KR101893109B1 - Internet of things based management and control system for building - Google Patents

Abstract

The present invention relates to a building management and control system based on the Internet of Things (IoT). The building management and control system based on the IoT comprises: a cooling and heating ventilation unit (130) ventilating indoor air of a building (BL) to the outside; a lamp (140) installed in the indoor side (R) of the building; a CCTV (160) installed inside and outside the building (BL); an entrance management unit (170) confirming an opening and closing state of an entrance of the building (BL); a firefighting device (180) installed inside and outside of the building (BL); an elevator (190) installed inside the building (BL); an energy measuring unit (150) measuring electric power consumed in the elevator (190), the firefighting device (180), the entrance management unit (170), the CCTV (160), the lamp (140), and the cooling and heating ventilation unit (130); a controller (110) managing and controlling air conditioning and heating and ventilation of the indoor side (R) of the building based on a data value received from the cooling and heating ventilation unit (130) and connected to the cooling and heating ventilation unit (130) by a network, wherein the controller (110) receives energy measured by the energy measuring unit (150) and analyzes the energy received; a server (122) connected to the controller (110) by the network and remotely controlling the controller (110); and a portable terminal (124) connected to the controller (110) by a wireless network and receiving power consumption data analyzed by the controller (110). Therefore, the building management and control system based on the IoT can save energy and power consumption.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an IOT-based building management and control system,

The present invention relates to a building management and control system, and more particularly, to an IoT-based building management and control system adapted to reduce power consumption and management and operation maintenance costs of buildings.

Generally, a small and medium-sized building, a factory, and a building (hereinafter, collectively referred to as a building) has a technology in which a comprehensive management system for heating and cooling a building is implemented.

As a conventional technology related to the heating / cooling and management system of a building, Korean Patent No. 10-1231827 (Apr. 23, 2014), Korean Patent No. 10-1522175 (May 25, 2015) and Korean Patent No. 10-1595413 (Feb. 12, 2016) and U.S. Patent US20130289790A1.

However, the above-described prior art is limited to the heating / air-conditioning management.

Document 1: Korean Patent No. 10-1231827 (Feb. Document 2: Korean Patent No. 10-1522175 (May 5, 2015) Document 3: Korean Patent No. 10-1595413 (Feb.

The object of the present invention is to provide a building management and control system based on Internet of Things (IoT) according to the present invention,

First, based on IoT, it can reduce the power consumption of the building and maintenance and operation maintenance cost,

Second, to prevent crime prevention and to achieve safe building,

Third, when rainwater enters the parking lot due to storm or heavy rain, it is detected automatically and the parking lot entrance is closed automatically so that the parking lot can be prevented from being inundated. Thus, it is possible to automatically manage the disaster in preparation for natural disasters It enables the implementation of smart buildings,

Fourth, when the parking lot is flooded with rainwater or other water, and the parking lot is going to flood, it is necessary to detect the pre-flooding step before flooding in earnest and inform it to all users and people in the building by alarm broadcasting. And to provide an IoT-based building management and control system that is suitable for preventing damages (e.g.

In order to achieve the above object, the present invention provides an IoT-based building management and control system including: an IoT-based building management and control system for performing a cooling and heating operation on an interior of a building, An indoor lighting unit installed in the building, a ventilation unit, a lighting unit installed in an indoor space of the building, a CCTV installed inside and outside the building, an entrance management unit confirming the opening and closing state of a door of a building, An energy measuring unit for measuring the power consumed by the cooling / heating ventilation unit, the illumination lamp, the CCTV, the door management unit, the fire extinguisher and the elevator, and an energy measuring unit connected to the cooling / heating ventilation unit via a network, Managing and controlling the cooling / heating and ventilation of the room in the building on the basis of the data value, A controller connected to the controller by a network and controlled by a controller remotely; and a controller connected to the controller by a wireless network, wherein the controller analyzes And a portable terminal for receiving one power consumption data.

In the IoT-based building management and control system according to the present invention, the controller calculates the energy efficiency and the performance index for each of the heating and cooling ventilation unit, the lighting, the CCTV, the door management unit, the fire protection equipment and the elevator based on the amount of power received from the energy measurement unit And transmits the calculated value to the portable terminal.

The IoT-based building management and control system according to the present invention is characterized in that the controller includes a power saving operation program storage unit in which a power saving operation program for saving energy of the cooling and heating ventilation unit is stored and an optimum operation program for saving energy of the heating and cooling ventilation unit And an optimum stop program storage unit for storing an optimum stop program for saving the energy of the cooling / heating ventilation unit.

The IoT-based building management and control system according to the present invention is characterized in that the cooling and heating ventilation unit includes a room temperature sensor for measuring a temperature of a room in a building and outputting the measured temperature to a controller, A CO 2 sensor for measuring the concentration of carbon dioxide in the indoor space of the building and outputting the measured CO2 concentration to the controller; a cooler provided in the building for cooling operation based on a cooler control signal output from the controller; A radiator provided in the room and operated based on a radiator control signal output from the controller to heat the room; and a control unit that is driven in response to a damper drive control signal outputted from the controller to open / And a fan drive control signal output from the controller Copper hayeoseo characterized in that the fan comprises a fan for forced discharge of room air to the outside.

The IoT-based building management and control system according to the present invention is further comprised of a ventilation valve that is driven in accordance with a valve drive control signal output from the controller to establish indoor and outdoor air circulation.

The IoT-based building management and control system according to the present invention having the above-described configuration has the following effects.

First, based on IoT, the power consumption of the building and the maintenance and operation maintenance cost can be reduced.

Second, it is effective to prevent the crime prevention and achieve a safe building.

Third, when storm water enters the parking lot due to storm or heavy rain, it is detected automatically and the parking lot entrance is closed automatically, so that the parking lot can be prevented from being flooded. As a result, disaster management is automatically It is effective to implement smart building that can do.

Fourth, when the parking lot is flooded by the heavy rain or the other kind of water, it is possible to detect before the immersion before flooding in earnest, and notify all users and people in the building by alarm broadcasting There is an effect that damage due to flooding (for example, flooding of the vehicle) can be prevented in advance.

1 is an illustration of a building in which an IoT-based building management and control system is implemented according to an embodiment of the present invention.
2 is a block diagram of an IoT-based building management and control system according to an embodiment of the present invention.
FIG. 3 is a detailed block diagram of the controller 110 in FIG.
FIG. 4 is a detailed block diagram of the cooling / heating ventilator 130 in FIG.
FIG. 5 is a flowchart of the optimum startup program stored in the optimum startup program storage unit in FIG.
6 is a flowchart of the optimum stop program stored in the optimum stop program storage unit in Fig.
7 is a flowchart of a power saving operation program stored in the power saving operation program storage unit in FIG.
FIG. 8 is a diagram illustrating a state of use of the IoT-based building management and control system according to an embodiment of the present invention, in which when the inflow water is detected, the parking entrance G1 of the building is automatically closed by the electric shutter 223, 8 (a) is a front view conceptual view of the parking lot entrance, and Fig. 8 (b) is a side view conceptual view of the parking lot entrance.

Hereinafter, preferred embodiments of the IoT-based building management and control system according to the present invention will be described in detail with reference to the accompanying drawings.

The buildings to be managed and controlled by the present invention can be small and medium-sized buildings, factories, collective buildings, and the like, all collectively referred to as buildings.

As shown in the figure, the IoT-based building management and control system according to an embodiment of the present invention performs the cooling and heating of the indoor room R of the building BL and the indoor air of the building BL to the outside A lighting system 140 installed in a room R of the building, a CCTV 160 installed inside and outside of the building BL and an opening and closing state of the doors of the building BL A fire extinguisher 180 installed inside and outside the building BL, an elevator 190 installed in the interior of the building BL, and a heating and cooling ventilation unit 130 and a lighting lamp 140 An energy measuring unit 150 for measuring electric power consumed in the CCTV 160, the door management unit 170, the fire-fighting equipment 180 and the elevator 190, and an energy measuring unit 150 connected to the heating and cooling ventilation unit 130 via a network And controls the cooling / heating and ventilation of the indoor room (R) of the building based on the data value received by the cooling / heating ventilator (130) And a controller 110 connected to the controller 110 through a network to control the controller 110. The control unit 110 controls the operation of the controller 110, And a portable terminal 124 connected to the controller 110 via a wireless network and receiving the power consumption data analyzed by the controller 110 .

In the IoT-based building management and control system according to an embodiment of the present invention, the controller 110 controls the cooling / heating ventilator 130, the illumination lamp 140, and the air conditioner 140 based on the amount of power received from the energy measuring unit 150, And calculates a consumption efficiency and a performance index for each of the CCTV 160, the door management unit 170, the fire fighting equipment 180 and the elevator 190, and transmits the calculated values to the portable terminal 124.

In the IoT-based building management and control system according to an embodiment of the present invention, the controller 110 is provided with an energy analysis and display program storage unit 112.

The energy analysis and display program storage unit 112 stores the energy analysis and display program storage unit 112 on the basis of the amount of power received from the energy measurement unit 150. The energy analysis and display program storage unit 112 stores the energy analysis and display program storage unit 112, Calculates a consumption efficiency and a performance index for each elevator 180 and elevator 190 and transmits the calculated value to the portable terminal 124.

In the IoT-based building management and control system according to an embodiment of the present invention, the controller 110 includes a power saving operation program storage unit 114, an optimum startup program storage unit 116, (118) is provided.

The power saving operation program storage unit 114 is a storage medium storing a power saving operation program for saving energy of the cooling and heating ventilation unit 130. [

The optimum startup program storage unit 116 is a storage medium storing an optimal startup program for saving energy of the cooling and heating ventilator 130. [

The optimal stop program storage unit 118 is a storage medium storing an optimal stop program for saving the energy of the cooling and heating ventilation unit 130. [

In the IoT-based building management and control system according to an embodiment of the present invention, the cooling / heating ventilator 130 includes a room temperature sensor 131, an outside temperature sensor 132, a carbon dioxide (CO ₂ ) sensor 133, A radiator 134, a radiator 135, a ventilation damper 136, and an air blower fan 137.

The room temperature sensor 131 measures the temperature of the room R of the building BL and outputs the measured temperature to the controller 110.

The outdoor temperature sensor 132 is a sensor for measuring the temperature outside the building BL and outputting the measured temperature to the controller 110.

The carbon dioxide (CO ₂ ) sensor 133 measures the concentration of carbon dioxide in the room R of the building BL and outputs it to the controller 110.

If the concentration value output from the carbon dioxide sensor 133 is high, it means that the room is contaminated. If the concentration value outputted from the carbon dioxide sensor 133 is low, it means that the room is not contaminated.

The air conditioner 134 may be an air conditioner provided in the indoor room R of the building BL and operated to perform a cooling operation based on a cooler control signal output from the controller 110.

The radiator 135 is installed in the room R of the building BL and operates based on the radiator control signal outputted from the controller 110 to heat the room R. The radiator 135 may be a heater, . ≪ / RTI >

The ventilation damper 136 is an actuator for opening and closing the window of the building BL by driving in accordance with a damper drive control signal outputted from the controller 110 in order to naturally vent the room air to the outside.

The ventilator fan 137 is driven in accordance with the fan drive control signal output from the controller 110 to forcibly discharge the air in the indoor R to the outside.

In the IoT-based building management and control system according to an embodiment of the present invention, a ventilation valve 138 for driving indoor and outdoor air by driving in accordance with a valve driving control signal output from the controller 110 And further comprising:

In the IoT-based building management and control system according to another embodiment of the present invention, a crime information database 213 in which face information data of a person who wears an electronic footrest and face information data of a wanted person are stored, An entrance photographing unit 211 installed at an entrance of the building for photographing a face of a passenger entering an entrance of a building and transmitting the face of the passenger to the controller 110, The controller 110 further includes a facial image reading unit 212 for comparing facial information data stored in the information database 213 and digitizing the facial image similarity to the controller 110, And transmits the facial image similarity value to the server 122 when the facial image similarity value is equal to or greater than the reference similarity value.

In the IoT-based building management and control system according to another embodiment of the present invention, the face image reading unit 212 reads out the protruding points and depression points from the face image of the passenger photographed by the passenger photographing unit 211 The facial image similarity is digitized by comparing the converted entrance image code value with the code value stored in the face information data stored in the criminal information database 213. [

For example, when the code value is equal to 90%, the similarity value is 9.0, and when the code value is equal to 80%, the similarity value is 8.0.

In the IoT-based building management and control system according to another embodiment of the present invention, it is provided in the parking garage entrance G1 of the building BL to detect whether the running water flows into the parking lot, A parking lot inflow water sensor 221 for detecting the detected water level and outputting a water sensing signal to the controller 110 so that the electric shutter 223 closes the parking lot entrance G1 when receiving the drive control signal from the controller 110 An electric shutter driving module 222 for driving the electric shutter 223 to unfold by rotating the electric shutter in one direction and an electric shutter 223 for closing or opening the parking opening G1 by driving the electric shutter driving module 222 And the controller 110 outputs a driving control signal to the motorized shutter driving module 222 when receiving a water sensing signal from the parking lot inflow water sensor 221. [ The.

In an IoT-based building management and control system according to another embodiment of the present invention, when installed in a parking lot of a building (BL), when water of a predetermined height set in a parking lot is flooded, a flood reserve signal is transmitted to the controller And the controller 110 further includes a parking lot flooding sensor 231 for outputting the parking lot flooding preliminary alarm signal to the audio output unit 110 when receiving the flood reserve signal from the parking lot flooding sensor 231. [ And the audio output unit 232 outputs the parking water immersion preliminary alarm through the speaker 233 provided in the building BL when receiving the parking water immersion preliminary alarm signal from the controller 110 .

The "parking flooding preliminary alarm" may be, for example, "Parking can be done but parked vehicles are all moving."

The operation of the IoT-based building management and control system according to an embodiment of the present invention will now be described.

5 shows a flowchart of the optimum startup program stored in the optimum startup program storage unit 116. As shown in FIG.

First, the controller 110 executes the optimum startup program stored in the optimum startup program storage unit 116. [

It is determined whether the optimum start mode is a state required by the data value input from the outside (S510).

When the optimum startup mode is required, it is determined whether the mode is the cooling mode or the heating mode (S512, S513).

In the cooling mode (S512), the room temperature sensor 131 and the outdoor temperature sensor 132 receive the room temperature value and the outdoor temperature value, respectively (S514).

Then, the startup time is calculated by an internal algorithm (S516). The algorithm for calculating the start-up time can be executed on the basis of the daily average data value and the power consumption.

It is determined whether the optimum startup time has been reached (S518), and when the optimum startup time has been reached, the optimum startup is performed (S530).

The same process is also performed in the heating mode. In the case of the heating mode (S513), the indoor temperature value and the outdoor temperature value are received from the indoor temperature sensor 131 and the outdoor temperature sensor 132, respectively (S520).

Then, in the heating mode, the startup time is calculated by an internal algorithm (S522). As described above, the algorithm for calculating the start-up time can be executed based on the daily average data value, the power consumption, and the like.

It is determined whether the optimum start time has been reached (S524), and when the optimum start time has been reached, the optimum start operation is performed (S532).

6 shows a flowchart of the optimum stop program stored in the optimum stop program storage unit 118. In FIG.

First, the controller 110 executes the optimum stop program stored in the optimum stop program storage unit 118. [

It is determined whether the optimum stop mode is required by the data value inputted from the outside (S610).

When the optimum stop mode is required, it is determined whether the mode is the cooling mode or the heating mode (S612, S613).

In the cooling mode (S612), the indoor temperature value and the outdoor temperature value are received from the indoor temperature sensor 131 and the outdoor temperature sensor 132, respectively (S614).

Then, the stop time is calculated by an internal algorithm (S616). The algorithm for calculating the stopping time can be executed based on the daily average data value, the power consumption, and the like.

It is determined whether the optimum stop time has been reached (S618), and if the optimum stop time has been reached, the optimum stop operation is performed (S630).

The same process is also performed in the case of the heating mode. Even in the heating mode (S613), the indoor temperature value and the outdoor temperature value are received from the indoor temperature sensor 131 and the outdoor temperature sensor 132, respectively (S620).

Then, in the heating mode, the stop time is calculated by an internal algorithm (S622). As described above, the algorithm for calculating the stopping time can be executed on the basis of the daily average data value, the power consumption, and the like.

It is determined whether the optimum stop time has been reached (S624), and when the optimum stop time has been reached, the optimum start operation is performed (S632).

7 shows a flowchart of a power saving operation program stored in the power saving operation program storage unit 114. As shown in FIG.

First, the controller 110 executes a power saving operation program stored in the power saving operation program storage unit 114. [

It is determined whether a power save mode is required (S710).

When the power saving mode is required, it is determined whether the cooling mode or the heating mode is selected (S712, S713).

If the mode is the cooling mode (S712), the indoor temperature value is input from the indoor temperature sensor 131, and the carbon dioxide concentration value is input from the carbon dioxide sensor 133 (S714).

Then, the power saving operation operation time is calculated by an internal algorithm (S716). The algorithm for calculating the running time of the running operation can be executed based on the daily average data value, the power consumption, and the like.

If the power saving operation start time is greater than the minimum startup time (S718), the power saving mode operates (S730).

If the power saving operation start time is less than the minimum startup time (S718), the controller 110 outputs a damper open control signal to the ventilation damper 136. The ventilation damper 136, which receives the damper opening control signal, (S734).

If the power saving operation start time is less than the minimum startup time in step S718, the controller 110 outputs a drive control signal to the fan fan 137, and the fan fan 137, which receives the drive control signal, And forcedly discharged to the outside (S734).

If the power saving operation start time is less than the minimum startup time in step S718, the controller 110 outputs an open control signal to the ventilation valve 138, and the ventilation valve 138, which receives the open control signal, The air is allowed to escape to the outside (S734).

The same process is also performed in the heating mode. Even in the heating mode (S713), the indoor temperature value is input from the indoor temperature sensor 131, and the carbon dioxide concentration value is input from the carbon dioxide sensor 133 (S720).

Then, the power saving operation operation time is calculated by an internal algorithm (S722). The algorithm for calculating the running time of the running operation can be executed based on the daily average data value, the power consumption, and the like.

If the power saving operation start time is greater than the minimum startup time (S724), the power saving mode operates (S730).

If the power saving operation start time is less than the minimum startup time in step S720, the controller 110 outputs a damper open control signal to the ventilator damper 136. The ventilator damper 136 is opened to open the window (S734).

If the power saving operation start time is less than the minimum startup time (S724), the controller 110 outputs a drive control signal to the fan fan 137, and the fan fan 137, which receives the drive control signal, And forcedly discharged to the outside (S734).

If the power saving operation start time is less than the minimum startup time in step S724, the controller 110 outputs an open control signal to the ventilation valve 138, and the ventilation valve 138, which receives the open control signal, The air is allowed to escape to the outside (S734).

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is self-evident to those who have.

Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

110:
112: Energy analysis and display program storage unit
114: Power saving operation program storage section
116: Optimal start program storage unit
118: Optimum stop program storage unit
122: server 124: portable terminal
130: cooling / heating ventilation unit 131: indoor temperature sensor
132: Outside temperature sensor 133: Carbon dioxide (CO ₂ ) sensor
134: air conditioner 135: heater
136: Ventilation damper 137: Ventilator fan
140: illumination lamp 150: energy measurement section
160: CCTV 170: Door Management Section
180: Fire extinguisher 190: Elevator
211: Attendant photographing section 212: Facial image reading section
213: Crime information database 221: Parking lot influent sensor
222: electric shutter driving module 223: electric shutter
231: parking water immersion sensor 232: audio output unit
233: Speaker

Claims (4)

In an IoT-based building management and control system,
A cooling and heating ventilation part 130 for cooling and heating the room R of the building BL and ventilating the room air of the building BL to the outside,
A lighting lamp 140 installed in the room R of the building,
A CCTV 160 installed inside and outside the building BL,
A door management unit 170 for confirming the opening and closing states of the doors of the building BL,
A fire fighting apparatus 180 installed inside and outside the building BL,
An elevator 190 installed inside the building BL,
An energy measuring unit 150 for measuring the power consumed by the cooling / heating ventilator 130, the illumination lamp 140, the CCTV 160, the door management unit 170, the fire extinguisher 180 and the elevator 190,
And controls and controls the cooling / heating and ventilation of the indoor room (R) of the building on the basis of the data value received by the cooling / heating ventilator (130), and the energy measurement unit A controller 110 for receiving an amount of power measured by the controller 150 and analyzing the received amount of power,
A server 122 connected to the controller 110 via a network and remotely controlling the controller 110,
And a portable terminal (124) connected to the controller (110) via a wireless network and receiving power consumption data analyzed by the controller (110)
The controller 110 controls the cooling and heating ventilation unit 130 and the illumination lamp 140, the CCTV 160, the door management unit 170, the fire fighting equipment 180, and the elevator 180 based on the amount of power received from the energy measuring unit 150 190, and transmits the calculated value to the portable terminal 124,
In the controller 110,
A power saving operation program storage unit 114 storing a power saving operation program for saving energy of the cooling / heating ventilation unit 130,
An optimal startup program storage unit 116 storing an optimal startup program for saving the energy of the cooling / heating ventilation unit 130,
An optimal stop program storage unit 118 storing an optimal stop program for reducing energy of the cooling / heating ventilation unit 130 is provided,
The cooling / heating ventilation part (130)
A room temperature sensor 131 for measuring the temperature of the room R of the building BL and outputting the measured temperature to the controller 110,
An outside temperature sensor 132 for measuring the temperature outside the building BL and outputting the measured temperature to the controller 110,
A carbon dioxide sensor 133 for measuring the concentration of carbon dioxide in the room R of the building BL and outputting the measured concentration to the controller 110,
A cooler 134 provided in the room R of the building BL for cooling operation based on a cooler control signal output from the controller 110,
A radiator 135 provided in the room R of the building BL and operated based on a radiator control signal outputted from the controller 110 to heat the room R,
A ventilation damper 136 which is driven in accordance with a damper drive control signal outputted from the controller 110 to open and close the window of the building BL to discharge the air in the room,
And a fan fan (137) driven in accordance with a fan drive control signal outputted from the controller (110) to forcibly discharge the air in the room (R) to the outside,
A criminal information database 213 in which face information data of the electronic footwear wearer and face information data of a place caller are stored,
A passenger photographing unit 211 installed at a doorway of the building BL for photographing a face of a passenger entering an entrance of the building and transmitting the face of the passenger to the controller 110,
A facial image reading unit 212 for comparing the facial information data stored in the crime information database 213 with the face image of the passenger photographed by the passenger photographing unit 211 to digitize the facial image similarity and outputting it to the controller 110, And further comprises:
The controller 110 receives the facial image similarity value from the facial image reading unit 212 and transmits the facial image similarity value to the server 122 when the facial image similarity value is equal to or greater than the reference similarity value,
The facial image reading section 212 extracts a protruding point and a depression point from the face image of the passenger photographed by the passenger photographing section 211 and converts it into the passenger face image code value and outputs the converted passenger image code value And the code value stored in the face information data stored in the criminal information database 213 to digitize the facial image similarity,
A parking inflow water sensor 221 installed at a parking garage entrance G1 of the building BL to detect whether inflow water is flowing into the parking lot and to sense a flow of inflow water into the parking lot and output a flow rate sensing signal to the controller 110, Wow,
An electric shutter drive module (not shown) for driving the electric shutter 223 to unfold by rotating the electric shutter in one direction so that the electric shutter 223 closes the parking opening G1 when the drive control signal is received from the controller 110 222,
And an electric shutter 223 for closing or opening the parking opening G1 by driving the electric shutter driving module 222,
The controller 110 outputs a driving control signal to the motorized shutter driving module 222 when receiving a water sensing signal from the parking lot inflow water sensor 221,
And a parking lot water immersion sensor 231 installed in the parking lot of the building BL for sensing the water level set in the parking lot and outputting a flood reserve signal to the controller 110,
The controller 110 outputs a parking flood preliminary warning signal to the audio output unit 232 and the audio output unit 232 outputs the flood prevention preliminary alarm signal to the controller 110. When the flood prevention preliminary signal is received from the parking lot flooding sensor 231, And outputs a parking water immersion preliminary alarm through the speaker (233) provided in the building (BL) when receiving the parking water immersion preliminary alarm signal from the building (BL). delete delete delete

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