KR102107651B1 - A system for management of an air-conditioning unit - Google Patents

Abstract

The present invention generally relates to a management system for electric devices, and more specifically, a management of an air conditioning unit that comprehensively controls the air conditioning unit by including a main power source 11 and a controller 12 for managing the air conditioning unit. It's about the system.

Description

Air conditioning unit management system {A SYSTEM FOR MANAGEMENT OF AN AIR-CONDITIONING UNIT}

The present invention generally relates to a management system for electrical equipment, and more particularly, the present invention relates to a management system for an air conditioning unit having a controller for controlling and monitoring the unit so that the system has universal control of the unit. It is about.

Air-conditioning units or split-system air conditioning units are often controlled by one or more controllers or components to control and manage other functions of the unit.

More often, these electrical appliances are controlled by a one-way communication or uni-directional control method in home automation and building automation systems, so the control and the state of these electrical appliances are common Is unknown. For example, the infrared transmitter of the remote control of a decentralized air conditioning unit can transmit a signal to the unit, but the power status of whether the unit is completely switched off or off at the main switch is turned off. Even if it indicates that it has been converted, it is still indefinite to the user. In this situation, power is wasted in the unit's standby mode.

In addition, the control of the main power switching (main power switching) only turns the air conditioning unit on or off, and the main switch allows the user to control the temperature, fan speed, humidity level, schedule ( scheduling) and other related functions. In addition, even if the power is turned ON, not all air conditioning units are automatically turned ON, so the units remain OFF until an infrared power ON command is sent to the air conditioning unit.

There is no prior art that discloses the control and management of other functions of the decentralized air conditioning units, but there are prior arts that disclose a system that controls an electric appliance, more specifically an HVAC unit. U.S. Patent No. 8,478,447 B2 discloses a system, method, and related computer program products for controlling one or more HVAC systems using a distributed arrangement of wirelessly connected sensing microsystems. A plurality of wireless communication sensing microsystems are provided, each sensing microsystem comprising a temperature sensor and a processor, at least one sensing microsystem connected to the HVAC for its control, and the plurality of sensing microsystems of It is configured to jointly perform at least one shared computational task related to control.

U.S. Patent US 2014/0149270 A1 discloses a controller of a private unit in a multi-unit building, which operates the HVAC facility of the individual unit, the processor, output display, memory, and communication. Includes an RF module for. The controller receives the temperature or flow value of the fluid passing through the HVAC facility. Using the received temperature value of the fluid passing through the HVAC facility, the controller calculates a measurement of the HVAC usage of the HVAC facility, which can be in units of energy or money.

U.S. Patent US 8,644,166 B2 discloses a sensor device that integrates ZigBee (trademark) technology into a power switch device to provide automatic control of connected devices along with monitoring and control of power usage, which includes a power line network. Communication (PLC) is used to transmit the collected data and provide remote control capability to connected devices. In conjunction with a master switch, a communicable switch, and a power switch device, the sensing device integrates communication, streaming media, monitoring, and remote control of power usage, as well as remote operation monitoring and control of connected devices at home. Provide an integrated home environment.

However, the prior art has not mentioned the need for a comprehensive control of a decentralized air conditioning unit, which can also provide information on the state, operating state and mode of connected of such related electrical devices.

An object of the present invention is to provide a system for managing electric devices of an air conditioning unit, having a controller for monitoring and controlling the air conditioning unit, the system being configured to comprehensively control the air conditioning unit.

One object of the present invention is to provide a controller for controlling the main power supply and the air conditioning unit, the controller controlling the operating state, the operating mode, and the power state and detecting the power drawn by the air conditioning unit It is to provide an electric device control system of an air conditioning unit.

Another object of the present invention is to provide a controller for controlling the main power supply and the air conditioning unit, and to control the electrical equipment of the air conditioning unit configured to have a reciprocal communication capability for the controller to facilitate two-way communication between the controller and the device. It is to provide a system.

Another object of the present invention is provided with a controller for controlling the main power and air conditioning unit, the controller is a power measurement function (power measurement function), power detector function (power detector function), remote control function (remote controller function), and It is to provide an electric device control system for an air conditioning unit having a main switch function.

Another object of the present invention is to provide a controller for controlling a main power supply and an air conditioning unit, and to provide an electric appliance control system for an air conditioning unit configured to allow the controller to learn energy consumption.

Another object of the present invention includes a controller for controlling the main power supply and the air conditioning unit, and the electric device control system for the air conditioning unit to determine the operating state and operation mode by measuring the power drawn by the controller through the infrared activity sensor Is to provide

The present invention provides an electric device control system for an air conditioning unit in which a controller according to the present invention provides comprehensive control to air conditioning units, and does not require an auxiliary device other than a single controller.

1 is a schematic block diagram showing a system structure of a preferred system according to the present invention.
2 is a schematic block diagram showing an embodiment of a system according to the present invention.
3 is a schematic block diagram showing an embodiment of a controller according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The following preferred embodiments illustrate examples and do not limit any features of the invention.

FIG. 1 schematically shows a system structure of a preferred system according to the present invention, which monitors, controls, and manages the air conditioning unit in such a way that the system can universally control the air conditioning unit. In the same vein, the system is configured to control the operating state, operating mode, and power state of the air conditioning unit within a single controller.

The air conditioning unit management system according to the present invention shown in FIG. 1 includes a main power supply 11 and a controller 12 for controlling the air conditioning unit. The controller 12 is configured to control the operating state and operation mode of the air conditioning unit and to perform comprehensive control to control the power supply state of the air conditioning unit.

Comprehensive control in the context of the present invention refers to overall control of the connected air conditioning unit, such that an auxiliary device for controlling the air conditioning unit is no longer needed. The preferred controller 12 of the present invention can integrate control functions with power management and power state control.

Here, the operating state of the air conditioning unit refers to the state of the air conditioning unit when the power state of the air conditioning unit is switched to ON. The operating state of the air conditioning unit is preferably a standby state, a use state, a sleep state, or a monitoring state, but is not limited thereto.

Here, the operation mode of the air conditioning unit refers to the mode of the air conditioning unit when the power state of the air conditioning unit is switched to ON. The operating mode of the air conditioning unit is preferably, but not limited to, the temperature or humidity mode of the air conditioning unit, or the fan speeds of the related application ceiling fan.

The power supply state of the air conditioning unit is switched ON or OFF by nature.

In a preferred embodiment of the present invention, the controller 12 is configured such that the controller 12 has intercommunication capabilities to provide a two-way communication system between the controller 12 and the air conditioning unit.

In the conventional system, the control of the air conditioning unit is often implemented as a one-way control method. Since the conventional control method follows the concept of master and slave, the clear state of the air conditioning unit is unknown, which is time and expense. It is undesirable for the reliable use of remote controllers and the advent of technology that can achieve a smooth response.

The problem with the remote control is that these devices generally transmit a control signal to the air conditioning unit via an infrared transmitter, and the air conditioning unit only responds to the control signal according to its condition. The air conditioning unit does not carry any information about its condition. In order to improve the control, it is necessary to know the clear state of the air conditioning unit, so reciprocal communication is important in this control method.

For example, power switching itself only switches the power status of the air conditioning unit to ON or OFF, and this switching does not allow the user to control the operating status and operating mode of the air conditioning unit. Even if the power is switched ON to the air conditioning unit, not all air conditioning units are automatically switched ON, but a control signal for a power ON switching command is transmitted to the air conditioning unit according to its unique configuration. Until it remains OFF.

The preferred embodiment of the controller 12 of the present invention is configured to have comprehensive control to sense the power drawn by the air conditioning unit. The controller detects the power drawn by the air conditioning unit and may control the power state so that the power state of the air conditioning unit is OFF when the operating state of the air conditioning unit is OFF.

The preferred controller 12 of the present invention is configured to learn energy consumption, wherein the controller 12 detects signals from the air conditioning unit, at least one wireless sensor 51 shown in FIG. 3 And, it has a power measurement function (power measurement function), a power detector function (power detector function), a remote controller function (remote controller function), and a power switch function (power switch function). These functions are integrated in the controller 12 in such a way as to eliminate the overall control of the air conditioning unit. This integration eliminates the need for a separate control unit that controls the power switch and the operating state of the air conditioning unit in its operating mode.

The power measurement function determines the operation state of the air conditioning unit by measuring the power drawn from the air conditioning unit. The power detector function detects the power drawn from the air conditioning unit to determine the power state of the air conditioning unit.

For example, if no power is used, the air conditioning unit has been switched OFF. When the energy is used, the air conditioning unit is turned ON. The controller 12 will sense the amount of power drawn by the air conditioning unit. Preferably, the power drawn is sensed through an infrared activity sensor, through the processing of received control commands allowing interpretation of the expected power level. By extending this, the controller will also be able to determine if the infrared code has been successfully received. When the infrared code is transmitted, the controller 12 will find a change in the power consumption of the air conditioning unit, which change will indicate that the infrared code was successfully received.

The at least one sensor 51 of the preferred controller 12 of the present invention is for detecting any one or combination of temperature, humidity, electromagnetic radiation, or motion, and the controller 12 is It is equipped with at least one signal transmitter for transmitting signals to the air conditioning unit, and a high accuracy to learn the operating state of the air conditioning unit so that the learning ability of the controller 12 can operate the air conditioning unit at an optimum level. Includes a power measurement chipset or power measurement module.

In addition, the power measurement function provides the controller 12 with a learning ability to learn the energy consumption of different operating modes of the air conditioning unit, and according to the electrical wiring, the controller 12 also determines the total power consumption of the air conditioning unit. Can be measured. The measured infrared libraries can be imported or selected through an application program or a browser and these codes can be sent to the air conditioning unit for control.

In other embodiments, the system of the present invention is configured to receive network support, preferably wireless network support, but is not limited thereto. A controller of a printed circuit board (PCB) of a platform network supporting WiFi, ZigBee, Z-Wave, Bluetooth, etc. that provides full access from a remote device such as a smartphone, tablet or personal computer to the air conditioning unit In addition to 12, the controller 12 can be configured to allow access from remote systems.

2, a preferred embodiment of the system according to the invention is schematically illustrated. The air conditioning unit shown in FIG. 2 is a split-system air conditioning unit 31, but is not limited thereto.

According to the invention, the air conditioning unit 31 is shown connected to the controller 12, and the controller 12 is connected to the main power supply 11 of the 220V main input. A typical conventional distributed air conditioning unit 31 often has an in-wall ON or OFF main power switch and an infrared remote control mounted in a cradle V on the wall. The controller 12 of the present invention eliminates the need for an infrared remote control.

Also, in the conventional distributed air conditioning unit 31, limited intelligence of the distributed air conditioning system, lack of ability to perform remote connection, lack of ability to control temperature in advance, and detection of occupancy can be performed. There have been problems that result in lack of capability, remote diagnostics impossibility, lack of ability to measure performance, lack of ability to judge timeliness of servicing.

The present invention replaces the existing controllers of the distributed air conditioning unit 31 with a controller 12 that provides comprehensive control capabilities to any home automation or building automation technical field. As described above, the controller 12 of the present invention controls the operation state and operation mode of the air conditioning unit, controls the power supply state of the air conditioning unit, and provides comprehensive control to detect the power drawn by the air conditioning unit. It is configured to. Here, the controller 12 controls the operating state, the operation mode, and the power state of the distributed air conditioning unit 31, and detects power drawn by the distributed air conditioning unit 31 through an infrared activity sensor.

The comprehensive control provides overall control of the decentralized air conditioning unit 31 so that a remote control for controlling the operating state and operation mode of the air conditioning unit 31 is no longer required. The controller 12 may integrate control functions including power management and power state control.

Here, the operating state of the air conditioning unit 31 refers to the state of the air conditioning unit 31 when the power state of the air conditioning unit 31 is switched to ON. The operating state of the air conditioning unit is preferably a standby state, a use state, a sleep state, or a monitoring state, but is not limited thereto.

Here, the operation mode of the air conditioning unit 31 refers to the mode of the air conditioning unit 31 when the power state of the air conditioning unit 31 is switched to ON. The operation mode of the air conditioning unit 31 is preferably a temperature mode, a humidity mode, or an ambient mode, but is not limited thereto.

The power supply state of the air conditioning unit 31 is ON or OFF switching in nature.

In a preferred embodiment of the present invention, the controller 12 is configured to have intercommunication capabilities such that the controller 12 provides a two-way communication system between the controller 12 and the air conditioning unit 31.

In addition, the preferred controller 12 of the present invention is configured to learn energy consumption, the controller 12 further comprising a power measurement function, a power detector function, a remote control function, and a power switch function. These functions are integrated to provide the controller 12 with the overall control capability of the air conditioning unit 31. This integration eliminates the need for devices to control the power switch and separate controls to control the operating state of the air conditioning unit 31 in its operating mode.

The power measurement function may measure power drawn by the air conditioning unit 31 to determine an operating state and an operation mode of the air conditioning unit 31. The power detector function may detect power drawn by the air conditioning unit 31 to determine the power state of the air conditioning unit 31.

For example, when electric power is not used, the air conditioning unit 31 is turned OFF, and when electric power is used, the air conditioning unit 31 is turned ON. The controller 12 will detect the amount of power drawn by the air conditioning unit 31. Preferably, the power drawn is sensed through an infrared activity sensor.

By extending this, the controller will also be able to determine if the infrared code was successfully received. When the infrared code is transmitted, the controller 12 will find a change in the power consumption of the air conditioning unit, which change will indicate that the infrared code was successfully received. The controller 12 also includes a high-accuracy power measurement chipset or power measurement module to learn the operating state of the air conditioning unit so that the learning ability of the controller 12 can operate the air conditioning unit to an optimal level.

The controller 12 of the present invention to be used for the decentralized air conditioning unit 310 preferably detects temperature to control temperature, detect humidity, detect electromagnetic radiation, and perform motion. It is configured to detect electrons, the radiation may or may not look like infrared light.

The temperature-sensing and humidity-sensing configuration is effective in providing a well-balanced and comfortable climate for the user by maintaining an appropriate temperature that provides an efficient cooling effect to the user within the surrounding environment. The visible light sensing configuration detects whether light is present in the surrounding environment or whether daylight is present, and the air conditioning unit 31 is switched ON or OFF according to a predetermined requirement for conserving energy. It is efficient to be able to be. The configuration that detects the motion is effective in detecting the occupancy of the user in the indoor environment so that the air conditioning unit 31 is switched OFF when no one is in the room.

In addition, the controller 12 of the present invention used in the decentralized air conditioning unit 31 is preferably configured to have a predetermined operation schedule, and the decentralized air conditioning unit (such as sleep and operation time) It is configured to be flexible in determining the operating state of 31) in advance. It is important that the controller 12 operates as a user interface that receives input from the user and displays a plurality of information of the air conditioning unit 31 to the user. The user interface is preferably a color liquid crystal (LCD) touch screen display, but is not limited thereto.

The controller 12 of the present invention is manufactured or used to be used for ceiling fan units, wall-mounted fan units, tower fan units, or heating, ventilating and air-conditioning (HVAC) devices. Since it can be easily installed and used, these features are not limited to the decentralized air conditioning unit 31 or any other air conditioning unit 31. The controller 12 of the present invention can be powered by a 2-wire or 3-wire circuit. The controller 12 can also be mounted in or fitted to a British or Australian standard electrical wall box.

Preferably, the system of the present invention is configured to have network support, but is not limited to a wireless network, so that the controller 12 is configured to allow access from a remote system. A printed circuit board (PCB) of a platform network supporting WiFi, ZigBee, Z-Wave, Bluetooth, etc., which provides full access to the air conditioning unit 31 from a remote device such as a smartphone, tablet or personal computer. It can be added to the controller 12.

3 schematically shows an embodiment of a controller 12 according to the present invention.

The controller 12 is shown as a boxed device with screens, buttons, and sensors. In a preferred embodiment of the present invention, the controller 12 includes at least one sensor 51 for detecting a signal from the air conditioning unit, at least one signal transmitter 53 for transmitting a signal to the air conditioning unit, and a user It has a user interface 54 that receives input from and displays information, and the controller 12 is configured to have a remote control function and a power switch function.

The controller 12 is configured to have at least an infrared transmitter, an LCD color display, function buttons, and a mechanical base plate, and is further configured to sense operation, temperature, visible light and humidity.

As described above, the infrared transmitter transmits a signal to and receives a signal from the air conditioning unit. The LCD color display is a user interface that receives input from a user and displays a plurality of information of the air conditioning unit. The sensor is for a configuration that senses temperature, senses humidity, and senses motion. The mechanical substrate provides support for the controller of the present invention.

To the extent that various modifications, changes, and changes can be made to the details of the present invention, all matters included in the above-described description and illustrated in the accompanying drawings should be interpreted by way of illustration and not of limitation.

Claims (26)

A main power supply 11;
Equipped with a controller 12 for monitoring and controlling the air conditioning unit,
The controller 12 is in an 'ON' state or an 'OFF' state of a power switch for controlling the operation state and operation mode of the air conditioning unit and controlling the supply of power to the air conditioning unit. It is configured to control the power status,
The controller 12 is composed of at least one wireless sensor 51, and manages the air conditioning unit to enable two-way communication between the air conditioning unit and the controller 12,
Characterized in that the controller 12 is configured to sense the power drawn by the air conditioning unit
Air conditioning unit management system. In claim 1,
The at least one wireless sensor 51 is configured to detect signals from the air conditioning unit
Air conditioning unit management system. In claim 2,
At least one wireless sensor 51 is an infrared activity sensor that detects the power drawn by the air conditioning unit
Air conditioning unit management system. In claim 2,
At least one wireless sensor 51 detects any one or a combination of temperature, humidity, electromagnetic radiation, or operation
Air conditioning unit management system. In claim 1,
The controller 12 includes at least one signal transmitter for transmitting signals to the air conditioning unit
Air conditioning unit management system. In claim 1,
The controller 12 is provided with a module for measuring the power of the air conditioning unit
Air conditioning unit management system. In claim 1,
The controller 12 is configured to learn the energy consumption of the air conditioning unit so that the air conditioning unit can operate at an optimum level.
Air conditioning unit management system. In claim 1,
The controller 12 is configured to receive network support
Air conditioning unit management system. In claim 8,
Network support is a wireless network
Air conditioning unit management system. In claim 1,
The controller 12 is configured to allow access from a remote system
Air conditioning unit management system. In claim 1,
The controller 12 is configured to control the temperature
Air conditioning unit management system. In claim 1,
The controller 12 is configured to have a predetermined operating schedule
Air conditioning unit management system. In claim 1,
The controller 12 is configured to be flexible in predetermining the operating state.
Air conditioning unit management system. In claim 1,
The controller 12 is provided with a user interface that receives input from the user and displays information.
Air conditioning unit management system. In claim 1,
The air conditioning unit is any one of an air conditioning unit, a distributed air conditioning unit, a ceiling fan unit, a wall mounted fan unit, or a tower fan unit.
Air conditioning unit management system. In claim 1,
The system is driven by a 2-wire wiring circuit.
Air conditioning unit management system. In claim 1,
The system is driven by a 3-wire wiring circuit.
Air conditioning unit management system. As a controller that controls the air conditioning unit,
At least one wireless sensor 51 that senses a signal from the air conditioning unit;
At least one transmitter (53) for transmitting a signal to the air conditioning unit; And
A user interface 54 for receiving input from a user and displaying information;
The controller includes at least one wireless sensor 51 for managing the air conditioning unit to enable two-way communication between the air conditioning unit and the controller 12, and the controller 12 is a single controller A remote control function for controlling an operating state and an operation mode within the power supply, and a power supply for controlling a power state in an 'ON' state or an 'OFF' state of a power switch controlling power supply to the air conditioning unit It is configured to have a switch function,
The controller 12 is configured to sense the power drawn by the air conditioning unit
A controller that controls the air conditioning unit. In claim 18,
Configured to have a power measurement function that measures the power drawn by the air conditioning unit
A controller that controls the air conditioning unit. In claim 18,
Equipped with a power detector function for detecting the power drawn by the air conditioning unit
A controller that controls the air conditioning unit. In claim 18,
The at least one wireless sensor 51 is capable of detecting any one or a combination of operation, temperature, visible light and humidity
A controller that controls the air conditioning unit. In claim 18,
The at least one signal transmitter 53 transmits an infrared signal
A controller that controls the air conditioning unit. In claim 18,
The controller 31 is configured to learn the energy consumption of the air conditioning unit so as to operate the air conditioning unit at an optimum level.
A controller that controls the air conditioning unit.

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