KR101135189B1 - System for controlling personally indoor microclimate and method thereof - Google Patents

Abstract

An indoor microclimate personalization control system and method are disclosed.
The indoor microclimate personalization control system includes a control manager that performs indoor microclimate adjustment in the control area and an integrated control server that controls the control manager of the plurality of control areas. The control manager delivers the user's tag information in the control area to the integrated control server, receives the user's preference profile from the integrated control server, and performs indoor micro-control according to the user's preference profile in the control area. The adjustment manager receives sensor values measured from sensor nodes within the adjustment area and adjusts the indoor microclimate by comparing the sensor values with thresholds of the preferred profile. The integrated control server receives the sensor nodes in the control area and the serial numbers of the control device from the control manager and integrates and manages them in response to the control area. It manages the devices according to the dynamic situation such as adding, deleting or moving them.

Description

Personalized control system and method for indoor microclimate {SYSTEM FOR CONTROLLING PERSONALLY INDOOR MICROCLIMATE AND METHOD THEREOF}

The present invention relates to an indoor environment control technology, and more particularly, to an indoor microclimate personalization control system and method thereof based on a wireless sensor network.

Recent advances in ubiquitous technology promise to make life more convenient and comfortable for individuals. Ubiquitous technology is used not only in the IT field but throughout society, and this trend will continue.

Recently developed new cities such as Songdo New Town and Paju New Town promise to use U-City more aggressively in accordance with these trends, which are currently the most used in the ubiquitous technology field and are expected to be developed in the future. The field is a field of wireless sensor networks such as Radio-Frequency IDentification (RFID) and Ubiquitous Sensor Network (hereinafter referred to as USN).

Among them, the wireless sensor network uses routers or gateways to collect data collected from each sensor node based on a short range wireless communication protocol using Zigbee or other radio frequency (RF) bands at low power from a plurality of randomly dispersed nodes. It is a technology that combines sensor and wireless communication that transmits to server through relay method and has been researched and developed for environmental monitoring.

For example, Coventry University's Cogent Computing ARC lab in Australia uses a sensor network applied to buildings to measure temperature, humidity, light intensity, and carbon dioxide concentration at various sampling intervals. Research has been conducted to apply to CO ₂ emission-reduced housing complexes.

In addition, many researches and developments have been conducted in this field in Korea. Based on the recent development of the Intelligent Building Systems Technology Research Institute, the wireless sensor and gateway for building control supporting Zigbee-like short range communication standards (802.15.4) The indoor wireless sensor detects the ambient temperature, humidity, and illuminance to transmit data to a gateway within a radius of 30m and can transmit wireless sensor information remotely through a sensor network.

In addition, research has been conducted to attempt personalized indoor microclimate control through sensor nodes and devices connected to the home network. For example, Soonchunhyang University proposed a service model that provides an intelligent home network service using a wireless sensor network composed of fixed sensor nodes arranged in a home and a user identification node attached to a user in a home network environment.

It builds a user preference profile registered in the home server as a database and environmental data collected from fixed sensor nodes as a database, analyzes the collected situation information, and automatically sets and automatically controls home appliances according to each user's preferences. It suggested how to provide services.

However, various related studies that are currently being researched or developed or conducted are preferred to develop dynamic situations such as movement, addition and deletion of sensor nodes or control devices as well as users in various spaces within the building, or users' preference after indoor microscopic observation. If a profile is not established or even if this preference profile exists, in some cases the preferred optimal microclimate condition differs from what is recorded in the database, the system gradually learns a new preference pattern for a particular user and, based on that, It does not cover more effective and efficient personalization-based indoor microclimate control mechanisms, such as improving the indoor microclimate control preference profile.

Therefore, there is a need for a system and method for performing a highly flexible and functionally efficient control of indoor microclimate in a building.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide an indoor microscopic personalization control system and a method for performing highly controllable and functionally scalable control in indoor microclimate control in a building.

Indoor microclimate personalization control system according to one feature of the present invention

A system for controlling indoor microscopic climate of each space in a building according to a user, the system comprising: at least one control manager configured to identify a user located in a control area and perform indoor microclimate control in a control area corresponding to the user; And an integrated control to transmit the indoor microclimate preference profile corresponding to the user identified by the at least one control manager to the control manager, and to store and manage a record of the indoor microcontrolling operation performed by the control manager. And a server, wherein the control manager includes at least one sensor node for measuring indoor microclimate factors in the control area and at least one control device for controlling indoor microclimate factors in the control area, wherein the integrated control server Receives the serial number of the sensor node and the control device from the at least one control manager, characterized in that for managing in response to the control area.

Indoor microclimate personalization adjustment method according to another feature of the present invention,

A method of controlling indoor microscopic climate of each space in a building according to a user, the method comprising: recognizing a tag information of a user within the controlled area by a control manager that controls the controlled indoor microscopic climate within a control area; The integrated control server which performs the control on the adjustment manager extracts the user's preference profile based on the tag information recognized by the adjustment manager, and the preference along with the profile of the sensor node and the control device within the adjustment area. Delivering a profile to the adjustment manager; Adjusting, by the adjustment manager, the indoor microclimate according to the preference profile in the adjustment area based on the profile of the sensor node and the adjustment device delivered from the integrated control server; And when the indoor micro-climate adjustment is completed, transferring the indoor micro-climate control operation information to the integrated control server to be recorded, wherein the integrated control server recognizes a plurality of users within the control area. And controlling the adjustment manager to perform indoor microscopic adjustment in the adjustment area according to the average value of the preference profile of the users or the preference profile of the user having the highest priority among the plurality of users.

According to the present invention, it is possible to perform a highly flexible and functionally scalable control in controlling indoor micro water in a building.

In particular, it is possible to manage according to dynamic situations such as the addition, deletion, and movement of sensor nodes and control devices existing in the control area for each space, thereby enabling efficient and error-free adjustment in the control area.

In addition, even if a large number of users exist in the indoor space, indoor microscopic adjustment is possible according to a plurality of user perceptions by performing indoor microscopic adjustment according to the average value of a plurality of users' preference profiles or preference profiles of priority users.

In addition, when the adjustment is performed near the adjustment threshold according to the operation and control method of the controller, by setting the buffer section at the threshold and controlling the possibility of distracting the operation near the threshold may be eliminated.

1 is a view schematically showing an indoor microclimate personalization control system according to an embodiment of the present invention.
FIG. 2 is a detailed block diagram of the adjustment manager shown in FIG. 1.
3 is a detailed block diagram of the integrated control server shown in FIG. 1.
Figure 4 is a flow chart of the indoor microscopic post personalization adjustment method according to an embodiment of the present invention.
5 is a flowchart of an indoor microscopic climate control process performed by an adjustment manager in a method for controlling indoor microscopic climate personalization according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating an example of a screen on which the touch user interface illustrated in FIG. 2 displays indoor climate adjustment control information.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise. Also, the terms " part, "" module," and " module "in the specification mean units for processing at least one function or operation and can be implemented by hardware or software or a combination of hardware and software .

Now with reference to the drawings with respect to the indoor micro-climate personalization control system and method according to an embodiment of the present invention will be described in detail.

1 is a view schematically showing an indoor microclimate personalization control system according to an embodiment of the present invention.

As shown in FIG. 1, the indoor microclimate personalization adjustment system 10 according to an embodiment of the present invention includes an indoor microclimate for at least one control region 10-1, 10-2,..., 10-n. It includes an integrated control server 100 for integrated management of personalization control.

Here, the control areas 10-1, 10-2, ..., 10-n represent the respective spaces in the building, and correspond to the rooms that can form a closed space in the building, respectively, and also open spaces. It may also correspond to the living room or lounge forming a.

In the control areas 10-1, 10-2,..., 10-n, the control area 10-1 is connected to the integrated control server 100 through a wired / wireless network under the control of the integrated control server 100. And an adjustment manager 200 for controlling indoor microclimate within 10-2, ..., 10-n). Herein, the adjustment managers 200 are included in the adjustment regions 10-1, 10-2,..., And 10-n, respectively, and the adjustment managers 200 are all configured in the same manner. Only the region 10-1 will be described in detail with an example.

In the adjustment region 10-1, at least one sensor node 300 for measuring indoor microclimate in the adjustment region 10-1 is provided.

The sensor node 300 is controlled by the adjustment manager 200 to measure indoor microclimate.

The indoor microscopic climate measured by the sensor node 300 is temperature, humidity, illuminance, carbon dioxide concentration, and the like. Sensor nodes for measuring these indoor microclimate factors are well known and will not be described here.

The sensor node 300 installs a wireless node wirelessly connectable to the regulation manager 200 through a wireless sensor network.

Zigbee or other wireless communication protocols may be used as the wireless node.

The sensor node 300 has a serial number such as an ID unique to the sensor node 300, and wirelessly transmits the serial number and the measured value to the control manager 200 through the wireless node.

In the adjustment area 10-1, at least one control device 400 for controlling indoor microclimate in the control area 10-1 is provided.

The adjusting device 400 is controlled by the adjusting manager 200 to adjust the indoor microclimate.

The indoor microscopic climate controlled by the controller 400 is temperature, humidity, illuminance, carbon dioxide concentration, and the like, and the controller 400 includes a lamp, a heater, an air conditioner, a humidifier, a ventilation fan, and the like. Furthermore, it will be obvious that indoor appliances may also be added as regulators.

The controller 400 installs a wireless node wirelessly connectable to the regulation manager 200 through a wireless sensor network.

Zigbee or other wireless communication protocols may be used as the wireless node.

The controller 400 also has a serial number, such as an ID unique to itself, and wirelessly transmits the serial number to the control manager 200 through the wireless node.

In addition, the controller 400 transmits its control operation state wirelessly to the adjustment manager 200 through the wireless node, and also receives a control command for adjustment transmitted from the adjustment manager 200 to correspond to the post-measurement. Perform the adjustment of the factor.

The adjustment manager 200 transmits and receives data with the integrated control server 100 through a wired or wireless network. For example, when the user enters the corresponding control area 10-1, the control manager 200 recognizes the user's tag information from the RFID tag possessed by the user, and recognizes the tag information on the wired / wireless network. Transfer to the integrated control server 100 through. In addition, the adjustment manager 200 receives the user-specific preference profile and the like identified according to the tag information recognized above from the integrated control server 100 and performs the corresponding indoor microscopic adjustment.

In addition, the adjustment manager 200 recognizes serial numbers of the sensor node 300 and the control node 400 in the control area 10-1 through the wireless sensor network and transmits them to the integrated control server 100.

Through this recognition, the integrated control server 100 can know the distribution of the sensor node 300 and the control device 400 in each control area (10-1, 10-2, ..., 10-n), and thus Due to this, it is possible to grasp the situation such as addition, deletion, and movement of the sensor node 300 and the control device 400 in the adjustment areas 10-1, 10-2, ..., 10-n.

Therefore, in the indoor micro-climate personalization control system 10 according to an embodiment of the present invention, mobility and fluidity of an object, that is, a user, a sensor node 300, and an adjusting device 400 are guaranteed.

The adjustment manager 200 performs the indoor microscopic adjustment for the corresponding adjustment area 10-1 using the sensor node 300 and the adjustment device 400, and displays a screen indicating the adjustment operation state. In addition, the adjustment manager 200 may receive a manual control request from the user and perform individual adjustments to the adjustment device 400.

On the other hand, the integrated control server 100 performs data transmission and reception via the wired and wireless network with the control manager 200 in the control area (10-1).

The integrated control server 100 may determine the identity of the user who has entered the corresponding area 10-1 through the tag information of the user transmitted from the adjustment manager 200. Then, the integrated control server 100 confirms the preference profile for the indoor microclimate adjustment corresponding to the identified user and transmits it to the adjustment manager 200.

In addition, the integrated control server 100 receives the serial number for the sensor node 300 and the control device 400 in the control area (10-1) from the control manager 200 in real time or periodically, the control area (10) It is possible to grasp the status of the distribution of the sensor node 300 and the control device 400 in -1). In addition, the integrated control server 100 stores and manages the current status of the distribution.

FIG. 2 is a detailed block diagram of the adjustment manager 200 shown in FIG. 1.

As shown in FIG. 2, the adjustment manager 200 includes an RFID unit 210, a network interface unit 220, a wireless node 230, a touch user interface unit 240, and an adjustment control unit 250.

When the user carrying the RFID tag enters the adjustment area 10-1, the RFID unit 210 recognizes the RFID tag of the user and transfers the tag information to the adjustment control unit 250.

The RFID unit 210 includes an RFID antenna 211 and an RFID reader 212. The RFID antenna 211 receives a signal transmitted from the RFID tag and transmits the signal to the RFID reader 212, and the RFID reader 212 receives a signal of the RFID tag transmitted from the RFID antenna 211 to receive information of the RFID tag. The reading is transmitted to the adjustment control unit 250. In the embodiment of the present invention, the RFID antenna 211 and the RFID reader 212 are integrally formed, but may be separately configured according to the form or use form of the space in which the RFID unit 210 is installed.

The network interface unit 220 provides a network interface for connecting to the integrated control server 100 by wire or wireless. For example, the network interface may be a wired or wireless LAN.

The wireless node 230 provides a wireless sensor network interface for wirelessly transmitting and receiving data by wirelessly connecting with the wireless node of the sensor node 300 and the wireless node of the controller 400 in the control area 10-1.

The touch user interface unit (touch GUI) 240 is controlled by the adjustment controller 250, and the state of the adjustment operation performed by the adjustment manager 200 on the adjustment area 10-1 through the adjustment device 400. In addition, the present invention provides a visual interface for providing a user with an indoor microclimate state and the like, and also provides a touch input interface capable of manually adjusting an indoor microclimate factor displayed to enable manual control of a user. At this time, the user's touch input for manual adjustment is transmitted to the adjustment controller 250, so that the adjustment controller 250 is connected to the adjustment device 400 through the wireless node 230 to enable manual adjustment.

The adjustment controller 250 controls the RFID unit 210, the network interface unit 220, the wireless node 230, and the touch user interface unit 240.

The adjustment control unit 250 transmits the tag information of the user received from the RFID unit 210 to the integrated control server 100 through the network interface unit 220.

The adjustment control unit 250 receives the user's preference profile or sensor node 300 related information and the adjustment device 400 related information transmitted from the integrated control server 100 through the network interface unit 220.

The adjustment control unit 250 transmits adjustment operation information or manual adjustment operation information to the integrated control server 100 through the network interface unit 220.

The adjustment control unit 250 receives the serial numbers of the sensor node 300 and the control device 400 in the adjustment area 10-1 through the wireless node 230.

The adjustment control unit 250 receives a measurement value of the indoor microscopic factor measured from the sensor node 300 through the wireless node 230, and transmits a control command for adjusting the indoor microscopic factor to the controller 400. do.

The adjustment control unit 250 displays the indoor micro post-condition adjustment operation state and the like through the touch user interface unit 240, and receives a manual adjustment request from the user to perform adjustment of the corresponding indoor micro post-factor.

3 is a detailed block diagram of the integrated control server 100 shown in FIG.

As shown in FIG. 3, the integrated control server 100 may include a network interface unit 110, a database (DB) 120, an identity verification unit 130, an adjustment command unit 140, an operation recording unit 150, and the like. The device distribution check unit 160 is included.

The network interface unit 110 provides a network interface for connecting to the control managers 200 located in the control areas 10-1, 10-2,. For example, the network interface may be a wired or wireless LAN.

DB 120 stores a variety of data that the integrated control server 100 is used for personalization adjustment after the microscopic building in the building.

The DB 120 includes a user DB 121, a device DB 122, and an operation record DB 123.

The user DB 121 stores information for identifying the identity of the user who has an RFID tag and a preferred profile for the user to control indoor microscopic climate for each user.

The device DB 122 stores information of the sensor node 300 and the control device 400 in each of the adjustment areas 10-1, 10-2,..., 10-n. That is, the device DB 122 is a serial number of the sensor node 300 and the control device 400, the currently located control area, in the case of the sensor node 300, device-specific functions, response characteristics, failure status, recommended sampling interval In the case of the profile, such as the control device 400, the profile of the function, operation method, efficiency, power consumption, performance, etc. for each device is stored.

The operation record DB 123 stores an operation record after completing the indoor microscopic adjustment operation for the adjustment areas 10-1, 10-2, ..., 10-n. Records stored at this time are stored so that users, control areas, and the like can be distinguished.

The identity checker 130 checks the identity of the user based on the information stored in the user DB 121 of the DB 120 when the tag information of the user is transmitted from the control manager 200 through the network interface. . At this time, the identity check unit 130 may secure a preference profile for the indoor micro-post personalization adjustment that is preset for the user whose identity is confirmed.

The adjustment command unit 140 uses the device node 122 and the sensor node 300 and the control device 400 in the control area 10-1 to which the user has been identified by the identification checker 130. After identifying through, and securing the profile of the corresponding device, and transmits to the adjustment manager 200 through the network interface unit 110 with the user's preferred profile secured by the identity verification unit 130. At this time, if the preferred profile is not set for the user in the identification unit 130, the adjustment command unit 140 is a general indoor microclimate profile, for example, generally recommended temperature, humidity, illuminance, carbon dioxide concentration Provide a statistically verified physiological reference value for the control manager 200.

The operation recorder 150 receives an operation record after completion of adjustment after indoor microscopic control transmitted from the adjustment manager 200 through the network interface unit 110 and stores the operation record in the operation record DB 123 of the DB 120. At this time, the operation recording unit 150 stores in the operation record DB 123 so that the adjustment area 10-1, the user, and the like in which the operation recording is performed can be distinguished.

The device distribution checking unit 160 receives and adjusts serial numbers of the sensor node 300 and the adjusting device 400 in the adjusting area 10-1 transmitted from the adjusting manager 200 through the network interface unit 110. The device distribution is stored in the device DB 122 so that the device distribution corresponds to the area 10-1.

The device distribution checking unit 160 is in the control area 10-1 and the serial number transmitted from the control manager 200 and the device distribution stored in the device DB 122 is different. Report that there is a movement such as addition, deletion, etc. of the sensor node 300 or the control device 400 in the) as a distribution corresponding to the serial number transmitted from the control manager 200 to the corresponding control area (10-1) Store device distribution details.

Hereinafter, with reference to Figure 4 will be described in detail with respect to the indoor microscopic post personalization adjustment method according to an embodiment of the present invention.

For convenience of description, a user using the indoor micro-climate personalization control system according to an embodiment of the present invention registers information for identifying his / her identity in the user DB 121 and then carries an RFID tag corresponding thereto. In addition, specific users will be described assuming that they have also registered a preference profile for personalization adjustment after indoor microscopic user in the user DB 121.

In addition, the adjustment manager 200 is fixedly installed at a specific location for each space in the building, for example, each room, toilet, living room, lounge, and the like, and is formed by the adjustment manager 200. 1) will be described assuming that the sensor nodes 300 that can measure the indoor microclimate factor of each space and the control device 400 that can adjust the indoor microclimate factor of each space are installed.

First, when at least one user enters into a specific space in a building, for example, the adjustment area 10-1 formed by the adjustment manager 200, the RFID unit 210 of the adjustment manager 200 is connected to the user. The RFID tag is detected (S100), and the personalization adjustment process is started after the indoor microcomputer according to the embodiment of the present invention. Here, the RFID reader 212 of the RFID unit 210 detects only a user tag within a predetermined radius, and when the user overlaps with the detection area of the RFID reader of the adjacent control area, the user is placed in the control area on the side where the strength of the monitoring signal is stronger. It is considered to belong.

When the control manager 200 detects a user's RFID tag, the control manager 200 detects serial numbers of the sensor nodes 300 and the control device 400 in the control area 10-1 through the wireless node 230 (S110). And transmits the RFID tag information to the integrated control server 100 (SS120). In this case, when there are a plurality of users detected by the RFID unit 210 in the adjustment area 10-1, the control manager 200 transmits the tag information of the plurality of users to the integrated control server 100.

The identity check unit 130 of the integrated control server 100 is preferred for personalized indoor micro-conditioning for the user whose identity is verified by using the tag information transmitted from the control manager 10-1 and the user DB 121. Check whether the profile exists (S130).

If the preference profile exists, the corresponding preference profile is prepared (S140). If the preference profile does not exist, general indoor microclimate condition information, which is a statistically verified physiological standard for indoor microclimate factors, is prepared (S150).

And, the control command unit 140 of the integrated control server 100 is the device DB corresponding to the serial number transmitted from the control manager 10-1 and the control node 400 and the profile for the control device 400 device DB Acquired through the 122 and transmits the above preference profile or general indoor microscopic condition information to the adjustment manager 200 (S160).

Therefore, the adjustment manager 200 uses the preference profile or general indoor microclimate condition information and device profile transmitted from the integrated control server 100 to control indoor microscopic adjustment in the personalized control area 10-1 to the user. It performs (S170).

Thereafter, when the indoor microscopic adjustment operation is completed, the adjustment manager 200 transmits the operation records according to time of the user, the sensor node 300 and the control device 400 participating in the adjustment process to the integrated control server 100. The integrated control server 100 stores the operation record transmitted from the adjustment manager 200 in the operation record DB 123 (S180).

Hereinafter, the indoor microclimate adjusting process S170 will be described in more detail with reference to FIG. 5.

First, the adjustment manager 200 receives the preference profile or general indoor micro-climate condition information and the device profile transmitted from the integrated control server 100 (S171).

As such, when the user-specific preference profile or the general indoor micro-climate condition information and the device profile are received from the integrated control server 100, the adjustment manager 200 may be configured from the sensor nodes 300 within the control region 10-1. Current measurement values, for example, sensor values such as temperature, humidity, illuminance, and carbon dioxide concentration are received (S172).

After that, the adjustment manager 200 determines the change amount of the indoor microclimate factor to be changed by comparing the received sensor values with the indoor microclimate optimization condition on the preferred profile and displays the determined change amount in the actual control area 10-. 1) to determine the control amount of the controller 400 to implement (S173). Here, if there is no preference profile and there is general indoor microclimate condition information instead, the amount of change of indoor microclimate factors is determined by comparing the sensor values received in step S173 with general indoor microclimate condition information. .

In addition, the adjustment manager 200 transmits the control amount of the adjustment device 400 determined in step S173 to the corresponding adjustment device 400 through a control command (SS174).

As such, each of the adjusting devices 400 receiving the control command for controlling the indoor microscopic factor from the adjustment manager 200 performs control of the corresponding indoor microscopic factor.

For this control, the regulator 400 sends its control operation state to the regulation manager 200 via the wireless node, and the sensor nodes 300 also adjust the measured values of the indoor microclimate factor that is changed in real time. It transmits to the manager 200 (S175).

Accordingly, the adjustment manager 200 evaluates whether the indoor post micro control threshold is achieved by using the measured values and the control operation state transmitted in real time from the sensor nodes 300 and the control device 400 as described above (S176). While performing feedback control. That is, in step S175, the indoor micro climate control threshold set by the control manager 200 using the measured value and the control operation state transmitted in real time from the sensor nodes 300 and the control device 400 is achieved. If it is determined that the control command to stop the operation for the indoor microscopic adjustment according to the user transmits to the control device (400) (S177).

On the other hand, the adjustment manager 200 as described above, in the process of performing the indoor micro-climate adjustment according to the user through the touch user interface 240 for the indoor micro-factors in the adjustment area (10-1) As shown in FIG. 6 attached with a graph showing the difference between the measured values and the measurement target, i.e., the preferred profile or the general indoor microclimate condition information, the monitor can be monitored through a visual interface such as a touch screen. Display.

In addition, the adjustment manager 200 enables a touch input for adjusting the indoor microscopic factors through the screen to which the touch function is provided. In other words, the user can manually adjust the adjusting devices by adjusting the slide bar displayed through the screen to which the touch function is applied. Therefore, when the manual control of the users is requested through the screen to which the touch function is applied, the adjustment manager 200 may transmit an adjustment command to the adjustment devices 400 using the change amount to be manually adjusted as the control amount. For example, although the brightness of the lamp is adjusted according to the user's preference profile, the user may enable manual control such as darkening the brightness of the lamp for listening to music or meditation.

As such, when there is a manual control request from the user, the adjustment manager 200 transmits the manual control request information and the record of the control operation performed by the user to the integrated control server 100 in step S180. The all are stored in the operation record DB 123 by the integrated control server 100.

In addition, this information not only provides useful data for similar indoor microclimate control processes in the future, but especially when a user's manual control request is included, the system updates the user's indoor microclimate preference profile so that the system can It is used as a starting point to provide individual users with a more comfortable indoor climate environment they prefer.

Meanwhile, in the above description, only one user is detected using the user's preferred profile when the user is detected within the adjustment area 10-1. However, the technical scope of the present invention is not limited thereto. It can also be applied when multiple users are detected within 1).

For example, when a plurality of users are detected in the adjustment area 10-1 by the adjustment manager 200 in step S100, the tag information of the plurality of users is displayed in the control manager (S120). In step S160, the integrated control server 100 determines an indoor micro-climate condition to be applied to a plurality of users and transmits the condition to the control manager 200. At this time, when two or more of the plurality of users have a preference profile, the integrated control server 100 obtains the average value on the two or more preference profile and generates a profile based on it and delivers it to the adjustment manager 200 ( Negotiation-based control method). Alternatively, the integrated control server 100 searches for the priorities of users having a preference profile in the user DB 121 and controls them according to a preference profile of a user with high priority, that is, a user who should be considered first, such as a disabled person or a patient. In order to perform the user's profile is delivered to the adjustment manager 200 (priority-based control method). In addition, when there is a preference profile of a plurality of users, the control may be possible based on the uniqueness of the intelligent building to which the indoor micro-climate personalization control system 10 according to the embodiment of the present invention is applied.

Therefore, even if a plurality of users are detected in the adjustment area 10-1, the adjustment manager 200 may be configured according to general indoor micro-climate condition information when the preference profile determined by the above method or all users do not have a preference profile. The indoor microscopic personalization adjustment can be performed on the control region 10-1.

In addition, although the above-described control is performed only according to a preference profile or general indoor micro-climate condition information, any one of two types of on / off control, that is, binary control or continuous control, is used. Control of the regulating devices 400 that can be controlled in one or two ways may be performed by applying a multi-threshold.

For example, if the indoor illuminance set in a particular user's preference profile is 500 lux (LUX), the indoor illuminance given by the sum of natural light through the window and artificial artificial lighting is 490 lux due to the dynamic real-time change of sunlight. When switching between and 510 lux, the adjustment manager 200 continues to turn on the power of the indoor lighting (not shown) which adjusts the lighting in the adjustment area 10-1 by the sensor value measured by the illumination sensor. Or by turning it off, the operation of the device can be distracted near the adjustment threshold. Therefore, in order to solve this problem, the adjustment manager 200 includes the change centering on the threshold value when the sensor value measured by the sensor node 300 is severely changed near the threshold which is the control target of the indoor microclimate factor. Set the buffer section to turn on, turn on the controller 400 for adjusting the corresponding factor only when the lower limit of the buffer section, and the controller 400 for adjusting the corresponding factor only when the upper limit of the buffer section is exceeded. Adjustment of the indoor microclimate factors is performed by turning off. Referring to the above example, since the threshold is 500 lux and the measured sensor value is between 490 lux and 510 lux, the buffer interval is 450 lux to 550 when the buffer interval is 50 lux based on the threshold. It is set to lux. Therefore, the indoor lamp is turned on only when the measured sensor value is less than 450 lux, and the indoor lamp is turned off only when the sensor value is higher than 550 lux. In this way, by setting the buffer interval, the indoor lamp remains on or off even when the measured sensor value is moved between 490 and 510 lux due to the dynamic real-time change of sunlight, which is natural light as described above. Can be. Thus, the above-described method can eliminate the phenomenon that the regulator 400 reacts too sensitively near the threshold.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (11)

In the system that controls the indoor microclimate of each space in the building according to the user,
At least one adjustment manager for identifying a user located in the adjustment area and performing indoor micro-climate adjustment in the adjustment area corresponding to the user; And
An integrated control server for transferring the indoor microclimate preference profile corresponding to the user identified by the at least one control manager to the control manager, and storing and managing a record of the indoor microcontrolling operation performed by the control manager. Including,
The control manager includes at least one sensor node for measuring indoor microclimate factors in the control area and at least one control device for controlling indoor microclimate factors in the control area,
The integrated control server receives the serial number of the sensor node and the control device from the at least one control manager and manages corresponding to the control area,
The integrated control server recognizes a movement including addition and deletion of a sensor node or a control device corresponding to the control area through the sensor node received from the control manager and a serial number of the control device, and corresponds to the control area. Reflected in the management of sensor nodes and control devices
Indoor microclimate personalization control system, characterized in that. delete The method of claim 1,
The adjustment manager,
An RFID unit for recognizing an RFID tag of a user located in the control area and outputting tag information;
A wireless node providing communication via a wireless sensor network with a sensor node and a control device located within the control area;
A user interface unit displaying indoor microclimate factors measured in the control area and adjustment operation information according to the user, and receiving a manual control request for indoor microclimate factors from the user; And
In order to transmit the tag information of the user recognized by the RFID unit to the integrated control server, and to perform indoor post micro adjustment in the adjustment area based on the user's preference profile transmitted from the integrated control server, Control unit for controlling the RFID unit, the wireless node and the user interface unit
Indoor microclimate personalization control system comprising a. The method of claim 3,
The integrated control server,
A database that stores information identifying the user's identity, preference profiles for indoor micro-climates by user, serial numbers for sensor nodes and control devices, and device-specific profiles;
An identity verification unit for verifying the identity of the user through the information of the user stored in the database using the tag information transmitted from the control manager;
An adjustment command unit for extracting a user's preferred profile and a device-specific profile from the database to the control manager; And
An operation recorder for storing, in the database, a record of an indoor microscopic adjustment operation in the adjustment area performed by the adjustment manager;
Indoor microclimate personalization control system comprising a. The method of claim 4, wherein
When the integrated control server has a large number of users recognized in the control area through tag information transmitted from the control manager, and there is a preferred profile corresponding to two or more users among the plurality of users, the integrated control server calculates an average value of the preferred profiles. Obtaining and generating a new preference profile and transferring it to the adjustment manager to perform indoor micro-control in the control area according to the generated preference profile. The method of claim 4, wherein
When the integrated control server has a plurality of users recognized in the control area through tag information transmitted from the control manager, and there exists a preference profile corresponding to two or more users among the plurality of users, the preference profile exists. The user's priority is compared and the preference profile of the user having the highest priority is transmitted to the adjustment manager so that indoor micro-climate adjustment is performed in the adjustment area according to the user's preference profile having the highest priority. Indoor microclimate personalization control system. The method of claim 1,
The adjustment manager sets a buffer section based on the control threshold value when the sensor value measured from the sensor node changes from a control threshold value on the preference profile, and controls the controller based on the buffer section. Indoor microclimate personalization control system, characterized in that. In the method to adjust the indoor microclimate of each space in the building according to the user,
Recognizing a tag information of a user in the adjustment area by an adjustment manager for controlling adjustment after indoor microscopic adjustment in the adjustment area;
The integrated control server which performs the control on the adjustment manager extracts the user's preference profile based on the tag information recognized by the adjustment manager, and the preference along with the profile of the sensor node and the control device within the adjustment area. Delivering a profile to the adjustment manager;
Adjusting, by the adjustment manager, the indoor microclimate according to the preference profile in the adjustment area based on the profile of the sensor node and the adjustment device delivered from the integrated control server; And
When the indoor microscopic climate control is completed, the indoor microclimate control operation information is transmitted to the integrated control server to record,
When the integrated control server recognizes a plurality of users in the control area, the indoor control after the indoor micro-control in the control area according to the average value of the preference profile of the users or the preference profile of the user with the highest priority among the plurality of users. Control the adjustment manager to perform an adjustment,
The control manager collects the serial numbers of the sensor node and the control device existing in the control area in real time and delivers them to the integrated control server,
The integrated control server recognizes a movement including addition and deletion of a sensor node or a control device corresponding to the control area through the sensor node and the serial number of the control device transmitted from the control manager to correspond to the control area. Reflected in the management of sensor nodes and control devices
Personalized control method of indoor microclimate, characterized in that. The method of claim 8,
The integrated control server replaces condition information based on statistically verified physiological criteria for indoor microclimate factors with a preference profile when there is no preference profile for the user.
Adjusting the indoor microclimate according to the preference profile,
Receiving a preference profile and a profile of the sensor node and the controller from the integrated control server;
Receiving a sensor value measured by the sensor node;
Performing control of the regulator by comparing the sensor value with a control threshold on the preference profile;
Stopping the indoor microclimate adjustment operation when a control threshold on the preference profile is achieved; And
Transmitting information of the indoor micro-climate control operation to the integrated control server;
Indoor microclimate personalization adjustment method comprising a. 10. The method of claim 9,
In the step of performing control of the control device,
When a sensor value measured from the sensor node changes from a control threshold on the preference profile, a buffer section is set based on the control threshold value, and the control device is controlled based on the buffer section. How to control indoor microclimate personalization. delete

Images