KR101736083B1 - The apparatus and method of smart remote contol with platform module of new korea electric communication intelligence context-aware - Google Patents

Abstract

The present invention relates to an on-site device check type IoT smart remote control device through an NCICA open platform module and a method thereof. The on-site device check type IoT smart remote control device through an NCICA open platform module according to an embodiment of the present invention is composed of a smart sensor node unit (100), a new Korea electric communication intelligence context-aware (NCICA) open platform module (200) which intelligently provides a proper IoT environment, and an integrated control server unit (300). Accordingly, the present invention can diagnose a fault of an on-site device and check a battery with an unmanned method by forming a near field communication network between the NCICA open platform module and the smart sensor node unit.

Description

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to an IoT smart remote control device and method using a NCICA open platform module,

In the present invention, the NCICA open platform module having the IoT function can form a plurality of smart sensor node units and a group network by themselves, connect the devices to the multi-channel short-range wireless communication, and connect them to the central control management unit through wired / wireless communication. It is possible to intelligently provide IoT environment suitable for the situation, send fault diagnosis signal and battery check signal to the field device, and issue fault diagnosis check data and battery check data, which are diagnosed in the field device as response signals, to NCICA open platform The present invention relates to an IoT smart remote control device and method for on-site device check with an NCICA open platform module capable of transmitting a module, and diagnosing failure of a field device and checking battery.

Recently, a public emergency room, a hospital restroom, a convenience store, a wireless emergency call bell, a field speaker, a waterproof microphone, and a warning light are installed.

In particular, when a radio emergency call bell is pressed in an emergency in an emergency, it is converted into an emergency telephone mode and connected to a remote control center at a remote location to transmit a bell signal indicating that a current emergency situation has occurred, Voice call is made.

However, in the case where the wireless emergency call bell, the field speaker, the waterproof microphone, the warning light, etc., which are installed on the spot in the conventional field, can not perform the original function due to failure, damage, or battery consumption, There is a problem that the inspection time is long and the inspection cost is expensive because the device is not available and the inspector is required to check and check every time while moving around.

Further, there is a problem in that, when a new field device is installed, there is no configuration for forming a 1: 1 customized communication protocol, the field device needs to be replaced entirely according to a new field device, There is no device for directly connecting the devices to the integrated control center at a remote place, and there is a problem in that a plurality of devices are installed in a single space, and the installation is complicated and the installation time is long because the device is bulky.

Korean Patent Registration No. 10-1404254

In order to solve the above problems, in the present invention, a smart sensor node unit can be easily installed on one side of a field device, and a short-range wireless communication network is formed between an NCICA open platform module and a smart sensor node unit, And transmits a battery check signal to the NCICA open platform module as a response signal corresponding to the fault diagnosis check data and the battery check data generated by the field device, Channel local wireless communication and wired / wireless communication can be established in the NCICA open platform module having the IoT function, and it is possible to output the broadcast signal through the integrated control server unit, The event signal (wireless emergency call signal) of the wireless call bell of IoT smart remote control device and method with on-site device check through NCICA open platform module which can control to make an IP call with a user located in the field device through the control terminal IP phone after calling control terminal IP phone The purpose is to provide.

In order to accomplish the above object, the IoT smart remote control device for on-site device check with the NCICA open platform module according to the present invention

It is connected to one side of the field device to form a short-range wireless communication network with NCICA open platform module to transmit fault diagnosis check data and battery check data which are diagnosed in the field device to the NCICA open platform module, A smart sensor node unit 100 for transmitting the generated event signal to the NCICA open platform module when a call signal, a speaker signal, and a microphone signal is generated,

The smart sensor node unit and the group sensor network unit are connected to each other through a multichannel short-range wireless communication unit. The smart sensor node unit is connected to the central control unit through wired / wireless communication. The smart sensor node unit receives the malfunction diagnosis signal and the battery check signal transmitted from the integrated control server unit, NCICA (New korea electric), which intelligently provides the IOT environment suitable for the situation of the on-site device by transmitting the fault diagnosis check data of the field device, the battery check data, and the event signal of the field device to the integrated control server section Communication Intelligence Context-Aware) open platform module 200,

It is connected to the NCICA open platform module and the wired / wireless communication network to send the fault diagnosis signal and battery check signal to the NCICA open platform module and receive the fault diagnosis check data as a response signal accordingly, And an integrated control server unit 300 for generating and reporting a 1: 1 customized signal in accordance with an event signal generated in the field device after the battery check data is received and the battery replacement timing is analyzed and notified, .

Also, the field device check type IoT smart remote control method using the NCICA open platform module according to the present invention

(S110) connecting the smart sensor node unit to one side of the field device to form a local wireless communication network with the NCICA open platform module,

A step S120 of sending a fault diagnosis signal and a battery check signal from the integrated control server unit to the NCICA open platform module,

In the NCICA open platform module, a plurality of smart sensor node units and a group network are formed and connected by multi-channel short-range wireless communication, and the central control unit is connected to wired / wireless communication, (S130) receiving the smart sensor node and transmitting it to the smart sensor node unit,

A step S140 of receiving the fault diagnosis signal and the battery check signal from the NCICA open platform module at the smart sensor node unit and transmitting the fault diagnosis check data and battery check data faulted by the field device to the NCICA open platform module,

(S150) of transmitting the fault diagnosis check data and the battery check data of the field device to the integrated control server section in the NCICA open platform module and intelligently providing the IoT environment suitable for the situation of the field device,

The integrated control server unit receives the failure diagnosis check data, compares the failure diagnosis check data with previously stored reference sound data to check the state of the field device, and receives the battery check data to analyze and notify the battery replacement time (S160) .

Also, the field device check type IoT smart remote control method using the NCICA open platform module according to the present invention

A step S210 of transmitting an event signal to the NCICA open platform module when an event signal (a radio emergency call signal, a speaker signal, a microphone signal) of the field device itself is generated in the smart sensor node unit,

Transmitting an event signal of the field device to the integrated control server section in the NCICA open platform module (S220)

The emergency bell IP broadcasting terminal of the NCICA open platform module receives the broadcasting signal from the remote control server unit located at the remote location, broadcasts the broadcasting signal to the field speaker of the VoIP / IP based field device, (Emergency call signal) is input, it is converted into an emergency telephone and directly connected between the integrated control server unit and the waterproof microphone of the field device or between the integrated controller server and the field speaker of the field device (S230 )Wow,

When the event signal (radio emergency call signal) of the wireless paging bell of the field device is input, the integrated control server section normally outputs the broadcast signal, calls the control terminal IP phone, And forming an IP phone call with a user located in the device (S240).

As described above, in the present invention,

First, since the smart sensor node portion can be easily installed on one side of the field device in a detachable manner, the installation property is excellent.

Second, a short-range wireless communication network is formed between the NCICA open platform module and the smart sensor node unit, and a fault diagnosis signal and a battery check signal are sent to a field device, and as a response signal, a fault diagnosis data The battery check data can be transmitted to the NCICA open platform module, enabling the fault diagnosis and battery check of the field devices to be unmanned, thereby reducing the inspection cost and inspection time by 70% compared with the existing one.

Third, the NCICA open platform module enables registration of new on-site devices and manager's smart devices, and can perform position and status management, which is highly compatible and can improve the application range by 80% compared with the existing one.

Third, NCICA open platform module with IoT function can build multi-channel short-range wireless communication and wired / wireless communication itself, and it can intelligently provide IoT environment suitable for the situation of field device.

Fifth, when a broadcast signal is output through the integrated control server unit and an event signal (radio emergency call signal) of a wireless call ring of the field device is inputted, the control terminal IP phone is called, It is possible to control the IP telephone to be formed with the user located in the device, thereby enabling the market of the intelligent IP emergency broadcasting system.

1 is a block diagram showing the components of an IoT smart remote control device 1 of a field device check type through an NCICA open platform module according to the present invention;
2 is a perspective view showing the components of the IoT smart remote control device 1 of the field device check type through the NCICA open platform module according to the present invention,
3 is a block diagram illustrating components of a smart sensor node unit according to the present invention.
4 is a block diagram illustrating components of a sensor node type short range wireless communication unit according to the present invention.
5 is a circuit diagram showing components of a sensor node type control unit according to the present invention,
FIG. 6 is an exploded perspective view showing components of an NCICA open platform module according to the present invention. FIG.
7 is a circuit diagram showing components of an NCICA open platform control unit according to the present invention;
8 is a circuit diagram showing components of an IP broadcast terminal control unit according to the present invention.
FIG. 9 is a block diagram illustrating components of a multi-channel short-range wireless communication unit according to the present invention.
FIG. 10 is a block diagram illustrating components of an emergency bell IP broadcast terminal according to the present invention.
11 is a block diagram illustrating components of an NCICA open platform control unit in accordance with the present invention;
12 is a block diagram showing the components of the integrated control server unit according to the present invention,
FIG. 13 is a block diagram of a smart sensor node unit according to the present invention, which receives a fault diagnosis signal and a battery check signal from an NCICA open platform module, transmits fault diagnosis check data and battery check data, which are diagnosed in a field device, to an NCICA open platform module , An embodiment showing the transmission of the fault diagnosis check data and the battery check data of the field device to the integrated control server section in the NCICA open platform module,
FIG. 14 is a diagram illustrating a state in which the emergency bell IP broadcast terminal of the NCICA open platform module according to the present invention receives a broadcast signal from a remote control server unit located at a remote location and outputs a broadcast signal to a field speaker of a field device based on VoIP / IP , When the event signal (radio emergency call signal) of the wireless call bell of the field device is input, it is converted into an emergency telephone, so that the communication between the integrated control server section and the waterproof microphone of the field device or between the integrated control server section and the field speaker In one embodiment illustrating direct coupling,
FIG. 15 is a flowchart illustrating a method of controlling a plurality of broadcast sound sources to be simultaneously transmitted from one device through a broadcast operating PC unit according to an embodiment of the present invention.
FIG. 16 is a flowchart showing a fault diagnosis and a battery check method of a field device among the IoT smart remote control method of the field device check type through the NCICA open platform module according to the present invention.
17 is a flowchart showing an emergency bell IP broadcasting method among the field device check type IoT smart remote control method using the NCICA open platform module according to the present invention.

First, VoIP / IP described in the present invention refers to a signal protocol capable of processing all telephone calls, video calls and texts.

In addition, the NCICA described in the present invention has a plurality of smart sensor node units and a group network and is connected to the multi-channel short-range wireless communication in order to have the IoT function and the intelligent function, It is a unique development of NCICA open platform module that can connect to wired / wireless communication and intelligently provide IoT environment suitable for the situation of field device.

Thus, they say whether the English name "New korea electric Communication" intelligent edaga how the present applicant that combines "Intelligence Context-Aware""N ew korea electric C ommunication I ntelligence C ontext- A ware".

Also, the field device according to the present invention may be composed of a wireless calling bell, a waterproof microphone, a field speaker, a CCTV camera, or a warning light, alone or in combination.

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

FIG. 1 is a block diagram showing components of an IoT smart remote control device 1 of a field device check type through an NCICA open platform module according to the present invention, and FIG. 2 is a block diagram of an NCICA open platform module according to an embodiment of the present invention. FIG. 1 is a perspective view illustrating components of an IoT smart remote control device according to the first embodiment of the present invention. FIG. 2 is a perspective view illustrating components of the IoT smart remote control device according to the first embodiment of the present invention. And an integrated control server unit 300.

First, the smart sensor node unit 100 according to the present invention will be described.

The smart sensor node unit 100 is connected to one side of the field device to form a short-range wireless communication network with the NCICA open platform module to transmit the failure diagnosis check data and the battery check data, which have been diagnosed in the field device, to the NCICA open platform module, When the event signal (radio emergency call signal, speaker signal, microphone signal) of the field device itself is generated, it transmits the generated event signal to the NCICA open platform module.

As shown in FIG. 3, the sensor node type short range wireless communication unit 110, the input / output connector unit 120, and the sensor node type control unit 130 are configured.

First, the sensor node type short range wireless communication unit 110 according to the present invention will be described.

The sensor node type short range wireless communication unit 110 performs near field wireless communication with the NCICA open platform module based on the short distance wireless communication protocol.

As shown in FIG. 4, the sensor node type Bluetooth communication unit 111 and the sensor node type Zigbee communication unit 112 are selected and configured.

The Bluetooth communication unit 111 performs low power wireless connection in a short distance of 10 meters or less and exchanges information.

It uses the Industrial Scientific and Medical (ISM) frequency band of 2400 to 2483.5 MHz. In order to prevent the interference of other systems that use the upper and lower frequencies, we use a total of 79 channels, ranging from 2400MHz to 2MHz and 2483.5MHz to 3.5MHz, except 2402 ~ 2480MHz.

In addition, in order to eliminate interference between systems, a frequency hopping scheme is used.

Frequency hopping is a technique for rapidly moving a large number of channels according to a specific pattern and transmitting packets (data) little by little. In the present invention, 79 channels are configured to hop 1600 times per second.

The Zigbee communication unit 112 serves to provide a data rate of 250 kbps toward a smart device located near (10 m to 75 m) using a frequency band of 2.4 GHz.

Second, the input / output connector unit 120 according to the present invention will be described.

The input / output connector unit 120 is detachably connected to the input / output unit of the field device.

It consists of a USB connector, an 8-pin socket, a 16-pin socket, and a 32-pin socket.

The input / output connector unit 120 includes an input / output connector 121 for a wireless call-up bell connected to a wireless paging ring of a field device, an input / output connector 122 for a waterproof microphone for connection to a waterproof microphone of a field device, An input / output connector 123 for an on-site speaker connecting to a speaker, an input / output connector 124 for a CCTV camera for connection to a CCTV camera of a field device, and an input / output connector 125 for a beacon for connection to a beacon of a field device .

Third, the sensor node type control unit 130 according to the present invention will be described.

The sensor node type controller 130 receives a fault diagnosis signal from the NCICA open platform module and sends a fault diagnosis signal and a battery check signal through the input / output connector to perform fault diagnosis and battery check of the field device, And controls to transmit the battery check data to the NCICA open platform module while transmitting an event signal (a radio emergency call signal, a speaker signal, a microphone signal) generated in the field device itself to the NCICA open platform module .

It consists of a sensing node microcomputer.

5, a microphone regulator is connected to the output terminal P2.0 / A0 to output an enable signal to the microphone regulator 131 as a fault diagnosis signal of the field device, and the input terminal P2.1 / When a battery check signal is output to the field device through the input / output terminals P1.7 to P1.3, the field device battery power sensed by the battery current sensing unit 132 is input as a current signal, Output connector P1.7 is connected to the input / output connector for wireless call bell to output the fault diagnosis signal and battery check signal to the wireless paging bell of the field device and to transmit the emergency emergency call signal And input / output connector for the wireless call bell is connected to another input / output terminal P1.6 to output the fault diagnosis signal and battery check signal to the waterproof microphone of the field device, The microphone signal of the event signal generated by the waterproof microphone of the field device is input and the input / output connector for the field speaker is connected to the other input / output terminal P1.5, so that the fault diagnosis signal and the battery check signal are outputted to the field speaker of the field device, Speaker signal, which is the event signal generated from the on-site speaker of the device, is input, and the input / output connector for CCTV camera is connected to another input / output terminal P1.4, and the trouble diagnosis signal and battery check signal are outputted to the field device for CCTV camera, CCTV video signal, which is an event signal generated from a CCTV camera field device, is input, and an input / output connector for a beacon is connected to another input / output terminal P1.3 to output a trouble diagnosis signal and a battery check signal to the beacon side of the field device, A signal of a beacon light, which is an event signal generated from a beacon of a field device, is input, and a sensor The NCICA open platform module receives the fault diagnosis signal and the battery check signal from the NCICA open platform module and transmits the fault diagnosis check data and the battery check data of the field device to the NCICA open platform module, Is connected to the output of the microphone regulator so that the electric signal of the field device sensed by the microphone regulator is input.

The microphone regulator 131 transmits a trouble diagnostic signal to the wireless call bell of the field device, and transmits a call ring sound from the wireless call bell and a trouble diagnosis signal to the waterproof microphone of the field device, Sound and fault diagnosis signals are transmitted to the field speaker of the field device, and the diaphragm detects the speaker sound from the field speaker and converts it into electric signal.

The battery current sensing unit 132 is connected to the field device battery and serves to sense the remaining amount of battery remaining in the field device battery as a current signal.

This constitutes the sensing resistance of R4 and R5.

The fault diagnosis is performed by sending a fault diagnosis signal from the sensor node type control unit 130 to the field device to transmit the fault diagnosis signal to the wireless call bell of the field device, It is transmitted to the waterproof microphone of the field device, and the microphone sound from the waterproof microphone and the fault diagnosis signal are transmitted to the field speaker of the field device, and the speaker sound from the field speaker is diagnosed as the electric signal through the microphone regulator part .

For example, when a trouble diagnostic signal is sent to the wireless paging bell of the field device, a call ring sound is automatically output, and the microphone regulator detects it. When the electric signal is input, Otherwise, if there is no signal detected by the microphone regulator unit and no electric signal is input, it is generated as fault diagnosis data that the fault condition is present.

The sensor node type control unit 130 sends a battery check signal to the field device to check the battery. The battery check signal is transmitted to the battery of each field device to sense the remaining battery level of the field device battery as a current signal It says.

For example, if a battery check signal is sent to the wireless paging bell of a field device, the battery current sensing portion senses the current remaining in the battery of the field device to generate battery check data.

Next, the NCICA (Open Communication Intelligence Context-Aware) open platform module 200 according to the present invention will be described.

The NCICA (Open Communication Platform Intelligence Context-Aware) (NCICA) platform module 200 connects a plurality of smart sensor node units and a group network with multi-channel short-range wireless communication and connects them to a central control management unit through wired / wireless communication, Receives the fault diagnosis signal and the battery check signal transmitted from the integrated control server unit and transmits the fault diagnosis signal and the battery check signal to the smart sensor node unit and transmits the fault diagnosis check data, the battery check data and the event signal of the field apparatus to the integrated control server unit , And intelligently provides the IoT environment suitable for the situation of the field device.

6, the module body 210, the power supply unit 220, the multi-channel short-range wireless communication unit 230, the emergency bell IP broadcast terminal unit 240, the wired / wireless communication unit 250, the NCICA open platform control unit 260).

First, the module body 210 according to the present invention will be described.

The module main body 210 is formed in a box shape and protects and supports each device from external pressure.

In this case, a power source unit is formed on one side of the inner space, a multi-channel short-range wireless communication unit is formed on one side of the power source unit, an emergency bell IP broadcast terminal is formed on one side of the multi- , And an NCICA open platform control unit is formed on one side of the wire / wireless communication unit.

Second, the power supply unit 220 according to the present invention will be described.

The power supply unit 220 is located at one side of the inner space of the platform body, and supplies power to the devices at 5V or 12V.

It consists of an AC commercial power connection, an AC-DC converter, a rectifier circuit, and a power transformer.

Third, the multi-channel short-range wireless communication unit 230 according to the present invention will be described.

The multi-channel short-range wireless communication unit 230 is located on one side of the power unit and is formed in a multi-channel manner to be connected to a plurality of field devices located near the module main body through a 1: 1 short-range wireless communication network, And transmits the fault diagnosis signal and the battery check signal to the field device, and receives the fault diagnosis check data and the battery check data of the field device as a response signal.

It consists of 2 channels (2 channels), 4 channels (4 channels), 8 channels (8 channels), 16 channels (16 channels) and 32 channels (32 channels)

As shown in Fig. 9, either the multi-channel type Bluetooth communication unit 231 or the multi-channel type Zigbee communication unit 232 is selected and configured.

The multi-channel type Bluetooth communication unit 231 performs low power wireless connection at a very short distance within 10 meters to exchange information.

It uses the Industrial Scientific and Medical (ISM) frequency band of 2400 to 2483.5 MHz. In order to prevent the interference of other systems that use the upper and lower frequencies, we use a total of 79 channels, ranging from 2400MHz to 2MHz and 2483.5MHz to 3.5MHz, except 2402 ~ 2480MHz.

In addition, in order to eliminate interference between systems, a frequency hopping scheme is used.

Frequency hopping is a technique for rapidly moving a large number of channels according to a specific pattern and transmitting packets (data) little by little. In the present invention, 79 channels are configured to hop 1600 times per second.

The multichannel Zigbee communication unit 232 functions to provide a data rate of 250 kbps toward a smart device located near (10 m to 75 m) using a frequency band of 2.4 GHz.

Fourth, the emergency bell IP broadcast terminal unit 240 according to the present invention will be described.

The emergency bell IP broadcast terminal 240 receives the broadcast signal from the remote control server unit at the remote site through the NCICA open platform control unit and outputs the broadcast signal to the field speaker of the VoIP / IP-based field device, When an event signal (radio emergency call signal) of the radio paging bell of the device is inputted, it is transmitted to the NCICA open platform control unit and converted into an emergency telephone, so that the integrated control server unit and the waterproof microphone of the field device or the integrated control server unit It acts as a direct connection between the on-site speaker of the field device.

10, a ring relay control unit 241, a CALL relay control unit 242, a waterproof microphone field device control unit 243, a first field device on-site speaker control unit 244, an IP And a broadcast terminal control unit 245.

Also, the emergency bell IP broadcast terminal 240 is driven in accordance with a control signal of the emergency bell IP broadcast terminal control unit, and is connected to the integrated control server unit at a remote location based on VoIP / IP.

The ring relay control unit 241 receives an event signal (a radio emergency call signal) from a radio paging bell of a plurality of field devices connected through a multi-channel short-range wireless communication unit as a ring signal, IP broadcasting terminal control unit.

As shown in FIG. 8, a ring relay control unit is connected to an input terminal GPIO2 of the IP broadcast terminal control unit.

The CALL relay control unit 242 converts an event signal (radio emergency call signal) of the wireless paging bell of the field device into an emergency call (CALL) according to a control signal of the IP broadcasting terminal control unit, And controls the direct connection between the integrated control server unit and the wireless call ring of the field device.

As shown in FIG. 8, the CALL relay control unit is connected to the input terminal GPIO3 of the IP broadcast terminal control unit.

The waterproof microphone field device controller 243 is connected to the waterproof microphone of the field device and is driven according to a control signal of the IP broadcast terminal controller to control the water microphone to receive input of the voice signal generated in the field through the waterproof microphone of the field device .

As shown in FIG. 8, it is configured to be connected to the IP broadcast terminal controller through the resistor R199.

The field speaker field device controller 244 is connected to the field speaker of the field device and is driven in accordance with the control signal of the IP broadcast terminal controller to display the voice output from the integrated controller server portion at the remote site through the field speaker of the field device .

As shown in FIG. 8, it is configured to be connected to the IP broadcast terminal controller through the resistor R288.

When the event signal (wireless emergency call signal) of the wireless paging bell of the field device is input, the IP broadcast terminal controller 245 controls the overall operation of each device and transmits the event signal to the NCICA open platform controller .

8, the memory unit is connected to the input terminals SD_DQ0 to SD_DQ15 to bring in the telephone number and IP information of the integrated control server unit stored in advance, and the memory unit is connected to the output terminals SD_A0 to SD_A11, The NCICA open platform control unit is connected to the input terminals SD_CLK, SD_CKE, SD_WE, SD_CAS, SD_CS, SD_DQM0, SD_DQM1, SD_BSA1 and SD_BSA0, and the NCICA open platform control unit is connected to the NCICA A clock signal, a DQM signal and a BSA signal are input from an open platform control unit, a NCICA open platform control unit is connected to another input terminal EN, a start signal is input from an NCICA open platform control unit, and an NCICA open platform control unit The system reset signal is input from the NCICA open platform control unit, the NCICA open platform control unit is connected to the output terminals GPIO17 to 31, And outputs the radio emergency call signal which is an event signal of the subwoofer. The field speaker field device control unit is connected to the output terminal GPIO10 through the resistor R199 to output the voice output from the remote control unit to the field speaker of the field device, When a CALL relay control unit is connected to the terminal GPIO3 and an event signal (radio emergency call signal) of the wireless call ring of the field device is inputted, the emergency call is converted into an emergency call (CALL) An output signal is output to directly connect between the wireless call bell of the device and a ring relay control is connected to the input terminal GPIO2 to receive an event signal (radio emergency call signal) from the wireless call bell of a plurality of field devices Ring signal, inputting it while relaying, field speaker field device control part connected to output terminal GPIO0 terminal, Section is configured to output a sound to be output from the integrated control server unit side speaker.

Fifth, the wired / wireless communication unit 250 according to the present invention will be described.

The wired / wireless communication unit 250 is connected to the integrated control server unit located at a remote location via a wired / wireless communication network, receives the fault diagnosis signal and the battery check signal transmitted from the integrated control server unit, .

The WiFi communication module is configured as a wireless communication module, and one of BACNET TCP / IP, BACNET MS / TP, and Modbus RTU is selected and configured as a wired communication module.

The WiFi communication module incorporates wireless technology and is composed of a wireless LAN technology that enables high performance wireless communication.

The wireless LAN uses a frequency band of 2.4 GHz, which is a method of building a network using radio wave or light without using a wire when constructing a network.

Sixth, the NCICA open platform controller 260 according to the present invention will be described.

The NCICA open platform control unit 260 is connected to the power unit, the multi-channel short-range wireless communication unit, the emergency bell IP broadcast terminal unit, and the wired / wireless communication unit to intelligently control the overall operation of each device, And the like.

It consists of an artificial intelligent embedded structure with self learning function.

7, the memory unit is connected to the input / output terminals PA0 to PA7 to store the failure diagnosis check data and the battery check data transmitted from the field device, and to transmit the emergency bell IP broadcast to the other input / output terminals PC0 to PC7 The terminal control unit is connected to the emergency bell IP broadcast terminal unit to output a broadcast signal to a field speaker of a VoIP / IP type field device, broadcasts an event signal (a wireless emergency call signal ) Is converted into an emergency telephone to control the direct connection between the integrated control server unit and the waterproof microphone of the field device and between the integrated control server unit and the field speaker of the field device, and the other input / output terminals PD0 to PD7, A multi-channel short-range wireless communication establishing control unit is connected to PE0 to PE7, and a plurality of field devices located near the module main body are assigned IDs to provide a 1: 1 short- Connected so as to control, and also a control unit connected to the other forming wire and wireless communication input-output terminal PG3 ~ PG4 drives the wire and wireless communication unit is configured to control so as to connect to a remote location in the integrated control server unit and the wired or wireless communication network.

11, the NCICA open platform control unit according to the present invention includes a service manager unit 261, a memory unit 262, a topology control manager unit 263, a device manager unit 264 A multi-channel short-range wireless communication control unit 265, a wired / wireless communication formation control unit 266, and an emergency bell IP broadcast terminal control unit 267.

[Service Manager Unit 261]

The service manager unit 261 is connected to the field device to perform service management functions related to fault diagnosis and battery check on the field devices.

This is a service registration module, a service modification module, a service removal module, a service request / response module (Service Request / Response Module), a service monitoring module (Service Monitoring Module) , A user service management module (User Service Management Module), and an API module.

The service registration module (Service Registration Module) serves to support the registration of the service developed by the service provider in the UICAS.

The Service Modification Module plays a role of supporting modification of a registered service from a service provider.

The service request / response module (Service Request / Response Module) plays a role of supporting the removal of the service registered by the service provider.

The service request / response module (Service Request / Response Module) transmits a situation recognized through the UICAS to a service, thereby enabling a user-oriented context aware service to be provided and supporting communication between the actual service and the system .

The service monitoring module registers the conditions necessary for service execution in the context manager and serves as an interface for notifying the condition when the conditions are satisfied. In this way, the service can be provided according to the user's situation.

The user service management module plays a role of supporting subscription or withdrawal to a service desired by the user.

The API module plays an role of supporting an open structure that facilitates service development by providing an API necessary for service providers to develop a service.

[Memory unit 262]

The memory unit 262 stores the failure diagnosis check data and the battery check data transmitted from the field device.

[ Topology  Control Manager (Topology Control Manager) 263)]

The topology control manager 263 functions to form a location-based mesh-type dynamic network between the field devices.

This includes a Map Data Management Module, a Shortest Path Finding Module, a Location Estimation Module, a Topology Reconfiguration Module, a Node Remove Module, And a node insertion module (Node Insertion Module).

The map data management module is a module for managing map information, and stores and manages data by mapping the positions of actual maps and field devices.

The Shortest Path Finding Module finds the shortest path between two field devices by using the shortest distance search algorithm that finds the shortest distance between two nodes.

Here, the node refers to a smart sensor node unit installed in the field device.

The Location Estimation Module serves to estimate the current location of the field device.

The Topology Reconfiguration Module is responsible for reconfiguring the existing network when adding / deleting nodes (registering and releasing field devices).

The Node Removal Module removes it from the network upon deregistration of a previously registered on-site device.

In this case, when the field device is unregistered, the removal from the network means that it is unregistered and removed from the network centering on the identification ID of the smart sensor node.

The Node Insertion Module serves to insert the Node Insertion Module into the network when registering the field device.

Here, the insertion into the network means inserting the identification ID of the smart sensor node unit.

[ device  Manager section 264]

The device manager 264 plays a role of performing registration, location and status management of the on-site device (wireless call bell, waterproof microphone, field speaker, CCTV camera) and the smart device of the administrator, do.

[Multichannel Short-range wireless communication  Formation control unit 265]

The multi-channel short-range wireless communication control unit 265 drives the multi-channel short-range wireless communication unit to provide identification IDs to a plurality of field devices located near the module main body, .

This is connected to the input / output terminals PD0 to PD7 and PE0 to PE7 of the NCICA open platform control unit.

[Wired / wireless communication formation control unit 256]

The wired / wireless communication control unit 256 controls the wired / wireless communication unit to be connected to a wired / wireless communication network with the integrated control server unit located at a remote location.

This is connected to the input / output terminals PG3 to PG4 of the NCICA open platform control unit.

[Emergency bell IP broadcast terminal control unit 267]

The emergency bell IP broadcast terminal unit control unit 267 drives the emergency bell IP broadcast terminal unit to output a broadcast signal to the field speaker of the field device of the VoIP / IP type to broadcast the event, (Radio emergency call signal) is input, it is converted into an emergency telephone to control the direct connection between the integrated control server unit and the waterproof microphone of the field device, and between the integrated controller server and the field speaker of the field device.

This is connected to the input / output terminals PC0 to PC7 of the NCICA open platform control unit.

Next, the integrated control server unit 300 according to the present invention will be described.

The integrated control server unit 300 is connected to the NCICA open platform module through a wired / wireless communication network and sends a fault diagnosis signal and a battery check signal to the NCICA open platform module, receives the fault diagnosis check data as a response signal, Monitors the state of the field device by comparing with the reference sound data, receives the battery check data, analyzes and reports the battery replacement timing, and monitors and monitors the 1: 1 customized signal according to the event signal generated by the field device .

Here, the 1: 1 customized signal is generated according to the event signal generated by the field device. When the event signal related to the emergency emergency call signal generated in the wireless call bell among the field devices is transmitted, And when an event signal related to a video signal captured by a CCTV camera among the on-site devices is transmitted, an on-site video signal is generated from 1: 1 customized signals, and an event signal related to a speaker signal generated from the on- When the signal is transmitted, it generates a speaker signal from a 1: 1 custom signal and generates a microphone signal from a 1: 1 custom signal when an event signal related to a microphone signal generated by a waterproof microphone in the field device is transmitted.

12, the integrated control server unit 300 includes a video server unit 310, a health check server unit 320, an emergency IP broadcast server unit 330, a monitoring server 340, a firewall module 350, and a broadcast operating PC unit 360.

The video server unit 310 receives a scene image taken by a CCTV camera of a field device and transmits the scene image to a monitoring server.

The health check server 320 transmits a health check signal made up of a fault diagnosis signal and a battery check signal of the field device to the NCICA open platform control unit and outputs a fault check data, And stores and manages the received data.

The emergency IP broadcast server unit 330 is connected to the emergency bell IP broadcast terminal of the NCICA open platform control unit through a VoIP / IP method to output a broadcast signal, and transmits an event signal (wireless emergency call Signal) is input, the control terminal calls the IP phone, and controls the control terminal to form an IP call with a user located in the field device through the IP phone.

It searches for field devices through emergency bell IP broadcasting terminal of NCICA open platform controller and sends customized broadcasting to specific field devices.

The monitoring server 340 monitors the field image transmitted from the video server unit, the failure diagnosis check data of the field device transmitted from the health check server, and the battery check data.

The firewall module 350 blocks unauthorized access to the wired / wireless communication network from outside to inside or from the inside to the outside in order to secure broadcasting information.

The broadcast operating PC unit 360 is connected to the video server unit, the health check server unit, the emergency IP broadcast server unit, and the monitoring server to control the overall operation of each device, And sends out the information.

As shown in FIG. 15, the broadcasting operating PC unit 360 is operated as follows to control a plurality of broadcasting sound sources to be simultaneously transmitted from one apparatus.

 First, the operating window of the broadcast operating PC unit is operated.

Then, the music broadcasting SW (software) is operated.

Then, run the Oracle VirtuaBox.

Next, install the USB sound card for the broadcast quantity.

Next, as shown in FIG. 15, when the music broadcast program of the broadcasting operating PC unit confirms the selected music list, the emergency IP broadcasting server searches for the field devices and broadcasts customized broadcasting to the specific field devices .

Hereinafter, the IoT smart remote control method of the on-site device check through the NCICA open platform module according to the present invention will be described in detail.

[ On-site  Fault diagnosis and battery check method]

First, as shown in FIG. 16, a smart sensor node unit is connected to one side of a field device to form an NCICA open platform module and a short-range wireless communication network (S110).

Next, the integrated control server unit sends a fault diagnosis signal and a battery check signal to the NCICA open platform module (S120).

Next, in the NCICA open platform module, a plurality of smart sensor node units and a group network are formed and connected to the multi-channel short-range wireless communication, and the central control unit is connected to wired / wireless communication, Receives the battery check signal, and transmits the battery check signal to the smart sensor node unit (S130).

Next, as shown in FIG. 13, the smart sensor node receives the fault diagnosis signal and the battery check signal from the NCICA open platform module and transmits the fault diagnosis check data and the battery check data, which are diagnosed in the field device, to the NCICA open platform To the module (S140).

Next, in the NCICA open platform module, fault diagnosis check data and battery check data of the field device are transmitted to the integrated control server section, thereby intelligently providing the IoT environment suitable for the situation of the field device (S150).

Finally, the integrated control server unit receives the failure diagnosis check data, compares the failure diagnosis check data with pre-stored reference sound data to check the state of the field device, receives the battery check data, and analyzes and reports the battery replacement time (S160).

[Emergency Bell IP broadcasting method]

17, when an event signal (radio emergency call signal) of the field device itself is generated at the smart sensor node unit, the generated event signal is transmitted to the NCICA open platform module at step S210.

Next, the NCICA open platform module transmits the event signal of the field device to the integrated control server module (S220).

Next, as shown in FIG. 14, the emergency bell IP broadcast terminal of the NCICA open platform module receives a broadcast signal from a remote control server unit located at a remote place, and outputs a broadcast signal to a field speaker of a VoIP / IP-based field device When the event signal (radio emergency call signal) of the wireless call ring of the field device is input, it is converted into an emergency phone, and the communication between the integrated controller server and the waterproof microphone of the field device or between the integrated controller server and the field device And direct connection is made between the on-site speakers (S230).

Finally, when the event signal (radio emergency call signal) of the wireless paging bell of the field device is input after the integrated control server unit normally outputs the broadcast signal, the control terminal IP phone is called and the control terminal IP phone To form an IP phone with a user located in the field device (S240).

1: IoT smart remote control device with on-site device check
100: Smart sensor node part 200: NCICA open platform module
300: Integrated control server unit

Claims (10)

It is connected to one side of a field device which is composed of a wireless call bell, a waterproof microphone, an on-site speaker, a CCTV camera, a warning light or a combination of two or more, and forms a short-range wireless communication network with the NCICA open platform module, Smart sensor that transmits diagnosis check data and battery check data to NCICA open platform module and transmits event signal generated by NCICA open platform module when event signal (radio emergency call signal, speaker signal, microphone signal) of field device itself is generated A node unit 100,
The smart sensor node unit and the group sensor network unit are connected to each other through a multichannel short-range wireless communication unit. The smart sensor node unit is connected to the central control unit through wired / wireless communication. The smart sensor node unit receives the malfunction diagnosis signal and the battery check signal transmitted from the integrated control server unit, NCICA (New korea electric), which intelligently provides the IOT environment suitable for the situation of the on-site device by transmitting the fault diagnosis check data of the field device, the battery check data, and the event signal of the field device to the integrated control server section Communication Intelligence Context-Aware) open platform module 200,
It is connected to the NCICA open platform module and the wired / wireless communication network to send the fault diagnosis signal and battery check signal to the NCICA open platform module and receive the fault diagnosis check data as a response signal accordingly, And an integrated control server unit 300 for generating and reporting a 1: 1 customized signal in accordance with an event signal generated in the field device after the battery check data is received and the battery replacement timing is analyzed and notified IoT Smart remote control device with on-site device check via NCICA open platform module.
The smart sensor node unit (100) according to claim 1, wherein the smart sensor node unit
A sensor node type short range wireless communication unit 110 for performing short range wireless communication with the NCICA open platform module based on the short range wireless communication protocol,
An input / output connector part 120 for detachably connecting the input / output part of the field device,
After receiving the fault diagnosis signal from the NCICA open platform module and sending the fault diagnosis signal through the I / O connector section, fault diagnosis of the field device is performed, and the fault diagnosis data is transmitted to the NCICA open platform module. And a sensor node type control unit (130) for controlling an event signal to be transmitted to the NCICA open platform module.
3. The apparatus of claim 2, wherein the sensor node type control unit (130)
A microphone regulator is connected to the output terminal P2.0 / A0 to output an enable signal to the microphone regulator 131 as a failure diagnosis signal of the field device. A current sensing part is connected to the input terminal P2.1 / A1, When a battery check signal is output to the field device through P1.7 to P1.3, the field device battery power sensed by the battery current sensing unit 132 is input as a current signal, and input / The connector is connected to output a fault diagnosis signal and a battery check signal to the wireless paging bell of the field device, receives a wireless emergency call signal which is an event signal generated from the wireless paging bell of the field device, Output connector for a waterproof microphone is connected to output a fault diagnosis signal and a battery check signal to the waterproof microphone of the field device and is generated at the waterproof microphone of the field device The microphone signal for event signal is input and the input / output connector for the field speaker is connected to another input / output terminal P1.5, so that the fault diagnosis signal and the battery check signal are outputted to the field speaker of the field device, And the input / output connector for the CCTV camera is connected to another input / output terminal P1.4, the fault diagnosis signal and the battery check signal are outputted to the field device for the CCTV camera, CCTV video signal, which is an event signal to be generated, is inputted and an input / output connector for a beacon is connected to another input / output terminal P1.3, and a trouble diagnosis signal and a battery check signal are outputted to the beacon side of the field device, And a sensor node type short range wireless communication unit is connected to the input / output terminal P1.0 It receives the fault diagnosis signal and battery check signal from the NCICA open platform module and transmits the fault diagnosis check data and battery check data of the field device to the NCICA open platform module. The output terminal of the microphone regulator is connected to the input terminal P3.6 And an electric signal of the field device sensed by the microphone regulator is input to the IoT smart remote control device of the on-site device through the NCICA open platform module.
The system of claim 1, wherein the NCICA open platform module (200)
A module body 210 which is formed in a box shape and protects and supports each device from external pressure,
A power supply unit 220 located at one side of the inner space of the platform main body and supplying 5V or 12V power to each device,
Channel communication line and a plurality of field devices located in the vicinity of the module main body and connected to the one-to-one short-range wireless communication network, Channel short-range wireless communication unit 230 receiving the failure diagnosis check data and the battery check data of the field device as a response signal,
The broadcast signal is output from the integrated control server unit located at a remote location to the field speaker of the VoIP / IP-based field device, and the event signal (radio emergency call signal) of the wireless call ring of the field device is input An emergency bell IP broadcast terminal unit 240 for directly connecting between the integrated control server unit and the waterproof microphone of the field device or between the integrated control server unit and the field speaker of the field device,
A wired / wireless communication unit 250 connected to the integrated control server unit located at a remote location and a wired / wireless communication network for receiving a fault diagnosis signal and a battery check signal transmitted from the integrated control server unit and transmitting fault diagnosis check data and battery check data of the field device, )Wow,
An NCICA open platform control unit (NCICA) that controls the overall operation of each device and intelligently provides an IoT environment suitable for the situation of a field device, connected to a power unit, a multi-channel short-range wireless communication unit, an emergency bell IP broadcast terminal unit, 260). The IoT smart remote control device of the on-site device check type using the NCICA open platform module.
5. The method of claim 4, wherein the emergency bell IP broadcast terminal unit (240)
A ring that receives an event signal (a radio emergency call signal) from a radio paging bell of a plurality of field devices connected through a multichannel short-range wireless communication unit and receives the ring signal as a ring signal and sequentially transmits the relay signal to the IP broadcast terminal controller, A relay control unit 241,
When an event signal (a wireless emergency call signal) of a wireless paging bell of a field device is inputted in accordance with a control signal of an IP broadcasting terminal control section, it is converted into an emergency call (CALL) A CALL relay control unit 242 for controlling direct connection between bells,
A waterproof microphone field device control unit 243 connected to the waterproof microphone of the field device and driven according to a control signal of the IP broadcast terminal control unit to control the water microphone of the field device to receive a voice signal generated in the field,
A field speaker field device controller (not shown) connected to the field speaker of the field device and driven according to a control signal of the IP broadcast terminal controller to control the voice output from the integrated controller server of the remote device through the field speaker of the field device 244,
An IP broadcast terminal control unit (not shown) for controlling the overall operation of each device and transmitting the event signal (radio emergency call signal) of the wireless paging bell of the field device to the NCICA open platform control unit, 245). The IoT smart remote control device of the on-site device check type using the NCICA open platform module.
6. The IP broadcasting terminal control system according to claim 5, wherein the IP broadcasting terminal control unit (245)
The memory unit is connected to the input terminals SD_DQ0 to SD_DQ15 to bring in the telephone number and IP information of the integrated control server unit that has been stored in advance and the memory unit is connected to the output terminals SD_A0 to SD_A11 to store the telephone number of the integrated control server unit, The NCICA open platform control unit is connected to the input terminals SD_CLK, SD_CKE, SD_WE, SD_CAS, SD_CS, SD_DQM0, SD_DQM1, SD_BSA1 and SD_BSA0 of the wireless call bell, The DQM signal and the BSA signal are inputted to the NCICA open platform control unit, the NCICA open platform control unit is connected to another input terminal EN, the start signal is input from the NCICA open platform control unit, the NCICA open platform control unit is connected to the reset terminal, And the NCICA open platform control unit is connected to the output terminals GPIO17 to 31 so that the wireless call bell of the field device And a field speaker field device control unit connected to an output terminal GPIO10 via a resistor R199 to output a voice output from a remote control unit to a field speaker of a field device, When a CALL relay control unit is connected and an event signal (radio emergency call signal) of the wireless paging bell of the field device is input, the CALL relay control unit is sequentially converted into an emergency call (CALL) And an output signal is output to directly connect between the wireless call bell and a ring relay control unit is connected to the input terminal GPIO2 to ring an event signal (radio emergency call signal) from the wireless call bell of a plurality of field devices Ring) signal and relay it, and the field speaker field device control section is connected to the output terminal GPIO0, Check field device type IoT smart remote control device via the NCICA open platform module being configured to output a sound to be output from the integrated control unit the server side increases.
5. The system of claim 4, wherein the NCICA open platform controller (260)
A service manager unit 261 that is connected to the on-site equipment and performs service management functions related to fault diagnosis and battery check on the on-site equipment,
A memory unit 262 for storing the failure diagnosis check data and the battery check data transmitted from the field device,
A topology control manager 263 for forming a location-based mesh-type dynamic network between the field devices,
A device manager unit 264 for performing registration, location and status management of the smart device of the manager and the performance management of the service currently being performed, a field device (wireless call bell, waterproof microphone, field speaker, CCTV camera,
A multi-channel short-range wireless communication control unit 265 for controlling the multichannel short-range wireless communication unit to be connected to the short-range wireless communication network at a ratio of 1: 1 by giving identification IDs to a plurality of field devices located near the module main body, ,
A wired / wireless communication formation control unit 256 for controlling the wired / wireless communication unit to be connected to a wired / wireless communication network and an integrated control server unit located at a remote location,
When an event signal (radio emergency call signal) of a wireless call bell of a field device is input while an emergency bell IP broadcast terminal is driven to output a broadcast signal to a field speaker of a field device of a VoIP / IP system, And an emergency bell IP broadcast terminal control unit 267 for controlling the direct connection between the integrated control server unit and the waterproof microphone of the field device and between the integrated control server unit and the field speaker of the field device IoT Smart remote control with on-site device check via NCICA open platform module.
The system according to claim 1, wherein the integrated control server unit (300)
A video server unit 310 for receiving a field image taken by a CCTV camera of the field device and transmitting the field image to a monitoring server,
A health check that transmits the health check signal composed of the fault diagnosis signal and the battery check signal of the field device to the NCICA open platform control section and receives the fault diagnosis check data and the battery check data of the field device as a response signal, A server unit 320,
When an event signal (a radio emergency call signal) of a wireless paging bell of a field device is input after outputting a broadcast signal by being connected to the emergency bell IP broadcast terminal of the NCICA open platform control unit through a VoIP / IP method, An emergency IP broadcast server unit 330 for controlling the IP phone to form an IP phone call with a user located in the field device through the control terminal IP phone,
A monitoring server 340 for monitoring the field image transmitted from the video server unit, the failure diagnosis check data and the battery check data of the field device transmitted from the health check server,
A firewall module 350 for blocking unauthorized access from the outside to the inside or outside the wired / wireless communication network in order to secure broadcasting information,
A broadcast operating PC unit connected to the video server unit, the health check server unit, the emergency IP broadcast server unit, and the monitoring server to control the overall operation of each device so that a plurality of broadcast sound sources are simultaneously transmitted from one device (360). The IoT smart remote control device of the on-site device check type using the NCICA open platform module.
(S110) connecting the smart sensor node unit to one side of the field device to form a local wireless communication network with the NCICA open platform module,
A step S120 of sending a fault diagnosis signal and a battery check signal from the integrated control server unit to the NCICA open platform module,
In the NCICA open platform module, a plurality of smart sensor node units and a group network are formed and connected by multi-channel short-range wireless communication, and the central control unit is connected to wired / wireless communication, (S130) receiving the smart sensor node and transmitting it to the smart sensor node unit,
A step S140 of receiving the fault diagnosis signal and the battery check signal from the NCICA open platform module at the smart sensor node unit and transmitting the fault diagnosis check data and battery check data faulted by the field device to the NCICA open platform module,
(S150) of transmitting the fault diagnosis check data and the battery check data of the field device to the integrated control server section in the NCICA open platform module and intelligently providing the IoT environment suitable for the situation of the field device,
The integrated control server unit receives the failure diagnosis check data, compares the failure diagnosis check data with previously stored reference sound data to check the state of the field device, and receives the battery check data to analyze and notify the battery replacement time (S160) IoT smart remote control method with on-site device check through NCICA open platform module.
A step S210 of transmitting an event signal to the NCICA open platform module when an event signal (a radio emergency call signal, a speaker signal, a microphone signal) of the field device itself is generated in the smart sensor node unit,
Transmitting an event signal of the field device to the integrated control server section in the NCICA open platform module (S220)
The emergency bell IP broadcasting terminal of the NCICA open platform module receives the broadcasting signal from the remote control server unit located at the remote location, broadcasts the broadcasting signal to the field speaker of the VoIP / IP based field device, (Emergency call signal) is input, it is converted into an emergency telephone and directly connected between the integrated control server unit and the waterproof microphone of the field device or between the integrated controller server and the field speaker of the field device (S230 )Wow,
When the event signal (radio emergency call signal) of the wireless paging bell of the field device is input, the integrated control server section normally outputs the broadcast signal, calls the control terminal IP phone, And forming an IP phone call with a user located in the device (S240).

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