KR102307726B1 - Building automation system using proximity communication - Google Patents

Abstract

Provided is a building automation system using a proximity communication. The building automation system using the proximity communication comprises: a zone controller that is wired to each of a control target device, a fire detection module, and a firefighting device in a zone, and transmitting a control command to each of the control target device, the fire detection module, and the firefighting device in the zone; a mobile terminal that transmits the control command based on the zone information to the zone controller by short-distance communicating with the zone controller after receiving the zone information from the zone controller when authenticate-processed by the zone controller by close communicating with the zone controller; and a tag that transmits the specific zone information within the zone to the mobile terminal by close communicating with the mobile terminal. Therefore, the present invention is capable of having an effect of simplifying a permission setting.

Description

Building automation system using proximity communication

The present invention relates to a building automation system using close-range communication.

A building automation system is a system introduced to economically maintain a building or an office environment.

The building automation system uses a computer to automate various functions in the building to reduce manpower. Building automation systems generally include functions such as electricity, access, water supply and drainage, air conditioning, disaster prevention, sanitation, lighting, and parking facilities, as well as intelligent functions such as communication functions.

In the conventional building automation system, since the various functions described above were managed in a centralized manner, there was a problem in that proper control was not achieved for each zone in the building. That is, the manager or the building user could not optimally control various control target devices arranged in a specific area within the central building according to the environment.

Moreover, despite the rapid spread of smartphones, the building automation system and the smartphone are hardly interlocked, and even if there are some interlocking functions, both the smartphone access right setting process and the interworking setting process with the device to be controlled are complicated. There was the inconvenience of doing it. In addition, emergency information such as fire occurrence cannot be provided quickly, and there is a limit to automatic firefighting.

The problem to be solved by the present invention is to provide a building automation system using proximity communication that can control a controlled device in a building with a smart phone by safely and easily connecting a smart phone and a controlling device without complicated permission setting or interlocking setting. aim to

In addition, an object of the present invention is to provide a building automation system using proximity communication capable of quickly coping with fire occurrence and enabling rapid suppression of lifesaving and fire.

The problems of the present invention are not limited to the problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

A building automation system using proximity communication according to an embodiment for solving the above problems is wired to each of a control target device, a fire detection module, and a firefighting mechanism in a zone, and a control target device, a fire detection module and a firefighting device in the zone a zone controller that transmits a control command to each of the units; communicates in close proximity with the zone controller to receive zone information from the zone controller when authentication is processed by the zone controller; and a mobile terminal for transmitting a control command based on zone information and a tag for transmitting specific area information within the zone to the mobile terminal in close communication with the mobile terminal, wherein the fire detection module includes: a body part; A first camera part disposed on one side, a second camera part disposed on the other side of the body part, and a cover part covering the body part, wherein the body part includes a first sensor module, a second sensor module, a speaker part, a first a light emitting unit and a second light emitting unit, wherein the first sensor module includes a heat sensor and a smoke sensor, the second sensor module includes a voice recognition sensor and a GPS sensor, the first sensor module and the The second sensor modules are spaced apart from each other in a first direction, and the speaker unit is disposed under the first sensor module and the second sensor module, and has a circular shape in plan view, and the first light emitting unit is disposed in a planar shape. It has a circular rim shape and is disposed to surround the speaker part, and the second light emitting part has a circular rim shape in plan view and is disposed to surround the first light emitting part, and the first light emitting part and the speaker part A first pattern region including a plurality of air passages is disposed between them, the first pattern region is formed in a planar circular rim shape, and a plurality of air passages are formed between the second light emitting unit and the first light emitting unit. a second pattern region including The plurality of air passages disposed include a first air passage and a second air passage, wherein the first air passage is filled with silicon, the second air passage is filled with tedradecane, the first air passage and The second air passage is made in a cylindrical shape, and has a diameter of 0.01 cm to 0.015 cm, and a heat blocking part is disposed on the body part, and the heat blocking part is the first sensor module and the second sensor module and a second light emission. It is located between the parts, and the heat-blocking part includes a plurality of heat-blocking pieces that are spaced apart from each other in the first direction, and the first camera part is configured to move the camera and the camera in a second direction that intersects the first direction. A first rotating member for rotating and a second rotating member for rotating the camera in the first direction, wherein the cover includes first to third hole regions including a plurality of holes, the first hole region is located corresponding to the first sensor module, the second hall area is located corresponding to the second sensor module, the third hall area is located corresponding to the speaker unit, and the fire detection module is a fire occurrence When this is detected, fire detection information is generated and transmitted to the portable terminal, and the portable terminal that has received the fire detection information generates a fire control command and transmits it to the zone controller, and the fire control command is transmitted to the portable terminal. The zone controller transmits a fire control command to the control target device and the fire detection module, and the first light emitting unit and the second light emitting unit of the fire detection module that received the fire control command output a warning light source, The speaker unit outputs a warning sound, the zone controller receiving the fire control command generates a fire control command and transmits the generated fire control command to the fire fighting device, and the fire fighting device receives the fire control command and is configured to spray fire water.

According to the building automation system using proximity communication according to an embodiment, when the mobile terminal is connected to the zone controller through proximity communication, the authentication process is performed by the zone controller, so that the authority setting is simple.

In addition, since the mobile terminal according to the present invention receives zone information from the zone controller through proximity communication after authentication processing and transmits a control command based on the zone information to the zone controller via short-distance communication, There is an effect that the operation can be controlled without a complicated setting process.

In addition, according to the present invention, by placing a tag in a specific area within the area, the mobile terminal receives specific area information from the tag in the specific area and generates a control command based on the specific area information, so that more appropriate control for each specific area is possible. It works.

Furthermore, it is possible to quickly cope with the occurrence of a fire, so that it is possible to save lives and quickly extinguish the fire.

Effects according to the embodiments are not limited by the contents exemplified above, and more various effects are included in the present specification.

1 is a diagram schematically illustrating a building automation system using proximity communication according to an embodiment.
2 is a diagram schematically illustrating the configuration of a zone controller of a building automation system using proximity communication according to an embodiment.
3 is a diagram schematically illustrating a configuration of a mobile terminal of a building automation system using proximity communication according to an embodiment.
4 is a diagram schematically illustrating a configuration of a tag of a building automation system using proximity communication according to an embodiment.
5 is a diagram schematically illustrating a fire detection module of a building automation system using proximity communication according to an embodiment.
6 is a diagram schematically illustrating a signal flow of a building automation system using proximity communication according to an embodiment.
7 is a diagram schematically illustrating a signal flow of a building automation system using proximity communication according to another embodiment.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention belongs It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims.

It should be understood that all flow diagrams, state transition diagrams, pseudo code, and the like may be tangibly embodied on computer-readable media and represent various processes performed by a computer or processor, whether or not a computer or processor is explicitly shown.

The functions of the various elements shown in the figures including a processor or functional blocks represented by similar concepts may be provided by the use of dedicated hardware as well as hardware having the ability to execute software in association with appropriate software. When provided by a processor, the functionality may be provided by a single dedicated processor, a single shared processor, or a plurality of separate processors, some of which may be shared. Like reference numerals refer to like elements throughout.

Hereinafter, specific embodiments will be described with reference to the accompanying drawings.

1 is a diagram schematically showing a building automation system using proximity communication according to an embodiment, and FIG. 2 is a diagram schematically showing the configuration of a zone controller of a building automation system using proximity communication according to an embodiment, FIG. 3 is a diagram schematically showing a configuration of a mobile terminal of a building automation system using proximity communication according to an embodiment, and FIG. 4 is a diagram schematically showing a configuration of a tag of a building automation system using proximity communication according to an embodiment 5 is a diagram schematically showing a fire detection module of a building automation system using proximity communication according to an embodiment, and FIG. 6 is a schematic diagram of a signal flow of a building automation system using proximity communication according to an embodiment 7 is a diagram schematically illustrating a signal flow of a building automation system using proximity communication according to another embodiment.

As shown in FIG. 1, the building automation system includes a zone controller 100 for controlling the operation of a control target device 500, a fire detection module FD, and a firefighting mechanism FE in the zone 10, a zone controller ( 100) through the mobile terminal 200 for close communication and short-distance communication, the tag 300 for transmitting information on the specific area 20 within the zone to the mobile terminal 200, the zone controller 100 and the communication line 400 It may be composed of a plurality of control target devices 500 and the like connected by wire.

The zone controller 100 is wired through a communication line 400 with the control target device 500, the fire detection module FD, and the firefighting mechanism FE disposed in the zone 10, and the control target device 500 , control the operation of the control target device 500, the fire detection module (FD), and the firefighting mechanism (FE) by transmitting the control command received from the mobile terminal 200 to the fire detection module (FD) and the firefighting mechanism (FE) can do.

The zone controller 100 is illustrated as being located outside the zone 10 in FIG. 1 , but may be located inside the zone.

The zone controller 100, the device to be controlled 500, the fire detection module FD, and the firefighting mechanism FE may be connected through a communication line 400 such as Ethernet or RS-485. A protocol used for the communication line 400 includes BACnet, an international standard for building automation networks, and KNX, LonWork, and the like may also be used. In addition, when applied to a home, a home network may be used, and an industrial fieldbus or industrial Ethernet may be used in a factory environment.

When the mobile terminal 200 is connected to the zone controller 100 through proximity communication and authenticated by the zone controller 100, the mobile terminal 200 receives zone information from the zone controller 100 and communicates with the zone controller 100 in short-range communication. A control command based on the zone information is transmitted to the zone controller 100 . The zone information may include location information within the zone, information about the control target device 500 , information about the fire detection module FD, and information about the firefighting mechanism FE.

The portable terminal 200 may be a portable terminal device such as a smart phone or a tablet PC, but is not limited thereto, and if there is a function to download and install software for generating control commands (software for control commands), any Any kind of terminal device is also possible.

The tag 300 is installed for each specific area 20 in the zone 10 and is connected to the portable terminal 200 through proximity communication to transmit specific area information to the portable terminal 200 . The specific area information may include location information of the specific area, information regarding the control target device 500 existing in the specific area, information regarding the fire detection module FD, and information regarding the fire fighting mechanism FE.

The controlled device 500 is connected to the zone controller 100 and its operation is controlled by the zone controller 100 . The control target device 500 may include a lighting device, a heating/cooling device, an entrance door, an air conditioning device, etc. that exist in the zone and control the environment of a building or office.

The fire detection module FD is connected to the zone controller 100 and its operation is controlled by the zone controller 100 . The fire detection module FD may be a device capable of detecting a flame, smoke, etc. existing in an area, and outputting a warning sound or a warning light source therefor. The fire detection module (FD) will be discussed in more detail later.

The firefighting mechanism FE is connected to the zone controller 100 and its operation is controlled by the zone controller 100 . The firefighting mechanism FE may include a device such as a sprinkler, a fire extinguisher, etc. which is present in the area and can spray firefighting water when a fire occurs.

As shown in FIG. 2 , the zone controller 100 includes a proximity communication unit 102 , a short-range communication unit 104 , a storage unit 106 , a device communication unit 108 , an authentication processing unit 110 , a control unit 112 , and the like. may include

The proximity communication unit 102 is a part for performing proximity communication with the mobile terminal 200 . Near field communication (NFC) is representative as proximity communication, and radio frequency identification (RFID) may also be classified as one type of proximity communication. The short-range communication unit 104 is a part for short-distance communication with the mobile terminal 200 . For short-distance communication, wireless LAN (Wi-Fi) or Bluetooth (Bluetooth) are representative, and communication such as Zigbee or UWB (Ultra Wide Band) may also be used.

The storage unit 106 stores zone information together with software for controlling the operation of the zone controller 100 . In addition, the storage unit 106 stores URL information from which software for control commands installed in the portable terminal 200 can be downloaded. In addition, the storage unit 106 stores the ID and password of the registered user required for authentication processing.

In some embodiments, the storage unit 106 may be formed of a blockchain network. As is known, a blockchain network is a distributed data storage technology that stores data in blocks, connects them in a chain, and replicates and stores them on numerous computers at the same time. Also called public ledger. Transaction history is sent to all users participating in a transaction without keeping transaction records on a centralized server, and every transaction has the advantage of preventing data forgery or falsification by sharing and collating information among all transaction participants.

The device communication unit 108 is a part for communicating with the control target device 500 , the fire detection module (FD), and the firefighting mechanism (FE). The device communication unit 108 transmits a control command of the portable terminal 200 to the control target device 500 , the fire detection module FD, and the firefighting mechanism FE. The zone controller 100, the control target device 500, the fire detection module (FD), and the firefighting mechanism (FE) are connected through a communication line such as Ethernet or RS-485, and at this time, the device communication unit 108 is an Ethernet communication interface It can be a module or an RS-485 communication interface module.

The authentication processing unit 110 is a part that authenticates the mobile terminal 200 connected through proximity communication. The authentication processing unit 110 compares the ID and password received from the mobile terminal 200 through proximity communication with pre-stored information and grants control authority to the mobile terminal 200 when they match. The authentication processing unit 110 classifies whether the mobile terminal 200 is an administrator or a general user according to pre-stored information, and informs the control unit 112 of this.

The controller 112 transmits, to the mobile terminal 200 , URL information from which software for a control command can be downloaded when the first proximity communication is performed between the mobile terminal 200 and the proximity communication unit 102 . If it is not the first proximity communication between the portable terminal 200 and the proximity communication unit 102 , the authentication processing for the portable terminal 200 is performed through the authentication processing unit 110 .

After the authentication processing by the authentication processing unit 110 is completed, the control unit 112 transmits the zone information to the portable terminal 200 . At this time, if the authenticated mobile terminal 200 is a manager terminal, the manager mode setting information is transmitted together with the zone information, and if the authenticated mobile terminal 200 is a general user terminal, the general user mode setting information is transmitted. After transmitting the zone information, when a control command based on zone information is received from the mobile terminal 200 through the short-range communication unit 104 , the control command is transmitted to the corresponding control target device through the device communication unit 108 .

As shown in FIG. 3 , the mobile terminal 200 includes a proximity communication unit 202 , a short-range communication unit 204 , a display unit 206 , an input unit 208 , a mobile communication unit 210 , a storage unit 212 , and the like. do.

The proximity communication unit 202 is a part for performing close-range communication with the zone controller 100 , and the short-range communication unit 204 is a part for short-range communication with the zone controller 100 .

The mobile terminal 200 receives authentication processing from the zone controller 100 through proximity communication, and receives URL information for software download for control commands and zone information within the building. In addition, the mobile terminal 200 transmits a control command based on the zone information to the zone controller 100 to the zone controller 100 through short-distance communication.

The display unit 206 may be composed of a display panel such as LCD or LED, and the input unit 208 may be composed of a keypad or a button. and the input unit 208 may be integrally configured. When the control command software installed in the mobile terminal 200 is executed, the control screen is displayed on the display unit 206, and the user touches the control screen to control the device 500, the fire detection module (FD), the firefighting mechanism ( FE) can be controlled.

The mobile communication unit 210 is a part for voice call or data communication. When the mobile terminal 200 receives the URL information for downloading the software for the control command, it can access the URL through the mobile communication unit 210 to download the software.

The storage unit 212 is a part for storing various application software and data. The storage unit 212 according to the present invention stores software for control commands and zone information.

The control unit 214 configures a control screen for generating a control command by executing software for a control command and processing the zone information received from the zone controller 100 . The control unit 214 generates a control command for controlling the operation of the control target device according to the zone information and transmits it to the zone controller 100 through the short-range communication unit 204 .

As shown in FIG. 4 , the tag 300 may include a proximity communication unit 302 for close communication with the mobile terminal 200 , a storage unit 304 for storing information on a specific area within an area, and the like.

When the mobile terminal 200 enters a specific area within the area and tags the tag 300 , information on the specific area is received from the tag 300 through proximity communication. By receiving the specific area information from the tag 300 , the mobile terminal 200 operates more accurately and precisely with respect to the control target device 500 , the fire detection module FD, and the firefighting mechanism FE disposed in the specific area. can take control.

As shown in FIG. 5 , the fire detection module FD has a sliding body that can open and close the body BP, the cameras CP1 and CP2 disposed on both sides of the body BP, and the body BP. It may include a type of cover part (CVP).

In some embodiments, the camera unit may include a first camera unit CP1 and a second camera unit CP2 , and the first camera unit CP1 and the second camera unit CP2 are disposed between the body unit BP. and may be aligned in the first direction (X-axis direction). Specifically, the first camera unit CP1, the body unit BP, and the second camera unit CP2 may be sequentially disposed in the first direction (X-axis direction).

The body part BP may include a first sensor module SM1 , a second sensor module SM2 , a speaker part SPP , a first light emitting part EL1 , and a second light emitting part EL2 .

The first sensor module SM1 and the second sensor module SM2 may be disposed to be spaced apart from each other in the first direction (X-axis direction).

In some embodiments, the first sensor module SM1 may include a heat sensor and a smoke sensor, and the fire detection module FD may detect a fire through the first sensor module SM1.

In some embodiments, the thermal sensor of the first sensor module SM1 is a temperature sensor that operates when a predetermined temperature is exceeded, and may include both a non-contact type and a contact type. The contact method is a method of measuring the temperature by directly contacting the temperature sensor to the measurement object, and the non-contact method is a method of measuring heat radiated from the measurement object. For example, it may include all of a thermocouple, a metal thermometer, a thermistor, an IC temperature sensor, a magnetic temperature sensor, a thermopile, a pyroelectric temperature sensor, and the like.

In some embodiments, the smoke detection sensor of the first sensor module SM1 may include both an ionization detector and a photoelectric detector as a smoke sensor. The ionization type detects fire by using a change in current when smoke enters the detection unit, and the photoelectric type detects fire by changing the value of the current that normally flows by the photoelectric element by the smoke when smoke enters the detection unit. .

In some embodiments, the second sensor module (SM2) is a sensor for detecting the position of a person in a building, and a voice recognition sensor for recognizing an urgent voice frequency such as a person's scream or shout by embedding an Arduino voice recognition module, etc.; It may include a GPS sensor for obtaining current location information by analyzing a GPS signal generated from a person's smart device in the building. The fire detection module FD may detect the position of a person through the second sensor module SM2.

In some embodiments, the speaker unit SPP may be disposed below the first sensor module SM1 and the second sensor module SM2 . For example, the speaker unit SPP may be positioned opposite to the second direction (Y-axis direction) with respect to the first sensor module SM1 and the second sensor module SM2 . The speaker unit SPP may be formed in a planar circular shape, but is not limited thereto.

In some embodiments, the speaker unit SPP may output a warning sound when a fire occurs.

In some embodiments, the first light emitting part EL1 may be disposed to surround the speaker part SPP. For example, the first light emitting part EL1 may have a circular rim shape in plan view and may be disposed to surround the outside of the speaker part SPP.

In some embodiments, the first light emitting unit EL1 may be disposed to be spaced apart from the speaker unit SPP. The first light emitting unit EL1 may output a warning light source when a fire occurs.

In some embodiments, the second light emitting part EL2 may be disposed to surround the first light emitting part EL1 . For example, the second light emitting part EL2 may have a circular rim shape and may be disposed to surround the outside of the first light emitting part EL1 .

In some embodiments, the second light emitting part EL2 may be disposed to be spaced apart from the first light emitting part EL1 . The second light emitting unit EL2 may output a warning light source when a fire occurs.

In some embodiments, a first pattern area PA1 including a plurality of air passages may be disposed between the first light emitting unit EL1 and the speaker unit SPP. The first pattern area PA1 may have a circular edge shape and may be positioned between the first light emitting part EL2 and the speaker part SPP.

In some embodiments, a second pattern area PA2 including a plurality of air passages may be disposed between the second light emitting part EL2 and the first light emitting part EL1 . The second pattern area PA2 may have a circular edge shape and may be positioned between the second light emitting part EL2 and the first light emitting part EL1 .

In some embodiments, the body portion BP may be formed of a metal material or a plastic material. A buffer material M1 may be filled in the air passages of the first pattern area PA1 and the second pattern area PA2 . As the buffer material M1, various materials such as silicone, rubber, and sponge may be used, and the present invention is not limited to the material prepared above, and various materials for shock absorption may be provided. As such, when the buffer material M1 is disposed in the air passages of the first pattern area PA1 and the second pattern area PA2, even if an impact is transmitted to the building such as an earthquake, the speaker unit SPP and the first light emitting unit Vibration or shock transmitted to the EL1 and the second light emitting unit EL2 may be attenuated.

In some embodiments, the air passages of the first pattern area PA1 and the second pattern area PA2 may be filled with the phase change material M2 . Such a phase change material M2 can prevent deformation of the speaker unit SPP, the first light emitting unit EL1, and the second light emitting unit EL2 according to the temperature change, and block heat to obtain the effect of heat insulation. can The phase change material M2 includes tedradecane, octadecane, nonadecane, calcium chloride, and the like, and may be filled in the air passage using other materials according to the user's needs.

In some embodiments, a plurality of air passages in the first pattern area PA1 and the second pattern area PA2 may be disposed, and the phase change material M2 and the buffer material M1 are alternately filled in the plurality of air passages. can be For example, each of the first pattern area PA1 and the second pattern area PA2 may include a plurality of first and second air passages, and the interior of the first air passage is filled with silicon, and the second air passage is filled with silicon. The inside of the air passage is filled with tedradecane, the first air passage and the second air passage may be alternately arranged.

In some embodiments, the air passages of the first pattern area PA1 and the second pattern area PA2 may have a cylindrical shape or a square pillar shape, and may have a diameter of 0.01 cm to 0,015 cm.

In some embodiments, the first heat-blocking part HSP1 and the second heat-blocking part HSP2 may be disposed on the body part BP.

The first heat blocking portion HSP1 may be disposed on the lower surface of the body portion BP, and the second heat blocking portion HSP2 may be disposed on the front surface of the body portion BP, the first sensor module SM1, the second It may be positioned between the sensor module SM2 and the second light emitting unit EL2 . In some embodiments, the second heat-blocking part HSP2 may be formed of a plurality of heat-blocking pieces, and the plurality of heat-blocking pieces may be disposed to be spaced apart from each other in the first direction (X-axis direction).

In some embodiments, the thickness in the second direction (Y-axis direction) of the first heat-blocking part HSP1 may be 1 mm to 3 mm, and the thickness of the second heat-blocking part HSP2 in the second direction (Y-axis direction) The thickness may be 0.5 mm to 1 mm.

Each of the first heat-blocking part HSP1 and the second heat-blocking part HSP2 may be a composition in which glass fire, phenolic resin, and calcium carbonate are mixed. For example, the second heat-blocking cover HSC2 may include 75% by weight of glass fiber, 17% by weight of phenolic resin, and 8% by weight of calcium carbonate.

The first camera unit CP1 rotates the camera CAM, the first rotation member RP1 for rotating the camera CAM in the second direction (Y-axis direction), and the camera CAM in the first direction (X-axis direction) It may include a second rotating member (RP1) for rotating. The first rotation member RP1 may connect the side surface of the body part BP and the first camera part CP1. The first rotation member RP1 and the second rotation member RP2 may control the rotation of the camera CAM using a rotation motor or the like.

Since the configuration of the second camera unit CP2 is the same as that of the first camera unit CP1, a redundant description thereof will be omitted.

In some embodiments, the cover part CVP may cover the body part BP. The cover part CVP may be in non-contact with the body part BP, and both ends of the cover part CVP are attached to the first rotation member RP1 of each of the first camera part CP1 and the second camera part CP2. can be contracted. The cover part CVP may be configured to move upwards of the body part BP in a sliding manner to expose the body part BP.

In some embodiments, the cover part CVP may include a plurality of hole areas. The plurality of hole areas may be defined as areas in which a plurality of holes passing through the cover part CVP are disposed. The plurality of hole areas may include a first hole area, a second hole area, and a third hole area. When the cover part CVP covers the body part BP, the first hole area may be positioned to correspond to the first sensor module SM1 , and the second hole area may correspond to the second sensor module SM2 . may be positioned, and the third hole area may be positioned to correspond to the speaker unit SPP. Also, the first Hall area may overlap the first sensor module SM1 in the thickness direction, the second Hall area may overlap the second sensor module SM2 in the thickness direction, and the third Hall area may be the speaker It may overlap with the part SPP in the thickness direction.

Also, in some embodiments, the cover part CVP may include a transparent region and an opaque region. When the cover part CVP covers the body part BP, the transparent region may include the first light emission of the body part BP. It may be positioned corresponding to the part EL1 and the second light emitting part EL2 . In addition, the transparent region may overlap the first light emitting part EL1 and the second light emitting part EL2 of the body part BP in the thickness direction.

A plurality of buffer patterns may be disposed on a surface of the cover portion CVP facing the body portion BP. The plurality of buffer patterns may include a plurality of protrusions made of a silicon material. In some embodiments, a plurality of buffer patterns may be disposed in the opaque area.

The camera units CP1 and CP2 may photograph within a certain radius of the fire detection module FD of the installed place during fire detection, and may transmit the photographed screen in real time. The camera units CP1 and CP2 may transmit the location of the fire and the fire image to the portable terminal 200 and/or the zone controller using an infrared camera that captures an infrared image and transmits it to the controller, and a CD camera.

As shown in FIG. 6 , when the user first brings the mobile terminal 200 to the zone controller 100 , close-range communication is established between the mobile terminal 200 and the zone controller 100 . When the mobile terminal 200 first communicates with the zone controller 100 in close proximity, the zone controller 100 transmits URL information from which software (application) for control commands can be downloaded to the mobile terminal 200 (S10). . If there is a history of the mobile terminal 200 having previously communicated with the zone controller 100 in close proximity, the authentication processing procedure S20 may be immediately performed.

When the mobile terminal 200 receives the URL information, it accesses the URL, downloads the application, and installs the application. When the application is installed, the application is automatically executed, and the authentication processing procedure S20 is performed between the mobile terminal 200 and the zone controller 100 . That is, when the user inputs the previously registered ID and password on the application execution screen of the mobile terminal 200 , the input ID and password are transmitted to the zone controller 100 . The zone controller 100 compares the ID and password with pre-stored information to authenticate the mobile terminal 200 if they match, and rejects the authentication if they do not match. When authentication of the portable terminal 200 is performed, the area controller 100 transmits the area information to the portable terminal 200 (S30).

This zone information transmission procedure is performed when the first proximity communication is connected between the mobile terminal 200 and the zone controller 100, and then, when the wireless terminal 200 and the zone controller 100 are connected to the zone controller 100, the zone information is the same. In this case, the area information transmission procedure can be omitted or only updated area information can be transmitted.

Next, short-range communication is connected between the mobile terminal 200 and the zone controller 100, and the mobile terminal 200 generates a control command based on zone information and transmits the control command to the zone controller 100 (S40). For example, upon receiving the zone information, the mobile terminal 200 may process the zone information and display the zone map on the application execution screen. The user may control the operation of the corresponding controlled device by touching an icon corresponding to the controlled device displayed at each location on the area map.

When the zone controller 100 receives a control command from the mobile terminal 200, it transmits the received control command to the control target device 500 through a communication line (S50) to control the operation of the control target device 500. . Accordingly, the mobile terminal 200 may control the operation of the air conditioner, the lighting fixture, the door, etc. according to the type of the control target device 500 through the zone controller 100 .

In addition, when fire is detected in the fire detection module FD, the fire detection module FD generates and transmits the fire detection information to the portable terminal 200 (S60). The user or manager can receive the fire detection information and determine the authenticity of the fire. For example, it is possible to determine the authenticity of the fire by checking the image information of the corresponding area included in the fire detection information. There is (S70). When the zone controller 100 receives the fire control command from the portable terminal 200, it transmits the fire control command to the control target device 500 (S80). For example, a fire control command may be transmitted to the control target device 500 to cut off electricity to the air conditioner and lighting equipment and to open the door.

Also, the zone controller 100 transmits the fire control command received from the portable terminal 200 to the fire detection module FD (S90). The first light emitting unit EL1 and the second light emitting unit EL of the fire detection module FD that has received the fire control command may output a warning light source, and the speaker unit SPP may output a warning sound.

In addition, when receiving the fire control command from the portable terminal 200, the zone controller 100 generates a fire control command and transmits it to the fire fighting mechanism FE (S99). The firefighting mechanism FE that has received the firefighting control command may spray firefighting water.

As shown in FIG. 7 , first, when a user enters a specific area within an area and brings the portable terminal 200 to the tag 300 located in the specific area, proximity communication is connected between the portable terminal 200 and the tag 300 . . Since the mobile terminal 200 undergoes an authentication procedure through proximity communication with the zone controller 100 before performing proximity communication with the tag 300 , the authentication procedure by the tag 300 is omitted.

When proximity communication is connected between the mobile terminal 200 and the tag 300 , the mobile terminal 200 receives specific region information from the tag 300 ( S100 ). Upon receiving the specific area information, the mobile terminal 200 establishes a short-range communication connection with the area controller 100, generates a control command based on the specific area information, and transmits the generated control command to the area controller 100 (S120).

When the zone controller 100 receives the control command from the portable terminal 200, it transmits the received control command to the control target device 500 through the communication line (S140). The operation of the control target device 500 is controlled according to the control command of the zone controller 100 .

For example, when a user enters a conference room and touches the mobile terminal 200 to a tag installed on the conference room table, the projector, screen, lighting, heating and cooling devices in the conference room can be controlled through the control screen of the mobile terminal 200. do.

In addition, when the user witnesses the occurrence of a fire, the user may generate a fire control command through the control screen of the portable terminal 200 and transmit it to the zone controller 100 ( S150 ). When the zone controller 100 receives the topic control command from the portable terminal 200, it transmits the fire control command to the control target device 500 (S160). For example, a fire control command may be transmitted to the control target device 500 to cut off electricity for the air conditioner and lighting equipment, and to open the door.

In addition, the zone controller 100 transmits the fire control command received from the portable terminal 200 to the fire detection module FD (S170). The first light emitting unit EL1 and the second light emitting unit EL of the fire detection module FD that has received the fire control command may output a warning light source, and the speaker unit SPP may output a warning sound.

In addition, when receiving the fire control command from the portable terminal 200, the zone controller 100 generates a fire control command and transmits it to the fire fighting mechanism FE (S180). The firefighting mechanism FE that has received the firefighting control command may spray firefighting water.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains may be embodied in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

10: Zone
20: specific area
100: zone controller
200 mobile terminal
300: tag
400: communication line
500: control target device
FD: fire detection module
FE: firefighting equipment

Claims (1)

a zone controller connected by wire to each of the control target device, the fire detection module, and the firefighting device in the zone, and transmitting a control command to each of the control target device, the fire detection module, and the firefighting device in the zone;
a mobile terminal that communicates with the zone controller and receives zone information from the zone controller when authentication is processed by the zone controller, and then communicates with the zone controller in short-range communication to transmit a control command based on the zone information to the zone controller; and
and a tag for transmitting information about a specific area within the area to the mobile terminal in close communication with the mobile terminal,
The fire detection module includes a body part, a first camera part disposed on one side of the body part, a second camera part disposed on the other side of the body part, and a cover part covering the body part,
The body unit includes a first sensor module, a second sensor module, a speaker unit, a first light emitting unit and a second light emitting unit,
The first sensor module includes a heat sensor and a smoke sensor, the second sensor module includes a voice recognition sensor and a GPS sensor, and the first sensor module and the second sensor module are spaced apart in a first direction and placed,
The speaker unit is disposed under the first sensor module and the second sensor module, and has a circular shape on a plane,
The first light emitting part is formed in a circular rim shape on a plane and is disposed in a shape surrounding the speaker part,
The second light emitting part is formed in a circular rim shape on a plane and is disposed in a shape surrounding the first light emitting part,
A first pattern area including a plurality of air passages is disposed between the first light emitting unit and the speaker unit, and the first pattern area has a circular rim shape in plan view,
A second pattern area including a plurality of air passages is disposed between the second light emitting unit and the first light emitting unit, and the second pattern area has a circular border shape in plan view,
A plurality of air passages disposed in each of the first pattern area and the second pattern area includes a first air passage and a second air passage, the first air passage is filled with silicon, and the second air passage is Tedradecan is recharged,
The first air passage and the second air passage are made in a cylindrical shape, and have a diameter of 0.01 cm to 0.015 cm,
A heat blocking part is disposed on the body part, and the heat blocking part is located between the first sensor module and the second sensor module and a second light emitting part,
The heat-blocking unit includes a plurality of heat-blocking pieces that are spaced apart from each other in the first direction,
The first camera unit includes a camera, a first rotating member for rotating the camera in a second direction intersecting the first direction, and a second rotating member for rotating the camera in the first direction,
The cover part includes first to third hole regions including a plurality of holes, the first hole region is positioned to correspond to the first sensor module, and the second hole region is positioned to correspond to the second sensor module. is located, and the third hole area is located corresponding to the speaker unit,
The fire detection module generates and transmits fire detection information to the portable terminal when a fire is detected,
The mobile terminal receiving the fire detection information generates a fire control command and transmits it to the zone controller,
The zone controller receiving the fire control command transmits the fire control command to the control target device and the fire detection module, and the first light emitting unit and the second light emitting unit of the fire detection module receiving the fire control command. The light emitting unit outputs a warning light source, the speaker unit outputs a warning sound,
The zone controller receiving the fire control command generates a fire control command and transmits it to the fire fighting device, and the fire fighting device that receives the fire control command is configured to spray fire water.

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