KR101631094B1 - UNITED CONTROLLING SYSTEM FOR INDUSTRIAL INSTALLATION, ELECTRIC POWER, and LED LIGHT - Google Patents

Abstract

The present invention relates to an integrated control system for building installation, power, and light. The integrated control system includes: a building installation internet of things (IoT) sensor which collects IoT data in real time; an energy monitoring unit which directly detects a load current flowing through an energy monitoring sensor; an energy management module which displays whether or not an installation, power, and lighting control point exist, and normally operate; and a touch LCD switch (TLS) which edits a button property, a screen configuration, and an operation function in an individual terminal, controls a lighting device within a screen, and applies a lighting scenario to the lighting device to operate the same.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an integrated control system for a building,

More particularly, the present invention relates to an integrated control system for building facilities, electric power, and lighting, and more particularly, to a system and method for controlling a building facility object data sensor in conjunction with an energy monitoring sensor (EMS) Addresses of each sensor are independently managed to enable independent information collection or operation control, and it is used not only in buildings with conventional E / F2, DALI, ZigBee communication, but also in buildings equipped with latest object data sensors (IoT sensors) Power, and lighting integrated control systems.

In general, the major technologies of the Internet include sensing technology, wired / wireless communication and network infrastructure technology, and service interface technology. Sensing technology collects, processes, stores, manages information from sensors and supports interface implementation for information to be implemented as service.

Therefore, it is one of the essential elements in recent years that a more stable, real-time scalable and high-capacity data processing and service can be provided for the Internet of objects installed in a building facility.

On the other hand, many technologies using automatic control system have been provided in everyday life, so that convenience of life can be provided. In recent years, as the number of high-rise buildings such as buildings and apartments has increased, an automatic control system is essential to manage such facilities as electricity, lighting, water, and cooling.

However, when changing the structure of each room in a building or constructing a new building, it was difficult to immediately provide a control device suitable for a new communication system.

In addition, lighting control of a building is to adjust the brightness level of a given space appropriately for a specific task or situation and to provide a good lighting environment.

However, it has been difficult to find a system that can save energy and improve work efficiency while controlling lighting appropriately.

In addition, in the conventional lighting control system, a time schedule which plays a role of automatically turning off the light by a regular and regular time schedule program over time requires a lot of energy consumption during operation, So that it is difficult to control the illumination.

Korea Patent No. 1174361 Korean Patent No. 1472656 Korea Patent Publication No. 2015-0094408 Korean Patent No. 1453372

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an IoT sensor for a building, a facility object data sensor, and an energy monitoring sensor (EMS) Power, and lighting integrated control system capable of performing independent information collection or operation control, etc.

In addition, the present invention can prevent electric power accidents such as standby power and insecure electric power use through precise energy monitoring, analyze the usage patterns, and have equipment fault diagnosis, a compact structure, a simple signal line, up function, a plurality of UI pages edited by the user, a brightness lowering, a screen turning off, an energy saving function of the battery, and a power and lighting integrated control system.

In order to solve the above problems, the present invention provides an integrated control system for a building, an electric power, and a lighting system, comprising: a building equipment object data sensor (IoT sensor) for collecting real time object data by being located in various building equipments, power equipments and lighting equipments; An energy monitoring unit for directly detecting a load current flowing through an energy monitoring sensor; The display unit displays a schedule setting screen for operating and controlling the facility, power, and lighting by measuring the "ON" / "OFF" time of the facility for operating and controlling the facility, And the set value is transmitted to the lighting control side. The real time communication with the building facility data sensor allows the user to determine whether there is a control point, a power, a lighting control point, An energy management module for displaying an operation status on the screen; It is possible to edit the button properties, screen configuration and operation functions in individual terminals, configure group / individual control of lighting devices in the screen, and apply the lighting scenarios based on lighting color temp. And a touch LCD switch (TLS) for displaying these operations on a screen, and a facility control unit for controlling various facilities of the building is provided with a load An EMS sensing module for each facility node including an energy monitoring sensor (EMS) for outputting a current signal proportional to a current; A hybrid relay valve control module for on / off control using a MCCB (wiring breaker) to control a pump of the building and valves of various air conditioning systems as latch relays; And a hybrid relay magnet control module for high-voltage magnet control using the hybrid relay in various facilities of the building, wherein the electric power control unit for controlling the electric power facility monitors the energy usage of the electric power facility A power plant node-specific EMS sensing module including an energy monitoring sensor (EMS) for outputting a current signal proportional to the load current so as to be able to output a current signal; And a hybrid relay magnet control module for high-voltage magnet control using the hybrid relay in the electric power facility, wherein the electric power control unit for controlling the lighting facility can monitor the energy usage of the lighting facility An EMS sensing module for each lighting facility node including an energy monitoring sensor (EMS) for outputting a current signal proportional to the load current so that the load current is proportional to the load current; The active arc suppressor is activated to shut off the arc, the zero cross point is detected to reduce the inrush current, and at the same time, And a hybrid relay terminal unit (HTU) for preventing generation of power noise due to a power failure.

A virtual channel is set in the E / F2-BUS installed in the integrated facility, power and lighting integrated control system of the building, and a channel set in the E / F2-BUS side is set in the Zigbee to E / F2- , Or a virtual channel is set in the E / F2-BUS and the channel set in the E / F2-BUS side is applied to the other device using the DALI to E / F2-BUS gateway.

The ZigBee device converts the object data into a ZigBee radio signal and transmits the ZigBee radio signal.

The different arrangement associated with the building equipment object data sensor is that the DALI master is differently addressed to different slaves (DALI slaves) connected to the DALI-bus via address assignment, ).

Wherein the control unit of the touch LCD switch is operated by an LCD touch or an electrostatic touch button in a sleep mode, Wake up function and user-edited UI page turn-off function. It charges battery by adding battery cell to perform trickle charge function in sleep mode, and operates LCD screen screen and monitoring function. And the energy stored in the battery is used.

The present invention further includes a power superposition type E / F2-BUS communication system module having a control signal communication network in which a power supply and a bidirectional communication function are simultaneously performed on a two-wire nonpolar wire line.

(Digital Input), DO (Digital Input), AI (Analog Input), and AO (Analog Output) communication control that controls the facility, power module, Digital Control) type of Energy Monitoring Controller module; (Digital Input), DO (Digital Output), AI (Analog Input), and AO (Analog Output), which are expanded to enable a plurality of states and control states of the energy monitoring controller, And an extension extension module.

In the present invention as described above, a building equipment object data sensor (IoT sensor) can be connected to an energy monitoring sensor (EMS) of various buildings, electric power facilities and lighting facilities, So that the address of each sensor is managed independently and can be used not only in a building having a conventional E / F2, DALI, ZigBee communication, but also in a building equipped with a latest object data sensor (IoT sensor).

In addition, the present invention can prevent electric power accidents such as standby power and unstable electric power use through precise energy monitoring, analyze the usage patterns, and provide equipment fault diagnosis, compact structure, Can be designed in a compact size, and it is possible to manage energy by load in real time by combining the function of sensing the current load and the relay function of turning on / off the load.

In addition, the present invention provides a touch-sensitive display device capable of performing a fixed function such as a wake up function, a plurality of UI pages edited by a user, a brightness lowering, a screen turning off, And has advantages of convenience and energy saving function.

FIG. 1 is a diagram showing the overall configuration of an integrated facility, power and lighting control system according to the present invention.
2 is a diagram illustrating a state in which an LCD board and an E / F 2 board exchange information with each other according to an exemplary embodiment of the present invention.
3 is a diagram illustrating a state in which an LCD board and a ZigBee board exchange information with each other according to an embodiment of the present invention.
FIG. 4 is a diagram illustrating an LCD board, an E / F2 board, and a ZigBee board exchanging information with each other according to an exemplary embodiment of the present invention.
5 is a diagram showing states (A, B, C, and D) in which information is exchanged between an LCD board, an IoT board, an E / F2 board, and a ZigBee board according to an embodiment of the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Further, detailed descriptions of well-known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

1, the present invention includes a building equipment object data sensor (IoT sensor) 11, an energy monitoring unit 20, an energy management module 22, a TLS (Touch LCD Switch) 24, And various facilities, power and lighting control units 31, 32, and 33, and the like.

The building equipment object data sensor 11 is a sensor for collecting real-time object data (for example, electric power consumption, lighting condition, standby power, etc.) by being located in various facilities of buildings, electric power facilities and lighting facilities, In conjunction with the automatic control field or valve control, high-pressure magnet unit control, or the energy monitoring sensor (EMS) described below, it is possible to monitor energy consumption in the power control field, Can play a role. Here, the IoT sensor of the building facility is connected to the energy monitoring sensor (EMS) of building facilities, power facilities and lighting facilities, Etc. are independently managed and are sensors that enable them to work well both in a building with a conventional E / F2, DALI, ZigBee communication set up, or with a modern object data sensor (IoT sensor).

The energy monitoring unit 20 is a device that directly detects a load current flowing through the energy monitoring sensor. The energy monitoring unit 20 detects a load current up to 20 A at a maximum accuracy of 0.2% error, By outputting a general 4 ~ 20mA current signal, it is possible to monitor not only ESU exclusive terminal ETU (CRC8200) but also general purpose AI (Analog Input) equipment.

In addition, the energy monitoring unit 20 can calculate the real time data of the complete power, current, and voltage by reducing the measurement error through precise measurement based on the technology of 0.1% and high precision power consumption measurement.

In addition, the energy monitoring unit 20 can precisely prevent electric power accidents such as standby power and insecure electric power use, analyze the usage patterns, and provide equipment fault diagnosis, a compact structure, It is possible to design the space smaller than the measuring equipment, and it is possible to manage the load energy in real time by combining the function of sensing the current load and the relay function of turning on / off the load.

The energy management module 22 measures the amount of power used by measuring the ON / OFF time of the facility for operating and controlling the facility, the electric power and the lighting, , A schedule setting screen for operating and controlling the illumination is displayed to set a desired schedule program as a user and a set value is transmitted to the illumination control side, And displays whether there are facilities, power, lighting control points (points), and normal operation on the screen. Here, the control point refers to a point having a specific control function on the setting screen for operating and controlling the facility, electric power, and lighting.

As shown in FIGS. 1 to 5, a touch LCD switch (TLS) 24 edits button attributes, screen configurations, and operation functions in individual terminals, and controls group / The lighting scenario based on the lighting color temperature display by the time of day can be applied to the lighting apparatus and operated. The LCD board is an LCD board that displays the buttons on the screen.

In order to explain this, the LCD board of FIG. 2 and the E / F 2 board exchange information with each other through the UART 3 port, and group / individual control of the lighting apparatus is configured in the screen. Here, the LCD board includes a TFT LCD and an LCD driver for driving the TFT LCD.

Also, it is shown that the LCD board and the ZigBee board in FIG. 3 exchange information with each other and group / individual control of the lighting apparatus is configured in the screen.

Also, it is shown that the LCD board, the E / F2 board, and the ZigBee board of FIG. 4 exchange information with each other and group / individual control of the lighting apparatus is configured in the screen.

(A, B, C, and D directions) of the LCD board, the I / O board, the E / F2 board, and the ZigBee board shown in FIG. This allows the LCD board to operate well in a building where the object data sensor (IoT sensor) is installed.

In addition, the touch LCD switch 24 constitutes a group / individual control of the lighting apparatus in the TLS screen to provide a user-oriented editing function, and the lighting color temperature display (morning / evening warm white, Can be applied to a lighting device and operated, and these operations can be displayed as a button on a TLS screen.

Also, a plurality of switches may be used to control the lighting device due to the necessity of the user or limitations of the circuit configuration in the indoor space. In this case, the user may have difficulty finding a switch that works with the lighting device. In order to solve this inconvenience, it is possible to distinguish lighting devices by displaying the floor plan of the building on the TLS screen, and individual control can be explicitly performed.

In addition, the operation portion of the touch LCD switch 24 can perform a fixed function such as a wake-up function and a plurality of UI pages edited by the user in a sleep mode through a plurality of electrostatic touch buttons in addition to an LCD touch button, Energy saving function.

Also, since the touch LCD switch 24 performs an electrostatic LCD touch function, energy consumption occurs, and the actual operation time is short for lighting control. Therefore, when there is no LCD touch operation, it is possible to save energy by lowering the brightness and turning off the screen.

In addition, by adding a battery cell to the touch LCD switch (24), it is possible to further enhance energy saving by charging the battery by performing a trickle charge function in the sleep mode and using the energy stored in the battery during operation and monitoring of the LCD touch screen have.

1, the facility control unit 31 for controlling various facilities of the building includes an EMS sensing module 311 for each facility node, a hybrid relay valve control module 312, a hybrid relay magnet control Module 313, and the like.

The EMS sensing module 311 for each facility node includes an energy monitoring sensor (EMS) for outputting a current signal proportional to the load current so as to monitor the energy consumption of various buildings.

The hybrid relay valve control module 312 is a latch relay that controls on / off using an MCCB (wiring breaker) to control the pump of the building and the valves of various air conditioning systems.

The hybrid relay magnet control module 313 is a module for high-voltage magnet control using the hybrid relay in various buildings.

The power control unit 32 for controlling the power equipment includes an EMS sensing module 321 for each power plant node, a hybrid relay magnet control module 322, and the like.

The EMS sensing module 321 for each power plant node includes an energy monitoring sensor (EMS) for outputting a current signal proportional to the load current so as to monitor the energy usage of the power facility.

The hybrid relay magnet control module 322 is a module for high-voltage magnet control using the hybrid relay in the electric power facility.

The power control unit 33 for controlling the lighting equipment includes an EMS sensing module 331 for each lighting equipment node, an E / F 2, a DALI, a ZigBee integrated interlocking control module 332, and a hybrid relay terminal unit 333, and the like.

The EMS sensing module 331 for each lighting equipment node is a module including an energy monitoring sensor (EMS) for outputting a current signal proportional to the load current so as to monitor the energy consumption of the lighting equipment.

In addition, the E / F2, DALI, and ZigBee integrated interlocking control module 332 can be installed in various kinds of buildings, electric power facilities, and lighting facilities, and a virtual channel is set in the E / F2- (Zigbee) to E / F2-BUS gateway, or set up a virtual channel on E / F2-BUS and set the channel set on E / F2-BUS to DALI E / F2-BUS gateway to other devices.

The E / F2, DALI, and ZigBee integrated interlocking control module 332 converts the object data into a ZigBee radio signal through the ZigBee device and transmits the converted ZigBee wireless signal, (DALI slave) connected to a bus (DALI-bus) are separately and group-controlled by address assignment through a DALI slave.

The hybrid relay terminal unit 333 activates an active arc suppressor at the moment when the relay contact is turned on or off to block the arc and detect a zero cross point It is a module that reduces inrush current and prevents generation of power noise due to input blocking.

In addition, the present invention may further include a power superposition type E / F2-BUS communication system module having a control signal communication network in which a power supply and a bidirectional communication function are simultaneously performed on two-wire non-polar wire wiring.

Further, the present invention controls a building module, a local module in which electric power is operated, a digital input (DI), a digital output (DO), an analog input (AI) (DDC) type energy monitoring controller module or control, and when there are a plurality of state points, one of the energy monitoring controllers is provided with a DI (Digital Input ), DO (Digital Output), AI (Analog Input), and AO (Analog Output) extension extension modules.

According to the above-described configuration, the building facility object data sensor 11 is connected to the energy monitoring unit 20 and the energy monitoring sensor (EMS) of various building equipments, power facilities and lighting facilities, The address of each sensor is managed independently so that it can be used not only in the building with the conventional E / F2, DALI, Zigbee communication, but also in the building where the latest object data sensor (IoT sensor) is installed. .

In addition, the present invention can prevent electric power accidents such as standby power and unsafe power usage through precise energy monitoring by the energy monitoring unit 20, analyze the usage patterns, and provide equipment fault diagnosis, a compact structure, It is possible to design a compact space compared to existing measuring equipment and it is possible to manage energy by load in real time by combining the function of sensing the current load and the relay function of turning on / off the load.

In addition, the present invention can be applied to various functions such as a wake up function, a plurality of UI pages edited by a user, brightness lowering, screen off, energy stored in the battery, and the like stored in a sleep mode through a control unit of a touch LCD switch (TLS) And a function of using a fixed function such as the convenience and energy saving function is advantageous.

11: Building equipment object data sensor
20: Energy Monitoring Department
22: Energy management module
24: TLS (Touch LCD Switch)
31: Equipment control section
311: EMS sensing module for each facility node
312: Hybrid relay valve control module
313: Hybrid relay magnet control module
32: Power control unit for controlling the power equipment
321: EMS sensing module for each power plant node
322: Hybrid relay magnet control module
33: Power control unit for controlling lighting equipment
331: EMS sensing module for each lighting facility node
332: E / F2, DALI, ZigBee Integrated Interlocking Control Module
333: Hybrid relay terminal control module

Claims (7)

In a building's facility, power and lighting integrated control system,
IoT sensor, which is located in various facilities, electric power facilities and lighting facilities, and collects real-time object data;
An energy monitoring unit for directly detecting a load current flowing through an energy monitoring sensor;
The display unit displays a schedule setting screen for operating and controlling the facility, power, and lighting by measuring the "ON" / "OFF" time of the facility for operating and controlling the facility, And the set value is transmitted to the lighting control side. The real time communication with the building facility data sensor allows the user to determine whether there is a control point, a power, a lighting control point, An energy management module for displaying an operation status on the screen;
It is possible to edit the button properties, screen configuration and operation functions in individual terminals, configure group / individual control of lighting devices in the screen, and apply lighting scenarios based on lighting color temp. , And a touch LCD switch (TLS) for displaying these operations on a screen as a button,
Wherein the facility control unit for controlling the various facilities of the building comprises:
An EMS sensing module for each equipment node including an energy monitoring sensor (EMS) for outputting a current signal proportional to a load current so as to monitor an energy usage amount of the various facilities of the building;
A hybrid relay valve control module for on / off control using a MCCB (wiring breaker) to control a pump of the building and valves of various air conditioning systems as latch relays; And
And a hybrid relay magnet control module for high-voltage magnet control using the hybrid relay in various facilities of the building,
The power control unit for controlling the power equipment includes:
An EMS sensing module for each power plant node including an energy monitoring sensor (EMS) for outputting a current signal proportional to a load current so as to monitor the energy consumption of the power facility; And
And a hybrid relay magnet control module for high-voltage magnet control using the hybrid relay in the electric power facility,
Wherein the power control unit for controlling the lighting equipment comprises:
An EMS sensing module for each lighting equipment node including an energy monitoring sensor (EMS) for outputting a current signal proportional to a load current so as to monitor energy consumption of the lighting equipment; And
Active Arc Suppressor is activated at the moment the relay contact is turned on or off to shut off the arc, detect the zero crossing point to reduce the inrush current, And a hybrid relay terminal unit (HTU) for preventing power noise from occurring. The method according to claim 1,
A virtual channel is set in the E / F2-BUS installed in the integrated facility, power and lighting integrated control system of the building, and a channel set in the E / F2-BUS side is set in the Zigbee to E / F2- F2, DALI, or E / F2-BUS, where the virtual channels are set in E / F2-BUS and the channels set in E / F2- And a ZigBee integrated interlocking control module. 3. The method according to claim 1 or 2,
And a ZigBee device for converting the object data into a ZigBee wireless signal and transmitting the ZigBee wireless signal. 3. The method according to claim 1 or 2,
The different devices associated with the building equipment object data sensor are different and grouped by address assignment to different slaves (DALI slaves) that are otherwise connected to the DALI-bus, Wherein the integrated control system of the building, the power and the lighting are integrated. The method according to claim 1,
Wherein the control unit of the touch LCD switch is operated by an LCD touch or an electrostatic touch button in a sleep mode, Wake up function and user-edited UI page turn-off function. It charges battery by adding battery cell to perform trickle charge function in sleep mode, and operates LCD screen screen and monitoring function. A building, a power and lighting integrated control system, characterized by using energy stored in the battery. The method according to claim 1,
And an E / F2-BUS communication system module with power supply and bidirectional communication function, wherein the power supply and bidirectional communication functions have a control signal communication network that simultaneously operates on a two-wire non-polar wire. The method according to claim 1,
(Digital Input), DO (Digital Input), AI (Analog Input), and AO (Analog Output) communication control that controls the facility, power module, Digital Control) type of Energy Monitoring Controller module; (Digital Input), DO (Digital Output), AI (Analog Input), and AO (Analog Output), which are expanded to enable a plurality of states and control states of the energy monitoring controller, Extension Extension module, which further includes a building's facility, integrated power and lighting control system.

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