KR101084156B1 - Illumination and air-conditioning system - Google Patents

Abstract

PURPOSE: A lighting and air conditioning system is provided to increase the convenience of a user indoors by connecting a lighting device to an air conditioning system. CONSTITUTION: A lighting and air conditioning system includes one or more indoor device(11-19), a lighting device, a smart meter, and an energy managing device(30). The smart meter receives information about variable electric charges peak time. The energy managing device two-way communicates with the smart meter and controls the indoor device and the lighting device based on the electric charges peak time. The lighting and air conditioning system is installed at an air conditioning area. A heat sensor obtains heat information about the air conditioning area or one or more heat sources within an air conditioning space.

Description

Lighting and air conditioning system {ILLUMINATION AND AIR-CONDITIONING SYSTEM}

The present invention relates to a lighting and air conditioning system, and in particular, to control the operation of the lighting and air conditioning system based on the electricity rate that varies depending on the time zone to reduce the electricity bill generated by the operation of the lighting and air conditioning system It relates to a lighting and air conditioning system that can be.

Electric power for the operation of electrical appliances such as home appliances used in homes or office equipment used in offices is generally supplied through a power plant operated by KEPCO, a transmission line, and a wiring line. It is characteristic.

It has the characteristics of a central power source, not a distributed power source, a radial structure that spreads from the center to the periphery, and is characterized by a unidirectional supplier center rather than a consumer center.

In addition, the technology base is analog or electromechanical, there is a problem that must be restored manually in case of an accident, and the equipment must also be restored manually.

The price information of electricity was not only known in real time, but was limitedly known through the power exchange, and the price system also included electricity price peak time zone, which is a time-varying time and the most expensive time period. Although some peak hours are being implemented in each sector, there is a problem that incentives such as incentives to consumers through price changes cannot be used.

In order to solve these problems and improve energy efficiency, research on smart grids (intelligent power grids) has been actively conducted recently.

The smart grid refers to the next generation power system and its management system that are realized through the convergence and complex of modern power technology and information communication technology.

As mentioned above, the current grid is a centralized, producer-controlled, vertical, centralized network, whereas the smart grid is less focused on suppliers and horizontal, collaborative to enable interaction between consumers and suppliers. It is an enemy, decentralized network.

The smart grid is sometimes called the "energy internet" because all electrical devices, power storage devices and distributed power supplies are networked to enable interaction between consumers and suppliers.

On the other hand, when the use of electrical appliances in real time to determine the electricity bill, to recognize the peak time of the electricity bill, and to avoid the use of electrical appliances at that time as much as possible in the electrical appliances and control method that can save the electricity bill The need has been raised.

In particular, the electric charges generated by the operation of the air conditioning system make up a large proportion of the electric charges generated at home or industrial sites. There has been a need for a system control method.

In addition, since the air conditioning space in which the air conditioning system operates is generally overlapped with the lighting area in which the lighting device operates, the air conditioning system and the lighting device are interlocked so as to turn on / off one of the air conditioning system and the lighting device. Accordingly, there has been a need for a system that can reduce the electric charges generated from lighting devices and air conditioning systems while increasing the convenience of indoor living in the air conditioning space by controlling the on / off of the remaining devices. .

An object of the present invention is to provide an air conditioning system that can reduce the electric charges generated from the air conditioning system.

In addition, another object of the present invention to provide a lighting and air conditioning system that can operate in conjunction with the lighting device and the air conditioning system.

In addition, another object of the present invention is to provide an air conditioning system that can reduce the electric charge generated from the lighting device and the air conditioning system.

The present invention for achieving the object of the present invention, one or more indoor unit is installed in one or more air conditioning space; An illumination device installed in an air conditioning space in which the indoor unit is installed and operating in association with the indoor unit; A smart meter for receiving information from an electric power source about an electric charge peak time system including an electric charge peak time period in which an electric charge varies according to a time zone; And an energy management device for bi-directional data communication with the smart meter and controlling the indoor unit and the lighting device based on the information on the electric charge peak time system, wherein the air conditioning space is divided into a plurality of air conditioning regions, The indoor unit and the lighting apparatus are lighting and air conditioning systems provided in at least one of the air conditioning area.

Another object of the present invention for achieving the object of the present invention, one or more indoor units installed in one or more air conditioning space; A smart meter for receiving information from an electric power source about an electric charge peak time system including an electric charge peak time period in which an electric charge varies according to a time zone; And an energy management device for bi-directional data communication with the smart meter and controlling the indoor unit based on the information on the electric charge peak time system, wherein the air conditioning space is divided into a plurality of air conditioning regions. At least one air conditioning system provided in the air conditioning area.

According to the problem solving means of the present invention, the present invention has an effect that can reduce the electric charge generated from the air conditioning system. In addition, the present invention can operate in conjunction with the lighting device and the air conditioning system, while increasing the convenience of the user's indoor living in the air conditioning space at the same time can reduce the electric charges generated from the lighting device and the air conditioning system Has an effect. In addition, the present invention can adjust the air conditioning conditions by dividing one air conditioning space into a plurality of air conditioning zones, and consumed due to unnecessary operation of the lighting device and / or air conditioning system in the air conditioning zone where no heat source (or user) exists. It has the effect of preventing waste of power.

1 is a schematic diagram of a smart grid.
2 is a schematic diagram of a power supply network system according to the present invention.
3 is a graph of the electric charge received by the smart meter to the energy management device.
4 is a schematic block diagram of an energy management apparatus according to the present invention.
5 is a schematic diagram of an air conditioning space and an air conditioning area in which air conditioning conditions are controlled by the air conditioning system of the present invention.
6A and 6B are schematic diagrams illustrating a control method of an illumination system and an air conditioning system when a specific air conditioning area is designated.
7A and 7B are schematic diagrams illustrating a control method of an illumination system and an air conditioning system when a specific air conditioning area is not designated.
8A and 8B are schematic diagrams illustrating a smart control mode of the lighting system and the air conditioning system according to the first embodiment in the case of the electric charge peak time range.
9A and 9B are schematic diagrams illustrating a smart control mode of the lighting system and the air conditioning system according to the second embodiment in the case of the electric charge peak time range.
10A and 10B are schematic diagrams illustrating a smart control mode of the lighting system and the air conditioning system according to the third embodiment in the case of the electric charge peak time period.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. For reference, in describing the embodiments of the present invention, if it is determined that a detailed description of a related known function or configuration may make the gist of the present invention unclear, the detailed description thereof will be omitted.

1 is a schematic diagram of a smart grid, a smart grid includes a power plant that generates power through thermal power, nuclear power or hydropower, and a solar power plant and a wind power plant using solar or wind power as renewable energy.

In addition, the thermal power plant or nuclear power plant or hydroelectric power station transmits power to a power station through a transmission line, and the power station sends electricity to a substation so that the electricity is distributed to a demand destination such as a home or an office.

The electricity produced by the renewable energy is also sent to substations to be distributed to each customer. Then, the electricity transmitted from the substation is distributed to the office or each home via the power storage device.

Even in homes that use a home area network (HAN), they can produce their own electricity through fuel cells mounted on solar or PHEV plug-in hybrid electric vehicles. Electricity can also be sold outside.

In addition, the smart measuring device is installed in the office or home to identify the real-time power and electricity bills used at each demand source. Through this, the user recognizes the amount of electricity and the electricity bill currently used, and according to the situation, the power consumption or the electricity bill according to the situation. Measures to reduce the

On the other hand, since the power plant, power station, storage device and the source of demand are bidirectional communication, only the unilaterally receive electricity from the source of demand, and notify the storage, power station, and power plant of the demand source to produce electricity according to the situation of the source of demand. Electric distribution can be performed.

Meanwhile, in the smart grid, an energy management system 30 (EMS) that is responsible for real-time power management and real-time prediction of power consumption of a demand destination, and a measurement device (AMI) that measures power consumption in real time ) Plays a pivotal role.

Here, the measuring device under the smart grid is a basic technology for integrating consumers on the basis of open architecture, and provides consumers with the ability to efficiently use electricity, and provides power providers with the ability to operate the system efficiently by detecting problems in the system. do.

Here, the open architecture, unlike a general communication network, refers to a standard that allows all electric devices to be connected to each other regardless of which manufacturer the electric device is manufactured in a smart grid system.

Thus, the instrumentation used in the smart grid enables a consumer friendly efficiency concept such as "Prices to Devices."

That is, the real-time price signal of the power market is relayed through the energy management device (EMS) 30 installed in each home, and the energy management device (EMS) 30 communicates with each electric device and controls the user. By looking at the management device (EMS) 30, the power information of each electric device is recognized, and based on this, power information processing such as power consumption or electric charge limit setting can be performed, thereby saving energy and cost.

The energy management device (EMS) is a local energy management device (EMS) 30 used in the office or home and the local energy management device (EMS) (EMS) (two-way communication with the local energy management device (EMS) 30) It is preferably composed of a central energy management device (EMS) for processing the information collected in 30).

Real-time communication of power information between suppliers and consumers can be realized in the smart grid, realizing “real-time grid response”, thereby reducing the high cost of meeting peak demand.

2 illustrates a power supply network system 10 in a home, which is a major consumer of a smart grid.

The power supply network system 10 includes a measurement device (or smart meter) 20 capable of measuring in real time power and electricity rates, power consumption peak time intervals, or electricity rate peak time intervals supplied to each home, and the measurement. An energy management device (EMS) 30 is connected to a device (smart meter) 20 and connected to a plurality of electric devices such as home appliances and controlling their operation.

Here, the energy management device (EMS) 30 has a screen 31 for displaying the current state of electricity consumption and the external environment (temperature, humidity), and provides an input button 32 or the like which can be operated by a user. It is preferably provided in the form of a terminal provided.

The energy management device (EMS) 30 again controls the air conditioning system through the refrigerator 101, the washing machine and the dryer 102, the air conditioning system 110, and the air conditioning system through a home network. In addition, it is connected to an electrical appliance such as a remote controller charger 130, a lighting device 140, a TV 105, or a cooking appliance 104, which charges the remote controller 120, thereby performing two-way communication with them.

Communication inside the house may be via wireless or wired such as PLC (Power Line Communication).

In addition, it is preferable that the electrical appliances are arranged to be connected to other electrical appliances so that communication is possible.

3 is a graph of the electric charge received by the smart meter to the energy management device. Specifically, FIG. 3 shows a graph of a change in electricity rates over time or over time provided from a power supply. This is an exemplary graph, and the present invention is not limited thereto.

As shown in FIG. 3, the information on the electricity rate provided from the power supply includes an electricity rate peak time period that varies with time zones. Here, the electricity tariff peak time system is an electric tariff system including an electric tariff peak time period (Δt _peak ), which is a time when the electric tariff is variable according to the time zone and the electric demand is expected to be high, and the tariff becomes the highest value of the day.

The smart meter 20 receives information (ie, a graph of the electric charge as shown in FIG. 3) regarding the change of the electric charge over time or over time. As shown in the graph of FIG. 3, the time period when the electric charge becomes the maximum value of the day becomes the electric charge peak time period Δt _peak . Information on the electric charge received by the smart meter 20 is transmitted to the energy management device 30 in a communication manner.

4 is a schematic block diagram of an energy management apparatus 30 according to the present invention.

As shown in FIG. 4, the energy management apparatus 30 according to the present invention includes a bidirectional communication with a power supply source and a smart meter 20 for measuring and displaying power information in real time and a communication module for bidirectionally communicating with an electric product. 39, an input unit 31 for inputting setting information by the user (ie, receiving an input force signal of the user), power information of the smart meter 20 received through the communication module 39, or the electricity Receives the setting information (ie, the user's input signal), the power information or the information about the electrical product through the display unit 35, the input unit 31 or the communication unit for displaying information about the product, the display unit 35 and a control unit 33 for controlling the operation of the electrical appliance. In addition, the energy management device 30 may include a memory 37 in which control commands or programs for indoor units (for example, I1 to I9) and / or lighting devices (for example, L1 to L9) are stored. have.

Here, preferably, the control unit 33 of the energy management device 30 may control the display unit 35 to graphically provide the setting information, the power information or the information about the electrical appliance to the user. .

5 is a schematic diagram of an air-conditioning space (AS) and an air-conditioning area (AA) in which air conditioning conditions are controlled by the air conditioning system 110 of the present invention.

Here, the air conditioning space AS refers to a space in which air conditioning conditions are controlled by the operation of the air conditioning system 110, and the air conditioning area AA is an area in which one air conditioning space AS is divided into an energy management apparatus ( This is a space set virtually for control.

For example, the air conditioning space AS may be one enclosed space, and a plurality of air conditioning regions AA separated in the air conditioning space AS may be open spaces.

One or more indoor units (for example, I1 to I9) and / or one or more lighting devices 140 (for example, L1 to L9) may be installed in the air conditioning space AS.

The energy management device 30 divides and controls the air conditioning space AS into a plurality of air conditioning regions AA, so that the energy management device 30 is installed in the air conditioning region AA in which the heat source U or the user does not exist in the air conditioning space AS. The indoor unit and / or the lighting device 140 may be stopped to prevent unnecessary electric charges from occurring.

6A and 6B are schematic views illustrating a control method of the lighting and air conditioning system 110 when a specific air conditioning area AA is designated.

As shown in Figure 6a and 6b, the lighting and air conditioning system according to the present invention, one or more indoor units (for example, I1 to I9) installed in one or more air conditioning space (AS); An illumination device 140 (for example, L1 to L9) installed in an air conditioning space (AS) in which the indoor unit is installed and operating in association with the indoor unit; A smart meter 20 for receiving information about an electricity rate peak time system including an electricity rate peak time period, wherein the electricity rate is variable according to a time zone from a power supply source; And an energy management device 30 for bi-directional data communication with the smart meter 20 and controlling the indoor unit and the lighting device 140 based on the information on the electric charge peak time system.

The air conditioning space AS may be divided into a plurality of air conditioning regions AA, and the indoor unit and the lighting device 140 may be provided at least one in the air conditioning region AA.

That is, the energy management device 30 may control at least one indoor unit and / or lighting device 140 installed in the plurality of air conditioning areas AA for each air conditioning area AA. In addition, the energy management device 30 receives the user's input signal through the input unit 31 of the energy management device 30 to set up at least one air conditioning area AA of the plurality of air conditioning areas AA. It can be specified as an area AA.

Here, the setting air conditioning area AA is an air conditioning area AA controlled by the energy management device 30 so that the lighting device 140 and the air conditioning system 110 operate in conjunction with each other. For example, the energy management device 30 may include at least one of the indoor unit and the lighting device 140 installed in the air conditioning area AA designated as the set air conditioning area AA through the input unit 31 of the energy management device 30. When the device is turned on (or vice versa off), the indoor unit and the lighting device 140 may be controlled such that the other device is turned on (or vice versa off) at the same time.

As shown in FIG. 6A, a user sets an air conditioning area AA of at least one of the air conditioning areas AA in the notification space through the input unit 31 of the energy management device 30 (FIG. (See hatching section 6). For example, referring to FIG. 6, the user may use the L2 lighting device and the I2 indoor device, the L3 lighting device and the I3 indoor device, and the L5 lighting device in an air conditioning space (AS) in which the L1 lighting device to the L9 lighting device and the I1 indoor unit to the I9 indoor device are installed. The air conditioning area (AA) in which the device and the I5 indoor unit, the L6 lighting unit and the I6 indoor unit are set as the setting air conditioning area (AA), the L2 lighting unit and the I2 indoor unit, the L3 lighting unit and the I3 indoor unit, the L5 lighting unit and the I5 indoor unit The L6 lighting unit and the I6 indoor unit can be set to operate in conjunction with each other.

After the user designates the setting air conditioning area AA through the energy management device 30, as shown in FIG. 6B, the user inputs the input unit 31 of the energy management device 30, the input unit 31 of the indoor unit, or When one of the indoor unit or the lighting device 140 in the setting air conditioning area AA is operated by using the power button of the lighting device 140, the energy management device 30 is located in which one operated device is located. The remaining devices can be controlled to operate the remaining devices in the air conditioning area AA.

7A and 7B are schematic views illustrating a control method of the lighting system and the air conditioning system 110 when a specific air conditioning area AA is not designated.

As shown in Figure 7a and 7b, the lighting and air conditioning system according to the present invention, one or more indoor units (for example, I1 to I9), the indoor unit is installed in the air conditioning space (AS) where the indoor unit is installed Illumination device 140 (for example, L1 to L9) that works in conjunction with, smart meter for receiving information about the electricity rate peak time system, including the electricity rate peak time zone that the electricity rate is variable according to the time zone from the power supply 20, an energy management device 30 for bidirectional data communication with the smart meter 20 and controlling the indoor unit and the lighting device 140 based on the information on the electric charge peak time system. have. In addition, the lighting and air conditioning system according to the present invention may further include at least one or more heat sensing units 150 installed in the air conditioning area AA or installed in at least one of the indoor unit or the lighting device 140. Can be.

The heat sensing unit 150 may obtain information about one or more heat sources U (eg, a user or a patient) in the air conditioning area AA or the air conditioning space AS. Here, the information about the heat source (U) is the position of the heat source (U) in the air conditioning space (AS) or the air conditioning area (AA), the direction of the heat source (U), or the distance of the heat source (U), or the air conditioning space At least one of the quantity of the heat source (U) in the (AS), the residence time of the heat source. The heat detection unit 150 may be preferably an infrared sensor.

The heat sensing unit 150 may be installed in the indoor unit as shown in FIGS. 7A and 7B. Alternatively, the heat sensing unit 150 may be installed between the plurality of air conditioning spaces AS in the air conditioning space AS. For example, one heat sensing unit 150 may be installed between two air conditioning areas AA or may be installed at the contacts of four air conditioning areas AA. Thus, by installing the heat sensing unit 150 between the plurality of air conditioning area (AA), it is possible to reduce the number of heat sensing unit 150 necessary to obtain information about the heat source (U), lighting and air conditioning The manufacturing cost of the system can be reduced.

The heat sensing unit 150 may obtain information about the heat source U and transmit the information about the heat source U to the energy management device 30. At this time, the energy management device 30 is the lighting device 140 and the indoor unit to operate the lighting device 140 and the indoor unit located in the set air conditioning area AA based on the information on the heat source (U). The indoor unit can be controlled.

The energy management device 30 sets and controls only the air conditioning area AA in which the heat source U is located among the plurality of air conditioning areas AA based on the information about the heat source U obtained from the heat sensing unit 150. Designated as an area AA or at least one of an air conditioning area AA in which the heat source U is located and one or more air conditioning areas AA around the air conditioning area AA in which the heat source U is located. It can be specified as the setting air conditioning area AA.

Here, the setting air conditioning area AA means an air conditioning area AA in which one or more indoor units and / or lighting devices 140 installed in the air conditioning area AA in which the heat source U exists are operated. In this case, the indoor unit and the lighting device 140 may be linked at the same time or at a time interval within the set air conditioning area AA.

In addition, the energy management device 30 may control the indoor unit and / or the lighting device 140 such that the set air conditioning area AA changes as the heat source U moves in the air conditioning space AS. For example, as shown in FIG. 7A, the energy management device when the heat source U (for example, the user or the occupant) is located in the air conditioning area AA in which the I8 indoor unit and the L8 lighting device 140 are located. The indoor unit 30 and the lighting unit 140 of the air conditioning area AA where the heat source U is located, as well as the indoor units and lighting of the air conditioning area AA around the air conditioning area AA where the heat source U is located. The device 140 may also control the indoor unit and the lighting device 140 to operate simultaneously. Subsequently, as shown in FIG. 7B, when the heat source U (for example, the user or the occupant) moves to the air conditioning area AA where the I5 indoor unit and the L5 lighting device 140 are located, energy management is performed. The device 30 is installed in the surrounding air conditioning area AA of the I5 indoor unit and the L5 lighting unit 140 where the heat source U is located, and the air conditioning area AA in which the I5 indoor unit and the L5 lighting unit 140 exist. The indoor unit and the lighting device 140 may be controlled to operate the I2 indoor unit and the L2 lighting device 140, the I3 indoor unit and the L3 lighting device 140, the I6 indoor unit and the L6 lighting device 140. In this way, by stopping the lighting device 140 and the indoor unit installed in the air conditioning area AA in which the heat source U does not exist or do not affect the heat source U, it is possible to prevent unnecessary operation and waste of power. have.

Hereinafter, the operation of the energy management device 30 for controlling the indoor unit and / or the lighting device 140 so that the energy management device 30 can reduce the electric charges generated from the lighting and air conditioning system. Shall be.

If the heat source (U) is a occupant, the occupant must pass through the air conditioning area (AA) other than the target air conditioning area (AA) in order to reach the target air conditioning area (AA), in which case energy management The device 30 determines only the presence or absence of the heat source U in the air conditioning area AA from the heat sensing unit 150 to operate the indoor unit and / or the lighting device 140 of the air conditioning area AA through which the occupants pass. Stops, unnecessary power waste occurs.

In order to prevent this, the energy management device 30 receives the information on the heat source (U) from the heat sensing unit 150. Thereafter, the energy management device 30 detects a residence time in the set air conditioning area AA of the heat source U based on the information about the heat source U. Thereafter, the energy management device 30 may control the lighting device 140 and the indoor unit to operate the lighting device 140 and the indoor unit when the residence time is more than a predetermined time.

As such, when the occupants reach the air conditioning area AA to be targeted and the occupant's residence time is more than a predetermined time, the air conditioning area AA to be aimed or the air conditioning area AA to be targeted and the surrounding air conditioning area ( By operating the indoor unit and / or the lighting device 140 installed in AA), the indoor unit and the lighting device 140 of the air conditioning area AA passing through to reach the target air conditioning area AA to be carried out by the occupant do not operate. While avoiding unnecessary power consumption, the indoor life of the occupant is conveniently operated by operating only the indoor unit and / or the lighting device 140 in the air conditioning area AA where the occupants are present (and / or in the surrounding air conditioning area AA). It can be done.

As another additional embodiment for preventing unnecessary power waste, the energy management device 30 is based on the information on the heat source (U) of the heat sensing unit 150, the heat source (U) in the set air conditioning area (AA). When detected, the lighting device 140 is controlled to operate the lighting device 140 located in the set air conditioning area AA of the heat source U, and the set air conditioning area AA of the heat source U is operated. The indoor unit may be controlled to operate the indoor unit when the residence time within the predetermined time is more than a predetermined time.

As the energy management device 30 controls the indoor unit and / or the lighting device 140 as described above, it is possible to secure a field of view while moving to the air conditioning area AA that the occupants want to target in the dark or at night. For example, the operation of the indoor unit and / or the lighting device 140 existing in the air conditioning area AA other than the target air conditioning area AA may be prevented from unnecessary waste of power.

As a still further embodiment to prevent unnecessary power waste, the energy management device 30 is based on the information on the heat source (U), when the heat source (U) is detected in the set air conditioning area (AA) The lighting device 140 is controlled such that the lighting device 140 positioned in the set air conditioning area AA of the heat source U is operated at a first predetermined light amount, and the set air conditioning area of the heat source U is controlled. The indoor unit and the lighting device 140 are controlled to operate the indoor unit when the residence time in AA is greater than or equal to a predetermined time and to operate the lighting device 140 at a second light amount lower than the first light amount. You may.

Hereinafter, the process of the energy management device 30 to operate the lighting and air conditioning system in the smart control mode will be described. Specifically, when the energy management device 30 determines from the smart meter 20 that the current time is the peak time period of the electricity bill, as shown in FIG. 3, the energy management device 30 is controlled from the lighting and air conditioning system. Control lighting and air conditioning systems to reduce electricity bills generated.

8A and 8B are schematic diagrams showing a smart control mode of the lighting system and the air conditioning system 110 according to the first embodiment in the case of the electric charge peak time period.

The energy management device 30 may designate one or more set air conditioning areas AA by the user's input signal through the input unit 31, or may provide information on the heat source U obtained through the heat detection unit 150. Based on this, one or more setting air conditioning areas AA are designated. Subsequently, the energy management device 30 is located in the set air conditioning area AA when it is determined that the current time is the electric tariff peak time period based on the information on the electric tariff peak time system received from the smart meter 20. The indoor unit may be controlled such that the indoor unit of the indoor unit, which is operated in a first preset operating state, is operated in a second operating state in which power consumption is lower than that of the first operating state.

In this case, the lighting device 140 located in the air conditioning area AA in which the indoor unit operating in the first operating state may be operated in conjunction with the indoor unit.

Here, the first operating state and / or the second operating state is the set temperature of the air conditioning system 110, the air volume of the air conditioning system 110, or the operating frequency of the compressor included in the air conditioning system 110 It may be at least one of.

For example, as shown in FIG. 8A, the energy management device 30 may include the I2 indoor unit, the I3 indoor unit, the I5 indoor unit, which are operating within the set air conditioning area AA when the current time is a time zone other than the electric charge peak time zone. The I6 indoor unit is controlled to operate with the first air volume having a large power consumption.

Subsequently, when the energy management apparatus 30 determines that the current time is the electric tariff peak time period based on the information on the electric tariff peak time system received from the smart meter 20, as shown in FIG. 8B, the energy The management device 30 operates the I2 indoor unit, the I3 indoor unit, the I5 indoor unit, the I2 indoor unit, the I3 indoor unit, the I5 indoor unit, or the I6 indoor unit so that the indoor unit is operated by lowering the air flow rate to a second air volume with less power consumption than the first air volume. Control the I6 indoor unit.

9A and 9B are schematic diagrams illustrating a smart control mode of the lighting system and the air conditioning system 110 according to the second embodiment in the case of the electric charge peak time period.

The energy management device 30 may designate one or more set air conditioning areas AA by the user's input signal through the input unit 31, or may provide information on the heat source U obtained through the heat detection unit 150. Based on this, one or more setting air conditioning areas AA are designated. Subsequently, when the energy management device 30 determines that the current time is the electric tariff peak time period based on the information on the electric tariff peak time system received from the smart meter 20, the heat source (A) of the air conditioning area AA is set. The lighting device 140 and the indoor unit may be controlled to operate only the lighting device 140 and the indoor unit positioned in the setting air conditioning area AA where U) is located. That is, the energy management device 30 is designated by the user's input signal through the input unit 31 of the energy management device 30 or the heat source through the heat detection unit 150 when the current time is the electric charge peak time zone. Based on the information on U), only the lighting device 140 and the indoor unit positioned in the setting air conditioning area AA in which the heat source U is located among the at least one or more setting air conditioning areas AA specified are operated, and at the same time, the heat source ( The lighting device 140 and the indoor unit are controlled to stop all of the lighting unit 140 and the indoor unit other than the indoor unit and the lighting unit 140 located in the setting air conditioning area AA where U) is located.

For example, as shown in FIG. 9A, the energy management device 30 may include the I2 indoor unit, the I3 indoor unit, the I5 indoor unit, which are operating within the set air conditioning area AA when the current time is a time zone other than the electric charge peak time zone. The indoor unit and / or the lighting device 140 are controlled to operate the I6 indoor unit and the L2 lighting device 140, the L3 lighting device 140, the L5 lighting device 140, and the L6 lighting device 140.

Subsequently, when the energy management apparatus 30 determines that the current time is the electric tariff peak time period based on the information on the electric tariff peak time system received from the smart meter 20, as shown in FIG. 9B, the energy The management device 30 controls the indoor unit and / or the lighting device 140 to operate only the I5 indoor unit and the L5 lighting unit 140 in the air conditioning area AA in which the heat source U exists, and the remaining indoor unit I2 indoor unit, The indoor unit and the lighting device 140 are controlled such that the L2 lighting device 140, the L3 lighting device 140, and the L6 lighting device 140 which are the I3 indoor unit, the I6 indoor unit, and the remaining lighting devices 140 are stopped.

10A and 10B are schematic diagrams illustrating a smart control mode of the lighting system and the air conditioning system 110 according to the third embodiment in the case of the electric charge peak time period.

The energy management device 30 may designate one or more set air conditioning areas AA by the user's input signal through the input unit 31, or may provide information on the heat source U obtained through the heat detection unit 150. Based on this, one or more setting air conditioning areas AA are designated. Subsequently, the energy management device 30 is located in the set air conditioning area AA when it is determined that the current time is the electric tariff peak time period based on the information on the electric tariff peak time system received from the smart meter 20. The lighting device 140 is controlled so that the lighting device 140 which is operated at a predetermined first light amount of the indoor unit is operated at a second light amount lower than the first light amount (ie, lower power consumption than the first light amount). can do.

At this time, the indoor unit located in the air conditioning area AA in which the lighting device 140 operated by the first light amount may be operated in conjunction with the lighting device 140.

For example, as shown in FIG. 10A, the energy management device 30 includes an I2 indoor unit, an I3 indoor unit, an I5 indoor unit that is operating within the set air conditioning area AA when the current time is a time zone other than the peak electricity tariff time period. The I6 indoor unit is controlled to operate with the first amount of light having high power consumption.

Subsequently, when the energy management apparatus 30 determines that the current time is the electric tariff peak time period based on the information on the electric tariff peak time system received from the smart meter 20, as shown in FIG. 8B, the energy The management device 30 is the L2 lighting device 140, L3 lighting device 140, L5 lighting device 140, L6 lighting device 140 in operation is a second light amount of less power consumption than the first light amount. The L2 lighting device 140, the L3 lighting device 140, the L5 lighting device 140, and the L6 lighting device 140 are controlled to operate by lowering the amount of light.

In the above, the lighting and air conditioning system in which the lighting device 140 and the air conditioning system 110 are operated in conjunction with each other has been described, but the air conditioning system 110 without the lighting device 140 is located in the air conditioning space AS. Even if present, the energy management device 30 may control the air conditioning system 110 similarly to the above-described lighting and air conditioning system.

To this end, the air conditioning system 110 according to the present invention includes one or more indoor units installed in one or more air conditioning spaces (AS); A smart meter 20 for receiving information about an electricity rate peak time system including an electricity rate peak time period, wherein the electricity rate is variable according to a time zone from a power supply source; And an energy management device 30 for bi-directional data communication with the smart meter 20 and controlling the indoor unit based on the information on the electric charge peak time system. Here, the air conditioning space AS is divided into a plurality of air conditioning regions AA, and the indoor unit is provided in at least one of the air conditioning regions AA.

Preferably, the air conditioning system 110 may include at least one heat sensing unit 150 installed in at least one of an air conditioning space AS, an air conditioning area AA, or an indoor unit. The heat sensing unit 150 may obtain information about one or more heat sources U in the air conditioning area AA or the air conditioning space AS.

The heat sensing unit 150 may be installed between the plurality of air conditioning areas AA in the air conditioning space AS in order to reduce the manufacturing cost of the air conditioning system 110.

In the air conditioning system 110 according to the present invention, the energy management device 30 is the heat source (U) of the plurality of air conditioning area (AA) based on the information on the heat source (U) obtained from the heat detection unit 150. At least one of the air conditioning area AA where) is located or one or more air conditioning areas AA around the air conditioning area AA where the heat source U is located may be designated as the setting air conditioning area AA.

Then, in order to prevent unnecessary power is wasted from the air conditioning system 110, the energy management device 30 is based on the information on the heat source (U) the indoor unit located in the set air conditioning area (AA) The indoor unit may be controlled to operate, or the energy management apparatus 30 may have a residence time within the set air conditioning area AA of the heat source U based on the information about the heat source U. In this case, the indoor unit may be controlled to operate the indoor unit.

In addition, the energy management device 30 is based on the information on the heat source (U), when the heat source (U) is detected in the set air conditioning area (AA) the set air conditioning area (AA) of the heat source (U) ) Control the indoor unit so that the indoor unit positioned in the main unit is operated in a first preset operating state, and the indoor unit is operated when the residence time in the set air conditioning area AA of the heat source U is equal to or greater than a preset time. The indoor unit may be controlled to operate to operate in a second operating state in which power consumption is lower than that of the first operating state.

In the air conditioning system 110 according to the present invention, the energy management device 30 may control the air conditioning system 110 in the smart control mode as in the above-described lighting and air conditioning system.

Specifically, the energy management device 30 is specified by the user's input signal through the input unit 31 or the information on the heat source (U) through the heat detection unit 150 when the current time is the electric charge peak time zone. The indoor unit may be controlled such that only the indoor unit located in the setting air conditioning area AA in which the heat source U is located is operated among the at least one set air conditioning area AA specified.

Alternatively, when the current time is the electric charge peak time period, the energy management device 30 is designated by the user's input signal through the input unit 31 or based on the information about the heat source U through the heat sensing unit 150. Control the indoor unit such that the indoor unit which is operated in the first preset operating state among the indoor units positioned in the at least one designated air conditioning area AA is operated in a second operating state in which the power consumption is lower than the first operating state. Can be.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the above-described embodiments, and the general knowledge in the field of the present invention without departing from the gist of the present invention as claimed in the following claims. Anyone with a variety of modifications are possible, of course, such modifications are within the scope of the claims.

20: smart meter 30: energy management device
110: air conditioning system 140: lighting device
150: heat detection unit

Claims (25)

One or more indoor units installed in one or more air conditioning spaces;
An illumination device installed in an air conditioning space in which the indoor unit is installed and operating in association with the indoor unit;
A smart meter for receiving information from an electric power source about an electric charge peak time system including an electric charge peak time period in which an electric charge varies according to a time zone; And
And an energy management device for bidirectional data communication with the smart meter and controlling the indoor unit and the lighting device based on the information on the electric charge peak time system.
The air conditioning space is divided into a plurality of air conditioning region, the indoor unit and the lighting device is at least one or more provided in the air conditioning region lighting and air conditioning system. The method of claim 1,
The energy management device receives an input signal from a user through an input unit, and designates at least one or more air conditioning zones of the plurality of air conditioning zones as a predetermined air conditioning zone. The method of claim 2,
The energy management device receives the user's input signal through an input unit and controls the lighting device and the indoor unit so that at least one of the lighting device or the indoor unit positioned in the set air conditioning area is operated in conjunction with the other. Characterized by lighting and air conditioning system. The method of claim 1,
And at least one heat sensing unit installed in at least one of the air conditioning area, the indoor unit, or the lighting device, and obtaining at least one heat source in the air conditioning area or the air conditioning space. Harmony system. The method of claim 4, wherein
And the heat sensing unit is installed between the plurality of air conditioning zones in the air conditioning space. The method of claim 4, wherein
The information on the heat source is at least one or more of the position of the heat source in the air conditioning space or the air conditioning area, the direction of the heat source, the distance of the heat source, or the quantity of the heat source in the air conditioning space. . The method of claim 4, wherein
The heat detection unit is an illumination and air conditioning system, characterized in that the infrared sensor. The method of claim 4, wherein
The energy management device designates at least one of the air conditioning area in which the heat source is located or the one or more air conditioning areas around the air conditioning area in which the heat source is located among the plurality of air conditioning areas as the setting air conditioning area based on the information on the heat source. Lighting and air conditioning system, characterized in that. The method of claim 8,
And the energy management device controls the lighting device and the indoor unit to operate the lighting device and the indoor unit located in the set air conditioning area based on the information on the heat source. The method of claim 8,
The energy management device controls the lighting device and the indoor unit to operate the lighting device and the indoor unit when the residence time in the set air conditioning area of the heat source is greater than or equal to a predetermined time based on the information on the heat source. Characterized by lighting and air conditioning system. The method of claim 8,
The energy management device controls the lighting device to operate a lighting device located in the set air conditioning area of the heat source based on the information on the heat source, when the heat source is detected in the set air conditioning area. And the indoor unit is controlled to operate the indoor unit when the residence time in the set air conditioning area is equal to or greater than a preset time. The method of claim 8,
The energy management device is configured to operate the lighting device such that the lighting device located in the set air conditioning area of the heat source is operated at a first predetermined amount of light when the heat source is detected in the set air conditioning area based on the information on the heat source. And control the indoor unit and the lighting device such that the indoor unit is operated when the residence time in the set air conditioning area of the heat source is equal to or greater than a predetermined time and the lighting device is operated at a second light amount lower than the first light amount. Lighting and air conditioning system, characterized in that for controlling. The method of claim 1,
When the current time is the peak electricity tariff time, the heat source is located in at least one or more setting air conditioning areas designated by the user's input signal through the input unit or specified based on the heat source information through the heat sensing unit. Lighting and air conditioning system, characterized in that for controlling the lighting device and the indoor unit so that only the lighting device and the indoor unit located in the setting air conditioning area. The method of claim 1,
The energy management device is one of indoor units located in at least one or more air conditioning zones specified by an input signal of a user through an input unit or specified based on information on a heat source through a heat detector when the current time is a peak electric charge period. Lighting and air conditioning system, characterized in that for controlling the indoor unit is operated in a second operating state, the indoor unit being operated in a first predetermined operating state is lower power consumption than the first operating state. The method of claim 14,
The first operating state and the second operating state is at least one of the set temperature of the air conditioning system, the air volume of the air conditioning system, or the operating frequency of the compressor included in the air conditioning system. . The method of claim 1,
The energy management device is one of indoor units located in at least one or more air conditioning zones specified by an input signal of a user through an input unit or specified based on information on a heat source through a heat detector when the current time is a peak electric charge period. The lighting and air conditioning system, characterized in that for controlling the lighting device to be operated at a second light amount lower than the first light amount is being operated at a predetermined first light amount. One or more indoor units installed in one or more air conditioning spaces;
A smart meter for receiving information from an electric power source about an electric charge peak time system including an electric charge peak time period in which an electric charge varies according to a time zone; And
And an energy management device for bidirectional data communication with the smart meter and controlling the indoor unit based on the information on the electric charge peak time system.
The air conditioning space is divided into a plurality of air conditioning zones, the indoor unit is provided with at least one air conditioning system in the air conditioning zone. The method of claim 17,
And at least one heat sensing unit installed in at least one of the air conditioning area or the indoor unit and obtaining information on at least one heat source in the air conditioning area or the air conditioning space. The method of claim 18,
And the heat sensing unit is disposed between the plurality of air conditioning zones in the air conditioning space. The method of claim 18,
The energy management device designates at least one of the air conditioning area in which the heat source is located or the one or more air conditioning areas around the air conditioning area in which the heat source is located among the plurality of air conditioning areas as the setting air conditioning area based on the information on the heat source. Air conditioning system, characterized in that. The method of claim 20,
And the energy management device controls the indoor unit to operate the indoor unit located in the set air conditioning area based on the information on the heat source. The method of claim 20,
And the energy management device controls the indoor unit so that the indoor unit is operated when the residence time of the heat source is greater than or equal to a predetermined time based on the information on the heat source. The method of claim 20,
The energy management device controls the indoor unit to operate an indoor unit located in the set air conditioning area of the heat source in a first preset operating state when the heat source is detected in the set air conditioning area based on the information on the heat source. And controlling the indoor unit so that the indoor unit is operated to operate in a second operating state in which the power consumption is lower than the first operating state when the residence time of the heat source is within a predetermined time period. Air conditioning system. The method of claim 17,
When the current time is the peak electricity tariff time, the heat source is located in at least one or more setting air conditioning areas designated by the user's input signal through the input unit or specified based on the heat source information through the heat sensing unit. And controlling the indoor unit so that only the indoor unit positioned in the setting air conditioning area is operated. The method of claim 17,
The energy management device is one of indoor units located in at least one or more air conditioning zones specified by an input signal of a user through an input unit or specified based on information on a heat source through a heat detector when the current time is a peak electric charge period. And an indoor unit operating in a first preset operating state to control the indoor unit to be operated in a second operating state in which power consumption is lower than that of the first operating state.

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