KR19990084896A - Value transfer and value storage method and value storage type watt hour meter using it - Google Patents

Abstract

The present invention relates to a new concept of value storage type watt hour meter, in which a power supplier, a power seller, or a power reseller server transmits a value through a power line using a built-in power modem, The value received through the power modem is stored in the value storage module and the value is reduced according to the power consumption to omit the meter reading, usage calculation, bill printing, shipping and settlement procedures, omit account receivables and delinquent payment processing procedures, To a value transmission and value storage type watt hour meter capable of reducing the power supply cost of the power user and maximizing the profitability of the power supplier. Added value can be transmitted through value storage type balance system, value added is transmitted, stored IC card is connected to other meters such as IC card payment type gas and water which operate offline, so that power value transmission and value added transmission can be done easily and quickly, But it has been improved so that the costs can be drastically reduced.

Description

Value transfer and value storage method and value storage type watt hour meter using it

The present invention relates to a new concept of value storage type watt hour meter technology, and more particularly, to a power meter or power resale company that transmits a value through a power modem to a store value module (SVM) A value storing method for storing a value or a value added to an IC card, and a prepayment and debit method watt-hour meter which does not require metering using the stored value.

Up to now, a conventional wattage meter (Watt / hour meter) measuring and measuring the electricity consumption per hour for a certain period of time has been used in homes, offices, public buildings, and all the facilities using electricity. This first-generation watt-hour meter visits the installation site of the watt-hour meter installed at each home or business from the supplier side and visually confirms the difference from the previous month's usage to the meter reading point, that is, After the bill is printed and mailed to the user through the computerized processing procedure of calculation, the user side must pay the paper to the bank and pay the paper, and the settlement of the supply and use result should be completed. It is operating in a very complex and costly manner, such as sending out invoices once.

As the proportion of the above costs in power supply costs such as labor intolerance due to the obsolescence avoidance phenomenon and increase in the labor cost of the meteoroid workers has increased, the second generation product remote The meter reading meter has been considered as a new meter reading method and is being applied in a limited manner. However, such remote meter reading can reduce the visit cost and labor cost of the probe, but the problems such as the computerized processing of the usage amount and the processing procedure of the bill payment and the account receivable and the arrears fee are left as they are. Costs such as gas, water meter and remote meter reading center server operation, telecommunication facilities and operation cost burden due to communication function for remote meter reading when operating in connection with gas, water meter, Because of the factors, both the supplier and the user were forced to avoid.

Therefore, it is possible to consider a third-generation IC card payment type watt hour meter which does not require meter reading. Although the watt-hour meter of the IC card payment method can solve the problems of the first and second generation watt-hour meters to a certain extent, its effectiveness is dependent on how to implement the process of recharging and setting the value information on the IC card, There was a problem that when the information was completely consumed and the power was cut off, the risk of an exceptional accident could not be excluded.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a power meter and a power meter, Value Saving Wattmeters By storing value in SVM or transmitting and storing value-added information to IC card, power supplier and power reseller can increase operation efficiency and reduce cost drastically. Thereby providing a value transmission and value storage method that enables the supplier side to generate high added value and the user side to drastically reduce the power price.

It is another object of the present invention to provide a method and system for providing value value information and money value information transferred through a power modem by applying a principle of value transfer and value storage in combination with an IC card electronic wallet, , A calorimeter, and so on, which can be used in connection with all the meters in the home.

Another aspect of the present invention is to provide a method and system for transmitting and storing amount value information to an IC card by communicating with a host of a certification authority through a power modem to increase the efficiency of operation by a power supplier or a power reseller, It is possible to cut down the power cost of the user by drastically reducing the related incident cost, to implement the power consumption input for a certain period, to omit calculation of the usage amount, to omit the server operation for bill printing process, And to provide a storage type watt hour meter.

Another object of the present invention is to completely eliminate all the problems of the first, second and third generation watt-hour meters, recharge the value quickly and conveniently, and use the value-charging path to add value to the IC card The present invention is to provide an improved value storage type watt hour meter capable of maximizing the efficiency of various businesses by expanding it to various meters such as gas, water, and calorimeter.

1 is a flowchart illustrating a method of transmitting and storing a value according to the present invention.

FIG. 2 is a flowchart for explaining the flow of the multi-level differential charge mode adjustment command (power charge system conversion) according to time, day, month, and season applied to the value storage watt-hour meter of the present invention.

3 is a flowchart illustrating a procedure for monitoring unusual power consumption or preventing illegal users by comparing the total power consumption per unit time based on the aggregation of daily, weekly, and monthly unit time usage applied to the watt-hour meter of the present invention .

4 is a schematic diagram for explaining a signature generation method and an encryption method applied to the present invention.

5 is a block diagram illustrating an internal configuration of a value storage watt-hour meter according to the present invention.

FIG. 6 is a diagram illustrating a flow of value information in the system according to the present invention.

7 is an exploded perspective view showing the appearance of the value storage type watt hour meter of the present invention.

Description of the Related Art

1 ... Latch relay 2 ... Shunt resistor

3 ... Conductivity sensor, 4 ... Buzzer

5 ... value / value-added storage IC card, 6 ... voltage divider

7 ... V-ADC1, V-ADC2 8 ... I-ADC1, I-ADC2

9 ... power consumption operation circuit, 10 ... token exchanger

11 ... RTC and power consumption table, 12 ... IC card read / write section

13 ... power modem, 14 ... AC / DC power supply unit

15 ... non-volatile memory, 16 ... security bus structure value storage unit

17 ... LCD display, 18 ... Power line input / output terminal

19 ... Arrester, 20 ... Digital intercom

21 ... Value transfer request keypad, 60 ... IC card slot

62 ... Confirmation / disassembly check seal nut, 64 ... Protective cap

66 ... Two-port input and output terminals.

In order to achieve the above object, according to the present invention, there is provided a wireless communication system, comprising: a wireless communication unit for communicating with a server on a power supply side through a power modem provided in a watt hour meter, storing value information in a value storing module in the watt hour meter, It provides a value-saving watt-hour meter that stops power supply when the scale is exhausted.

According to an aspect of the present invention, there is provided a value storing method for storing value information in a value storing module in the value storing watt-hour meter through communication between a host and each terminal through a power modem provided in a value storing watt- (A) generating and sending first random data to a terminal, generating a session key with a key generation algorithm using a terminal unique secret key, generating a first signature value with a signature generation algorithm to compare for terminal authentication Receiving the first random data and generating a session key in the same manner as a host using a terminal unique secret key; (b) a terminal generates a second signature value using a signature generation algorithm, generates second random data, and sends the second random data to the host, and the host authenticates the terminal by comparing the first and second signature values, The host generates a third signature value and sends it to the terminal together with the amount information; (c) the terminal receives the third signature value and the amount information from the host, generates a fourth signature value, verifies the host by comparing the third and fourth signature values, and if the host is authenticated, Decrypting the amount information to increase the value, and transferring a value obtained by encrypting the balance and the terminal ID using an encryption algorithm to the host; And (d) the terminal authenticates the terminal again by comparing the terminal ID obtained from the decrypted result with the terminal ID obtained by decrypting and storing the decrypted value, and if the authentication is successful, backing up the balance in the record file And provides a storage method.

According to another aspect of the present invention, there is provided a power meter including a power line input / output terminal and measuring and measuring a used power amount, the power meter including: a power consumption calculation unit for measuring a voltage and a current of a power line to calculate a used power; A power modem for data communication between the host and the terminal via the power line; CPUs, Secure Access Modules (SAMs) that store cryptographic keys and cryptographic algorithms for storing values, Store Value Modules (SVMs) that store value, Value storage, hacking, excludes cryptographic attacks, and when the token is requested by the SVM, it can only be received after the authentication process of the SAM. An on / off latch relay switch for interrupting power supply in accordance with a result of the balance of the SVM; And a token exchanger for reducing a token from the SVM input value according to the amount of power consumed per unit time and requesting a new token from the SVM when the internal token is consumed, To provide a value-saving watt-hour meter.

Preferably, an IC card to be used for another meter such as water, gas, or calorimeter is inserted into the watt hour meter to receive value online from the host and to record and transmit the transferred value to the inserted IC card. And further comprising:

Preferably, the IC card read / write section has a communication port composed of eight terminals defined in ISO 7816 Part 2 such as Vcc, Clk, DIO, Reset, and Gnd for synchronous and asynchronous communication with the IC card in accordance with ISO 7816 It is possible to store the electric power related value through the IC card, and it is applied to the water, gas, and calorimeter adopting the IC card method which records the added value of the gas, water, etc. on the IC card through the power modem and operates offline.

Preferably, the watt hour meter includes an AC / DC converter for supplying an operating voltage required by the watt hour meter; When the latch relay is cut off, a sensor is in a normal state when the output of the sensor is " 0 " Further comprising a buzzer for requesting a new token in the SVM after the token exchanger balance is exhausted, generating an audible alarm when the last token is received, and guiding the value transfer and value storage to the power user.

Preferably, the power consumption calculation unit includes: a shunt resistor unit for measuring an AC current amount; A voltage divider for connecting two resistors in series and selecting a voltage range at a ratio of two resistors in order to adjust an AC voltage of the power line to an input voltage range of the voltage meter; A current analog-to-digital converter for converting an alternating current signal flowing in the shunt resistor into a 16-bit or 20-bit digital signal; And a voltage analog-to-digital converter for converting the AC voltage value analog signal of the voltage division unit into a 16-bit digital signal, compares the phases of the voltage and the current to calculate angles that deviate from the phase agreements, And outputs the output signal.

Preferably, the watt-hour meter is a power meter that uses a multi-stage power usage fee differently depending on the power supply status such as 50%, 75%, 100%, 150%, 200% And a power consumption table which is a charge mode table.

Preferably, the watt-hour meter stores a unique 3-byte ID number and records the current state of power use for a predetermined period of time, day of week, month, etc. to remotely monitor a challenge or abnormal power consumption, And a nonvolatile memory.

Preferably, the watt-hour meter includes an LCD display for displaying the balance of the value, the transmission status, the real-time power consumption status and the accumulated power usage status by a liquid crystal so that the user can visually identify the balance, If the SVM drops below a certain level for a user who has not been able to do so, the buzzer beeps.

The value storage type watt hour meter of the present invention includes a digital interphone capable of communicating with a person in charge of a host server by voice or transmitting a voice message for convenience of storing value of a user and a keypad for directly requesting a user to store a value The present invention can be extended to a simple and reliable payment means by the SET electronic commerce procedure using the next generation credit and debit card of EMV '96 in combination with the IC card read / write device.

Preferably, the power line input / output terminal includes a cover and a physical seal for preventing physical tapping, thereby making it difficult to consume electric power or abnormal power consumption.

Preferably, the watt hour meter further includes an arrestor circuit for absorbing a lightning strike or a surge voltage on a power line on the supply side.

Preferably, the watt-hour meter can request a voice message from a service person with a speaker and a keypad switch of a built-in digital interphone, and conversely, a service person transmits a voice message to a subscriber to facilitate a value transmission and storage procedure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in greater detail with reference to the accompanying drawings, in which: FIG. 1 is a block diagram of a value transmission and value storing method according to a first embodiment of the present invention;

The present invention can be applied to both a watt hour meter, a gas meter, a water meter, and a calorimeter that employ a direct debit method and a prepayment method that use an electronic wallet method. In addition, in all communication procedures such as the value transmission and storage of the present invention, a basic encryption algorithm is applied as an example of triple-DES. The communication between the server host and the watt hour meter terminal is as follows. First, the session key (Ks) is created at the server and the terminal. Then, the encryption algorithm triple-decease is applied through the session key. In some cases, it is necessary to generate a signature. In this case, a MAC-CBC using triple-de-esses is used. When storing the value in the watt hour meter terminal, it stores the value storage, the calculation mode table of the power consumption calculation mode, the unit charge, the time to be corrected, etc. When reading the value from the watt hour meter terminal, the balance, day, month, year usage, A mode table (abnormal monitoring), a unit charge (abnormal monitoring), and a timer time (abnormal monitoring) are read.

First, before describing the value transmission and value storing method of the present invention, an example of a signature generation and encryption algorithm applied thereto will be described below with reference to FIG.

Through the communication between the server and the value-storing watt-hour meter, the work of creating the session key (Ks) is first performed at the server and the terminal, and then the encryption algorithm triple-diase is applied through the session key (Ks). You also need a signature generation job, which can use MaxiBy using triple-de-esses. Hereinafter, the signature generation and encryption algorithm will be described in more detail with reference to FIG.

For signatures, the original data size is padded to a multiple of 64 bits in the first step. This is D ₁ , ..., D _N in Fig. In the second step, the 64-bit data value D _n is tripled with the input key K, and the signature value is O ₁ , ..., O _N in the third step. do. At this time, a value obtained by adding each data value (D _n ) to the signature value (O _n-1 ) of the preceding stage except for the first signature value (O ₁ ) is encrypted.

Similarly, in the first step, the size of the original text data is multiplied by 64 bits to form D ₁ ,..., D _N. In the next step 2, the F-encrypt applies triple-de-esses, and the encrypted message is O ₁ + ... + O _N in the third step.

All the keys used here are 128 bits in size. There are three kinds of keys: the host's master key (KH), the unique key (KT) of each terminal, and the session key (Ks) have. The terminal unique key KT is generated from the master key KH of the host and the session key Ks is generated from the terminal unique key KT. The host's master key (KH) and terminal unique key (KT) can be arbitrarily selected by using several sets.

The unique key KT of the terminal is generated by encrypting the ID of the terminal by triple-diverse using the master key KH of the host. The terminal stores the unique key at the production stage and is created at the beginning of the communication by the host. That is, KT = Encript (ID, KH).

The session key (Ks) is generated each time communication is performed. The session key (Ks) is generated by encrypting a random number generated by the host using the terminal inherent key (KT) in a triple-diverse manner. All the encryption performed in the communication process uses the session key (Ks). That is, Ks = Encrypt (R, KT).

In the present invention, it is possible to provide a method of controlling a terminal device, such as (1) a value storing command, (2) a time, day, month, And the algorithm will be described in detail with reference to FIG. 1 to FIG.

First, the flow of the value store command will be described with reference to FIG.

Step 10: The host generates first random data (R1, R2, n) and sends it to the terminal. And generates a session key using a key generation algorithm using a terminal unique secret key (KT [n]). At this time, Ks = Encrypt (R1, KT [n]). And generates a first signature value S1h = Sig (R2, Ks) with a signature generation algorithm for comparison in terminal authentication. The terminal receives the first random data R1, R2, n and generates a session key in the same manner as the host using the terminal unique secret key KT [n]. That is, Ks = Encrypt (R1, KT [n]).

Step 12: The terminal generates the second signature value S1t = Sig (R2, Ks) with the signature generation algorithm, generates the second random data (R3), and sends it to the host. The host can authenticate the terminal by comparing S1h with S1t. When the terminal is authenticated, the host generates a third signature value of S2h = Sig (H + R3 + EnAmnt, Ks) and sends it to the terminal together with the encrypted total amount information EnAmnt. Where H is a header indicating the value store command.

Step 14: The terminal can authenticate the host by generating a fourth signature value of S2t = Sig (H + R3 + EnAmnt, Ks) and comparing S2h and S2t. When the host is authenticated, the terminal increases the value and encrypts Balance + ID, such as M = Encrypt (Balance + ID, Ks), and passes the password value M to the host.

Step 16: The host decrypts the password value M such as Balance '+ ID' = Decrypt (M, Ks) to verify the terminal once again by comparing the ID 'and the ID. If the authentication is successful, the host backs up the balance in the record file .

Next, referring to FIG. 2, the flow of time, day of week, month, seasonal differential fare mode adjustment command (charge system conversion) will be described.

Step 20: The host generates first random data (R1, R2, n) and sends it to the terminal. And generates a session key using a key generation algorithm using a terminal unique secret key (KT [n]). That is, Ks = Encrypt (R1, KT [n]). And generates a first signature value S1h = Sig (R2, Ks) with a signature generation algorithm for comparison in terminal authentication. The terminal receives the first random data R1, R2, n and generates a session key in the same manner as the host using the terminal unique secret key KT [n]. That is, Ks = Encrypt (R1, KT [n]).

Step 22: The terminal generates a second signature value S1t = Sig (R2, Ks) with a signature generation algorithm, and generates second random data (Random Data) R3 to the host. The host can authenticate the terminal by comparing S1h with S1t. When the terminal is authenticated, the host generates a third signature value of S2h = Sig (H + R3 + Mode + Unit, Ks) and sends the mode information and the unit charge information unit together to the terminal.

Step 24: The terminal can authenticate the host by generating a fourth signature value of S2t = Sig (H + R3 + Mode + Unit, Ks) and comparing S2h and S2t. Once the host is authenticated, the terminal converts the tariff and encrypts Balance + ID, such as M = Encrypt (Balance + ID, Ks), and passes the password value M to the host.

Step 26: The host decrypts the password value M such as Balance '+ ID' = Decrypt (M, Ks) and compares the ID 'with the ID so that the terminal is once again authenticated. If the authentication is successful, the balance is backed up to the record file .

Finally, referring to FIG. 3, the flow of daily, weekly, monthly, and timer information confirmation commands (abnormal monitoring) will be described in detail.

Step 30: The host generates first random data (R1, R2, n) and sends it to the terminal. And generates a session key using a key generation algorithm using a terminal unique secret key (KT [n]). That is, Ks = Encrypt (R1, KT [n]). And generates a first signature value S1h = Sig (R2, Ks) with a signature generation algorithm for comparison in terminal authentication. The terminal receives the first random data (R1, R2, n) and generates a session key in the same manner as the host using the terminal unique secret key KT [n]. That is, Ks = Encrypt (R1, KT [n]).

Step 32: The terminal generates a second signature value S1t = Sig (R2, Ks) with a signature generation algorithm, generates second random data (R3), and sends it to the host. The host can authenticate the terminal by comparing S1h with S1t. When the terminal is authenticated, the host generates a third signature value of S2h = Sig (H + R3 + Time, Ks) and sends it to the terminal with time.

Step 34: The terminal can authenticate the host by generating a fourth signature value of S2t = Sig (H + R3 + Time, Ks) and comparing S2h with S2t. When the host is authenticated, the terminal encrypts an information file (Info) including a log, a differential charge mode table (ModeTB), a terminal time (Timer), a balance balance and an ID.

That is, the terminal encrypts Info with M = Encrypt (Info, Ks) and passes the password value M to the host. Where Info = log + ModeTB + Balance + ID.

Step 36: The host decrypts the password value M such as Info '= Decrypt (M, Ks) and compares the ID with ID. Once the terminal is authenticated once again and authenticated, the record file can be used for daily, weekly, Backup and verify timer information.

In the foregoing, the value transmission and value storage encryption algorithm applied to the present invention has been described. However, the following considerations apply to an actual watt-hour meter.

The maximum number of value-saving watt-hour meters that can be connected to one pillar transformer is limited to a maximum of 256. In a pillar transformer that converts 3.3 KV to 220 V supply voltage, one LS (Local Service & Surveillance) manages 256 value-wise watt-hour meters. LSs with different numbers are connected to the secondary side of several pillar- One AS (Area Service & Surveillance) connecting 256 LSs can manage a total of 65536 value-saved watt-hour meters. In managing these 256 ASs, one local server can manage a total of 16 million servers in a tree structure. However, considering the performance and efficiency of the servers, the number of value-saving watt-hour meters However, a 3-byte ID is given to the power modem and the watt-hour meter microcomputer in case a signal is passed to the other 220V side of the general power modem user and the pillar-type transformer. The microcomputer has a bus scrambling function to prevent theft by protecting the encryption algorithm and the encryption key, or to selectively use an IC card SAM in the form of SIM (Subscriber Identification Module). The calculation of the power consumption, the token tank and the display may be performed using a separate microcontroller. At this time, when the watt hour meter communicates with the host, check that the LCD display and power usage calculation are not affected. Consider that there is a time limitation in providing visual information to the watt-hour meter. That is, assuming that 1 second is required to transmit visual information to one household, it takes 1 hour for 3600 households. The watt-hour meter itself is equipped with a real-time clock and applies a differential charge according to the time, and corrects and monitors the normal time from time to time. When power modem is connected to PC and tapping or hacking is done, abnormal power usage monitoring or digital sealing is done.

The digital seal is a system that is implemented by combining software and hardware. The terminal transmits daily, weekly, monthly, and annual usage data to the server with 2.44 kilobytes of information, and the server records the information in the DB, The digital seal is used to monitor abnormal power usage by comparing with the total usage amount of power by computing with information. When the voltage is applied to the take-out terminal while the latch relay is shut off, And a system for transmitting information.

The power usage details of the server can be estimated by estimating power usage by day, day, month, and season based on hourly, day, month, and seasonal power use aggregates. .

If the circuit breaker cuts off the power supply and the stored value is exhausted, it is possible to check whether the load is low or not. , That is, the challenge.

For value added transmission and storage through power modem, the watt-hour meter, the gas meter meter, the water meter meter, and the calorimeter meter are classified into the SVM and the IC card.

Hereinafter, the construction and operation of a watt-hour meter constructed in consideration of the above-described matters will be described in more detail with reference to FIG. 5 to FIG.

Figure 5 shows a value transfer and value storage watt-hour meter via a power line modem. In Fig. 5, the latch relay 1 is an on / off latch type relay switch for interrupting power supply. The Shunt Resistor (2) measures the alternating current with a manganese resistance of 0.1 milliohms. The power consumption sensor 3 is in a normal state when the output of the sensor is "0" when the latch relay 1 is shut off. When the output of the sensor 1 is "1" It is a sensor circuit that senses that a path is being challenged. The buzzer 4 requests a new token in the value storage module SVM after the balance of the token changer 10 has been exhausted and generates an audible alarm sound when the last token is received to inform the power user Value transfer and value storage. The value / value-added storage IC card 5 registers the CSN (Card Serial Number) of the subscriber IC card in the operator DB by the master key of the power reseller managing the value storage type watt hour meter, and when there is a value transfer request to the server , To check illegitimate use by checking whether CSN is registered legitimately.

Voltage Divider (6) is a voltage divider that adjusts the 117/220/240 V AC voltage to the input voltage range of a voltage analog-to-digital converter (V-ADC). It connects two resistors in series, To select the voltage range. The V-ADC 7 is a circuit for converting an AC voltage analog signal into a 16-bit digital signal. A current analog-to-digital converter (I-ADC) 8 is a circuit for converting an alternating current signal flowing in the shunt resistor 2 into a 16-bit or 20-bit digital signal. The power consumption calculation circuit 9 calculates a power Watt by multiplying the digital signal of the V-ADC 7 and the I-ADC 8, and then converts the power Watt into a pulse number and a width signal. 9) can apply the differential charge to instantaneous use of the inductive load by comparing the phase of the voltage and the current to calculate the phase difference and the offset angle and output the phase difference signal. The token exchanger 10 reduces the token according to the amount of power consumed per unit time (Watt / hour), and when a token in the token exchanger 10 is exhausted, the token exchanger 10 requests a new token in the token tank 10 times, Reduce it accordingly. If the 10x unit token tank is exhausted, it operates with a structure to replenish the 10x unit token tank by requiring 100x unit tokens to the value storage module (SVM) to be described later. When a token is requested to the SVM 166, the authentication can be performed only after the authentication process of the SAM 164 is performed. The RTC and the power consumption table 11 are based on a real time clock composed of YYMMDDHHMMSS at the time of day and the power consumption table is 50%, 75%, 100%, 150%, 200% This is a mode table in which multi-level power usage fees are applied differently.

The IC card read / write section 12 according to ISO 7816 is a communication port composed of eight terminals defined in ISO 7816 Part 2, such as Vcc, Clk, DIO, Reset, and Gnd for synchronous and asynchronous communication with an IC card. By inserting a normally issued IC card into the watt hour meter, a multipurpose value such as electric power, gas, water, hot water, calorie, pay-TV, etc. can be constructed in one IC card, Record. On the other hand, if the value transmitted from the gas service server is recorded on the IC card through the present value transmission and value storage type watt hour meter, the card is taken out and inserted into the gas meter, the value information is transferred to the gas meter, It can be operated offline.

A power line modem 13 is a modem for data communication through a power line, and each modem is set to one address PLMID (Power Line Modem ID) among 256 lines. The AC / DC power supply unit 14 supplies the operating voltage required by the present value storage type watt hour meter. The 3-byte (Byte) ID is the unique number of the value-saving watt-hour meter and is recorded in ROM at the time of production. The nonvolatile memory 15, which can be constituted by a flash memory, records the power consumption details for 24 hours, that is, one day, using the 16-bit information of the power consumption every 60 seconds of the present value storage type watt hour meter, It is a memory that records the status of power usage for a certain period of time, such as one month of power usage information for one week, and remotely monitors the challenge or abnormal power consumption to perform the role of electronic seal. The scrambled bus 16 includes an information storage module (SAM) storing a cryptographic key and a cryptographic algorithm for storing a value including a CPU 162, a SAM 164 and an SVM 166, Store Value Module (SVM), which prevents the use of manipulation of value information, the use of falsified values, and hacking, and excludes cryptographic attacks. The LCD display 17 displays the balance of the value, the transmission status, the real-time power consumption status, and the accumulated power usage status with a liquid crystal so that the user can visually identify the balance. The power line input / output terminal 18 is composed of 1s, 2s, 2L, and 1L, and is formed of a lid for connecting power input and output lines and preventing physical tapping. Arrester (19) is a circuit that absorbs lightning or surge voltage.

The watt-hour meter of the present invention includes the voltage divider 6, the V-ADC 7, the I-ADC 8, the latch relay 1, And shunt resistor 2 according to the number of types of corresponding electric power, two or more types of electric power can be measured. That is, when a corresponding voltage division unit, a V-ADC, the I-ADC, a latch relay, and a shunt resistor are added so that two or more kinds of power source sources can use different voltages selectively or use two or more kinds of power sources at the same time Each current can be separately measured or calculated.

The operation of the value storage watt-hour meter having the above-described configuration will now be described. As described above, the power supply company or the power resale company transmits a value from the host via the power modem 13 to the SVM 166 of each terminal The watt-hour meter calculates a charge according to the power consumption calculated by the power consumption calculator 9, compares the calculated charge with the balance of the value information stored in the SVM 166, and performs the charge adjustment through the token changer 10 . At this time, if the remaining amount of the remaining amount is less than a predetermined amount in the SVM 166, the buzzer 4 sounds to inform the user of the remaining balance state. If the remaining amount is insufficient, the value is stored in the SVM 166 from the host through the above- Or the latch relay 1 is operated to interrupt the power supply. The value storage type watt hour meter of the present invention may store the direct value information in the SVM 166 through communication between the host and the terminal. However, in another embodiment, the value storing type watt hour meter may store electricity, gas, And the power value information stored in the IC card 5 may be transferred and stored in the internal SVM by inserting the water and heat quantity IC card 5 into the value storing type watt hour meter of the present invention.

In other words, the watt-hour meter of the present invention uses a certain amount of power in the value range recorded in the SVM to display information such as the monthly usage amount and the card balance to the liquid crystal display element 17 installed in the watt-hour meter, When the remaining balance of the card remains, the buzzer 4 informs the alarm sound to request the user to transmit the value to the server so that the account can be automatically transferred from the bank account number of the contracted bank or can be paid from the credit card, The value is transmitted to the SVM 166 via the power line and then stored in the SVM 166. When the value of the SVM 166 is consumed, the latch relay 1 To stop the supply of electric power.

As a result, electric power suppliers and electric power resellers can reduce the cost by omitting meter reading labor, computation input and computation, billing printing and dispatching procedures, and payment of electric power usage fees in advance, And the benefit of the difference between the purchase price of electricity and the price of the sale is returned to the benefit of the user for the reduction of the electricity tariff, and the electric utility can enjoy the high value-added business .

When a card is inserted into a terminal by placing a SAM 164 for authenticating the validity of the card in the watt-hour meter in order to prevent the use of the card that has been legitimately issued by a power supplier such as a home or business resident or a power reseller Even when the terminal and the card are subjected to the mutual authentication procedure and the amount information of the card transmits the value information to the terminal, the card and the card operate according to the encryption processing procedure shown in Fig. In order to counteract a cryptographic attack by an external hacker such as disassembling a value storage type watt-hour meter in order to falsify a terminal or a card, a method of volatilizing a cryptographic key in disassembling the meter may be considered. However, So that the amount information or the value can not be increased by having only the reduction key for reducing the value information according to the consumption amount of the information. In particular, in the present invention, when a user / subscriber accesses an ARS server through a telephone or a digital interphone to request a value transfer, the user / subscriber can selectively pay a usage amount such as a credit card, a bank account debit or the like, The value transfer procedure begins. This process can be done over the Internet, especially for people who have never used a computer or an information network at all, but the value stored by a power account / power reseller and a bank's account transfer contract is reduced to a certain size You can also have the value transfer automatically. In particular, when EMV '96 next-generation credit and debit cards are used to make payment request transactions by the SET electronic commerce procedure, the server is the role of the cyber mall and the transactions are recorded in a digital envelope (DE) You may not deny or tamper with the transaction procedure.

The above-described implementation procedures and conditions of the present invention will be described in more detail below.

1) Generation, transmission, and storage of value

Value information is generated by interlocking with the subscriber management database by the master key (Mk) of the electric power seller or the electric power reseller. After passing through AS (Area Service & Surveillance) and LS (Local Service & Surveillance) Select the ID number of the requested subscriber. When the subscriber ID number is called and the communication connection is completed, mutual authentication is performed between the server and the terminal by mutual authentication procedure as described above. When the mutual authentication is completed, the requested amount value information is transmitted. The value information transmitted through the power line is stored in a store value module (SVM).

2) Transfer and storage of value added

Value-added transmission function that can be used in conjunction with a measuring instrument that operates off-line by an IC card without a separate communication line such as gas, water, heat, hot water other than electric power is added to double the utility of the present invention. This added value is made in the same way as the above-mentioned generation and transmission procedure, and is stored in the IC card instead of being stored in the watt hour meter. Value-added information such as gas, water, hot water, and heat amount stored in the IC card by this procedure can be stored in the IC card offline water supply, which can accommodate the IC card as disclosed in Korean Patent Application Nos. 98-6947 and 98-6948 It can be inserted into the meter and operated to maximize the efficiency of the operation.

3) Consumption of value information

The value-of-money information stored in the SVM 166 is reduced to a few milliwatts, a few watts, and a few kilowatts by the token exchanger (TE) 10 according to the power consumption, If the unit token is exhausted, the stored amount value information is reduced by a procedure requiring a new token.

4) Different application of power consumption rate

The power usage mode that can differently apply the multi-stage power usage charge according to the weekday, holiday time, season, and month using power is automatically selected by the program and applied automatically. For example, 75% discount on weekdays, 100% discount on weekdays, 50% discount on late night, 200% premium on daily hours, Saturdays before and after weekdays, and 300% surcharge on 2 ~ The power consumption mode table 11 to which a variety of usage fees such as time, day, month, and season can be applied differently according to power supply / use characteristics is applied by the real time clock RTC, ) To apply the stored value differently, thereby optimizing power consumption at the time of power generation to optimize the supply and demand of power by increasing efficiency of power generation and supply, We have to set up conditions to be able to.

5) Balance confirmation and car terminal

The amount value information of the SVM 166 is displayed on a display device such as a liquid crystal so that the user can check the balance at any time. When the value of the money is exhausted, the token exchanger alerts the audible frequency when the token of the last unit remains Inform the user. If the value of the value is not recharged until the last token is consumed, the power supply is shut off by sending a signal to shut off the latch relay in series with the power line.

In order to satisfy the above-mentioned various implementation procedures and conditions, the present invention is based on the following structure and principle, and various gas, which can transmit added value by an IC card based on a value transmission and value storage watt- Can be used in conjunction with water meter.

The value storage type watt hour meter of the present invention measures the voltage (V) and the current (A) in real time, calculates the amount of power (W) through the AD converter (9), calculates power consumption per unit time, The token exchange unit 10 reduces the token according to the amount of power consumed per unit time and requests the new value information when the token is consumed. In addition, all the information that the user needs to know, such as the remaining amount of the value information and the power consumption status, is displayed on the liquid crystal display screen 17. When the last value information is converted into the token, And when the internal value information is exhausted, the latch relay 1 is cut off to cut off the power supply.

The mode table (MT) 11, in which the power usage fee can be applied in five or more stages, is 50%, 75%, 100%, and 200% depending on the weekday, , 300%, and so on. That is, even if the same power per unit time is used, the token exchanger (TE) 10 applies the multilevel power usage charge according to the time program defined in the mode table (MT) It is possible to optimize the power consumption at the time of power generation, to reduce the reserve power supply ratio by balancing the supply and demand of the electric power, and to plan the production of electric power, The electricity use rate system gives discounts according to the user's selective use. In the summer, it is possible to give discounts to electric power consumers, such as households and businesses that use electric power at night by introducing a heat storage system, in addition to giving an extra charge when using an air conditioner intensively in all offices.

The value storage type watt hour meter of the present invention has a scramble bus structure in which the CPU 162 and the internal memory can not be deciphered by the general public in order to prevent the stored value from being forged or tampered with, A Secure Access Module (SAM) 164 for embedding an encryption algorithm, and a Store Value Module (SVM) 166 for storing value information. In order to falsify the value information, even if a hacker or a password attacker disassemble the watt hour meter, the information content such as the SAM and the SVM encryption key and the encryption algorithm can not be seen. SAM and SVM in the watt-hour meter can verify and authenticate each other by mutual authentication with the master key (Mk) of the host computer, and then transfer and store value information only by the procedure described above. And the value added information can be transmitted and stored, and the money value information can be stored in the IC card by Mk or the value added information can be stored. When an IC card is inserted into a watt-hour meter, it sends a reset signal to the card, receives an ATR (Answer To Reset) signal, mutually authenticates the legitimacy of the IC card, exchanges value information through the SVM and SAM, The amount of money information is reduced only for the use of the card, and recording of the amount information is recorded by the issuer's separate cryptographic key (Mk). These procedures are performed in compliance with international standards such as physical standards such as ISO 7816 Part1, Part2, Part3, Part4, Part8, Part10 of the international standard, electrical signals, communication protocols and encryption procedures, By storing the encryption key in parallel, one encryption key is updated at a predetermined time interval, and the security system that selectively uses the encryption key prevents the value storage from being falsified and used.

The transmission of value, the transmission of added value, and the legitimate monitoring of value use are done through a power modem, where the user visits a place where the watt hour meter is installed and monitors illegal challenges or abnormal power consumption without visually inspecting the lead or tin seal In order to take a sanction measure, the electric power use information of a predetermined time is recorded in a nonvolatile memory (NVM) These circuits can be periodically monitored by LS and AS, enabling electronic sealing functions without visual confirmation of physical lead.

The value storage watt-hour meter has a 3-byte unique number (SVPMSN), and the power modem 13 communicates with the LS with an M-ID address of 1/256. The server of the power supplier or the resale vendor starts the short distance communication with the value storage type watt hour meter of the subscriber by the addressing procedure of selecting the M-ID of the subscriber who has made the value transfer request (VSPMSN; Value Store Power Meter Serial Number, M -ID; Modem Identification Number).

The subscriber can access the ARS of the electric power retailer or the electric power reseller through a telephone or digital interphone 20 and a keypad 21 to select a credit card or bank account number payment, When a value transmission is requested, the value management server requests value transmission by the payment authorization number (AN) given by the credit card company's server. The power retailer value management server calls M-ID via AS and LS and transmits the value to SVPM by the value storing procedure as described above and stores it.

LS continuously monitors the power consumption of up to 256 value-added watermill (SVPM) subscribers through a power modem connected to a 117V / 220V power line of up to 3km. 1/256 ... n / 256 SVPM in order to check SVPM's internal real-time clock change status and re-adjust, charge system mode adjustment, card's CSN check, value storage balance backup, confirmation of challenge and abnormal power consumption, , Weekly, and monthly power consumption report, aggregate power demand statistics, forecast electricity demand, use it as data to negotiate electricity purchase price, and use it as basic data such as readjusting supply price.

In addition value transmission and storage, gas, water, heat and hot water meters other than electric power are very complicated due to the poor installation environment, so they are composed of weighing instruments that are operated offline by IC card without separate communication line. When the IC card is inserted into the water, gas or calorimeter after storing the added value information transmitted through the storage type watt hour meter in the IC card, the respective value added information is stored in the meter and the token is reduced by the same value reduction procedure, When the information is exhausted, it acts as a principle to shut off the valve to stop the supply. In this way, the added value transmission function that can be used in conjunction with the value transmission and storage type watt hour meter and the value added service is added to double the utility of the present invention. This added value is made in the same way as the above-mentioned generation and transmission procedure, and is stored in the IC card instead of being stored in the watt hour meter. Value-added information such as gas, water, hot water, and heat amount stored in the IC card by this procedure can be stored in an IC card off-line water supply capable of accommodating the IC card disclosed in Korean Patent Application Nos. 98-6947 and 98-6948, So that the efficiency of the operation can be maximized.

Referring to FIG. 6, a value transmission request and a value transmission procedure through a power line modem will be described below.

The subscriber IC card 52 is issued by the master key IC card 51 of the system operator who is the power reseller 50 to the person wishing to receive the IC card. In the field, electricity, gas, water, hot water, calories, etc. are paid by cash or credit card, and the value is stored in the IC card. When the IC card is inserted into the value storage type watt hour meter of the subscriber of the user side 55 so that the power value in the IC card is stored in the watt hour meter and inserted into the gas, water, hot water and calorie meter of the user side 55, . After the primary value storage, the value / value added storage consists of the value transfer procedure through the power modem. Value transfer requirements can be value transmission and value storage via telephone, the Internet, P-ATM (EMV '96), value storage and intelligent watt-hour meters. The transmission and storage of the values are performed by the above-mentioned encryption algorithm executing procedure. The value / value added transmission path obtains the subscriber's history information from the subscriber database information of the host server of the power reseller 50, and selects a payment credit card number, a debit card number, or a bank account number to guarantee the payment by the bank or the VAN company , Generates value information using the SAM's master key, calls subscriber value storage type watt-hour subscriber ID via AS and LS network, and transmits value / value-added information via mutual authentication procedure. LS (Local Surveillance) is a system that enables users to download the time, daily weekly, monthly power usage history information of the value storage type watt hour meter, monitor the power usage status by time, day, monitor the value balance, And monitoring of usage. It is also possible to cause the amount settlement system 54 and the power reseller 50 of the power supplier 53 to carry out the amount settlement in a manner similar to the above-described procedure.

7 is an exploded perspective view showing the external appearance of the value storing type watt hour meter of the present invention. The value storing watt-hour meter of the present invention is provided with an LCD display 17 on the upper part of the front face, Respectively. The power take-in and take-out power line is connected to the lead-out terminal 66, and the lead-out prevention cap 64 is covered for safety and security. A digital interphone 20 and a keypad 21 for value transfer request are provided on the upper surface of the conductive protection cap 64. Further, on one side of the watt-hour meter, an IC card insertion port 60 is formed to insert an IC card so as to store the value in the IC card or to read the recorded value from the IC card. Further, a watt-hour meter 62 is formed in the watt-hour meter to seal the watt-hour meter so that electricity can not be illegally stolen.

As described above, the present invention eliminates the entire process of printing and mailing invoices without inputting and processing all the weighing and measuring instruments such as power, gas, water, and calorimeter without meter reading, It is possible to reduce costs such as processing costs, billing mailing costs, settlement costs, etc., so that the related fee can be reduced.

In addition, while the present invention reduces losses due to receivables and delinquent payments of electric power usage fees, it is possible to create added value in which pre-paid interest income is generated as the value transfer amount is paid by a new procedure such as credit card, The operator can create high added value.

The present invention provides a hybrid watt-hour meter capable of simultaneously solving the economical and security problems of the visiting meter reading and the remote meter reading of the existing watt-hour meter.

Claims (17)

1. A value storing method for storing value information in a value storing module inside a value-storing watt-hour meter through communication between a host and each terminal through a power modem provided in a value-storing watt- (a) generating and sending first random data to a terminal, generating a session key with a key generation algorithm using a terminal unique secret key, generating a first signature value with a signature generation algorithm to compare for terminal authentication, Receiving the first random data and generating a session key in the same manner as a host using a terminal unique secret key; (b) a terminal generates a second signature value using a signature generation algorithm, generates second random data, and sends the second random data to the host, and the host authenticates the terminal by comparing the first and second signature values, The host generates a third signature value and sends it to the terminal together with the amount information; (c) the terminal receives the third signature value and the amount information from the host, generates a fourth signature value, verifies the host by comparing the third and fourth signature values, and if the host is authenticated, Decrypting the amount information to increase the value, and transferring a value obtained by encrypting the balance and the terminal ID using an encryption algorithm to the host; And (d) the host authenticates the terminal once again by comparing the terminal ID obtained from the decrypted result with the terminal ID obtained by decrypting the received password value, and if the terminal is authenticated, backing up the balance to the record file Way. The method according to claim 1, a1) generating a first random data at a host and sending it to a terminal, generating a session key with a key generation algorithm using a terminal unique secret key, generating a first signature value with a signature generation algorithm for comparison at terminal authentication, Receiving a first random data and generating a session key in the same manner as a host using a terminal unique secret key; b1) generating a second signature value with a signature generation algorithm, generating second random data and sending it to the host, and authenticating the terminal by comparing the first and second signature values, and if the terminal is authenticated, Generating a signature value and sending it to a terminal together with mode information (Mode); c1) a terminal receives a third signature value and mode information from the host, generates a fourth signature value, verifies the host by comparing the third and fourth signature values, and if the host is authenticated, Generating a password value by encrypting the mode information and the terminal ID using an encryption algorithm, and sending the password value to the host; d1) The host receives the password value, decrypts it, and compares the stored terminal ID with the terminal ID obtained from the decryption result, and once the terminal is authenticated again, backing up the balance to the record file ≪ / RTI > 3. The method of claim 2, a2) generating a first random data at the host and sending it to a terminal, generating a session key using a key generation algorithm using a terminal unique secret key, generating a first signature value with a signature generation algorithm for comparison at terminal authentication, Receiving a first random data and generating a session key in the same manner as a host using a terminal unique secret key; b2) a terminal generates a second signature value using a signature generation algorithm, generates second random data, and sends the second random data to the host. The host authenticates the terminal by comparing the first and second signature values, Generating a third signature value and sending it to the terminal with Time information; c2) the terminal receives the third signature value and the time information from the host, generates a fourth signature value, verifies the host by comparing the third and fourth signature values, and if the host is authenticated, the terminal uses the encryption algorithm Passing a password value encrypted with a history log file (Logfile) to a host; d2) The host receives the password value, decrypts it, compares the stored terminal ID with the terminal ID obtained from the decryption result, and authenticates the terminal once again. If authentication is performed, the daily, weekly, monthly use and timer information is backed up And a use information confirmation command process including the step of confirming the use of the value. A watt hour meter having a power line input / output terminal and measuring and measuring the amount of power used, A power consumption calculation unit for measuring a voltage and a current of a power line to calculate a used power; A power modem for data communication between the host and the terminal via the power line; CPUs, Secure Access Modules (SAMs) that store cryptographic keys and cryptographic algorithms for storing values, Store Value Modules (SVMs) that store value, Value storage, hacking, excludes cryptographic attacks, and when the token is requested by the SVM, it can only be received after the authentication process of the SAM. An on / off latch relay switch for interrupting power supply in accordance with a result of the balance of the SVM; And And a token exchanger for reducing the token from the SVM input value according to the amount of power consumed per unit time and requesting a new token from the SVM to the token tank when the internal token is consumed and reducing the token according to the amount of power used Watt-hour watt-hour meter. 5. The IC card according to claim 4, wherein an IC card to be used for another meter such as water, gas, or a calorimeter is inserted into the watt hour meter to transmit an online value to the inserted IC card, And a read / write unit. The IC card read / write unit according to claim 5, wherein the IC card read / write unit includes a communication port configured by eight terminals defined in ISO 7816 Part 2, such as Vcc, Clk, DIO, Reset, Gnd for synchronous and asynchronous communication with an IC card in accordance with ISO 7816 It is also applicable to water, gas, and calorimeter that uses IC card method that stores the value of electric power through IC card by recording the added value of gas, water etc. on the IC card through power modem and operates offline. Value storage type watt hour meter. The power meter according to claim 4, wherein the watt hour meter includes an AC / DC converter for supplying an operating voltage required by the watt hour meter; When the latch relay is cut off, a sensor is in a normal state when the output of the sensor is " 0 " Further comprising a buzzer for requesting a new token in the SVM after the token exchanger balance is consumed and generating an audible alarm when the last token is received, Value-saved watt-hour meter. The apparatus of claim 4, wherein the power consumption calculation unit comprises: a shunt resistor unit for measuring an AC current amount; A voltage divider for connecting two resistors in series and selecting a voltage range at a ratio of two resistors in order to adjust an AC voltage of the power line to an input voltage range of the voltage meter; A current analog-to-digital converter for converting an alternating current signal flowing in the shunt resistor into a 16-bit or 20-bit digital signal; And a voltage analog-to-digital converter for converting an AC voltage value analog signal of the voltage divider to a 16-bit digital signal, wherein the phase of the voltage and the current is compared to calculate an angle of deviation from a phase match, And the output of the watt-hour meter. The power meter according to claim 4, wherein the watt-hour meter is configured such that the power consumption table is differentiated according to the power supply status such as 50%, 75%, 100%, 150%, 200% And a power consumption table, which is a power charge mode table. The watt-hour meter as claimed in claim 4, wherein the watt-hour meter stores a unique 3-byte ID number, records the current state of power use for a predetermined period of time, day of the week, month, etc. to remotely monitor a challenge or abnormal power consumption, Wherein said nonvolatile memory includes a nonvolatile memory capable of storing said nonvolatile memory. The method according to claim 4, wherein the watt-hour meter includes an LCD display for displaying a balance, a transmission status, a real-time power consumption status, and a cumulative power usage status of a value in a liquid crystal display Type watt hour meter. The value-saving watt hour meter may be a telephone, an Internet, a P-ATM (EMV '96), a digital intercom, or the like, which can communicate with a person in charge of a host server by voice or transmit a voice message, And a keypad for directly requesting the user to store the value, so that it is possible to use the next generation credit and debit card of EMV '96 in combination with the IC card readout recorder for simple and reliable payment by the SET electronic commerce procedure The watt-hour meter is characterized by the fact that it can be applied to the watt-hour meter. The watt hour meter as claimed in claim 4, wherein the power line input / output terminal of the watt hour meter includes a cover and a physical seal for preventing physical tapping, thereby making it difficult to consume electric power or abnormal power consumption. 5. The watt-hour meter as claimed in claim 4, wherein the watt-hour meter further comprises an arrestor circuit for absorbing a lightning strike or a surge voltage on a power line on a supply side. The transformer according to claim 4, further comprising a current transformer for measuring the total amount of current in the power line of the transformer which reduces the voltage of 3.3 KV to a normal use voltage such as 110 V / 220 V / 240 V, LS (Local Service & Surveillance) equipped with a power modem to communicate with a value-saving watt-hour meter, and an Area Service & Surveillance (AS) that manages up to 256 LS units. 16. The method of claim 15, wherein the host issues an IC card of a subscriber to an IC card having a master key, automatically transmits a value when the subscriber requests value storage according to the procedure, And a server for power reseller and power reseller capable of redetermining a price when power purchase is performed by analyzing aggregate analysis of management and subscriber detailed power usage statuses and each server is connected to a plurality of ASs, LS and value-saved watt-hour meter can be used as a tree structure, value-transfer watt-hour watt-hour meter that plays a role of managing, monitoring, and storing value-saving watt-hour meter. 16. The power supply according to claim 15, wherein at least two kinds of power source sources selectively use different voltages, or a corresponding voltage division unit, a V-ADC, an I-ADC, a latch relay and a shunt resistor Is added so that each current amount can be separately measured or calculated.