KR20190116027A - Method for firmware upgrade using bluetooth low energy communication - Google Patents

Abstract

The present invention relates to a method for upgrading a firmware using a low power Bluetooth communication, which can convert a LoRa network, which is a public network, into a self-network by upgrading a firmware through a low power Bluetooth communication. To this end, the method of the present invention comprises the following steps: displaying, by a control server, a download message for new firmware data on a customer terminal; downloading, by the customer terminal, the new firmware data by receiving the download message from the control server and accessing the control server; activating a low power Bluetooth communication with an IoT terminal connected to the control server through a public network connected to a fixed electronic device in a digital manner and including a LoRa communication network; transmitting, by the customer terminal, the new firmware data downloaded from the control server to the IoT terminal through the low power Bluetooth communication; and upgrading, by the IoT terminal, an existing firmware to the new firmware data received from the customer terminal.

Description

Firmware upgrade method using low power Bluetooth communication {METHOD FOR FIRMWARE UPGRADE USING BLUETOOTH LOW ENERGY COMMUNICATION}

The present invention relates to a firmware upgrade method using low-power Bluetooth communication, and more particularly, to a firmware upgrade method using low-power Bluetooth communication capable of converting a firmware communication through low-power Bluetooth communication into a self-network. .

Generally, a water meter which measures water consumption is installed in each home or building. These water meters are installed in the pipeline of water pipes buried in the ground. At this time, for protection of the water meter and easy meter reading, a meter protector with a cover is embedded in the ground, and the water meter is installed to be located inside the meter protector. Accordingly, the meter reading meter reading the amount of water used to perform the water meter reading by opening the cover and checking the scale of the water meter installed inside the meter protector.

Here, when the water meter is installed outdoors, no problem occurs when the meter reader reads the water meter regardless of whether or not there is a person in the water. However, the water meter is usually installed indoors of the consumer. Therefore, it is impossible to read the water meter when there are no people in the water. For this reason, in order to read a water meter, a meter reader often needs to revisit the customer to be read many times, and a lot of time is required for meter reading. In addition, in the case of a large number of customers subject to meter reading, in proportion to this, a large number of meter readers are required, and thus, metering costs are also high.

In order to solve this problem, conventionally, a water meter automatic meter reading system has been proposed to install a camera in the water meter and allow the meter reader to read the water usage outdoors. However, such a metering system has a problem that it is difficult to maintain and manage the camera, and the visitor visits all the customers, and thus, the effectiveness of the metering system is not very high in consideration of the metering time, labor cost, and maintenance cost. to be.

Republic of Korea Patent Publication No. 10-0829350 (2008.05.06.)

The present invention has been made to solve the problems of the prior art as described above, an object of the present invention is to use a low-power Bluetooth communication that can be converted to a public network, the Laura network to the own network by upgrading the firmware through low-power Bluetooth communication It is to provide a firmware upgrade method.

To this end, the present invention, a method for upgrading the firmware using low-power Bluetooth communication, the control server, the step of expressing a download message for the new firmware data to the customer terminal; Receiving, by the client terminal, the download message from the control server and then accessing the control server to download the new firmware data; Activating, by the customer terminal, low power Bluetooth communication with an Internet of Things (IoT) terminal digitally connected to a fixed electronic device and connected to the control server through a public network including a Laura communication network; Transmitting, by the customer terminal, the new firmware data downloaded from the control server to the IoT terminal through the low power Bluetooth communication; And upgrading, by the IoT terminal, the existing firmware to the new firmware data received from the customer terminal.

Here, the stationary electronic device may include a water meter, an electricity meter, and a gas meter.

In addition, the new firmware data may include firmware for converting the Laura communication network to its own network.

The new firmware data may include firmware for upgrading the existing firmware related to the fixed electronic device to the latest version.

According to the present invention, by transmitting the firmware data from the customer terminal to the IoT terminal through low-power Bluetooth communication, wireless data communication can be implemented with a small current, as a result, the user side without the help of a specific engineer or mechanical and electronic equipment installation personnel In a simple operation such as a customer terminal, for example, a smartphone application click, the firmware installed on the IoT terminal digitally connected to the water meter installed on the consumer side can be easily upgraded. This can be very useful for the hard meter reading area.

In addition, according to the present invention, by transmitting the firmware data for upgrading the water meter-related firmware from the customer terminal to the IoT terminal through low-power Bluetooth communication, not only can the water meter-related firmware always be kept up-to-date but also economical In addition, by transmitting the firmware data for converting the public network, Laura network to the self-network, it can reduce the enormous communication costs incurred due to the use of the public network of the existing carrier.

According to the present invention, the control server, by using the LoRa (Long Range) network and the Internet communication network bidirectional communication with the Internet of Things (IoT) terminal that is digitally connected to the water meter, water leakage rate and water The dead rate of the meter can be improved, and ultimately, the reliability, convenience and economy of the water meter reading can be secured.

In addition, according to the present invention, customer satisfaction can be realized by the control server periodically providing meter reading information on the water meter to a customer terminal, for example, a smartphone or a PC, connected to the customer.

In addition, according to the present invention, the control server automatically sends an electronic bill for the usage of the water to the customer terminal of the customer side connected to this, and at this time to link the web address for bill payment to the electronic bill or for mobile payment By linking an electronic payment service such as linking a mobile payment app, convenience of both the manager side and the consumer side can be enhanced.

1 is a block diagram showing a water smart metering system according to a first embodiment of the present invention.
2 is a block diagram illustrating a water smart metering system according to a first embodiment of the present invention.
3 is a block diagram illustrating an IoT terminal of a water smart metering system according to a first embodiment of the present invention.
4 is a block diagram showing a control server of the water smart metering system according to the first embodiment of the present invention.
5 is a block diagram illustrating a fare management server of a water smart metering system according to a first embodiment of the present invention.
6 is a block diagram showing a water smart metering system according to a second embodiment of the present invention.
7 and 8 are flowcharts illustrating a water smart metering method according to an embodiment of the present invention.
9 is a flowchart illustrating a fee calculation process of a fee management server in a water smart metering method according to an embodiment of the present invention.
10 is a flowchart illustrating a firmware upgrade process in a water smart metering method according to an embodiment of the present invention.
11 is a flowchart illustrating a communication network switching method according to an embodiment of the present invention.

Hereinafter, a firmware upgrade method using low power Bluetooth communication, a water smart metering system using the same, and a method thereof according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In addition, in describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

First, as shown in Figure 11, the firmware upgrade method according to an embodiment of the present invention is a method for upgrading the firmware using a low power Bluetooth communication. The firmware upgrade method includes a message display step S1, a firmware download step S2, a BLE communication activation step S3, a firmware transmission step S4, and a firmware upgrade step S5.

First, in the message display step (S1), the control server expresses a download message for the new firmware data to the customer terminal.

Then, in the firmware download step (S2), a customer terminal such as a smartphone receives a download message from the control server. Subsequently, the customer terminal connects to the control server and downloads the new firmware data.

Next, in the BLE communication activation step (S3), the customer terminal activates low-power Bluetooth communication with the IoT terminal in order to deliver new firmware data downloaded to the IoT terminal. The IoT terminal is digitally connected to the fixed electronic device and is connected to the control server through a public network including a Laura communication network. In this case, the stationary electronic device may include a water meter, an electricity meter, and a gas meter.

Then, in the firmware transmission step (S4), the customer terminal transmits the new firmware data downloaded from the control server to the IoT terminal through the activated low power Bluetooth communication.

Finally, in the firmware upgrade step (S5), the IoT terminal upgrades the existing firmware with new firmware data received from the customer terminal. In an embodiment of the present invention, the new firmware data downloaded by the customer terminal connected to the control server may include firmware for converting the Laura communication network into its own network. Through this, the Laura network, which is a public network, is easily converted into a self-network.

In addition, in the embodiment of the present invention, the new firmware data downloaded by the customer terminal connected to the control server may include firmware for upgrading the existing firmware related to the fixed electronic device to the latest version.

As such, according to the present invention, by using low power Bluetooth communication as a firmware data transmission method, wireless data communication can be implemented with a small current, and as a result, a customer terminal, for example, You can easily upgrade the firmware installed on the IoT terminal by simply touching or clicking an application on your smartphone, which can be very useful for hard reading areas. In addition, according to the present invention, it is possible to easily switch to the public network of the Laura communication network, and to reduce the enormous communication costs incurred due to the use of the public network of the existing telecommunications operators, and fixed electronic devices, such as water Meter-related firmware can always be kept up-to-date and economical.

In the following, for example, when the electronic device connected to the IoT terminal is a water meter, a water smart metering system and a method using the communication network switching method according to an embodiment of the present invention will be described in detail with reference to FIGS. Shall be.

1 and 2, the smart water metering system 100 according to the first embodiment of the present invention remotely reads the water meter 110 installed at the customer, and reads meter information, for example, water supply. It is a system for automatically providing the customer of the customer side the water rate according to the water consumption or information on the water consumption and meter reading schedule of the meter 110.

The smart water metering system 100 according to the first embodiment of the present invention includes a water meter 110, an Internet of Things (IoT) terminal 120, a repeater 130, an IoT platform 140, The control server 150, the charge management server 160 and the customer terminal 170 is formed.

The water meter 110 is installed at a consumer such as a home or a building. At this time, the water meter 110 is preferably provided as a digital water meter for connection with the IoT terminal 120. In addition, the water smart metering system 100 according to the first embodiment of the present invention communicates with the IoT terminal 120 through a Long Range Wide Area Network (LoRaWAN) 10 and is connected thereto. Remotely read 110. As a result, even if the water meter 110 is installed indoors, the water meter 110 can be read remotely, and the water meter 110 can be read remotely even if there is no person on the customer side. That is, the water smart metering system 100 according to the first embodiment of the present invention may read the water meter 110 in real time regardless of the installation position of the water meter 110 and regardless of time.

The IoT terminal 120 is digitally connected to the water meter 110. In this case, the IoT terminal 120 may be directly connected to the water meter 110 and may be integrally formed. The IoT terminal 120 transmits meter reading data about the amount of water used by the water meter 110 through the Laura communication network 10 connected thereto. Here, Laura communication refers to a large-scale low-power long-distance wireless communication technology, in particular, a technology that is mainly used in smart cities or outdoors due to low standby power and low module price. In particular, unlike the existing smart device connection environment that requires a high-speed, broadband network, it is possible to send and receive small data at low power by placing a chip set on the device without a separate base station or relay equipment. In addition, the Laura communication method is a communication method capable of communication distance of up to 21 km, low power consumption, and can maintain the terminal battery life for a long time. The smart water metering system 100 according to the first embodiment of the present invention can reduce the cost of remote water meter reading by using the Laura communication and the IoT terminal 120.

Meanwhile, the IoT terminal 120 according to the first embodiment of the present invention upgrades existing firmware by receiving new firmware data from the customer terminal 170 of the consumer through low power Bluetooth (BLE) communication. To this end, as shown in FIG. 3, the IoT terminal 120 according to the first embodiment of the present invention includes a low power Bluetooth module 121, a Laura communication module 122, and a Laura communication controller 123. Can be formed.

Here, the low power Bluetooth module 121 communicates with the customer terminal 170 in a low power blue pitch to receive new firmware data from the customer terminal 170. In addition, the Laura communication module 122 receives new firmware data transmitted from the low power Bluetooth module 121. The Laura communication controller 123 is connected to the low power Bluetooth module 121 and the Laura communication module 122 to control them. The Laura communication controller 123 transmits the new firmware data received by the low power Bluetooth module 121 to the Laura communication module 122. In addition, the Laura communication controller 123 upgrades existing firmware stored in the Laura communication module 122 with new firmware data received in the Laura communication module 122. In this case, the Laura communication controller 123 may be wired to the low power Bluetooth module 121 and the Laura communication module 122 through a universal asynchronous receiver / transmitter (UART).

As such, the IoT terminal 120 according to the first embodiment of the present invention receives firmware data from the customer terminal 170 through the low power Bluetooth communication 40. Through this, the water metering system 100 according to the first embodiment of the present invention can implement a wireless data communication with a small current, as a result, the customer terminal (on the user side without the help of a specific engineer or mechanical and electronic equipment installation personnel) 170, for example, the firmware of the IoT terminal 120 digitally connected to the water meter 110 installed at the consumer side may be easily upgraded by a simple action such as a smartphone application click.

Here, the new firmware data received by the IoT terminal 120 according to the first embodiment of the present invention through the low-power Bluetooth communication 40 through the customer terminal 170 may be a local network (Rora communication network 10) own network ( private LoraWAN). As such, when the Laura communication network 10 is upgraded to its own network through a firmware upgrade, it is possible to reduce the enormous use costs incurred due to the use of the public network of the existing communication service provider.

In addition, the new firmware data received by the IoT terminal 120 according to the first embodiment of the present invention through the low-power Bluetooth communication 40 through the customer terminal 170 is the latest version of the existing firmware related to the water meter 110. May be firmware data to be upgraded. Accordingly, the Laura communication controller 123 upgrades the existing firmware related to the water meter 110 stored with the new firmware data.

As such, when a wireless communication environment in which the existing firmware related to the water meter 110 is upgraded through the low power Bluetooth communication 40 is established, the firmware related to the water meter 110 may be easily upgraded, and the water meter 110 may be upgraded. The firmware can be kept up-to-date at all times and can be economical compared to manual firmware upgrades.

The repeater 130 is disposed between the IoT terminal 120 and the IoT platform 140. In this case, the repeater 130 is connected to the IoT terminal 120 and the Laura communication network 10, and is connected to the IoT platform 140 and the Internet communication network 20. The repeater 130 collects meter reading data on the amount of water used by the water meter 110 transmitted from the IoT terminal 120. In addition, the repeater 130 transmits the meter reading data on the water usage of the collected water meter 110 to the IoT platform 140.

The IoT platform 140 is disposed between the repeater 130 and the control server 150. In this case, the IoT platform 140 is connected through the repeater 130 and the Internet communication network 20, and is connected through the control server 150 and the virtual private network (VPN) for security. The IoT platform 140 is an open platform, serves as a medium for connecting the IoT terminal 120 and the control server 150, and provides an IoT service to the control server 150. That is, the IoT terminal 120 and the control server 150 communicate with each other through the IoT platform 140.

The IoT platform 140 provides metering data acquired from the IoT terminal 120 to the control server 150, and the meter reading method, the number, the time, etc. of the water meter 110 transmitted from the control server 150. The control method is provided to the IoT terminal 120.

The control server 150 is connected to the IoT platform 140 through the virtual private network 30. Through this, the control server 150 is extracted from the IoT terminal 120 to extract the meter reading data on the water usage of the water meter 110 received by the IoT platform 140 via the repeater 130 and Save it.

To this end, as shown in FIG. 4, the control server 150 according to the first embodiment of the present invention includes a data extractor 151, a data converter 152, a data storage 153, and a data transmitter. And 154.

The data extractor 151 extracts meter reading data received by the IoT platform 140. At this time, since the IoT platform 140 and the control server 150 are connected through the virtual private network 30, the meter reading data extracted by the data extraction unit 151 is received in an encrypted state. The data converter 152 decrypts the meter reading data extracted by the data extractor 151 and encrypted and transmitted by the virtual private network 30. The data storage unit 153 also stores the meter reading data decoded by the data conversion unit 152. The data transmission unit 154 transmits the meter reading data stored in the data storage unit 153 to the fee management server 160.

On the other hand, the control server 150 is connected to the customer terminal 170 of the customer side. As such, when the customer terminal 170 on the customer's side is connected to the control server 150, the control server 150 uses the customer terminal 170 on the customer's side, for example, the water meter 110 using a smartphone or a PC. The amount of water used according to the meter reading, the number of meter readings, the meter reading time, the state of the water meter 110 and the like can be provided, thereby realizing customer satisfaction.

To this end, the control server 150 according to the first embodiment of the present invention may further include a first display unit 155. The first display unit 155 periodically displays meter reading data on the amount of water used by the water meter 110 stored in the data storage unit 153 to the customer terminal 170 on the customer side. Also, the first display unit 155 may periodically display the meter reading time, the number of meter readings, and the state information of the water meter 110 to the customer terminal 170 on the customer side.

In addition, the control server 150 according to an embodiment of the present invention may further include a data receiving unit 156, the electronic bill generating unit 157 and the second display unit 158. The data receiver 156 receives data about the water rate from the charge management server 160. In addition, the electronic bill generating unit 157 generates an electronic bill for the water bill received by the data receiving unit 156. At this time, the electronic bill generation unit 157 may provide a customer's convenience by linking a web address for using a web payment service to the electronic bill when generating the electronic bill. In addition, when the electronic bill generation unit 157 generates an electronic bill, the mobile payment app for using the mobile payment service can be linked with the electronic bill to help the customer make simple payment. The second display unit 158 expresses the electronic bill generated by the electronic bill generating unit 157 as described above to the customer terminal 170 of the customer.

The control server 150 according to the first embodiment of the present invention automatically sends an electronic bill for usage of the water to the customer terminal 170 of the customer side connected thereto, and at this time, links the web address to the electronic bill. In addition, by linking the electronic payment service, such as linking the mobile payment app, it is possible to enhance the convenience of both the manager side and the consumer side.

Meanwhile, the control server 150 according to the first embodiment of the present invention may control the IoT terminal 120 through the IoT platform 140. That is, the control server 150 instructs the IoT terminal 120 to read the water meter 110 through the IoT platform 140. Accordingly, the IoT terminal 120 measures and sends meter reading data on the amount of water used by the water meter 110, and thus, the meter reading data transmitted is transmitted through the relay 130 and the IoT platform 140. It is received by the control server 150.

The control server 150 according to the first embodiment of the present invention instructs the IoT terminal 120 to read the water meter 110 through the IoT platform 140, and the customer terminal 170 of the customer side. ) Can provide a service for expressing the meter reading schedule for the water meter (110).

Meanwhile, the customer terminal 170 transmitting new firmware data to the IoT terminal 120 through the low power Bluetooth communication 40 downloads the new firmware data from the control server 150. To this end, the control server 150 according to the first embodiment of the present invention may further include a firmware storage unit 159a and a third display unit 159b. Here, the firmware storage unit 159a receives and stores new firmware data by the administrator. In addition, when inputting and storing new firmware data to the firmware storage unit 159a is confirmed, the third display unit 159b expresses a download message for the new firmware data to the customer terminal 170. Accordingly, the customer terminal 170 receives a download message for the new firmware data expressed by the third display unit 159b, accesses the firmware storage unit 159a, and downloads the new firmware data. That is, the customer terminal 170 of the customer side is connected to the control server 150 to receive, that is, download new firmware data for the IoT terminal 120 from the control server 150. In addition, the customer terminal 170 transmits the new firmware data downloaded from the control server 150 to the IoT terminal 120 through the low-power Bluetooth communication 40, the existing firmware installed in the IoT terminal 120 To upgrade the new firmware, for example, the firmware to convert the public Laura communication network 10 to its own network. In addition, it is possible to upgrade the firmware related to the water meter 110 to the latest version of firmware.

The fee management server 160 is connected to the control server 150. The charge management server 160 receives meter reading data from the data transmission unit 154 of the control server 150 and calculates a water rate of the water meter 110.

To this end, as shown in FIG. 5, the fee management server 160 according to the first embodiment of the present invention includes a receiver 161, a first database 162, a fee calculator 163, and a second database ( 164 may be formed.

Here, the receiver 161 receives meter reading data transmitted from the data transmitter 154 of the control server 150. The first database 162 stores cumulative meter reading data of the water meter 110 received from the meter reading up to now. The rate calculator 163 calculates a water rate of the water meter 110 based on the rate of change of the meter reading data received by the receiver 161 and the meter reading data previously stored in the first database 162. The second database 164 stores data about the water rate calculated by the rate calculator 163. At this time, the control server 150 receives the water bill data stored in the second database 164, generates an electronic bill for the received water bill and displays it to the customer terminal 170 of the customer side.

As described above, the water smart metering system 100 according to the first embodiment of the present invention uses the Laura communication network 10, the Internet communication network 20, and the virtual private network 30 to digitally control the water meter 110 and the water meter. The control server 150 for bidirectional communication via the IoT terminal 120 and the IoT platform 140 to be connected, and is connected to the control server 150 to calculate the water rate for the water usage of the water meter 110 Is connected to the rate management server 160 and the control server 150 to receive meter reading information and the like for the water meter 110 from the control server 150, the new firmware data through the low-power Bluetooth communication 40 through the Internet of Things The customer terminal 170 of the customer side to transmit to the terminal 120 is provided. Through this, the water smart metering system 100 according to the first embodiment of the present invention may improve the leak rate of the water and the dead rate of the water meter 110, and ultimately secure the reliability, convenience, and economics of the water meter reading. In particular, the firmware installed in the IoT terminal 120 may be easily upgraded.

Hereinafter, a water smart metering system according to a second embodiment of the present invention will be described with reference to FIG. 6.

6 is a block diagram showing a water smart metering system according to a second embodiment of the present invention.

As shown in FIG. 6, the water smart metering system 200 according to the second embodiment of the present invention includes an IoT apparatus set 210, a repeater 130, an IoT platform 140, and a control server 150. , A charge management server 160 and a plurality of customer terminals 170 are formed.

Compared to the first embodiment of the present invention, the second embodiment of the present invention differs only in that the concept of the IoT apparatus set is introduced, and therefore, the same reference numerals are assigned to the same components. Detailed description thereof will be omitted.

One IoT apparatus set 210 includes one water meter 110 and one IoT terminal 120 digitally connected thereto. The smart water metering system 200 according to the second embodiment of the present invention is a water metering system for the case where the IoT apparatus set 210 is installed in a plurality of consumers, respectively. The IoT apparatus set 210 installed in each of the plurality of consumers transmits the meter reading data, and the repeater 130 collects the meter reading data and transmits the meter reading data to the IoT platform 140. At this time, to identify the meter reading data, each IoT apparatus set 210 is given a unique ID value. Therefore, when the IoT apparatus set 210 transmits meter reading data, the IoT apparatus set 210 also transmits its own ID value. Accordingly, the control server 150 extracts and stores the metering data for each IoT device set 210 received from the IoT platform 140 and the unique ID value assigned thereto.

Referring back to FIG. 5, the receiver 161 of the fee management server 160 may read meter data for each IoT device set 210 transmitted from the control server 150 and each IoT device set 210. Receive the unique ID value given to. In addition, the fee calculator 163 compares the unique ID value received by the receiver 161 with the unique ID value of the IoT apparatus set 210 previously stored in the first database 162, and determines the unique ID value. The water rate for the water meter 110 of the IoT apparatus set 210 is calculated based on the previously stored cumulative meter reading data having the same value and the rate of change of the meter reading data received by the receiver 161.

On the other hand, the control server 150 provides a service for displaying information on the water meter 110 to the plurality of customer terminals 170 of the customer side. In addition, the plurality of customer terminals 170 are connected to the IoT terminal 120 and the low-power Bluetooth communication 40, the new firmware data wirelessly via the low-power Bluetooth communication 40, the corresponding IoT terminal Transmit to 120.

As such, the water smart metering system 200 according to the second embodiment of the present invention may secure reliability, convenience, and economics of the water meter reading, and provide customer convenience even when targeting a plurality of consumers.

Hereinafter, a water smart metering method according to an embodiment of the present invention will be described with reference to FIGS. 7 to 10. In this case, reference numerals of the elements refer to FIG. 1.

7 and 8 are flowcharts illustrating a water smart metering method according to an embodiment of the present invention, and FIG. 9 is a flowchart illustrating a rate calculation process of a fee management server in the water smart metering method according to an embodiment of the present invention. 10 is a flowchart illustrating a firmware upgrade process in a water smart metering method according to an embodiment of the present invention.

As shown in FIG. 7, the water smart metering method according to an embodiment of the present invention is divided into a metering process and a firmware upgrade process. The metering process includes a meter reading data extracting step S110, a meter reading data decoding and storing step S120, a meter reading data transmitting step S130, and a water bill calculating step S140. In addition, the firmware upgrade process includes a new firmware transfer step (S103) and a firmware upgrade step (S104).

First, the metering process will be described. In the meter reading data extraction step (S110), the control server 150 is connected to the Laura communication network 10 from the IoT terminal 120, which is digitally connected to the water meter 110 installed at the customer. The meter reading data on the usage of the manual meter 110 received at the IoT platform 140 via the repeater 130 connected to the terminal 130 is extracted.

Prior to this, in the water smart metering method according to an embodiment of the present invention, the control server 150 instructs the IoT terminal 120 to read the water meter 110 through the IoT platform 140. At this time, the control server 150 may provide a service for expressing the meter reading schedule for the water meter 110 to the customer terminal 170 of the customer side.

Next, in the step of decrypting and storing the meter reading data (S120), the control server 150 decrypts the meter reading data transmitted through the virtual private network 30 after being extracted from the IoT platform 140 and is encrypted and transmitted. . In this case, as shown in FIG. 8, the water smart metering method further includes a meter reading data display step S121 in which the control server 150 periodically displays the stored meter reading data to the customer terminal 170 on the customer side. It may include.

Next, in the meter reading data transmission step (S130), the control server 150 transmits the stored meter reading data to the fee management server 160.

Next, in the water rate calculation step (S140), the rate management server 160 calculates the water rate of the water meter 110 based on the meter reading data received from the control server 150. In this case, as shown in FIG. 8, in the smart water metering method, the control server 150 receives the water rate calculated from the charge management server 160, generates an electronic bill for the water rate, and generates the generated electronic bill. The electronic bill presentation step (S122) displayed on the customer terminal 170 may be further included. At this time, in the electronic bill presentation step (S122), the control server 150, when generating the electronic bill, links the web address for using the web payment service to the electronic bill or the mobile payment app for using the mobile payment service with the electronic bill. Can be linked.

On the other hand, as shown in Figure 9, in the water rate calculation step (S140), the rate management server 160, first, meter reading data from the control server 150 and the corresponding IoT terminal 120 or the IoT device set ( A unique ID value of 210 in FIG. 5 is received. (S211),

Next, the fee management server 160 compares the received unique ID value with the unique ID value of the IoT terminal 120 or the IoT device set 210 previously stored. (S212)

Then, if these unique ID values match, the fee management server 160 determines the IoT terminal 120 or the IoT device set 210 based on the rate of change of the stored meter reading data and the received meter reading data. After calculating the water rate of the water meter 110 for the stored). (S213, S214)

Next, the firmware upgrade process will be described.

First, when the firmware upgrade of the IoT terminal 120 needs to be upgraded, for example, when it is desired to switch the existing communication network, the Laura communication network 10 to its own network, the control server 150 in the new firmware transmission step (S103). The new firmware data for the IoT terminal 120 received from the controller is transmitted to the IoT terminal 120 through the low power Bluetooth communication 40.

Prior to this, as shown in Figure 10, the water smart metering method according to an embodiment of the present invention may further include a new firmware display step (S101) and a new firmware download step (S102).

In the new firmware display step (S101), the control server 150 displays the download message for the new firmware data input and stored by the administrator to the customer terminal 170. This may be achieved through the third display unit 159b of the control server 150. Next, in the new firmware download step (S102), the customer terminal 170 receives a download message from the control server 150, and then accesses the control server 150 to download new firmware data.

In this way, the new firmware display step (S101) by the control server 150, the new firmware download step (S102) and the new firmware transmission step (S103) by the customer terminal 170 proceeds to the wireless communication, then the firmware upgrade step In S104, the existing firmware in which the IoT terminal 120 is installed is upgraded with new firmware data received from the customer terminal 170.

As described above, although the present invention has been described with reference to the limited embodiments and the drawings, the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

100, 200; Water metering system 110; Water meter
120; IoT terminal 121; Low power bluetooth module
122; Laura communication module 123; Laura communications controller
130; Repeater 140; IoT platform
150; Control server 151; Data extractor
152; A data converter 153; Data storage
154; A data transmitter 155; First expression
156; A data receiver 157; Electronic bill generation unit
158; Second display portion 159a; Firmware store
159b; Third display unit 160; Charge management server
161; Receiver 162; First database
163; A charge calculator 164; Secondary database
170; Customer terminal 210; IoT device set
10; Laura's Network 20; Internet network
30; Virtual private network 40; Bluetooth communication

Claims (4)

In the method for upgrading the firmware using low power Bluetooth communication,
Displaying, by the control server, a download message for the new firmware data to the customer terminal;
Receiving, by the client terminal, the download message from the control server and then accessing the control server to download the new firmware data;
Activating, by the customer terminal, low power Bluetooth communication with an Internet of Things (IoT) terminal, which is digitally connected to a fixed electronic device and connected to the control server through a public network including a Laura communication network;
Transmitting, by the customer terminal, the new firmware data downloaded from the control server to the IoT terminal through the low power Bluetooth communication; And
Upgrading, by the IoT terminal, the existing firmware with the new firmware data received from the customer terminal;
Firmware upgrade method comprising a.
The method of claim 1,
The fixed electronic device includes a water meter, an electricity meter and a gas meter.
The method of claim 1,
The new firmware data includes a firmware for converting the Laura communication network to its own network.
The method of claim 1,
The new firmware data includes a firmware for upgrading the existing firmware related to the fixed electronic device to the latest version.