KR102047603B1 - Electronic watt hour meter with earthquake detection function and earthquake occurrence management server - Google Patents

Abstract

The present invention relates to an electronic wattmeter having an earthquake detection function, which reduces the number of various safety accidents due to power by forcibly blocking the power supplied to a customer through the electronic wattmeter in the event of an earthquake, and can actively and quickly respond to the earthquake occurrence by spreading earthquake occurrence information in a specific area to pre-registered users or other customers.

Description

Electronic watt hour meter with earthquake detection function and earthquake occurrence management server

The present invention relates to an electronic electricity meter, and more particularly, to measure a seismic sensitivity to check a dangerous state, and in an emergency, a seismic detection function that can cut off power supplied to a customer or propagate it to a user or another customer. It relates to an electronic electricity meter and seismic generation management server.

In general, the AMI system (Advanced Metering Infrastructure System) remotely reads the usage of various meters such as electricity, gas, water, hot water, and heat installed in consumers consuming energy, and automatically collects the information from the host system. In other words, it means a two-way communication infrastructure that analyzes, processes and provides it back to the consumer.

The AMI system is a next generation version of the AMR system (Advanced Meter Reading System) for providing a simple method of collecting energy consumption information of a conventional consumer to a consumer. As an energy metering infrastructure, it is widely used in the electric power field worldwide thanks to the promotion of smart grid introduction.

In the conventional AMI system, the amount of the electronic electricity meter installed on the consumer side is collected by the data concentration unit (DCU) using the slave modem and the master modem for the AMI, and then transmitted to the AMI server.

Here, the AMI server manages configuration information of meter reading devices such as an electronic electricity meter and modem installed for meter reading, acquires and stores meter reading data, and provides usage information of each customer through a web browser. In addition, the data concentrator (DCU) is a device for collecting meter data of the customer-side electronic electricity meter in the AMI system. An electronic electricity meter is a meter that measures and stores the amount of electricity consumed by the customer and provides information through communication.

The present invention is to solve the problems of the prior art as described above, the electronic power meter and earthquake generation management server with an earthquake detection function that can cut off the power supplied to the customer during the earthquake detection or propagate to the user or other customers The purpose is to provide.

An object of the present invention as described above, the electronic wattmeter provided on the lead wire of the customer and includes a power amount measuring unit for measuring the power consumption of the customer, seismic sensitivity measurement sensor unit for measuring the earthquake sensitivity; A power meter controller configured to determine a dangerous state by comparing a preset value and a measured value measured by the earthquake sensitivity measuring sensor unit, and generate a dangerous state flag in a dangerous state; And a communication unit configured to transmit a dangerous state flag generated by the electricity meter control unit to an earthquake occurrence management server.

In the above embodiment, when the risk generation flag is generated more than a predetermined number of times for a predetermined time or continuously generated for a predetermined time, a power interruption unit for forcibly cutting off the power supplied to the customer is further provided. .

In the above embodiment, when the risk generation flag is received from the earthquake generation management server, the electricity meter control unit forcibly drives the power cutoff unit to cut off the power supplied to the customer.

In the above embodiment, the setting unit for setting the earthquake sensitivity that is a criterion for determining whether or not a risk occurs.

In addition, an object of the present invention, the communication unit for receiving a dangerous state flag from the electronic electricity meter of each customer in a specific region registered in advance; A server controller determining whether an earthquake has occurred in a corresponding region by comparing a preset number of customers and a number of customers who receive a dangerous state flag through the communication unit; And determining that an earthquake has occurred in a specific area by the server controller, the earthquake occurrence management server configured to include a communication unit for transmitting an earthquake occurrence alert to a user or a customer registered in advance.

In the above embodiment, the seismic generation management server is a wired communication method of RS485 or RS232 using an AMI (Advanced Metering Infrastructure) system or a wireless communication method of one or more of RF, Zigbee, Rola, Wi-Sun, LTE, NBIOT Receive dangerous status flags from each consumer's electronic wattmeter.

In the above embodiment, when it is determined that an earthquake has occurred in a specific region, the server controller transmits a risk generation flag for notifying the risk of the earthquake to the electricity meter of each consumer located in the corresponding region.

In the above embodiment, when it is determined that the earthquake has occurred in a specific region, the server control unit transmits a risk generation flag for notifying the risk of the earthquake to the electronic electricity meter of the customer who does not receive the danger occurrence flag among the customers located in the specific region. do.

According to the present invention, when the earthquake occurs, by cutting off the power supplied to the customer through the electronic electricity meter, it is possible to reduce the occurrence of various safety accidents due to the power source, by spreading the earthquake occurrence information to a user or another customer registered in advance, the earthquake There is an effective and quick response to the problem.

1 is a schematic diagram illustrating a connection relationship between an electronic electricity meter, an earthquake occurrence management server, and a user terminal according to an exemplary embodiment of the present invention.
FIG. 2 is a configuration diagram of the electronic wattmeter shown in FIG. 1.
3 is a flowchart illustrating an operation of the electronic wattmeter of FIGS. 1 and 2.
4 is a block diagram of an earthquake occurrence management server disclosed in FIG.
FIG. 5 is a flowchart for describing an operation of the earthquake occurrence management server of FIG. 4.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram illustrating a connection relationship between an electronic electricity meter, an earthquake occurrence management server, and a user terminal according to an exemplary embodiment of the present invention.

Referring to FIG. 1, the present invention measures power consumption of a customer, transmits measurement information to a power company, cuts off power supplied to a corresponding customer when measuring an earthquake, and is registered in advance through an earthquake occurrence management server 200. An earthquake generation management server 200 in which the electronic electricity meter 100 that propagates to a user or another customer, and the earthquake occurrence alarm when the electronic electricity meter 100 of each consumer measures earthquake occurrence measurement is transmitted to another consumer; and The user terminal 300 receives earthquake occurrence information from the earthquake occurrence management server 200.

2 is a configuration diagram of the electronic wattmeter 100 disclosed in FIG. 1.

Referring to FIG. 2, the electric watt hour meter 100 located in each customer includes an electric power meter 110 installed on a customer's lead line and measuring power consumption of the customer, and an earthquake sensitivity measurement sensor unit 120 measuring earthquake sensitivity. A power meter controller 130 which determines a dangerous state by comparing a preset value set in advance and the measured value measured by the earthquake sensitivity measurement sensor unit 120, and generates a dangerous state flag in a dangerous state; The communication unit 140 transmits a dangerous state flag generated by the controller 130 to the earthquake occurrence management server 200.

The electronic electricity meter 100 is a power interruption unit forcibly cutting off the power supplied to the customer when the risk generation flag is generated more than a predetermined number of times for a predetermined time or continuously generated for a predetermined time ( 150 is provided, it is possible to prevent a safety accident.

In the electronic watt hour meter 100, the watt hour control unit 130 forcibly shuts off the power supplied to the customer by forcibly driving the power cut-off unit 150 when a danger occurrence flag is received from the earthquake occurrence management server 200. Thus, even when the electronic watt-hour meter located in another consumer measures the occurrence of the earthquake, the power supplied to the consumer can be forcibly cut off.

The electronic watt hour meter 100 is further provided with a setting unit 160 for setting the earthquake sensitivity (3 to 5, that is, 4) as a criterion for determining whether or not a risk occurs, it is possible to arbitrarily set the earthquake sensitivity of the dangerous state . In the above embodiment, the setting of the dangerous state to the seismic sensitivity has been described as an example, but the present invention is not limited thereto and may be set to a SI (Spectral Intensity) value.

In addition, the electronic electricity meter 100 is provided with a dangerous state display unit 170 composed of one or more of a speaker, a buzzer, a warning light, etc., so that a dangerous state due to an earthquake can be quickly recognized and coped with by a consumer in which the electronic electricity meter is located.

3 is a flowchart illustrating an operation of the electronic wattmeter of FIGS. 1 and 2.

Referring to FIG. 3, when a setting value as a reference for determining a dangerous state due to an earthquake is set (S11) by the manipulation of the setting unit 160, the electricity meter control unit 130 stores the setting value in a memory (not shown). Will be saved.

When the preset value is stored as described above, when the measured value is measured (S12) and input by the seismic sensitivity measurement sensor unit 120, the electricity meter control unit 130 is set in advance and the seismic sensitivity measurement sensor unit The dangerous state is determined (S14) by comparing the measured value measured by 120 (S13), and a dangerous state flag (S15) is generated at the dangerous state (S15).

In addition, the electricity meter control unit 130 itself outputs an earthquake occurrence alarm (S16) and transmits a dangerous state flag to the earthquake occurrence management server 200 through the communication unit 140 (S17). In addition, when the risk generation flag is generated more than a predetermined number of times for a predetermined time or continuously generated for a predetermined time, the electricity meter control unit 130 drives the power cutoff unit 150 to supply power to the customer. Is forcibly blocked (S18).

In addition, the electricity meter control unit 130 forcibly drives the power cut-off unit 150 to cut off the power supplied to the consumer even when a danger generation flag is received from the earthquake occurrence management server 200, thereby preventing the electronic electricity meter of another customer. Even if the earthquake detects an earthquake, it can cope with it.

4 is a block diagram of the earthquake occurrence management server 200 disclosed in FIG.

Referring to FIG. 4, the earthquake occurrence management server 200 of FIG. 1 may include a communication unit 210 which receives a dangerous state flag from the electronic electricity meter 100 of each customer in a specific region registered in advance, and the number of previously set customers. The earthquake occurred in a specific region by the server controller 220 and the server controller 220 to determine whether an earthquake occurred in a corresponding region in preparation for the number of customers receiving the dangerous state flag through the communication unit 210. If it is determined that, it is composed of a communication unit 230 for transmitting an earthquake occurrence warning to a user or a customer registered in advance.

In the above embodiment, the earthquake occurrence management server 200 is an RS485 or RS232 wired communication method using an AMI (Advanced Metering Infrastructure) system or one or more of RF, Zigbee, Rola, Wi-Sun, LTE, NBIOT The wireless communication method receives a dangerous state flag from the electronic electricity meter 100 of each customer.

In the above embodiment, if it is determined that the earthquake has occurred in a specific region, the server controller 220 transmits a risk occurrence flag for notifying the risk of the earthquake to the electricity meter 100 of each customer located in the corresponding region, thereby generating an earthquake. Other customers' electricity meters could not detect earthquakes.

In more detail, when it is determined that the earthquake occurs in a specific region, the server controller 220 generates a risk for notifying the risk of the earthquake occurrence to the electronic electricity meter 100 of the customer who has not received a danger flag among the customers located in the specific region. By sending a flag, another customer's electronic wattmeter that failed to measure the earthquake can also recognize the earthquake.

In the above embodiment, the earthquake occurrence management server 200 is provided with an earthquake generation display unit 240 to display the earthquake occurrence, the administrator who manages the earthquake occurrence management server 200 also recognizes the occurrence of earthquake in a specific region You can respond quickly.

FIG. 5 is a flowchart for describing an operation of the earthquake occurrence management server 200 of FIG. 4.

Referring to FIG. 5, the server control unit 220 of the earthquake occurrence management server 200 monitors whether a dangerous state flag corresponding to an earthquake is received from the electronic electricity meter 100 of each customer through the communication unit 210. (S21).

When the dangerous state flag is received from the electronic electricity meter 100 of a specific customer, the server controller 220 compares the number of consumers who receive the dangerous state flag received from the electronic electricity meter 100 with the preset number of customers (S22). ), It is determined whether an earthquake occurs in the region (S23).

If it is determined that an earthquake has occurred in a specific area because a dangerous state flag is received from more than a predetermined number of customers, the server controller 220 alerts the user terminal 300 registered beforehand or the customer to the customer. Transmission (S24) is made.

In addition, when it is determined that the earthquake has occurred in a specific region, the server controller 220 reverses a risk generation flag for notifying a risk of an earthquake to the electronic wattmeter 100 of a customer who does not receive a danger generation flag among customers in a specific region. By transmitting to the electronic power meter of another customer who could not measure the earthquake, it is also possible to recognize the earthquake.

Although specific embodiments of the present invention have been described so far, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

100: electronic power meter 110: power measurement unit
120: earthquake sensitivity measurement sensor unit 130: power meter control unit
140, 210, 230: communication unit 150: power cut off
160: setting unit 170: dangerous state display unit
200: earthquake occurrence management server 220: electricity meter control unit
240: earthquake occurrence display unit 300: user terminal

Claims (8)

delete delete delete delete A communication unit 210 for receiving a dangerous state flag from the electronic electricity meter 100 of each customer in a specific region registered in advance;
A server controller 220 for determining whether an earthquake has occurred in a corresponding region by comparing a preset number of customers and a number of customers who receive a dangerous state flag through the communication unit 210; And
When it is determined by the server controller 220 that an earthquake has occurred in a specific region, the communication unit 230 for transmitting an earthquake occurrence alert to a user or a customer registered in advance
It is configured to include,
The server control unit 220,
If it is determined that an earthquake has occurred in a specific region, the risk for notifying the risk of earthquake occurrence to the electricity meter 100 of each customer located in the region or the customer's electronic electricity meter 100 of which the danger flag is not received among the consumers located in the specific region. An earthquake occurrence management server, characterized by transmitting an occurrence flag.
The method of claim 5,
The seismic generation management server 200 is a wired communication method of RS485 or RS232 using an AMI (Advanced Metering Infrastructure) system or a wireless communication method of one or more of RF, Zigbee, Rola, Wi-Sun, LTE, NBIOT of each customer Earthquake generation management server, characterized in that for receiving a dangerous state flag from the electronic electricity meter (100). delete delete

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