KR101913722B1 - CONFUGURE SYSTEM FOR IoT DEVICE - Google Patents

Abstract

The present invention relates to an IoT device setting system for wirelessly setting IoT device equipment including one IoT data communication part to perform a set operation and output result data generated by the performed operation. The IoT device setting system comprises: an IoT device outputting predetermined identification data by using low-power communication; and a main server receiving the identification data and outputting setting data matching the identification data to the IoT device to set up the IoT device.

Description

IoT device setting system {CONFUGURE SYSTEM FOR IOT DEVICE}

This technology relates to a setting system in which a plurality of IoT devices can be set easily.

And more particularly, to a setting system capable of automatically identifying an IoT device using a low power proximity communication method and transmitting setting data corresponding to the identified IoT device, thereby wirelessly setting the IoT device from the center to the wireless.

Devices are evolving. Conventional devices have been required to perform passive operations such as repeating a given operation or performing predetermined repetitions according to input. However, as Internet technology has developed, it has become necessary to perform operations other than a given operation through data transmission / And perform an active operation to perform a specific operation. Such a device is termed a generic IoT device.

However, in order for the IoT device to perform an active operation as described above, information for performing an active operation must be provided to the IoT device. That is, when the specific data is transmitted to the IoT device, So that the corresponding operation is performed. That is, the smooth operation of the IoT device is changed according to the setting of the IoT device.

In the case of IoT devices that have various kinds of IoT devices but perform specific operations only and transmit result data generated according to specific operations, considering the cost and convenience of production, Do not configure the configuration to a high percentage.

In addition, the IoT device has poor performance of the CPU 110 performing the core operation of the IoT device. Therefore, when the IoT device is activated, the IoT device itself requests the setting data to the server and receives the setting data from the server The receiving operation is almost impossible. Therefore, most of these IoT devices are currently set up by the programmer device manager manually.

It is not a problem if the number of IoT devices with poor CPU and communication performance is small. However, when an IoT device having poor communication performance is installed for performing a plurality of different operations on a wide area such as a factory or a ship, / Time cost is a big problem.

Once the programmer has set up the IoT device to connect to the IoT device by locating the IoT device adjacent to the IoT device as the device manager walks through the vast area, this is inefficient in terms of wasting human labor, .

However, if IoT device communication performance is improved, the problem of product cost, design, production cost, etc. arises because of a bigger navel than a ship.

Therefore, there is a need for a new IoT device setting system capable of setting a number of IoT devices with poor communication performance by using a central management system wirelessly.

Korean Patent Registration No. 10-0560931 "" System And Method For Setting Mobile Station" Korea Registered Patent Registration No. "10-1592865" "NETWORK ASSIGNING SYSTEM AND METHOD THEREOF"

It is an object of the present invention to provide an IoT device setting system capable of centrally and wirelessly setting an IoT device whose communication device performance is poor.

It is an object of the present invention to provide an IoT device setting system capable of minimizing the power consumption of the IoT device at the time of setting.

It is another object of the present invention to provide an IoT device setting system that transmits setting data to a priority order when setting a plurality of IoT devices, thereby improving the efficiency of IoT device setting.

The technical object of the present invention is not limited to the above-mentioned technical objects and other technical objects which are not mentioned can be clearly understood by those skilled in the art from the following description will be.

The IoT device setting system of the present invention wirelessly sets the IoT device equipment including one IoT data communication unit to perform the set operation and output the result data generated by the performed operation.

The IoT device outputs predetermined identification data using low-power communication, and the main server receives the identification data and outputs setting data matching the identification data to the IoT device.

Here, the IoT device includes an IoT data communication unit for receiving the setting data, a beacon transmitting unit for outputting the identification data, and an IoT communication unit for receiving the setting data.

Here, the main server includes a gateway device and a management server, and the gateway device includes a beacon receiving unit for receiving the identification data and a gateway communication unit for transmitting the identification data to the management server, And a server communication unit for receiving the identification data and setting data matched in the database to the gateway communication unit.

Here, the management server sets an order to the identification data according to a predetermined operation upon receipt of a plurality of the identification data, and loads the setting data matched in the database according to the order.

Here, the management server may be configured to receive, when the newly stored setting data among the setting data of the database is stored, the IoT device outputting the identification number matching the newly stored setting data so that the IoT device is set by the newly stored setting data Through the server communication unit.

Here, the gateway communication unit of the management server includes a first gateway communication unit for communicating with the IoT data communication unit and a second gateway communication unit for communicating with the server communication unit.

Here, the IoT device includes an IoT database that stores received configuration data, and stops power supply to the beacon transmission unit when the configuration data is stored in the IoT database.

In the present invention, a beacon transmitter for transmitting identification data is installed in the IoT device, and the IoT device is set by transmitting the setting data matched according to the identification data to the IoT device, so that the IoT device having poor communication performance can be set wirelessly .

In addition, according to the present invention, when the setting data is received, the present invention can reduce power wasted by turning off the power to the beacon transmission unit, thereby improving the efficiency of power use.

Further, according to the present invention, the priority order of the plurality of IoT devices is set by setting the order of transmitting the setting data, so that the setting of the IoT device can be made efficient.

1 is an overall block diagram of an IoT device setting system according to the present invention.
2 is a detailed block diagram of the control operation unit of the management server of the IoT device setting system according to the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to exemplary drawings. However, this is not intended to limit the scope of the invention.

It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, the size and shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms specifically defined in consideration of the constitution and operation of the present invention are only for explaining the embodiments of the present invention, and do not limit the scope of the present invention.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise. It should be noted that the terms such as " part, "" module, " .

The IoT device (100) setting system of the present invention includes an IoT device (100) and a main server (200).

Here, the IoT device 100 performs only the set operation, performs the set operation, and outputs the generated result data. One example of such an IoT device 100 is an IoT pressure measuring sensor that measures the pressure of an LNG gas tank and transmits measured data, and an IoT temperature measuring sensor that transmits data measured by measuring temperature .

The IoT device 100 transmits data and does not have a large weight for the receiving communication device, and the performance of the CPU 110, which is responsible for the operation of the IoT device 100, is not high. Is almost impossible.

However, as described above, it is inefficient to manually set up the IoT device 100 when the different IoT devices 100 are installed in a wide position. Therefore, the IoT device 100 must be set up wirelessly.

The beacon transmission unit 120 is installed in the IoT device 100 and the identification data is transmitted through the beacon transmission unit 120. [ The beacon is a short-range wireless communication based on the Bluetooth 4.0 (BLE) protocol, and the beacon transmission unit 120 of each IoT device 100 has different predetermined identification data set.

When the main server 200 receives the identification data transmitted from the beacon transmitter 120, the main server 200 transmits the setting data matching the identification data to the IoT device 100 to set the IoT device 100. That is, the IoT device 100 can be set up by outputting the setting data matched with the identification data transmitted from the beacon transmitting unit 120. [

The IoT device 100 according to the present invention includes a CPU 110, a beacon transmitter 120, an IoT data transmitter, and an IoT database 140.

The CPU 110 causes the IoT device 100 to perform a predetermined operation. The CPU 110 is connected to the beacon transmission unit 120. The CPU 212 transmits predetermined identification data via the beacon transmission unit 120. [ Here, the identification data may be ID data that does not overlap in one example. That is, different identification numbers or identification information are set in each IoT device 100.

The main server 200 includes a gateway device 210 and a management server 220.

A plurality of gateway devices 210 are installed at predetermined positions. A gateway device 210, a beacon receiving unit 211, a CPU 212, and a gateway communication unit 213.

A plurality of gateway devices 210 are installed at predetermined locations to connect a plurality of IoT devices 100 to a management server 220 located at a remote location. Here, the beacon receiving unit 211 of the gateway device 210 receives the identification data transmitted from the adjacent location. The beacon receiving unit 211 outputs the received identification data to the CPU 212. [ The CPU 212 processes the received identification data and transmits it to the management server 220 located at a remote location using the gateway communication unit 213.

The management server 220 includes a control operation unit 221, a database 225, and a server communication unit 226. The management server 220 receives the identification data transmitted by the gateway communication unit 213 using the server communication unit 226. [ The control operation unit 221 receives the identification data, loads the setting data matched with the identification data in the database 225, and transmits the setting data to the gateway device 210 through the server communication unit 226.

The gateway device 210 receives the setting data using the gateway communication unit 213 and processes the setting data using the CPU 212 and outputs it to the IoT device 100 using the gateway communication unit 213. [ The IoT data communication unit 130 of the IoT device 100 installs the setting data via the CPU 110 and stores it in the IoT database 140. [ Whereby the IoT device 100 can be set up.

On the other hand, a plurality of identification data is received in the gateway device 210, and a plurality of identification data can be transmitted to the management server 220. The gateway device 210 is connected to a plurality of IoT devices 100 via a beacon and may be communicatively coupled to a plurality of IoT devices 100, but the number of IoT devices 100 that can be connected is fixed.

For example, suppose that there is a limit of 10 pieces of setting data to be transmitted to the IoT device 100 through the gateway device 210 for smooth setting, and 12 IoT devices 100 are connected to the gateway device 210, And 12 pieces of configuration data to be matched by the 12 IoT devices 100, there will be a setback in the setting of the IoT device 100. [

In order to overcome this problem, the IoT device (100) setting system of the present invention assigns priority among data.

The control operation unit 221 of the management server 220 of the present invention includes a matching unit 222, a sequence setting unit 223, and a scanning unit 224. The matching unit 222 matches the identification data with the setting data.

The order setting unit 223 receives the identification data and sets a rank in the setting data to be transmitted. For example, if it is assumed that the identification data is ID data, if the data including the ID data A is given priority over the data including the ID data, the setting data matching the identification data including the ID data A among the plurality of setting data And transmits the setting data matched with the identification data including the ID data B when all of the setting data transmission is completed.

 If the data including the ID data A is competing, the data including the ID data C is set in the priority order immediately next to the A, and the setting data matching the data including the ID data AC is the same Is transmitted prior to the setting data matching with the data including the ID data that does not exist.

Thus, connection overload between the gateway device 210 and the IoT device 100 can be prevented.

On the other hand, when the setting data is updated and updated, the scanning unit 224 catches it and transmits it to the IoT device 100. [ That is, the scanning unit 224 scans the database 225 and transmits new setting data to the IoT device 100 even if identification data is not received when new setting data is stored in the database 225. [

In this case, the IoT device 100 may receive the new setting data through the gateway device 210 and store the new setting data in the IoT database 140.

Here, the setting data transmitted by the scanning unit 224 may be set to a lower order than other setting data. This is because the setting data transmitted by the scanning unit 224 is a concept of upgrading the already set IoT device 100 and the setting data transmitted by the matching unit 222 is for driving the initial IoT device 100. [

The gateway communication unit 213 of the gateway device 210 may be connected to the first gateway communication unit 214 and the first gateway communication unit 214 in order to smoothly connect the IoT device 100 and the management server 220. [ 2 gateway communication unit 215.

The first gateway communication unit 214 transmits and receives data to and from the IoT data communication unit 130 of the IoT device 100 and the second gateway communication unit 215 transmits and receives data only to the server communication unit 226 of the management server 220 Respectively. That is, the IoT device 100 and the management server 220 can communicate with each other via the gateway device 210 using the non-overlapping communication unit.

On the other hand, when the setting data is stored in the IoT database 140, the CPU 110 of the IoT device 100 cuts off the power applied to the beacon transmission unit 120. This is because the beacon transmission unit 120 of the IoT device 100 performs its role by transmitting the identification data to the gateway device 210 using the low power proximity communication.

The IoT device 100 can effectively use the battery by turning off the power supplied to the beacon transmission unit 120. [ The IoT device 100 can increase the operation time even a little and the set IoT device 100 does not transmit the identification data to the beacon receiver 211 of the gateway device 210, May not interfere with the transmission of the identification data to the beacon receiving section 211. [

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

100: IoT device 110: CPU of (IoT device)
120: Beacon transmission unit 130: IoT data communication unit
140: IoT database 200: main server
210: gateway device 211: beacon receiver
212: CPU (of gateway device)
213: gateway communication unit 214: first gateway communication unit
215: second gateway communication unit 220: management server
221: control operation unit 222:
223: order setting unit 224:
225: Database (of the management server)
226: Server communication section

Claims (7)

1. An IoT device setting system for wirelessly setting an IoT device equipment including one IoT data communication unit to perform a set operation and output result data generated by an executed operation,
An IoT device for outputting predetermined identification data using low-power communication; And
And a main server which receives the identification data and outputs setting data matching the identification data to the IoT device to set up the IoT device,
Wherein the IoT device includes an IoT data communication unit for receiving the setting data and a beacon sending unit for outputting the identification data,
Wherein the main server comprises a gateway device including a beacon receiving unit for receiving the identification data and a gateway communication unit for transmitting the identification data, a database including pre-stored configuration data, and the identification data transmitted by the gateway communication unit, And a server communication unit for transmitting configuration data matched in the database to the gateway communication unit,
Wherein the management server sets an order to the identification data according to a predetermined operation upon receipt of a plurality of the identification data, and loads the setting data matched in the database according to the set order. delete delete delete The method according to claim 1,
The management server includes:
When the newly stored setting data among the setting data of the database is stored, the IoT device outputs the identification data matched with the newly stored setting data so that the IoT device is set by the newly stored setting data, To do
Lt; RTI ID = 0.0 > IoT < / RTI > The method according to claim 1,
The gateway communication unit of the main server
A first gateway communication unit communicating with the IoT data communication unit and a second gateway communication unit communicating with the server communication unit
Lt; RTI ID = 0.0 > IoT < / RTI > The method according to claim 1,
The IoT device includes:
And an IoT database for storing the received setting data,
And if the setting data is stored in the IoT database, stopping the power supply to the beacon transmitting unit
Lt; RTI ID = 0.0 > IoT < / RTI >

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