal through which the indoor lead wire constituting the indoor network is drawn out are arranged in parallel with each other; An electric power metering casing which is fastened to an upper end of the terminal casing, the electric power metering unit is built-in, and a front cover is fastened by a first sealing member to protect the electric power metering unit; And The service metering part is detached through the upper end and the support member of the power metering part casing, the service metering part is built in, and the front part includes a service metering part casing provided with a second cover which is fastened by a second sealing member to protect the service metering part. Casing structure of service-added meter gateway. The method of claim 14, The support member is provided in a protruding form at the upper end of the power metering casing, and inserted into a support groove provided at the lower end of the service metering casing and fastened to the service metering casing to be engaged with the service metering casing. rescue. The method of claim 14, The second sealing member is a casing structure of the service-added meter gateway to fasten the first fastening member installed on the upper end of the first cover and the second fastening member provided on the lower end of the second cover. A power line communication system using the service gateway of claim 1. The method of claim 17, The home office performs power line communication with the plurality of terminals of a corresponding customer through the home network, and provides an interface with a subscriber to request the service data to the service type meter gateway in response to the service data request of the subscriber. Information control apparatus; And Perform data communication with the local information controller through a data communication network, provide service data corresponding to a service request of the service-added meter gateway, and read the meter data and the meter service data provided from the local information controller. Powerline communication system further comprising an external server for charging based on. The method of claim 18, The service supplementary meter gateway is a power line communication system for performing data transmission and reception with the premises information control device and the plurality of terminals using a private encryption key in the premises network. The method of claim 19, The private encryption key is registered in the service additional meter gateway, the indoor information control device and the plurality of terminals through an encryption key registration device capable of wireless infrared communication. The method of claim 17, The service additional meter gateway is a power line communication system for performing data transmission and reception with the area information control device using a common encryption key in the subscriber network. The method of claim 21, The common encryption key is a power line communication system registered in the service additional meter gateway and the local information control device through a cryptographic key registration device capable of wireless infrared communication. The method of claim 20 or 22, The encryption key registration device is a PDA (Personal Digital Assistant) capable of wireless infrared communication, notebook or remote control power line communication system. The method of claim 23, wherein the remote control, An operation control input unit operated by a subscriber's operation to control the writing or reading of the common encryption key and / or the private encryption key; Read the common cryptographic key and / or the private cryptographic key transmitted from the wireless meter port of the service supplementary meter gateway or the local information controller, or read the common cryptographic key and / or the private cryptographic key A wireless data communication module unit for writing to a meter gateway or a wireless infrared port unit of the local information controller; A data storage unit for storing the common encryption key and / or the private encryption key; A status display unit displaying a writing process or a reading process of the common encryption key and / or the private encryption key; And The common encryption key and / or the private encryption key transmitted from the wireless data communication module unit are stored in the data storage unit under the control of the operation control input unit, or the common encryption key and / or stored in the data storage unit. And a central processing unit for extracting the private encryption key and providing the private encryption key to the wireless data communication module unit. The method of claim 24, And the status display unit comprises an LED, configured to emit red light when the writing process or the reading process fails, and to emit green light when the writing process or the reading process is successful.